Controlling
Dangerous
Pathogens
A Prototype
Protective
Oversight
System
John Steinbruner
Elisa D. Harris
Nancy Gallagher
Stacy M. Okutani
��Controlling Dangerous Pathogens
A Prototype Protective Oversight System
John Steinbruner
Elisa D. Harris
Nancy Gallagher
Stacy M. Okutani
The Center for International and Security Studies at Maryland
Advanced Methods of Cooperative Security Program
The University of Maryland
College Park, Maryland
March 2007
��Acknowledgements
This� monograph� is� the� product� of� an� intensive� effort� by� a� diverse� group� of
scientists,� public� policy� experts,� and� lawyers� to� grapple� with� the� many
challenges�posed�by�advanced�biotechnology.�� We�are�particularly�grateful�to
Ron� Atlas,� Rocco� Casagrande,� Nancy� Connell,� Malcolm� Dando,� Christopher
Davis,�Neil�Davison,�Richard�Ebright,�Gerald�Fink,�Alex�Greninger,�Gigi�Kwik
Gronvall,�Peter�Jahrling,�Carl�Kaysen,�Barry�Kellman,�Shan�Lu,�Alan�Pearson,
Jens� Kuhn,� Piers� Millett,� Kathryn� Nixdorff,� Janet� Peterson,� David� Sabatini,
Richard�Spertzel,�Rob�Sprinkle,�Mark�Wheelis,�and�Simon�Whitby�who�have
contributed� enormously� to� our� deliberations� through� their� working� papers� or
presentations�at�project�workshops�in�the�United�States.�Their�participation�and
our� acknowledgement� does� not� imply� that� they� endorse� the� arguments� we
advance.�Some�have�major�disagreements.
Similarly,� we�also�have�benefited� greatly�from� the�presentations� given�at� our
regional�workshops�by�Ottorino�Cosivi,�Maria�Espona,�Roberto�Fernandez,�Jozef
Furesz,� Joxel� Garcia,� Walter� Mendoza,� Roque� Monteleone-Neto,� Kathryn
Nixdorff,�David�Sawaya,�Karl�Simpson,�Simone�Scholze,�Geoffrey�Smith,�Mario
Soberon,�and�Ana�Maria�Tapajos.��Special�mention�should�also�be�made�of�the
in-country�assistance�provded�by�Lajos�Rozsa�and�Jack�Woodall�in�organizing
our�regional�workshops.�� We�also�appreciate�the�time�many�other�individuals
have�devoted�to�attending�project�workshops�or�consulting�with�us�on�specific
aspects�of�the�project.
A�list�of�individuals�who�have�participated�in�one�or�more�of�the�U.S.-based
workshops� can� be� found� at� Appendix� A.��� A� list� of� individuals� who� have
participated� in� our� regional� workshops� can� be� found� at� Appendix� B.� Again,
inclusion�on�these�lists�should�not�be�taken�as�an�indication�that�the�individual
endorses� the� ideas� outlined� herein.�� Special� thanks� are� also� owed� to� Tim
Gulden,�Jason�Harenski,�Jessica�Mann�McCormick,�and�Gordon�McMillan�for
their�work�on�our�prototype�data�management�system�and�to�Marc�Caplan,�Paula
Harrison,� Andrea� Hoshmand,� Jennifer� Lindsey,� Robert� Maly,� Katie� Swanson,
and�Margot�Siemer�for�outstanding�research�and�administrative�support.
We�would�especially�like�to�acknowledge�the�financial�and�intellectual�support
of� the� Alfred� P.� Sloan,� Ford,� and� John� D.� and� Catherine� T.� MacArthur
Foundations� without� which� this� exploration� of� the� problem� of� controlling
dangerous�pathogens�would�not�have�been�possible.
��Table of Contents
Acknowledgements...................................................................................................i
Table�of�Contents.................................................................................................. iii
Introduction .............................................................................................................1
Context�of�the�Problem...........................................................................................3
Current�State�of�Oversight ......................................................................................9
International�Controls .........................................................................................9
US�Controls ......................................................................................................11
UK�Controls......................................................................................................15
Smallpox�Research............................................................................................18
Existing�Arrangements�and�the�BRSS..............................................................19
Elements�of�a�Prototype�Oversight�System..........................................................21
Defining�Research�of�Concern..........................................................................21
System�Architecture..........................................................................................26
Principles�and�Elements................................................................................27
Information�Disclosure .................................................................................29
Institutional�Arrangements............................................................................32
Compliance�and�Verification........................................................................35
The�System�in�Practice.....................................................................................37
Institutional�Review�–�Activities�of�Potential�Concern ...............................39
National�Review�–�Activities�of�Moderate�Concern....................................40
International�Review�–�Activities�of�Extreme�Concern...............................42
The�Way�Forward .................................................................................................45
Concluding�Observations ......................................................................................49
Appendix�A:�US-Based�Project�Workshop�Participants ......................................51
Appendix�B:�Regional�Workshop�Participants .....................................................57
Appendix�C:�Prototype�Data�Management�System:�Overview ............................61
Appendix�D:�Prototype�Licensing�Questionnaire .................................................67
Appendix�E:�Prototype�Project�Questionnaires ....................................................71
End�Notes..............................................................................................................79
�iv Controlling�Dangerous�Pathogens�Report
�.�.�.�.�.�.�.�.�.�. Introduction
.�.�.�.�.
As�has�become�increasingly�evident�in�recent�years,�advances�in�biology�are
posing� an� acute� and� arguably� unprecedented� dilemma.� � The� same� basic
science�that�could�in�principle�be�highly�beneficial�could�also�be�enormously
destructive,�depending�on�how�it�is�applied.��Although�the�scope�of�actual
consequence�remains�uncertain,�the�potential�is�clearly�extraordinary�with�the
health�of�individuals,�the�stability�of�societies�and�the�viability�of�the�global
ecology�all�apparently�at�stake.
Since� compelling� good� and� appalling� harm� cannot� be� disentangled� at� the
level�of�fundamental�science,�a�burden�of�management�is�being�imposed�that
human�institutions�are�not�currently�prepared�to�handle.��The�dilemma�itself
has�been�exemplified�in�several�widely�noted�experiments1�and�professionally
acknowledged�in�reports�issued�by�the�United�States�National�Academies�of
Science� (NAS)� and� by� the� British� Royal� Society.2�� Not� surprisingly,
however,�and�perhaps�inevitably,�efforts�to�devise�an�effective�response�are
still�at�an�embryonic�stage.�� The�proposals�separately�advanced�by�the�two
scientific� societies� are� directed� at� their� own� communities� and� are� largely
voluntary�in�character.��Those�are�natural�initial�steps
but�would�not�alone�provide�robust�global�protection. �
In�an�effort�to�encourage�productive�discussion�of�the
problem� and� its� implications,� this� monograph
discusses� an� oversight� process� designed� to� bring
independent� scrutiny� to� bear� throughout� the� world
without�exception�on�fundamental�research�activities
that�might�plausibly�generate�massively�destructive�or
otherwise� highly� dangerous� consequences.� The
suggestion�is�that�a�mandatory,�globally�implemented
process�of�that�sort�would�provide�the�most�obvious
means�of�protecting�against�the�dangers�of�advances
in� biology� while� also� pursuing� the� benefits.� � The
underlying� principle� of� independent� scrutiny� is� the
central�measure�of�protection�used�in�other�areas�of
major�consequence,�such�as�the�handling�of�money,
and�it�is�reasonable�to�expect�that�principle�will�have
to�be�actively�applied�to�biology�as�well.
The� monograph� outlines� an� advanced� oversight
arrangement,� provisionally� labeled� the� Biological
Research�Security�System�(BRSS),�which�is�designed
to� help� prevent� destructive� applications� of� biology,
whether�inadvertent�or�deliberate.�� The�arrangement
is� put� forward� with� full� realization� that� meaningful
The suggestion is that
a mandatory, globally
implemented process
of this sort would
provide the most
obvious means of
protecting against the
dangers of advances
in biology while also
pursuing the benefits.
Controlling�Dangerous�Pathogens�Report 1
�protection�can�only�be�achieved�by�imposing�some�constraint�on�freedom�of
action�at�the�level�of�fundamental�research,�where�individual�autonomy�has
traditionally�been�highly�valued�for�the�best�of�reasons.�� Constraints�of�any
sort� on� research� will� not� be� intrinsically� welcome� and� will� have� to
demonstrate�that�the�protection�provided�justifies�the�costs�entailed.��A�great
deal� of� conceptual� innovation,� legal� specification,� institutional� design� and
political�accommodation�would�admittedly�be�required�to�establish�such�an
oversight�process,�and�there�is�very�little�precedent�to�work�with.�� Because
of� the� demands� imposed� and� the� inconvenience� involved,� the� monograph
concedes� that� human� societies� after� due� reflection� might� choose� at� least
initially�to�accept�lesser�standards�of�protection�and�it�discusses�more�limited
incremental� measures� that� might� be� undertaken.�� The� central�contention,
however,�is�that�the�eventual�outcome�should�be� a�fully�considered�choice
and�not�the�default�result�of�inertia�or�neglect.
2 Controlling�Dangerous�Pathogens�Report
�.�.�.�.�.�.�.�.�.�. Context of the Problem
.�.�.�.�.
Because�the�potential�consequences�of�advanced�biology�are�so�extraordinary,
the� problems� of� management� posed� are� arguably� becoming� one� of� the� most
consequential� problems� of� public� policy� ever� encountered.�� Knowledge� of
fundamental� life� processes� has� progressed� to� the� point� that� extensive� human
intervention�in�the�course�of�natural�evolution�has�apparently�become�feasible,
not�only�to�determine�particular�outcomes�but�to�redirect�the�process�itself.��One
can�credibly�imagine�the�eradication�of�a�number�of�known�infectious�diseases.
One� can� also� credibly� imagine� the� deliberate� or� inadvertent� creation� of� new
pathogens�dramatically�more�dangerous�than�those�that�have�naturally�evolved.
One�can�similarly�imagine�both�therapeutic�and�destructive�applications�affecting
basic�features�of�cognitive,�emotional,�and�reproductive�activity.�� Hundreds�of
millions� of� lives� might� be� enhanced,� salvaged,� manipulated,� degraded,� or
terminated�depending�on�how�the�same�basic�knowledge�is�applied.�� Little�of
that�potential� has� yet� been� accomplished� but� none� of� it� can� be� dismissed� as
fantasy.
Unfortunately,�the�capacity�to�alter�basic�life�processes�is�not�remotely�matched
by�the�capacity�to�understand�the�extended�implications.�� For�the�foreseeable
future,� moreover,� that� imbalance� is� much� more� likely� to� accelerate� than� to
diminish.�� It�is�not�realistic�to�expect�that�the�current�momentum�in�molecular
biology,� in� particular,� will� extend� to� the� many� other� disciplines� necessary� to
assess�the�consequences�for�the�evolutionary�process�as�a�whole.�� As�a�result,
the�human�species�is�relentlessly�acquiring�power�far�in
excess� of� its� vision� and� this� is� thereby� posing
monumental� problems� of� prudential� judgment� –
problems� that� society� is� not� yet� conceptually� or The human species
institutionally� equipped� to� handle.�� Those� are� the� stark
facts�of�the�situation.
is relentlessly
Admittedly,�facts�of�that�character�and�magnitude�are�not
readily� absorbed.�� They� are� being� explored� by� some
groups,�but�the�institutions�that�would�be�responsible�for
managing�the�problem�have�not�seriously�acknowledged
the� situation� nor� fathomed� the� implications.�� They� are
understandably�reluctant�to�admit�problems�they�do�not
know�how�to�solve,�particularly�if�the�requirements�are
as�extensive�and�as�radical�as�they�appear�to�be�in�this
case.�� The� dominant� inclination� is� to� reduce� even� the
most� monumental� questions� to� terms� that� can� be
managed� by� gradual� adjustment.�� It� is� reasonable� to
assume�that�current�management�of�advanced�biology�is
in� the� early� stages� of� such� a� process.�� It� is� also
reasonable� to� assume� that� the� adjustment� eventually
required� will� be� much� more� extensive� than� currently
admitted�and�the�schedule�on�which�it�occurs�more�rapid.
acquiring power far
in excess of its vision
and this is thereby
posing monumental
problems of
prudential judgment.
Controlling�Dangerous�Pathogens�Report 3
�It� is� important� that� those� who� are� willing� to� assume� that� much� begin� to
anticipate�the�innovations�likely�to�be�necessary.
In� current� public� discussion� of� the� subject,� fear� of� terrorism� has� been� a
particularly�prominent�theme,�especially�in�the�United�States�in�the�aftermath�of
the� 2001� anthrax� letters.�� That� concern� reflects� a� circumstance� of� obvious
importance.�� Any�individual�or�organization�dedicated�to�destruction�but�only
capable�of�undertaking�small-scale�operations�might�plausibly�choose�advanced
biology�as�the�instrument�of�choice.��There�is�no�indication�that�anyone�has�ever
attempted�wanton�destruction�of�that�sort,�and�there�would�be�very�appreciable
practical� difficulties� and� risks� involved.�� Nonetheless,� an� attack� with� an
especially� virulent� pathogen� might� in� principle� induce� a� disease� epidemic
sufficient� to� disorganize� an� entire� society� or� degrade� an� entire� economy.
Otherwise� a� clandestine� operation� could� only� accomplish� genuinely� massive
social� destruction� by� the� use� of� nuclear� explosives,� and� the� fissile� material
required� is� currently� much� more� elaborately� protected� than� are� pathogens.
Biotechnology� is� one� of� only� two� technologies� that� truly� deserve� the� label
“agent�of�mass�destruction”�and�it�is�by�far�the�more�accessible�of�the�two.
For� all� its� current� prominence,� the� threat� of� bio-terrorism,� including� statesponsored�terrorism,�is�not�the�exclusive�or�even�the�primary�source�of�danger.
As�a�practical�matter,�terrorist�organizations�by�their�nature�are�forced�to�evade
detection� and� thus� cannot� independently� generate� the� fundamental� science
required�to�perpetrate�acts�of�mass�destruction�–�as�distinct�from�acts�of�mass
sensation.�� The�basic�knowledge�required�would�have�to�be�extracted�from�the
legitimate� research� community,� and� the� people
involved� would� have� to� have� been� trained� within
that�community.��At�the�moment�there�is�very�little
…protective standards
organized� protection� against� the� diversion� of
legitimate� science� to� malicious� purpose;� more
robust�protection�can�be�and�almost�certainly�will
will have to be
be� devised.�� In� so� doing,� it� will� be� necessary� to
address�the�deeper�problem�of�inadvertence.
developed for their own
sake within the
legitimate research
community. That is the
first, most important
and most promising
line of defense against
deliberate maliciousness.
4 Controlling�Dangerous�Pathogens�Report
Precisely�because�the�rate�of�discovery�in�biology
is� far� outrunning� the� more� integrated� science
required�to�assess�the�extended�social�effects,�there
is� considerable� danger� that� legitimate� scientists
pursuing� compelling� research� ideas� will� initiate
chains�of�consequence�they�cannot�visualize�and�do
not� intend.�� The� extensive� and� necessarily� open
process� of� medical� and� agricultural� research� is
regularly� producing� results� that� are� compellingly
beneficial� but� that� also,� as� an� unavoidable� byproduct,� could� be� exceedingly� dangerous.�� Given
that�situation,�protective�standards�will�have�to�be
developed�for�their�own�sake�within�the�legitimate
research� community.�� That� is� the� first,� most
important� and� most� promising� line� of� defense
against� deliberate� maliciousness.�� If� that� line� of
defense� is� not� constructed,� nothing� else� will� be
effective�and�literally�everyone�increasingly�will�be
in�danger.
�The� relevant� biomedical� research� community� is� very� extensive� and� globally
distributed.��More�than�a�million�scientific�articles�are�published�every�year�and
seminal� results� are� generated� in� all� parts� of� the� world.�� Information� flows
rapidly� among� leading-edge� scientists� and� knowledge� of� fundamental
developments�also�transfers�rapidly�to�those�in�training.��Given�that�situation,�it
seems� obvious� that� adequate� measures� of� protection� against� the� misuse� of
biological� research� would� have� to� be� devised� globally,� not� just� for� academic
researchers� but� also� for� those� working� in� commercial� and� government� labs.
However,� current� regulation� of� advanced� biology� is� conducted� primarily� by
national� governments� and� is� principally� concerned� with� the� localized
containment� of� dangerous� pathogens,� the� safety� of� research� personnel,� the
treatment�of�research�animals,�and�the�preparation�of�distributed�products�such
as� drugs� and� vaccines.�� As� discussed� below,� there� have� been� as� yet� only
embryonic�efforts�to�organize�prudential�judgment�at�the�outset�of�fundamental
research�regarding�the�extended�implications�of�the�knowledge�to�be�generated.
The�legitimate�fear�of�interfering�with�the�process�of�scientific�discovery�has
minimized�oversight�at�that�stage.��Moreover,�in�areas�considered�to�be�relevant
to� weapons� application,� national� governments� have� imposed� security
classification�and�are�actively�exploring�the�destructive�application�of�biology
under� the� justification� of� “threat� assessment.”�� That� practice� is� intensifying
suspicion�among�the�many�governments�already�inclined�to�be�suspicious�of�one
another.
Particularly� in� the� United� States,� reaction� to� the� 2001� terrorist� events� has
strongly�reinforced�the�instinct�to�focus�on�national�responses.��� New�terrorism
legislation� adopted� in� May� 2002� imposed� registration� requirements� on
individuals� and� institutions� that� possess� selected� pathogens� declared� to� be
dangerous,�under�terms�that�have�made�national�identity�a�major�criterion�for
access.�� The� fact� that� registration� requirements� would� have� to� be� globally
enacted�to�be�effective�appears�to�have�received�no�consideration.�� There�has
also�been�a�dramatic�increase�in�US�government�funding�for�bio-terrorism�and
bio-defense�research,�with�little�recognition�of�the�need�to�accompany�that�effort
with� a� protective� oversight� process.� Bioterrorism� funding� at� the� National
Institutes�of�Health�(NIH),�for�example,�has�grown�from�a�modest�$53�million
in� fiscal� year� 2001� to� $1.9� billion� (requested)� in� fiscal� year� 2007.3� � The
Department� of� Homeland� Security� is� also� playing� a� leading� role� in� this� area,
establishing,�as�part�of�its�multi-million�dollar�National�Biodefense�Analysis�and
Countermeasures� Center� (NBACC),� a� new� Biothreat� Characterization� Center
(BTCC)� to� conduct� studies� and� experiments� to� better� understand� current� and
future�biological� threats.4� The� mission� of� NBACC� is� “to� provide� the� nation
with� the� scientific� basis� for� awareness� of� biological� threat� and� attribution� of
their�use�against�the�American�public”�by:
Understanding� current� and� future� biological� threats,� assessing
vulnerabilities,� and� determining� potential� impacts� to� guide� the
development�of�biodefense�countermeasures;�and,
Providing� national� capability� to� conduct� forensic� analysis� of� evidence
from� bio-crimes� and� terrorism� to� attain� a� “biological� fingerprint”� to
identify�perpetrators�and�determine�the�origin�and�method�of�attack.�5
Controlling�Dangerous�Pathogens�Report 5
�Construction�of�a�new�facility�for�NBACC�at�Ft.�Detrick�began�in�June�2006.
The� 160,000� square� foot� facility� will� house� the� Biological� Threat
Characterization�Center�and�the�National�Bioforensic�Analysis�Center�(NBFAC).
It�will�include�over�70,000�square�feet�of�laboratory�space,�20%�of�which�will
be�built�to�BL-4�standards.
This�reliance�on�national�measures�was�also�reflected�in�the�2001�US�decision,
over� broad� international� objection,� to� block� efforts� to� develop� a� compliance
protocol� for� the� Biological� Weapons� Convention� (BWC).�� Within� the� current
administration� especially,� the� largely� implicit� but� powerfully� entrenched
assumptions�are�that�the�danger�derives�mainly�from�hostile�foreign�sources�and
that�it�can�be�managed�primarily�by�controlling�access�to�dangerous�pathogens
themselves.�� Understandable�and�perhaps�inevitable�as�that�reaction�may�be�in
political�and�emotional�terms,�it�is�highly�dysfunctional�in�terms�of�scientific
reality�and�will�almost�certainly�intensify�the�underlying�peril.
A�collision�between�attitude�and�circumstance�is�a�familiar�human�drama.��It�is
unusually�pronounced�in�this�case�but�not�unique.�� Over�the�longer�term�it�is
reasonable� to� expect� that� circumstances� as� compelling� as� those� biology� is
creating� will� eventually� conquer� even� the� most� recalcitrant� attitudes,� but
obviously�there�are�major�questions�as�to�how�soon�that�might�happen�and�in
what� manner.�� Although� dysfunctional� attitudes� are� often� abandoned� only� in
reaction� to� compellingly� painful� experience,� one� cannot� responsibly� wait� for
such�experience�in�this�case.�� Those�who�are�able�to�understand�the�situation
clearly�have�some�responsibility�to�visualize�an�appropriate�response.��Although
the�consequences�of�advances�in�biology�might�turn�out�to�be�less�dramatic�than
they�currently�seem,�it�is�nonetheless�necessary�to�explore�the�implications�of
current� projections.�� Since� that� exploration� will� require� very� extensive,� very
demanding,� and� doubtless� time-consuming� discussion,� it� is� quite� important� to
begin.
The basic method
of protective
oversight will have
to be based on
systematic
information
disclosure and
informed peer review.
In� broad� outline� the� requirements� of� managing� advanced
biology� are� not� difficult� to� discern.�� The� hard� part,
actually,� is� taking� the� problem� seriously� enough� to� be
willing� to� examine� the� fairly� obvious� answer.�� It� can� be
presumed� that� inherently� dangerous� areas� of� biological
research� will� have� to� be� subjected� to� a� much� more
systematic� process� of� protective� oversight� than� is� yet
practiced� in� any� country.�� That� will� have� to� be� done
globally�and�therefore�will�have�to�be�globally�formulated
and�globally�implemented.��The�basic�method�of�protective
oversight�will�have�to�be�based�on�systematic�information
disclosure�and�informed�peer�review.��In�areas�of�research
capable�of�having�massive�consequence,�it�is�truly�a�vital
matter� to� bring� independent,� adequately� informed,� and
broadly�representative�scrutiny�to�bear.�� No�individual�or
research� team,� however� competent,� honorable,� and
patriotic,�should�carry�the�burden�or�be�given�the�authority
to�make�research�decisions�that�might�put�an�appreciable
fraction�of�the�human�species�as�a�whole�at�risk�without
subjecting�themselves�to�independent�oversight�in�advance
and�throughout�the�course�of�their�work.
6 Controlling�Dangerous�Pathogens�Report
�The�judgments�required�in�such�an�oversight�process�cannot�be�entirely�derived
from� any� set� of� general� guidelines,� although� common� risk-benefit� assessment
criteria�would�be�an�essential�feature�of�the�process.��Valid�judgments�about�the
balance�of�benefit�and�risk�in�any�specific�instance�can�only�be�made�in�detailed
context�by�people�capable�of�understanding�both�the�scientific�issues�in�question
and� the� social� consequences.�� That� implies� a� broadly� representative� group,
including�scientists,�security�and�public�health�experts�and�public�representatives
not�directly�involved�in�the�research�in�question.�� They�would�have�to�operate
through� oversight� bodies� of� extraordinary,� indeed� unprecedented,� credibility.
That� credibility� would� have� to� be� established� not� only� by� the� quality� of� the
individuals� but� also� by� a� highly� refined� specification� and� limitation� of� their
powers.
The� oversight� system� would� be� tiered,� matching� the� degree� of� risk� with� the
information� disclosure� and� review� requirements.�� In� the� prototype� Biological
Research�Security�System�outlined�in�this�paper,�local�oversight�bodies�would�be
charged�with�reviewing�research�projects�of�potential�concern�being�proposed�by
licensed�researchers�working�at�licensed�facilities.��� Such�research�encompasses
those�activities�that�may�increase�the�destructive�potential�of�biological�agents
that� otherwise� would� not� be� considered� a� threat.�� National� oversight� bodies
would�be�responsible�for�research�activity�of�moderate�concern,�such�as�work
with�anthrax�and�other�agents�already�identified�as�having�biological�weapons
potential.�� Both�the�local�and�national�oversight�bodies�would�operate�on�the
basis� of� internationally� agreed� standards.�� An� international� body� would� be
charged�with�approving�and�monitoring�all�research�projects�of�extreme�concern.
That�authority�would�be�narrowly�focused�only�on�those�research�activities�that
could�put�an�appreciable�fraction�of�the�human�species�at�risk,�such�as�work
with� smallpox� or� a� yet� more� lethal� contagious� pathogen.�� Ultimately,� the
oversight� process� would� have� to� be� extended� beyond� individual� projects
involving� consequential� work� with� pathogens� to� address� broader� advances� in
immunology�and�neurobiology,�for�example,�which�may�have�little�to�do�with
pathogens.
Biological Research Security System
International Oversight
Activities of Extreme Concern
National Oversight
Activities of Moderate Concern
Local Oversight
Activities of Potential Concern
No Oversight
All Other Research
Controlling�Dangerous�Pathogens�Report 7
�These�oversight�provisions�have�some�precedent�in�current�national�regulatory
practice.�� The�entire�arrangement�constituted�on�an�international�basis�has�no
close� precedent,� however,� and� there� are� many� people� who� would� summarily
declare�it�to�be�impossible.�� Perhaps�in�the�end�it�will�be,�but�in�that�case�the
consequences�are�likely�to�be�very�dire�indeed.�� If�one�is�determined�to�be�a
hardheaded� realist� in� this� situation,� it� is� prudent� to� anticipate� some� response
commensurate�with�the�magnitude�of�what�is�at�stake.�� Protective�oversight�is
the� prime� candidate.�� Whatever� the� eventual� outcome,� it� will� have� to� be
seriously�explored.
8 Controlling�Dangerous�Pathogens�Report
�.�.�.�.�.�.�.�.�.�.
CCurrent State of Oversight
.�.�.�.�.
Various� treaties,� laws,� regulations,� and� other� legal� and� political� instruments
govern�the�handling�and�use�of�pathogens.�� Few�of�these�controls�address�the
research�process�itself,�and�fewer�still�require�an�independent�evaluation�of�the
possible�security�and�public�health�consequences�of�a�given�biological�research
project� before�the�work�is�undertaken.��This�section�looks�at�some�of�the�more
important� oversight� arrangements� –�on�the�international�level,�within�the�US,
within�the�UK,�and�as�regards�the�special�case�of�smallpox�research�–�in�terms
of� their� scope,� limitations,� and� potential� relevance� to� a� future� Biological
Research�Security�System.
International�Controls
The� most� significant� development� in� the� history� of� international� efforts� to
prevent�the�misuse�of�biology�for�hostile�purposes�was�the�conclusion�of�the
1972� Biological� Weapons� Convention,� which� prohibits� the� development,
production,� and� possession� of� biological� agents� or� toxins� for� other� than
prophylactic,� protective� or� other� peaceful� purposes.�� The� BWC� imposes� no
limits,� however,� on� research� involving� biological� agents� and� contains� no
provisions�for�verifying�compliance�with�its�obligations.��In�an�effort�to�help�fill
these� gaps,� BWC� States� Parties� agreed� at� past� treaty� review� conferences� that
certain�open-air�tests�fall�within�the�scope�of�the�BWC’s�prohibitions�and�that
basic�research�in�the�biological�sciences�should�generally�be�unclassified.��They
also�adopted�a�series�of�confidence-building�measures�requiring�the�exchange�of
information�on�specific�types�of�biological�research�activities�and�facilities.
As�noted�above,�efforts�to�move�beyond�these�politically�binding�arrangements
toward�a�more�robust,�legally�binding�BWC�compliance�protocol�collapsed�in
2001,�with�the�US�citing�concerns�about�the�potential�impact�of�the�proposed
declaration� and� inspection� measures� on� confidential� business� and� national
security� information.�� Although� both� the� European� Union� (EU)� and� many
moderate� non-aligned� (NAM)� countries� believed� that� the� draft� protocol
contained� adequate� provisions� for� protecting� such� sensitive� information,� the
Bush�administration�disagreed,�and�scuttled�the�protocol�because�of�this�issue.
The�other�major�stumbling�block�was�the�NAM’s�insistence�on�technical�and
economic�assistance,�including�the�efforts�of�some�to�try�to�use�the�protocol�to
eliminate�existing�controls�on�the�export�of�biological-related�materials.
To�help�fill�the�void�left�by�the�failure�of�the�protocol�negotiations,�BWC�States
Parties� agreed� in� November� 2002� to� a� new� process,� whereby� one� experts
meeting� and� one� political� meeting� would� be� held� each� year� to� discuss� and
promote� common� understanding�and� effective� action�on�certain�agreed�issues.
At�the�insistence�of�the�US,�however�each�experts�meeting�was�only�two�weeks
long�and�each�political�meeting�a�week.��In�addition,�participants�were�limited�to
Controlling�Dangerous�Pathogens�Report 9
�exchanging� information� on� the� agreed� topics� and� had� no� decisionmaking
authority.�� In�2003,�States�Parties�discussed�national�implementing�legislation
and� the� security� and� oversight� of� pathogens.�� In� 2004,� they� focused� on� the
issues� of� disease� surveillance� and� investigations� of� alleged� use� of� biological
weapons� and� suspicious� outbreaks� of� disease.�� In� 2005,� scientific� codes� of
conduct�were�discussed.��These�meetings�helped�keep�the�issue�of�strengthening
the� BWC� on� the� international� agenda� and� encouraged� States� Parties� to� share
information�about�their�national�activities�in�each�of�these�areas.��But�because�of
the�limitations�placed�on�the�process�by�the�US,�no�guidelines�or�best�practices
could�be�agreed�and�recommended�for�adoption�by�States�Parties.
At� the� Sixth� Review� Conference� in� December� 2006,� States� Parties� agreed� to
hold�a�new�round�of�annual�experts�and�political�meetings�between�2007�and
2010.�� Of� particular� importance� are� the� topics� to� be� considered� in� 2008:
national,� regional� and� international� measures� to� improve� biosafety� and
biosecurity;�and�oversight,�education,�and�other�measures�aimed�at�preventing
the� misuse� of� advances� in� the� biosciences� and� biotechnology� research.
Unfortunately,�the�time�for�the�experts�meeting�on�these�issues�was�halved,�from
two�weeks�to�one.��Moreover,�the�US�again�rejected�efforts�to�give�these�intersessional�meetings�decisionmaking�authority,�thus�raising�questions�about�their
ultimate�impact.6
Other�international�instruments�also�have�been�adopted�to�deal�with�concerns
about� the� environmental� and� public� health� implications� of� advances� in
biotechnology,�in�particular.7��In�1992,�a�Code�of�Conduct�for�the�Release�of
Organisms�into�the�Environment�was�developed�by�the�United�Nations�Industrial
Development�Organization�(UNIDO).8��The�UNIDO�Code,�which�is�voluntary�in
nature,� called� for� the� establishment� of� national� risk� assessment� and� decisionmaking�structures�to�provide�scientific�judgments�concerning�the�use�and�release
of� genetically� modified� organisms� (GMOs).�� It� also� called� for� linking� safety
precautions�and�monitoring�arrangements�to�the�level�of�assessed�risk,�based�on
the�biological�properties�of�the�organism�and�the�receiving�environment.��Under
the�1992�Biodiversity�Convention,�countries�are�legally�required�to�regulate�the
use�and�release�of�genetically�modified�organisms�that�could�have�an�adverse
impact�on�biodiversity�and�to�provide�information�on�their�regulations�to�other
States�Parties�to�whom�such�organisms�are�being�transferred.9��The�International
Technical�Guidelines�for�Safety�in�Biotechnology,�which�were�adopted�by�the
United� Nations� Environment� Programme� (UNEP)� in� December� 1995,� also
emphasize�the�importance�of�effective�oversight�of�activities�involving�organisms
with� novel� traits.�� Under� the� UNEP� Guidelines,� such� oversight� is� defined� as
including�risk�assessment,�disclosure�of�relevant�information�and�careful�record
keeping.�� It� can� also� include� prior� notification� of� certain� contained� uses� and
releases�of�organisms�with�novel�traits�and�prior�approval�by�relevant�national
authorities.10
Finally,� the� World� Health� Organization� published� the� first� edition� of� its
Laboratory�biosafety� manual�in�1983�to�provide�guidance�to�countries�on�the
safe�handling�of�pathogenic�microorganisms.�� A�third�edition�was�published�in
2004�that�included�new�sections�on�biosecurity,�risk�assessments,�and�the�safe
use�of�recombinant�DNA�technology.11
10 Controlling�Dangerous�Pathogens�Report
�US�Controls
As�on�the�international�level,�both�security�considerations�and�environmental�and
public� health� concerns� have� shaped� US� policy� on� the� handling� and� use� of
dangerous�pathogens.�� Prior�to�the�conclusion�of�the�BWC,�President�Richard
Nixon�decided,�in�1969,�that�the�US�should�unilaterally�renounce�the�possession
of� biological� weapons� and� confine� the� US� biological� weapons� program� to
research�and�development�for�defensive�purposes�only.�� But�this�policy,�which
is� still� in� effect,� permits� research� into� those� offensive� aspects� of� biological
agents� necessary� to� determine� defensive� requirements,� thus� underscoring� the
difficulties�of�distinguishing�between�legitimate�and�illegitimate�activities�in�this
area.12
Over� the� past� decade,� a� variety� of� measures� have� also� been� adopted� to
strengthen�controls�on�access�to�dangerous�pathogens.��Under�the�Antiterrorism
and�Effective�Death�Penalty�Act�of�1996,�any�facility�involved�in�the�transfer�of
a� “select�agent”�from�a�list�of�human�pathogens�developed�by�the�Centers�for
Disease�Control�and�Prevention�(CDC)�must�register�with�CDC�and�notify�it�of
all�proposed�transfers.13��In�the�aftermath�of�the�anthrax�letters,�new�legislation
was� adopted� in� October� 2001� prohibiting� the� knowing� possession� of� any
biological� agent,� toxin� or� delivery� system� that� is� not� reasonably� justified� for
prophylactic,� protective,� bona� fide� research,� or� other� peaceful� purposes.�� The
law,�known�as�the�USA�Patriot�Act�also�makes�it�a�crime�for�certain�restricted
persons,�including�illegal�aliens�and�individuals�from�terrorist-list�countries,�to
possess,�transport,�or�receive�select�agents.14
In� May� 2002,� additional� bio-terrorism� legislation� extended� the� registration
requirement� for� facilities� that� transfer� select� agents� to� include� facilities� that
possess � select� agents� as� well.�� Under� the� Public� Health� Security� and
Bioterrorism�Preparedness�and�Response�Act�of�2002,�government�background
checks�are�required�for�anyone�that�is�to�be�given�access�to�select�agents.�� In
addition,�the�Department�of�Health�and�Human�Services�(HHS)�is�required�to
develop� a� national� database� of� registered� persons� and� the� select� agents� they
possess,�including�strain�and�other�characterizing�information�if�available,�and�to
carry�out�inspections�of�relevant�facilities.�� The�US�Department�of�Agriculture
(USDA)�is�required�to�develop�parallel�registration,�security,�record�keeping,�and
inspection� measures� for� facilities� that� transfer� or� possess� specific� plant� and
animal�pathogens.15��Under�the�final�regulations�to�implement�the�legislation,�all
affected�facilities�are�also�required�to�develop�a�biosafety�plan,�drawing�on�the
biosafety� and� biosecurity� standards� for� work� with� pathogens� outlined� in� the
CDC�manual,�Biosafety�in�Microbiological�and�Biomedical�Laboratories.16
Since� 1976,� guidelines� have� been� issued� by� the� NIH� Recombinant� DNA
Advisory� Committee� (RAC)� to� ensure� the� safety� of� research� involving
recombinant� DNA� molecules� and� organisms� and� viruses� containing� such
molecules.�� The�original�NIH�Guidelines�prohibited�six�types�of�experiments.
Over� time,� however,� these� prohibitions� were� replaced� by� a� system� of� tiered
oversight�and�review,�in�which�Institutional�Biosafety�Committees�(IBCs)�and
Institutional�Review�Boards�(IRBs)�at�individual�facilities�displaced�the�RAC�as
the�primary�oversight�authority�for�most�categories�of�regulated�research.17
Although� the� NIH� Guidelines� formally� apply� only� to� research� conducted� at
institutes�in�the�US�and�abroad�that�receive�NIH�funding�for�recombinant�DNA
Controlling�Dangerous�Pathogens�Report 11
�research,� it� is� widely� believed� that� many� private� companies� and� foreign
researchers�follow�the�Guidelines�voluntarily.18�A�2004�study�by�the�Sunshine
Project�of�US-based�IBCs,�however,�revealed�that�scores�of�US�biotechnology
companies,� including� some� three� dozen� companies� conducting� biodefense
research�for�the�US�government,�had�no�IBC�registered�with�NIH�and�many�of
the�university�and�other�IBCs�that�were�registered�either�did�not�meet�or�issued
blanket� approvals� rather�than� review� each� specific�project.19�� No�comparable
study�has�been�done�of�US-based�IRBs�and�none�seems�likely�given�privacy
considerations.�� Nevertheless,�federal�regulations�governing�IRBs�are�far�more
elaborate�than�those�that�currently�exist�for�IBCs,�containing�not�only�specific
requirements� for� IRB� approval� of� human� subject� research,� including� for
assessing�the�risks�and�benefits�of�such�research,�but�also�for�documenting�the
results�of�IRB�deliberations.
Under�the�current�NIH�Guidelines,�only�two�categories�of�laboratory�research
involving� recombinant� DNA� technology� require� oversight� by� the� NIH� itself.
The� first,� “Major� Actions,”� cannot� be� initiated� without� the� submission� of
relevant� information� on� the� proposed� experiment� to� the� NIH� Office� of
Biotechnology� Activities� (OBA)� and� require� IBC� approval,� RAC� review,� and
NIH� Director� approval� prior� to� initiation.�� These� include� experiments� that
involve�the�“deliberate�transfer�of�a�drug�resistance�trait�to�microorganisms�that
are� not� known� to� acquire� the� trait� naturally� if� such� acquisition� could
compromise�the�use�of�the�drug�to�control�disease�agents�in�humans,�veterinary
medicine,� or� agriculture.”�� The� second� class� of� experiments� requiring� IBC
approval�and�NIH/OBA�review�prior�to�initiation�involves�the�cloning�of�toxin
molecules�with�LD50�of�less�than�100�nanograms�per�kilogram�body�weight.20
Under� the� new� regulations� to� implement� the� May� 2002� bioterrorism� bill,� the
Secretary�of�HHS�must�also�approve�experiments�that�fall�under�these�categories
if� they� involve� the� use� of� agents� or� toxins� on� the� select� agent� list,� and� the
Administrator� of� USDA’s� Animal� and� Plant� Health� Inspection� Service� must
approve�them�if�they�involve�agents�or�toxins�on�USDA’s�control�lists.21��Unlike
the�NIH�Guidelines,�however,�these�requirements�are�both�legally�binding�and
apply�to�all�entities�conducting�the�relevant�research,�not�just�to�those�receiving
funding�from�NIH�for�recombinant�DNA�research.
Other� types� of� research� may� soon� be� added� to� the� NIH� Guidelines� and� thus
subject� to� IBC� and,� in� some� cases,� possibly� national-level� review.�� In� its
October� 2003� report,� “Biotechnology� Research� in� an� Age� of� Terrorism,”�an
expert� panel� convened� by� the� US� National� Academy� of� Sciences,� under� the
chairmanship� of� MIT� professor� Gerald� Fink,� recommended� giving� IBCs
responsibility� for� considering� the� security� implications� of� seven� categories� of
dual-use�research.22��These�“experiments�of�concern,”�as� the�Fink�Committee
called�them,�included�those�that�would:
•
•
•
•
•
•
•
demonstrate�how�to�render�a�vaccine�ineffective;
confer�resistance�to�antibiotics�or�antiviral�agents;
enhance�the�virulence�of�a�pathogen�or�render�a�nonpathogen�virulent;
increase�the�transmissibility�of�a�pathogen;
alter�the�host�range�of�a�pathogen;
enable�evasion�of�diagnosis�or�detection�methods;�or
enable�weaponization�of�a�biological�agent�or�toxin.
12 Controlling�Dangerous�Pathogens�Report
�The�Fink�Committee�also�recommended�the�development�of�education�programs
for� scientists� on� the� dual-use� issue;� pre-publication� review� of� manuscripts� by
scientists�and�scientific�journals;�enhanced�communication�between�the�national
security,�law�enforcement�and�life�sciences�community�on�threat�assessment�and
countermeasures� development;� and� international� harmonization� of� efforts� to
manage� the� risks� from� dual-use� research.�� To� help� guide� these� efforts,� the
Committee� also� called� for� the� establishment� of� a� National� Science� Advisory
Board�for�Biodefense�within�HHS.
In� March� 2004,� the� Bush� administration� responded� to� the� Fink� Committee
report,� announcing� the� creation� of� a� new� government� body� to� advise� US
government�agencies�on�how�to�reduce�the�risk�that�legitimate�research�will�be
misused�for�hostile�purposes.23��The�main�functions�of�this�new�body,� known�as
the�National�Science�Advisory�Board�for�Biosecurity�(NSABB),�include:
developing�criteria�for�identifying�dual-use�research�and�research�results;
developing� guidelines� for� local� (IBC)� oversight� of� dual-use� research,
including�the�risk/benefit�analysis�of�such�research;
advising�on�criteria�and�processes�for�referring�research�to�the�NSABB
for�additional�guidance;
responding�to�requests�from�institutions�for�advice�on�research�that�has
been�denied�by�an�IBC;
providing�recommendations�on�the�development�of�a�code�of�conduct�for
scientists�and�laboratory�workers;
providing� recommendations� on� the� development� of� mandatory
biosecurity�education�and�training�programs�for�scientists�and�laboratory
workers�at�federally�funded�institutions;
advising� on� national� policies� governing� the� dissemination� of� research
results,�including�publication;�and
recommending�strategies�for�coordinated�international�oversight�of�dualuse�research.
At�its�first�meeting,�at�the�end�of�June�2005,�the�NSABB�agreed�to�establish
working� groups� in� five� initial� areas:�� criteria� for� dual-use� research;
communication�of�research�results;�codes�of�conduct;�international�collaboration;
and� synthetic� genomics.�� A� sixth� working� group,� on� the� critical� issue� of
oversight�of�dual-use�research,�was�not�added�until�a�year�later.��At�the�Board’s
July� 2006� meeting,� the� NSABB� also� approved� the� initial� work� done� by� its
criteria,� communications,� and� codes� working� groups.�� In� all� three� areas,
however,�the�results�were�limited�at�best.24�The�criteria�for�identifying�dual-use
research� of� concern,� for� example,� were� largely� a� reformulation� of� the� Fink
Committee’s�experiments�of�concern.�� Like�the�Fink�Committee�approach,�the
NSABB� criteria� are� too� broad,� and� thus� likely� to� capture� a� wide� swath� of
research.��The�criteria�also�focus�exclusively�on�research�activities,�rather�than�a
combination�of�agents�and�activities,�and�fail�to�distinguish�between�levels�of
risk.�� Finally,�the�definition�of�dual-use�research�of�concern�that�accompanies
the�criteria�–�“research�that,�based�on�current�understanding,�can�be�reasonably
anticipated�to�provide�knowledge,�products�or�technologies�that�could�be�directly
misapplied� by� others� to� pose� a� threat� to� public� health,� agriculture,� plants,
animals,�the�environment,�or�material”�–�both�fails�to�consider�the�problem�of
inadvertence� and� requires� a� judgment� about� the� likelihood� that� the� research
results�could�be�misused.�� In�short,�the�NSABB�draft�criteria�are�unlikely�to
Controlling�Dangerous�Pathogens�Report 13
�provide�an�adequate�basis�for�identifying�whether�specific�research�projects�pose
potential�dual-use�concerns�and�thus�should�be�subject�to�independent�oversight.
At�the�Board’s�October�2006�meeting,�the�newly�established�oversight�working
group� outlined�its�initial� ideas.25 Of�particular� interest� were� the�key�features
identified� by� the� working� group� for� the� oversight� system.�� They� include� the
following:
•
•
•
•
institutional� review� of� the� scientific,� ethical,� and� possible� social
consequences�of�dual-use�research�and�research�findings;
the�use�of�risk�assessment�and�risk�management�principles�in�the�review
process,�with�the�degree�of�institutional�oversight�linked�to�the�assessed
risk;
a�process�for�appealing�the�decisions�of�the�institutional�review�body;
and,
the�training�of�scientists,�reviewers�and�others�who�are�involved�in�dualuse�research.
Unfortunately,� at� least� in� its� initial� formulation,� the� working� group� suggested
that� compliance� with� the� oversight� system� should� be� mandatory� for� federally
funded� institutions� but� voluntary� for� others.�� Classified� research� already� is
exempt� from� the� NSABB’s� purview� by� its� charter.�� If� research� at� private
companies� and� other� institutions� that� do� not� receive� federal� funding� is� also
exempted�from�mandatory�oversight,�the�system�being�proposed�by�the�NSABB
will�have�limited�effect.
Development of Oversight Arrangements in the US
1976 NIH guidelines establish institutional biosafety committees (IBCs) to
provide local oversight for recombinant DNA work. The Recombinant
DNA Advisory Committee (RAC) at NIH reviews “Major Actions,”
including some transfers of drug resistance and the cloning of toxin
molecules with an LD50 of less than 100 ng/kg body weight.
1996 Registration requirement and notification to the CDC for any transfer of a
human pathogen on the select agent list
2001 Legal prohibition on knowing possession of any biological agent, toxin or
delivery system not reasonably justified for prophylactic, protective, bona
fide research, or other peaceful purposes. Criminalizes possession and
transfer of select agents by restricted persons, including illegal aliens and
individuals from terrorist-list countries.
2002 Extension of the registration requirements to facilities that possess select
agents. Government background checks required for anyone having
access to select agents. HHS required to develop a national database of
registered persons and select agents they possess. USDA required to
keep similar registration, security, record keeping, and inspection
measures for facilities that transfer or possess specific plant and animal
pathogens. The Secretary, HHS and Administrator of APHIS (USDA)
must approve certain experiments with agents or toxins on the select
agent or control list, respectively.
2004 National Science Advisory Board for Biosecurity established to advise
US government agencies on how to reduce the risk that legitimate
research will be misused for hostile purposes.
14 Controlling�Dangerous�Pathogens�Report
�In� addition� to� the� NIH� Guidelines,� there� are� also� a� number� of� other� US
government� regulations� concerning� the� handling� or� use� of� pathogens.�� Even
those�that�govern�research�with�pathogens,�however,�focus�on�their�transfer�or
release� rather� than� laboratory-based� activities.�� For� example,� under� USDA
regulations,� any� person� wishing� to� import,� move,� or� release� genetically
engineered� plant� pests� within� the� US� must� either� submit� a� notification� to� or
obtain�a�permit�from�USDA�before�proceeding�with�the�proposed�activity.�� A
USDA�permit�also�is�required�for�the�import�of�microorganisms�that�can�cause
infectious,� contagious,� or� communicable� diseases� in� poultry� or� livestock.26
Under�Environmental�Protection�Agency�(EPA)�regulations,�small-scale�tests�of
certain�genetically�modified�microbial�pesticides�must�be�notified�to,�and�receive
approval�from,�EPA.�� An�experimental� release�application� must�also�be�filed
with�EPA�for�certain�research�and�development�activities�with�microorganisms
for�commercial�purposes.27��EPA�also�administers�the�National�Environmental
Policy� Act,� under� which� federal� agencies� are� required� to� prepare� detailed
environmental� impact� statements� assessing� both� the� risks� of� their� proposed
activities� and� efforts� to� mitigate� risk� through� facility� design� and� laboratory
practices.28� � The� US� Army� also� regulates� research� and� other� activities� with
biological�agents�under�the�Biological�Defense�Program,�requiring�audit�trails�of
all� agent� shipments� and� the� use� of� simulants� in� all� open-air� tests� unless� the
Secretary�of�Defense�determines�that�testing�with�actual�agents�is�necessary�for
national�security�reasons.29
UK�Controls
The�United�Kingdom�has�what�may�be�the�most�robust�oversight�arrangements
in�place�for�research�and�other�activities�involving�pathogens.�� Unlike�the�US,
the�UK�government�has�direct�legal�authority�over�relevant�research�anywhere�in
the� country,� and� does� not� have� to� rely� on� funding� mechanisms� to� help� bring
scientists�into�their�oversight�systems.
Following� the� September� 11� terrorist� attacks,� the� UK� enacted� new� antiterrorism-related� controls� on� pathogens� similar� to� those� adopted� in� the� US.
Under� the� Anti-Terrorism,� Crime� and� Security� Act� passed� in� October� 2001,
facilities�that�possess�or�plan�to�possess�specified�human�pathogens�are�required
to� notify� the� government� and� to� comply� with� any� reasonable� security
enhancements�that�may�be�imposed�after�an�inspection�of�the�site.��The�bill�also
requires�facility�personnel�to�comply�with�official�requests�for�information�about
security�measures�at�their�facility�and�about�persons�who�have�or�are�proposed
to� have� access� to� controlled� pathogens.�� It� also� contains� provisions� for
background�checks�and�gives�the�government�the�authority�to�deny�individuals
access�to�controlled�pathogens�or�the�facilities�in�which�they�are�held.��The�bill
allows�but�does�not�require�the�same�notification�and�other�requirements�to�be
extended�to�animal�and�plant�pathogens�and�plant�pests.��The�UK�anti-terrorism
legislation�does�not,�however,�require�prior�review�of�research�projects�involving
these�controlled�pathogens.30
Since� the� 1970s,� the� UK� has� also� established� a� variety� of� controls� on� the
handling� and� use� of� genetically� modified� organisms.�� As� with� the� NIH
Guidelines,� the� UK� system� was� initially� voluntary,� with� the� categorization� of
experiments�covered�by�the�notification�guidelines�broadly�similar�to�that�in�the
Controlling�Dangerous�Pathogens�Report 15
�US.31��In�1992,�a�new�Genetically�Modified�Organisms�(Contained�Use)�Regulation
was�issued�to�implement�the�tighter�controls�on�GMOs�being�developed�in�the
European� Union� (EU).�� This� regulation,� as� revised� in� 2000,� requires� a� risk
assessment�prior�to�beginning�any�work�with�a�genetically�modified�organism
and� prior� notification� to� UK� health� authorities� of� plans� to� carry� out� genetic
modification� work� in� any� facility� for� the� first� time.32� � The� regulation� also
requires�prior-notification�to�local�genetic�modification�safety�committees�of�all
but�the�lowest�risk�genetic�modification�work,�with�higher�risk�research�requiring
government� consent.� � Prior� to� the� 2001� terrorist� attacks,� all� notifications� were
maintained� in� a� register� open� to�the� public.33� � A� separate� regulation� on�the
deliberate�release�of�GMOs�issued�in�1992�and�revised�most�recently�in�2002
requires� government� consent� before� marketing� a� GMO� or� releasing� such� an
organism� into� the� environment.�� The� application� for� consent� must� include� an
assessment�of�the�environmental�risk�of�the�proposed�activity�as�well�as�detailed
information� on� the� GMO� itself,� monitoring� arrangements� and,� as� appropriate,
marketing�or�release�plans.34
Other� regulations� have� been� adopted� in� the� UK� to� implement� EU� oversight
requirements�for�human,�plant�and�animal�pathogens�that�could�have�an�adverse
impact� on� public� health� or� the� environment.35� � Under� the� 1994� Control� of
Substances�Hazardous�to�Health�Regulation,�as�amended�most�recently�in�2002,
employers�must�notify�UK�health�authorities�30�days�prior�to�storing�or�using
certain�human�pathogens�for�research�or�other�purposes�for�the�first�time.��The
notification�must�include�an�assessment�of�the�risks�to�worker�health�and�safety,
information�on�the�pathogen,�and�proposed�measures�to�protect�worker�health
and�reduce�the�risk�of�exposure.36��The�1993�Plant�Health�Order�prohibits�the
import� of� infected� plants� or� plant� pests� into� the� UK� for� research� purposes
without� a� license.�� The� regulation� also� prohibits� the� import,� movement,� or
keeping�of�genetically�modified�plant�pests�or�genetic�modification�work�with
plant�pests�without�a�license.37��Under�the�1980�Importation�of�Animal�Pathogens
Order,�a�license�is�required�to�import�an�animal�pathogen�or�carrier�into�the�UK.
The� 1993� Specified� Animal� Pathogens� Order,� as� amended� in� 1998,� requires
laboratories� and� scientific� establishments� that� wish� to� hold� or� handle� certain
pathogens�or�nucleic�acids�capable�of�producing�such�pathogens�to�be�licensed.
The�pathogens�covered�by�this�regulation�are�those�that�could�potentially�cause
an�epidemic�among�livestock.38
The�UK�has�even�more�extensive�oversight�arrangements�for�research�activities
involving�animals.��Under�the�1986�Animals�(Scientific�Procedures)�Act,�a�costbenefit�analysis,�weighing�the�potential�for�animal�suffering�against�the�possible
medical� benefits,� must� be� done� before� undertaking� any� research� project
involving� animals.�� The� Act� provides� for� a� triple� licensing� system� of� places,
projects,�and�personnel.��More�specifically,�it�requires�that�animal�research�take
place�only�at�establishments�that�have�appropriate�animal�accommodation�and
veterinary�facilities,�as�part�of�an�approved�research�or�testing�program,�and�by
individuals� with� sufficient� training,� experience,� and� skills.�� Inspectors� visit
licensed�research�establishments,�usually�without�warning,�an�average�of�eleven
times�a�year.�� In�1998,�the�existing�oversight�arrangements�were�expanded�to
include� a� requirement� for� an� ethical� review� process� at� all� licensed
establishments.�� This� process,� begun� at� the� conceptual� stage� of� new� research
projects,�aims�to�provide�support�and�independent�ethical�advice�for�licensees�on
potential�issues�concerning�ethics�and�animal�welfare.�� As�of�1999,�there�were
13,700�active�personal�licenses�and�296�facility�licenses.39
16 Controlling�Dangerous�Pathogens�Report
�Development of Oversight Arrangements in the UK
1986 Triple licensing system established for places, projects, and
personnel for animal research. Inspection of such licensed research
establishments done an average of eleven times per year.
1993 Licensing requirement for the import of infected plants or plant pests
into the UK for research purposes or for the import, movement, or
keeping of genetically modified plant pests or genetic modification
work with plant pests.
1998 Licensing requirement for laboratories and scientific establishments
intending to hold or handle certain pathogens or nucleic acids
capable of producing such pathogens.
2000 Requirement for a risk assessment prior to initiating work with a
genetically modified organism and prior notification to UK health
authorities of plans to carry out genetic modification work in any
facility for the first time. Also a requirement for prior notification to
local genetic modifications safety committees of all but the lowest risk
genetic modification work, with higher risk requiring government
consent.
2002 Requirement for employers to notify UK health authorities 30 days
prior to storing or using certain human pathogens for research or
other purposes for the first time.
2001 Notification and security enhancement requirements for facilities that
possess or plan to possess specified human pathogens.
The�UK�Government�has�established� several�bodies�to�provide�advice�to�UK
health�and�safety�agencies�on�these�oversight�arrangements.40��GMO�regulation
and�control�are�the�focus�of�the�Advisory�Committee�on�Genetic�Modification41
and�the�Advisory�Committee�on�Releases�to�the�Environment.42��The�Advisory
Committee�on�Dangerous�Pathogens43�assists�the�UK�Government�in�protecting
workers�and�others�against�the�risks�from�exposure�to�human,�plant�and�animal
pathogens.��All�three�advisory�bodies�are�composed�of�employee�and�employer
representatives,�as�well�as�experts�from�the�scientific�community,�thus�allowing
the�UK�Government�to�ensure�that�any�new�controls�and�regulations�are�based
on�field�experience�and�are�effective.
As�in�the�United�States,�the�UK’s�leading�scientific�advisory�body,�the�Royal
Society�has�also�considered�the�risks�from�dual-use�research�and�recommended
relying�predominantly�on�scientists�themselves�to�prevent�hostile�applications�of
their�work.�� Like�the�Fink�Committee,�the�Royal�Society�has�proposed�greater
oversight�of�dual-use�research�by�funding�bodies�and�research�institutes�as�part
of� their� general� peer� review� process� and� by� research� institutions� during
execution� of� the� work.�� They� have� given� particular� emphasis� to� the� role� of
scientific� codes� of� conduct,� both� as� a� means� of� raising� consciousness� among
scientists�about�the�potential�for�misuse�of�their�work�and�as�a�focal�point�for
education� and� training� programs� on� both� national� laws� and� regulations� and
international� treaty� obligations.�� They� have� also� called� for� the� research
community�to�retain�responsibility�for�assessing�potential�risks�associated�with
publication� of� their� work� and� to� help� develop� universal� standards� for� the
Controlling�Dangerous�Pathogens�Report 17
�conduct� of� dual-use� research� that� could� be� incorporated� into� existing
international�treaties.44
Smallpox�Research
The�World�Health�Organization�(WHO)�successfully�led�the�global�program�to
eradicate�the�smallpox�virus�from�nature.�45�As�a�result�of�its�prominent�role,�without
which�the�virus�could�have�continued�killing�millions�in�the�25�years�since�its
eradication,�WHO�acquired�the�scientific�and�moral�authority�to�set�policies�for
the�safe�handling�of�the�variola�virus�at�the�two�authorized�depositories,�in�the
US�and�Russia.��In�1999,�the�World�Health�Assembly�(WHA)�decided�to�delay
destruction�of�all�known�viral�stocks�in�favor�of�a�limited�research�program�with
the�virus�that�WHO�was�to�oversee.46
Although� the� Committee� on�Orthopoxvirus�Infections�set�guidelines�for�work
with�the�variola�virus�in�1994,47�a�new�body,�the�Advisory�Committee�on�Variola
Virus� Research,� was� later� formed� to� implement� the� WHA’s�1999�resolution.
The�Advisory�Committee�conforms�to�WHO�rules�regarding�adequate�regional
representation�while�also�including�the�necessary�scientific�expertise�to�ensure
that�the�experimental�design�is�safe�and�commensurate�with�the�goals�set�by�the
WHA.48
Under�this�international�process,�WHO�has�approved�research�with�the�live�virus
aimed�at:�determining�the�full�or�partial�DNA�sequences�of�isolates�in�the�US
and�Russian�collections;�validating�improved�diagnostic�tests;�screening�antiviral
drugs�to�identify�those�suitable�for�treating�smallpox;�developing�and�producing
monoclonal� antibodies� to� treat� the� disease;� developing� a� safer� vaccine;� and
creating� a� model� of� smallpox� in� a� non-human� primate� to� facilitate� testing� of
antiviral�drugs,�vaccines,�and�diagnostics.49
In�November�2004,�the�Advisory�Committee�recommended�revisions�to�the�1994
guidelines� to� allow� newer� techniques� to� be� used� for� more� efficient� drug
screening,� among� other� purposes.50� � While� scientific� consensus� was�reached
within� the� committee,� its� recommendations� caused� some� controversy� at� the
WHA’s� annual� meeting� in� May� 2005,� leading� to� a� ban� on� proposed� genetransfer�studies,�while�allowing�other�types�of�research�to�proceed�with�closer
scrutiny.51
As� currently� structured,� WHO’s� oversight� process� provides� for� international
scientific�review�of�all�research�with�the�variola�virus,�while�also�assuring�states
that�the�research�will�be�performed�in�a�safe�manner�and�in�accordance�with
WHA’s�agreed�research�agenda.��That�balance�is�now�being�put�at�risk�by�WHO
member�states�wanting�to�have�more�direct�authority�over�the�research�rather
than� allowing� the� scientific� committee� its� own� discretion� to� make� those
judgments.�� Research� is� now� reviewed� twice� before� commencing:�� by� the
Advisory�Committee�and�by�the�WHA,�both�of�which�meet�only�once�a�year.
This�adds�significant�delays�and�uncertainties.
Despite� these� many� hurdles� and� restrictions,� no� US� or� Russian� scientist� is
known� to� have� violated� the� recommendations� of� the� WHO� committees� on
smallpox�research�since�the�agreed�research�program�began�in�1999.�� The�US
and� Russian� governments� comply� with� the� arrangement,� including� biosafety
18 Controlling�Dangerous�Pathogens�Report
�inspections�of�their�BL-4�labs,�even�though�WHO�resolutions�are�only�politically
binding.�� WHO’s�oversight�process�provides�accountability�and�legitimacy�to
research� with� the� variola� virus� and� reassurance� about� the� defensive� intent� of
such�research.��This�process�is�a�potential�precedent�for�how�to�conduct�highly
consequential�research�through�a�scientifically�rigorous�and�politically�inclusive
system.
Existing�Arrangements�and�the�BRSS
It�is�clear�from�this�review�that�a�variety�of�oversight�arrangements�have�been
developed�both�internationally�and�nationally�in�response�to�concerns�about�the
possible� misuse� of� biology.�� Most� focus� narrowly� on� limiting� or� controlling
access�to�potentially�dangerous�pathogens�or�on�ensuring�that�such�pathogens�are
handled� safely,� including� minimizing� any� adverse� impact� from� research
involving� their� release� into� the� environment.�� The� few� proposals� aimed� at
addressing�the�risks�posed�by�dual-use�research�apply�to�only�a�portion�of�the
life� sciences� research� community� and� are� generally� based� on� voluntary
adherence�to�measures�that�are�national�in�scope.
Despite�these�limitations,�some�of�the�key�principles�of�a�more�advanced�system
for� oversight� of� dual-use� research� can� be� found� within� these� existing
arrangements.��As�with�WHO�oversight�of�smallpox�research,�the�system�would
be� based� upon� rules� and� procedures� that� have� been� developed� and� agreed
internationally,� with� a� presumption� of� equitable� treatment� of� all� legitimate
participants.��� It�would�establish�legally�binding�obligations�for�the�handling�of
dangerous�pathogens�as�the�BWC�and�the�Biodiversity�Convention�do.��It�would
apply�to�all�relevant�biotechnology�research�activities�–�academic,�government
and�industry�–�as�is�the�case�with�the�UK�regulations�on�GMOs.��And�like�the
NIH� Guidelines,� it� would� rely� heavily� on� input� from� scientists� themselves,
whose� judgments� would� be� critical� to� any� evaluation� of� the� potential
implications�of�a�given�research�project.
Many�of�the�specific�elements�that�might�be�included
in�an�advanced�oversight�system�like�the�BRSS�can
also� be� found� within� these� existing� oversight
arrangements.�� Several� of� the� provisions� of� the� US
and� UK� anti-terrorism� legislation,� for� example,
including� those� requiring� facility� registration,
information� disclosure� (on� both� researchers� and
pathogens),� data� management,� background� checks,
and�inspections,�are�directly�relevant�to�strengthening
oversight� of� biological� research.�� The� US� NIH
Guidelines�and�the�UK�regulations�on�GMOs�take�the
oversight� process� one� step� further,� requiring� tiered
oversight�and�prior�approval�of�certain�categories�of
research� involving� the� construction� of� genetically
modified� organisms.�� Both� the� UNEP� Technical
Guidelines� and� current� US� regulations� governing
human� subject� research� require� a� risk-benefit
assessment� of� all� proposed� research� projects� and
careful� record� keeping� throughout� the� oversight
process.���Even�more�advanced�still�are�the�oversight
…some of the key
principles of a more
advanced system for
oversight of dual-use
research can be found
within these existing
arrangements.
Controlling�Dangerous�Pathogens�Report 19
�arrangements�in�the�UK�for�animal�research,�in�which�risk-benefit�assessment�is
coupled�with�a�triple�licensing�system�—�of�places,�people,�and�projects�—�in
an�effort�to�guard�against�inappropriate�or�dangerous�experiments.��All�of�these
elements�have�a�potential�role�to�play�in�a�Biological�Research�Security�System.
20 Controlling�Dangerous�Pathogens�Report
�.�.�.�.�.�.�.�.�.�.
.�.�.�.�.
Elements of a Prototype
Oversight System
Individual�scientists,�institutions,�and�security�officials�must�currently�find�their
own�balance�between�the�norm�against�destructive�applications�of�biology�and
the� equally� strong� but� sometimes� contradictory� scientific� drive� to� answer
interesting� questions� and� find� useful� applications� of� fundamental� research.52
They�have�little�knowledge�of�the�decision�rules�used�by�others,�and�often�no
independent�external�review.�� The�Biological�Research�Security�System�would
reflect�a�shared�recognition�that,�for�some�types�of�research,�either�foregoing�the
work� or� proceeding� with� inadequate� protections� could� have� damaging
consequences�that�extend�far�beyond�the�laboratory,�firm,�or�country�where�the
decision�was�made.��For�these�consequential�lines�of�research,�the�BRSS�would
provide� common� standards,� peer� review,� and� reassurance� that� the� power� of
biology�was�being�used�appropriately.
The� right� balance� between� freedom� of� scientific� investigation� and� protective
oversight�depends�on�the�degree�of�risk�involved.��Therefore,�the�design�of�the
Biological� Research� Security� System� must� start� by� attempting� to� define� the
different�levels�of�research�activity�of�concern�so�that�they�can�be�matched�with
the� appropriate� oversight� procedures.�� The� next� step� is� to� address� a� set� of
architectural� questions� associated� with� the� overall� system� design,� such� as
principles� and� elements,� information� disclosure� requirements,� institutional
structure,�and�verification�and�compliance�management.�� The�third�requirement
is�to�explain�how�the�system�might�work�in�practice�at�each�level�of�oversight.
Each�of�these�issues�is�addressed�below.
Defining�Research�of�Concern
The�first�and�arguably�most�critical�step�in�establishing�a�protective�oversight
arrangement� is� that� of� determining� a� reasonably� clear,� globally� credible� and
judiciously�limited�scope�of�application.�� Legal�obligations�cannot�be�imposed
unless�they�are�precisely�and�legitimately�defined.��Obligations�formally�imposed
will�not�be�effectively�implemented�unless�the�burden�entailed�is�credibly�related
to�a�justifying�purpose.��The�determination�of�that�purpose�must�be�understood
and�accepted�in�the�entire�community�affected.
In�regulatory�practice�to�date,�the�purpose�of�oversight�has�been�more�restricted
but�the�scope�of�application�often�more�expansive�than�the�Biological�Research
Security� System� would� presumably� require.�� For� almost� three� decades,
pathogens� have� been� graded� into� four� categories� of� danger� in� order� to� set
biosafety� standards� for� preventing� laboratory� accidents.�� The� more� recent� US
select�agent�list�and�UK�pathogen�control�lists�were�constructed�by�researchers
and�medical�professionals�taking�into�account�the�demonstrated�effects�of�the
Controlling�Dangerous�Pathogens�Report 21
�agents�in�question�as�well�as�their�susceptibility�to�public�health�measures�and
medical�treatment.��The�judgments�made�are�plausible�in�each�instance,�but�the
security�risks�associated�with�the�various�listed�agents�differ�considerably.
The�threat�posed�by�anthrax,�for�example,�is�quite�severe�–�usually�lethal�–�to
those� who� inhale� the� bacterial� spores� without� realizing� they� have� done� so.
Since�there�is�typically�a�two-day�incubation�period�before�the�disease�produces
detectable� symptoms,� however,� and� since� the� toxin-producing� spores� are
normally� quite� susceptible� to� antibiotic� treatment,� the� severity� of� the� threat
depends�a�great�deal�on�the�stealth�and�efficiency�of�its�original�dissemination.
A� person� afflicted� with� anthrax� generally� will� not� infect� another� individual.
Smallpox,�by�comparison,�is�less�likely�to�be�lethal�to�a�given�individual�but�is
nonetheless�much�more�dangerous�to�society�generally�because�the�virus�spreads
from�one�individual�to�another.��In�some�historical�outbreaks�of�smallpox�each
infected�individual�has�infected�on�average�some�two�to�three�other�individuals,
a�multiplication�factor�sufficient�to�generate�a�devastating�epidemic,�absent�rapid
intervention.�� The�case�fatality�rate�for�smallpox�epidemics�has�typically�been
around�30%.��Most�variants�of�the�influenza�virus�are�yet�more�contagious�than
smallpox� but� also� much� less� lethal.�� Even� so,� the� notorious� 1918� H1N1
influenza�strain�killed�somewhere�between�20�and�40�million�people�worldwide
in�the�course�of�a�year,�with�a�case�fatality�rate�estimated�to�have�been�about
4%.�� The�anthrax�bacterium�and�the�variola�virus�that�causes�smallpox�are�on
the� select� agent� list.�� Until� October� 2005,� when� H1N1� was� added,� the� only
influenza�strain�on�the�select�agent�list�was�avian�influenza.
An
If�one�of�the�primary�goals�of�the�BRSS�is�to�prevent�both�the�inadvertent�and
the�deliberate�creation�of�biological�agents�that�are�yet�more�lethal�or�otherwise
more�destructively�consequential�than�those�presently�known,�then�the�current
control�lists�are�inherently�inadequate.��They�do�not�include�pathogens�that�have
become� conceivable� but� do� not� yet� exist� and� are� not� officially� named.
Regarding� those� pathogens� that� do� exist� and� provide� the� basis� for� the
construction�of�more�destructive�variants,�the�lists�are�at�once�too�inclusive�and
not�inclusive�enough.��They�designate�agents�such�as�anthrax�that�are�notorious
but�do�not�pose�a�mass�danger.��But�until�recently,�they�omitted�one�of�the�most
virulent� strains� of� influenza,� perhaps� the� most
contagious�known�agent,�despite�the�fact�that�it�could
be� made� more� lethal.�� They� do� not� address� research
techniques� that� might� transform� currently� benign
initial
biological�agents�into�massively�destructive�ones.
approximation of the
concept of intrinsic
danger can be
derived from basic
epidemiology.
To�address�the�priority�concern�effectively,�an�intrinsic
definition�of�danger�will�not�only�have�to�be�devised
but�also�translated�into�a�form�that�can�be�implemented
successfully.��Admittedly,�these�requirements�are�much
easier� to� state� than� to� accomplish.�� But� an� initial
approximation�of�the�concept�of�intrinsic�danger�can�be
derived� from� basic� epidemiology.�� It� is� generally
understood� that� the� course� of� an� infectious� disease
depends� on� two� basic� characteristics� of� the� pathogen
that�causes�it:�the�ability�to�transfer�spontaneously�from
one�host�to�another�and�the�consequence�for�the�host�of
the�resulting�infection.�Using�common�sense�terms,�one
can� label� the� first� property� transmissibility� and� the
22 Controlling�Dangerous�Pathogens�Report
�second� virulence.� Although� any� disease� outbreak� is� also� affected� by
environmental�circumstances,�public�health�measures,�individual�immune�system
reactions�and�therapeutic�treatment,�for�a�given�set�of�such�conditions�pathogens
clearly� vary� in� terms� of� transmissibility� and� virulence.� None� of� the� currently
known�pathogens�sets�the�highest�standard�for�both�properties,�and�there�is�some
tradeoff� between� them.� In� particular� a� disease� that� is� too� rapidly� lethal
undermines�its�ability�to�propagate�between�hosts.�There�is�no�reason�to�believe,
however,� that� either� the� intrinsic� limits� of� these� properties� or� the� most
destructive�combination�has�yet�been�demonstrated�in�nature.�As�the�dynamics
of�disease�are�understood�in�more�detail,�it�has�become�evident�that�the�natural
process� of� evolution� has� been� moderating� rather� than� maximizing� the� overall
lethality�of�human,�plant,�and�animal�pathogens.�In�principle,�this�moderating
effect�might�be�overturned�by�deliberate�or�accidental�human�intervention.
One�can�imagine�a�definition�of�intrinsic�danger�based�on�the�combination�of
transmissibility�and�virulence�of�known�pathogens�as�suggested�in�Figure�1.��In
principle�these�two�properties�might�be�measured�in�some�standard�manner�and
each� known� pathogen� or� agent� located� in� the� two� dimensional� space� of� the
Figure.� The� space� might� then� be� segmented� in� terms� of� the� degree� of� social
danger�posed�as�indicated�by�the�bands.�Research�techniques�can�be�conceived
as�vectors�operating�in�this�space�–�that�is,�as�arrows�indicating�magnitude�and
direction.�� If� a� given� technique� is� judged� or� shown� to� be� capable� of
transforming�a�given�agent�so�as�to�move�it�into�a�higher�danger�zone,�then�the
oversight�procedures�associated�with�that�zone�would�be�applied�as�soon�as�the
potential�is�recognized.�� This�approach�would�consider�the�pathogens�and�the
research�techniques�being�applied�to�them,�thus�combining�elements�of�the�US
select�agent�program,�which�focuses�solely�on�agents,�and�the�Fink�Committee
and�NSABB�approaches,�which�focus�solely�on�research�activities.
Under� this� conception,� the� highest� demonstrated� values� for� each� of� the
dimensions� would� delineate� the� threshold� of� maximum� concern,� and� the
oversight� process� would� attempt� to� keep� the� area� beyond� those� thresholds
unoccupied�in�nature�even�if�it�is�explored�in�science.�� Work�with�a�restricted
set�of�pathogens�whose�performance�defines�the�threshold�area�would�be�given
special� designation� and� subjected� to� the� most� active� form� of� international
oversight.�� Successively�less�intrusive�and�more�permissive�forms�of�oversight
would�be�applied�to�the�lower�bands�of�concern.
Admittedly,�it�would�be�very�difficult�to�establish�broadly�agreed�measures�of
transmissibility�and�virulence�for�all�known�pathogens,�let�alone�to�predict�how
much�change�might�result�from�a�proposed�research�activity.��Generally�agreed
specifications�for�even�the�most�prominent�pathogens�cannot�be�extracted�from
existing� literature,53� and� a� systematic� effort� to� undertake� the� measurements
required�could�not�be�organized�until�the�feasibility�and�importance�of�doing�so
was� broadly� established.��One� can� nonetheless� attempt� to� connect� the� basic
conceptualization� of� danger� represented� in� Figure� 1� to� an� operational
specification�of�differing�risk�levels�that�practicing�scientists�would�recognize.
A�notional�categorization�scheme�is�outlined.
Controlling�Dangerous�Pathogens�Report 23
�Figure 1: Conceptual Categorization of Danger
Extreme Concern
Work involving the most
dangerous of currently
known pathogens or
possibly resulting in the
creation of a significantly
more dangerous pathogen.
Moderate concern
Work with listed agents,
particularly activities that
enhance weaponization.
Potential concern
Work that significantly
increases the destructive
potential of non-threat
agents.
The� category� of� extreme� concern� is� limited� largely� to� the� relatively� few
activities�that�involve�or�could�result�in�pathogens�significantly�more�dangerous
than�those�that�currently�exist.��It�also�includes�some�work�with�agents�classified
as�BSL-4/ABSL-4�in�the�United�States�or�equivalent�levels�in�other�countries.
The� category� of� moderate� concern� encompasses� a� larger� universe� of� activity
involving�biological�agents�already�identified�as�posing�a�threat�to�public�health,
particularly�activities�that�enhance�the�potential�of�such�agents�to�be�used�as�a
weapon.�� The� US� select� agent� list� is� used� for� illustrative� purposes,� but� it� is
recognized� that� an� agreed� list� would� have� to� be� developed� and� maintained.
Under� an� advanced� oversight� system,� this� would� be� done� internationally,� as
discussed�below.��The�category�of�potential�concern�focuses�largely�on�activities
that�increase�the�destructive�potential�of�biological�agents�that�otherwise�would
not�be�considered�a�threat.��The�research�activities�covered�by�these�categories
are�very�similar�to�the�experiments�of�concern�outlined�in�the�Fink�Committee
report,� but� have� been� calibrated� to� distinguish� between� different� levels� of
concern.
In�principle,�the�research�activities�listed�in�Table�I�could�be�used�to�determine
oversight�jurisdiction�while�the�parameters�of�transmissibility�and�virulence�in
Figure�I�could�be�used�as�general�guidelines�for�judgment�within�each�of�the
oversight�jurisdictions.�� But�as�discussed�below,�more�specific�criteria�are�also
needed�to�assess�the�benefits�and�risks�of�proposed�research�projects�and�thus
whether�and�under�what�circumstances�they�should�proceed.
24 Controlling�Dangerous�Pathogens�Report
�Table I: Illustrative Categories of Research Activities
Activities of Extreme Concern (AEC)
Work with eradicated agents*; work with an agent assigned as BL-4 / ABL-4; de
novo synthesis of above; expanding the host range of an agent to a new host (in
humans, other animals and plants) or changing the tissue range of a listed agent**;
construction of antibiotic- or vaccine-resistant listed agent.
Activities of Moderate Concern (AMC)
Increasing virulence of listed agent or related agent; insertion of host genes into
listed agent or related agent; increasing transmissibility or environmental stability
of listed agent or related agent; powder or aerosol production of listed agent or
related agent; powder or aerosol dispersal of listed agent or related agent; de
novo synthesis of listed agent or related agent; construction of antibiotic- or
vaccine-resistant related agent; genome transfer, genome replacement, or
cellular reconstitution of listed agent or related agent.
Activities of Potential Concern (APC)
Work with listed agents – or exempt avirulent, attenuated, or vaccine strain of a
listed agent –- not covered by AEC/AMC; Increasing virulence of non-listed
agent; increasing transmissibility or environmental stability of non-listed agent;
powder or aerosol production of non-listed agent; powder or aerosol dispersal of
non-listed agent; de novo synthesis of non-listed agent; genome transfer, genome
replacement, or cellular reconstitution of non-listed agent.
*� This� would� include,� for� example,� activities� with� the� 1918� influenza� virus� and� chimeric
influenza�viruses�with�at�least�one�gene�from�the�1918�influenza�virus.
**�This�would�include,�for�example,�activities�with�chimeric�influenza�viruses�with�at�least�one
gene�from�a�human�influenza�virus�and�at�least�one�gene�from�an�avian�influenza�virus.
Table Definitions
Agent: fungus, protozoan, bacterium or archaeon, virus, viroid, or prion; or genetic element,
recombinant nucleic acid, or recombinant organism.
Listed Agent: agent on CDC Select Agent list, USDA High-Consequence Livestock Pathogens
list, or USDA/APHIS/PPQ Plant Pathogens list.
Related agent: for fungi, protozoans, or bacteria or archaea, an agent that currently is, or in
the last two years was, assigned to the same genus as a listed agent; for viruses, viroids, or
prions, an agent that currently is, or in the last two years was, assigned to the same family as
a listed agent; for genetic elements, recombinant nucleic acids, or recombinant organisms, an
agent orthologous to a listed agent. (This includes any avirulent, attenuated, or vaccine strain
of a listed agent, if said strain is exempt under the CDC Select Agent list, USDA HighConsequence Livestock Pathogens list, or USDA/APHIS/PPQ Plant Pathogens list.)
Non-listed agent: agent other than a listed agent or related agent.
Eradicated agent: agent previously in circulation in nature but not within the last decade, as
determined by cases of or isolation from humans, animals, or plants, or by detection of antibodies
to the agent from individuals younger than the time-span elapsed since the last recorded isolation.
De novo synthesis: construction of agent using synthetic genomic nucleic acid (non-prion agents) or
synthetic protein (prions), irrespective of whether said construction require additional reagents, extracts,
cells, or ‘helper’ entitites. For purposes of this definition, ‘synthetic genomic nucleic acid’ refers to
nucleic acid that corresponds to an agent genome and that is prepared using, in any step or set of steps,
chemically synthesized oligonucleotides, corresponding to at least 5% of said agent genome.
Powder: powder other than lyophilized reference specimen (<10 mg).
Antibiotic: antibiotic of therapeutic utility against listed agent.
Vaccine: vaccine of therapeutic utility against listed agent.
Controlling�Dangerous�Pathogens�Report 25
�This� approach,� which� focuses� on� the� impact� of� certain� research� activities� on
pathogens,�will�be�criticized�by�those�concerned�with�consequential�applications
of� biotechnology� that� do� not� involve� pathogens.�� The� manipulation� of� the
immune� system,� for� example,� using� bioregulators�delivered�by�non-microbial
mechanisms�such�as�immunotoxins�or�fusion�proteins�is�a�case�in�point.54��But
the� most� likely� means� of� delivery� for� bioregulators,� the� ones� that� have� been
developed�farthest�up�to�now,�are�either�aerosols�or�modified�viruses�or�bacteria,
both�of�which�are�covered�by�our�oversight�system.�� Moreover,�if�very�large
numbers�of�people�—�in�the�hundreds�of�millions�or�more�—�are�to�be�exposed
to�a�lethal�or�otherwise�nefarious�effect�in�a�short�period�of�time,�at�the�moment
that�could�only�be�accomplished�by�a�highly�transmissible�and�highly�virulent
pathogen.�� That� fact� provides� an� obvious� rationale� for� devising� an� oversight
arrangement�whose�initial�scope�of�application�is�limited�to�the�effects�of�certain
research�techniques�on�the�inherent�properties�of�pathogens.
The� Fink� Committee� clearly� believed� that� the� experiments� of� concern� that� it
proposed�for�oversight�were�a�starting�point�for�what�ultimately�would�be�an
evolving�system�of�review.��“The�Committee�has�initially�limited�its�concerns�to
cover�those�possibilities�that�represent�a�plausible�danger,”�the�report�declared.
“Over�time,�however,�the�Committee�believes�it�will�be�necessary�to�expand
the� experiments� of� concern� to� cover� a� significantly� wider� range� of� potential
threats.”55��So�too�is�it�with�our�approach.��Extensive�additional�discussions�within
the�many�relevant�professional�communities�will�be�required�to�work�out�which
research�activities�should�fall�under�the�different�oversight�levels�in�our�system
and,�ultimately,�to�extend�the�oversight�process�to�include�other,�non-pathogenrelated�concerns.��One�cannot�be�confident�in�advance�that�workable�consensus
could�be�achieved.�� It�seems�evident,�however,�that�an�organized�effort�of�this
sort� should� be� attempted.�� If� it� did� succeed,� it� would� provide� the� clarity� of
definition�that�is�essential�for�a�protective�oversight�arrangement.�� If�it�did�not
succeed,�presumably�the�effort�would�be�instructive.
System�Architecture
Since� there� appears� to� be� no� valid� categorical� distinction� that� can� be� made
between�potentially�beneficial�and�potentially�destructive�lines�of�fundamental
research,� there� is� a� natural� presumption� that� protective� oversight� must� be
performed�by�scientific�peers�able�to�understand�the�technical�details�of�each
individual�project�and�to�discern�the�probable�implications.��But�there�is�also�a
presumption� that� protective� oversight� would� have� to� include� people� whose
experience� and� training� would� prepare� them� to� judge� social� consequence� –�a
significant� extension� of� the� established� practice� of� scientific� peer� review.
Because� both� the� scientific� and� the� social� judgments� made� would� have� very
broad�consequence�and�would�be�potentially�controversial,�one�would�want�them
to� emerge� from� a� collaborative� effort� involving� the� relevant� professional
communities�and�government�authorities,�rather�than�simply�being�imposed�by�a
government�bureaucracy�alone.��At�the�same�time,�one�needs�the�legal�authority,
financial� resources,� and� the� clarity� of� obligations� that� come� from� formal
intergovernmental�agreement�on�oversight�standards�and�practices.
26 Controlling�Dangerous�Pathogens�Report
�For�maximum�effectiveness,�an�oversight�system�would�have�to�be:
globally�implemented;
applied�without�exception�to�all�scientists�engaged�in�relevant�research;
adequately�financed;
efficiently�organized;
backed�by�appropriate�legal�authority;�and
accompanied�by�credible�provisions�to�prevent�misuse�of�its�authority.
In�meeting�those�requirements�the�oversight�process�would�have�to�establish�and
preserve�some�important�balances.��Comprehensive�jurisdiction�over�all�relevant
research� would� have� to� be� qualified� by� judicious� limitation� of� the� oversight
mandate� to� those� areas� of� research� that� validly� pose� the� possibility� of� broad
social�danger�–�hence�the�importance�of�identifying�the�determinants�of�social�as
distinct� from� individual� danger.�� Within� that� limited� mandate,� oversight
judgments�would�have�to�assess�the�balance�of�benefit�and�risk�and�recommend,
whenever�possible,�ways�to�achieve�the�beneficial�objectives�while�minimizing
potential�danger.
Full� realization� of� all� of� those� provisions� would� clearly� be� a� major� feat� of
institutional�innovation.��Many�would�argue�it�is�an�improbable�accomplishment
and� some� would� consider� it� intrinsically� undesirable� because� of� its� inherent
intrusiveness.�� The� underlying� problem� is� certainly� serious� enough� to� induce
innovation�of�some�sort,�however,�and�those�who�pose�categorical�objections�are
obliged� to� offer� an� equally� effective� scheme.�� Meanwhile� the� idea� of� an
advanced�oversight�arrangement�is�a�useful�reference�both�for�assessing�potential
alternatives�and�for�considering�other�measures�that�could�lay�the�foundation�for
a�more�advanced�oversight�system�and�that�could�more�readily�be�achieved.
Principles�and�Elements
The�basic�standard�on�which�any�oversight�arrangement�would�be�based�is�the
principle� that� biology� should� not� be� used� to� do� deliberate� harm� under� any
circumstance�for�any�reason.��That�is�the�core�principle�of�the�Hippocratic�Oath
that�has�been�recognized�since�ancient�times.�� It�is�also�the�core�principle�that
underlies�the�prohibition�on�the�use�of�biological�weapons�promulgated�in�the
1925�Geneva�Protocol�and�on�the�possession�of�biological�weapons�embodied�in
the�Biological�Weapons�Convention.��Although�neither�of�those�accords�enjoys
universal� legal� adherence,� no� country� currently� proclaims� the� right� or� the
intention� to� deploy� biological� weapons.�� The� basic� standard� is� already� in
practice� a� universal� norm,� and� it� could� be� substantially� strengthened� with� a
dedicated� effort� to� do� so.�� Indeed,� a� central� purpose� of� an� oversight� process
would� be� to� assure� consciousness� of� the� basic� standard� by� those� undertaking
work� that� could� pose� a� meaningful� violation� and� to� provide� reasonable
reassurance�of�their�compliance�calibrated�to�the�degree�of�danger�entailed�in�the
work�they�are�doing.
The� oversight� process� would� include� two� key� elements.�� The� first,� national
licensing,�would�be�used�to�identify�relevant�individuals�and�research�facilities
and�formalize�their�adherence�to�the�basic�norm.��Similar�processes�are�already
being�used�in�advanced�biology�to�ensure�that�certain�individuals�and�facilities
meet�specified�security�and�safety�requirements.�� For�example,�both�the�May
2002� bioterrorism� bill� and� the� select� agent� regulations� in� the� US� require
Controlling�Dangerous�Pathogens�Report 27
�background� checks� on� any� individual� having� access� to� select� agents� and
registration� of� relevant� facilities.�� Various� regulations� in� the� US� and� other
countries� also� require� licensing� of� facilities� that� produce� drugs� and� other
products� derived� from� biotechnology� to� ensure� their� safety� and� efficacy.
Outside� of� biology,� there� are� other� examples� of� licensing� requirements� for
individuals� and� facilities� engaged� in� activities� that� could� affect� substantial
numbers� of� people� —� doctors,� for� example,� and� laboratories� that� work� with
radioactive�materials.
The�personnel�licensing�requirement�would�extend�to�all�scientists,�students�and
technical�staff�proposing�to�conduct�research�covered�by�the�oversight�system.
The�purpose�of�the�licensing�would�be�to�ensure�that�the�affected�individuals�are
technically� qualified� (either� by� virtue� of� an� academic� degree� or� on� the� job
experience),�have�undertaken�biosecurity�training�(and�thus�have�been�sensitized
to� the� dual-use� potential� of� their� work� and� educated� about� both� national� and
international�oversight�rules),�and�have�nothing�in�their�background�(such�as�a
past�biosafety�violation)�that�would�make�it�inappropriate�for�them�to�conduct
consequential�research.�� Receipt�of�a�personnel�license�would�be�viewed�as�an
acknowledgment� of� the� individual’s� special� status� within� his� or� her� broader
professional�community.��The�facility�licensing�requirement�would�extend�to�all
facilities�where�relevant�research�takes�place,�and�would�be�designed�to�ensure
that�such�facilities�meet�existing�safety�and�security�standards.
In� addition� to� personnel� and� facility� licensing,� there� would� also� be� a� vetting
requirement�for�other�students,�secretaries,�janitors�and�individuals�working�in
licensed�facilities�but�who�are�not�themselves�conducting�research�that�is�subject
to�oversight�under�the�system.��The�purpose�of�this�vetting�process�would�be�to
ensure�that�there�is�nothing�in�the�individual’s�background�that�would�make�it
inappropriate�for�them�to�have�access�to�areas�where�controlled�pathogens�are
stored.�� In� implementing� both� this� vetting� requirement� and� the� personnel
licensing� system,� it� will� be� important� to� ensure� that� individuals� are� not
arbitrarily� disapproved� for� political� or� other� reasons� unrelated� to� their
qualifications�to�carry�out�the�relevant�work.
The� second� element� is� independent� peer� review� of� relevant� projects� prior� to
their�initiation.��Any�individual�interested�in�conducting�research�covered�by�the
oversight�system�would�be�required�to�provide�information�about�their�proposed
project�to�the�appropriate�oversight�body�for�review�and�approval.�� To�ensure
equitable�treatment�of�all�proposed�research�projects�both�within�and�between
the�different�oversight�levels,�common�criteria�would�be�needed�by�the�relevant
review�bodies�for�use�in�assessing�the�potential�benefits�of�the�work�as�well�as
the�possible�risks.�� Such�a�risk-benefit�assessment�process�would�be�similar�to
that�which�is�currently�required�in�the�US�for�IRB�approval�of�human�subject
research.��Like�the�IRB�review�process,�the�risk-benefit�assessment�of�dual-use
biological�research�would�apply�to�all�relevant�research,�irrespective�of�whether
it� is� to� be� carried� out� in� a� government,� industry� or� academic� laboratory.�� In
addition,� the� relevant� review� body� would� be� required� to� consider� certain
specified�issue�areas�as�part�of�its�deliberations�and�to�document�the�discussion
of� these� issues� as� well� as� its� overall� risk-benefit� assessment� in� its� meeting
minutes.��A�record�of�the�review�judgments�would�be�preserved�at�all�levels�and
under� the� most� advanced� arrangement� the� international� review� body� would
periodically� organize� efforts� to� harmonize� the� judgments� made� by� separate
28 Controlling�Dangerous�Pathogens�Report
�national� and� local� review� bodies� using� project� case� histories� as� the� basis� for
discussion.
Ten�issue�areas�and�nearly�two�dozen�suggested�questions�are�listed�on�the�IRB
review�protocol.56��Based�on�a�peer�review�simulation�exercise�of�five�hypothetical
projects,57�we�have�developed�a�comparable�set�of�issues�and�questions�that
could� be� used� to� assess� the� risks� and� benefits� of� proposed� dual-use� research
projects.��The�first�two�issue�areas,�which�focus�on�biosafety�and�the�details�of
the�proposed�research�plan,�concern�the�conduct�of�the�work.�� The�remaining
four�issue�areas�relate�to�the�justification�for�the�work,�and�cover�public�health,
biodefense,� current� necessity� and� potential� impact.�� Similar� issue� areas� and
questions�have�been�suggested�by�the�British�Royal�Society�for�assessing�dualuse� research.58� � Our� notional� risk-benefit� assessment� criteria� are� listed� in
Table�II.
Information�Disclosure
As� the� criteria� outlined� above� show,� meaningful� peer� review� would� require
disclosure�to�the�appropriate�review�body�of�detailed�information�necessary�to
weigh� the� risks� and� benefits� of� a� proposed� experiment.��� In� an� advanced
arrangement,�the�international�review�body�would�have�primary�right�to�information�directly�relevant�to�projects�falling�under�its�jurisdiction.�� In�particular,
information�demonstrating�extreme�risk�to�the�human�species�as�a�whole�would
have�to�be�disclosed,�as�would�information�relating�to�the�defining�determinants
of�risk.��Within�a�strict�definition�of�direct�relevance,�these�requirements�would
override� considerations� based� on� proprietary� interest� or� national� security.
National�and�local�review�bodies�would�also�need�sufficient�information�to�be
able�to�assess�projects�and,�assuming�that�the�overall�judgment�was�positive,�to
make�recommendations�about�ways�to�maximize�benefit�while�minimizing�risk.
In� rare� cases,� the� relevant� review� body� might� decide� to� approve� a� proposed
project�but�to�restrict�the�dissemination�of�information�about�the�project�or�its
results.�� That� would� require� agreed� guidelines� for� determining� whether� and
under�what�circumstances�information�might�have�to�be�restricted�or�classified.
It� would� also� require� an� agreed� process� for� determining� who� could� be� given
access� to� controlled� information,� based� on� professional� qualification� and
documented� responsibility� rather� than� on� national� identity� or� organizational
affiliation.�� At� the� moment� there� are� no� such� provisions,� and� practical
discussions� generally� debate� the� merits� of� open� publication� as� compared� to
propriety�or�national�security�classification.
One�possible�approach�would�be�to�build�upon�the�ideas�outlined�in�1982�by�a
National�Academy�of�Sciences�panel�on�scientific�communication�and�national
security� chaired� by� former� Cornell� University� President� Dale� Corson.�� The
Corson�Report,�as�it�is�known,�concluded�that�the�national�welfare,�including
national�security,�is�best�served�by�allowing�the�free�flow�of�all�scientific�and
technical�information�“not�directly�and�significantly�connected�with�technology
critical� to� national� security.”�The� report� recommended� that� most� fundamental
research� at� universities� should� be� unclassified;� that� a� limited� amount� might
require� classification;� and� that� a� small� grey� area� could� require� limited
restrictions� short� of� classification.�� Criteria� for� making� these� classification
decisions�were�also�included,�which,�with�some�modification,�could�serve�as�a
model�for�similar�decisions�concerning�sensitive�life�sciences�research�today.59
Controlling�Dangerous�Pathogens�Report 29
�Table II: Notional Criteria for
Risk-Benefit Assessment of Dual-Use Research
Biosafety Issues
(1) Does the proposed research plan contain appropriate protections to minimize risk
to the public or environment?
•
Proposals receiving a “no” answer would have a low biosafety rating
Evaluation of Research Plan
(1) Are the proposed research plan and stated rationale for the work consistent with
one another?
(2) Are the risks posed by the agent (either from the perspective of public health or
bioterrorism) and the stated rationale for the work consistent with one another?
(3) Is the proposed research plan logically sequenced?
(4) Are there scientific reasons why the same outcome cannot be pursued through
alternate means? For example, could other methods or materials be used?
•
Proposals receiving two or more “no” answers would have a low
research plan evaluation rating
Public Health Considerations
(1) Do agents to be constructed currently exist in nature?
(2) If not, are said agents expected to be generated by natural processes?
(3) Will the research advance our understanding of disease-causing properties of
currently existing agents?
•
Proposals receiving “no” answers either to questions (1) and (2) or
to question (3) would have low public health rationale
Biodefense Considerations
(1) Do agents to be constructed currently exist in nature?
(2) If not, is the work being done in response to a “validated threat” (i.e. one for
which there is credible information) or “theoretical threat” (i.e. one that is
possible but for which there is no credible information)?
(3) Will the countermeasures that are expected to result from the work significantly
reduce the threat posed by the agent?
•
Proposals receiving two or more “no” answers would have low
biodefense rationale
Current Necessity
(1) Are countermeasures against agents to be constructed currently unavailable?
(2) Are there scientific reasons why countermeasures cannot be developed without
access to such agents?
•
Proposals receiving one or more “no” answers would be of limited
current necessity
Potential Impact
(1) Will the proposed research contribute to new knowledge (e.g., by furthering our
understanding of basic life processes or pathogenesis) rather than primarily
confirm work already done?
(2) Are the research results likely to be definitive enough to inform policy decisions
(e.g., vaccination strategies)?
(3) Are there significant obstacles to using the research results to develop a more
dangerous pathogen or to overcome current countermeasures?
•
Proposals with two or more “no” answers would have limited
positive impact
30 Controlling�Dangerous�Pathogens�Report
�Admittedly,� the� context� in� which� the� Corson� panel� put� forward� its
recommendations�is�very�different�than�the�one�the�world�currently�faces.��The
1982�Report�was�a�response�to�concerns�that�the�Soviet�Union�was�benefiting
militarily�from�access�to�US�scientific�and�technical�information,�especially�in
computer�science�and�other�areas�of�the�physical�sciences.��Today,�the�dominant
concern�is�about�a�much�more�diffuse�set�of�national�and�possibly�subnational
actors�misusing�advances�in�the�life�sciences�for�hostile�purposes.��But�no�rogue
nation�much�less�any�terrorist�group�that�currently�exists�is�better�capable�than
the�Soviet�Union�was�of�adapting�fundamental�research�results�for�destructive
purposes.�� If� these� criteria� were� deemed� appropriate� to� deal� with� the� Soviet
military� threat,� they� should� be� at� least� as� effective� against� the� much� less
sophisticated�threats�the�world�now�faces.
Drawing�on�the�Corson�Report,�one�could�require�that�no�restrictions�should�be
placed�on�basic�or�applied�research�or�research�results�at�university,�industry�or
government�laboratories�unless�the�following�criteria�are�met:
the� technology� is� developing� rapidly� and� time� from� basic� science� to
application�is�short;
the�technology�has�identifiable�direct�military�applications�or�is�is�dualuse�and�involves�process�or�production-related�technologies;
the�transfer�of�technology�would�give�a�BW�proliferator�(e.g.,�national
level�or�subnational)�a�significant�near-term�capability;
there�are�no�other�sources�of�information�about�the�technology,�or�all
those�that�could�also�be�the�source�have�effective�systems�for�securing
the�information;�and,
the�duration�and�nature�of�the�proposed�restrictions�would�not�seriously
compromise�the�work�of�those�directly�responsible�for�public�health.
The� requirement� to� take� account� of� the� public� health� implications� of� any
proposed� restrictions� was� not,� of� course,� part� of� the� original� Corson� panel
approach.��But�precisely�because�legitimate�applications�of�life�sciences�research
can�have�a�profoundly�positive�impact�on�public�health,�considering�only�the
security�implications�of�such�research�is�not�sufficient.
In�situations�where�certain�research�results�might�need�to�be�restricted,�it�would
be� important� to� ensure� that� anyone� with� a� legitimate� need� to� know� for� the
purposes�of�research,�public�health�or�medical�practice�would�have�access�to�the
relevant�information,�and�that�such�access�is�documented�and�the�individual�is
held� accountable� to� rules� about� the� use� and� further� dissemination� of� the
information.�� A� relevant� process� was� used� by� the� US� NAS� to� handle� the
dissemination�of�sensitive�portions�of�its�2002�study�on�agricultural�bioterrorism.
In�response�to�security�concerns�from�the�US�Department�of�Agriculture,�which
funded� the� study,� NAS� officials� developed� guidelines� for� the� types� of
individuals�who�could�be�given�access�to�the�controlled�information.�� Anyone
interested� had� to� submit� a� written� request� and� be� interviewed� by� NAS� staff
before�being�provided�a�copy�of�the�controlled�information.60
Arguably,� arrangements� such� as� this� for� the� disclosure� and� use� of� scientific
information�might�be�more�readily�accepted�in�the�public�health�community�and
academia�than�in�industry�or�in�the�many�national�security�establishments�that
conduct�biological�research�programs.�� The�operating�principles�of�most�public
Controlling�Dangerous�Pathogens�Report 31
�health� practitioners� and� academics� are� generally� aligned� with� the� rules� of
transparency�and�independent�peer�review�even�if�they�do�not�as�yet�implement
them�to�the�extent�that�an�advanced�oversight�arrangement�would�require.�� In
contrast,� proprietary� and� national� security� organizations� generally� reserve� the
right� to� restrict� outside� access� to� their� research� activities� and� consider� that
practice� to� be� justified� by� their� respective� missions.�� At� the� present� time,
prevailing�definitions�of�legitimate�interest�are�not�refined�or�robust�enough�to
provide� a� widely� agreed� basis� for� subordinating� these� organizations� to� an
advanced�oversight�process.��The�authoritative�delineation�of�legitimate�interest
therefore� would� be� one� of� the� first� and� fundamental� requirements� for
implementing�such�an�oversight�arrangement.
Advanced�information�technology�would�be�used�at�each�level�of�the�oversight
system�to�help�protect�against�the�unauthorized�release�of�sensitive�information
and�to�facilitate�reporting�by�affected�researchers�and�to�speed�the�peer�review
process.�� To� illustrate� how� this� might� be� done,� we� built� a� prototype� data
management� system� using� open� source� software� and� financial-grade� security
standards.�� The�system�we�have�developed�has�a�tree-like�structure,�with�each
oversight�node�(i.e.�local�institutions,�national�authorities,�and�the�international
body)� operating� its� own� secure� server� for� storing� information� under� its
jurisdiction.�� Information� required� for� licensing� and� peer� review� would� be
collected�using�questionnaires�that�meet�BRSS�reporting�requirements�as�well�as
other� national� or� local� reporting� requirements.�� Information� would� be� sent
securely�from�one�node�to�another�–�such�as�when�a�proposed�project�meets�the
requirements�for�higher-level�review�–�but�higher-level�nodes�would�not�be�able
to�access�information�from�lower�nodes�without�the�lower�node’s� permission.
The�data�management�system�makes�it�easy�to�add�new�questionnaires�or�revise
existing�ones�and�automatically�propagate�these�changes�throughout�the�system
to�keep�pace�with�advances�in�science�and�technology.��The�use�of�open-source
software�decreases�expense�and�allays�concerns�about�hidden�features�while�still
including� multiple� levels� of� security.�� Details� about� the� prototype� data
management�system�are�in�Appendix�C.
Institutional�Arrangements
Decisions� concerning� the� institutional� entities� necessary� to� implement� the
oversight�system�would�naturally�be�a�product�of�the�process�that�created�them.
For� purposes� of� immediate� discussion,� we� use� the� term� Biological� Research
Security� System� to� describe� the� overall� arrangement.�� The� term� International
Pathogens�Research�Authority�(IPRA)�refers�to�the�body�that�would�fulfill�the
international� functions� of� the� BRSS.�� National� Pathogens� Research� Authority
(NPRA)�refers�to�the�governmental�bodies�exercising�national�oversight,�while
Local�Pathogens�Research�Committee�(LPRC)�refers�to�the�review�bodies�that
would�exercise�oversight�within�individual�institutions�or�regionally.
WHO�has�some�of�the�relevant�expertise�and�mission�that�would�be�relevant�to
a�fully�developed�IPRA,�given�its�work�in�recent�years�helping�develop�national
preparedness� and� response� capabilities,� international� disease� surveillance
systems,� and� laboratory� biosafety� and� biosecurity� guidelines� for� handling
pathogens.�� But� neither� it� nor� any� other� existing� international� organization
currently�has�either�the�specific�mandate�or�the�full�range�of�scientific,�security,
legal,� and� other� expertise� necessary� to� implement� an� advanced� oversight
arrangement.��Moreover,�since�plant�and�animal�pathogens�would�also�be�within
32 Controlling�Dangerous�Pathogens�Report
�its� scope� of� concern,� the� IPRA� would� have� to� have� a� close� functional
relationship�with�the�Food�and�Agricultural�Organization�(FAO)�and�the�World
Organization�for�Animal�Health,�known�as�the�OIE.�� Thus,�although�it�might
ultimately�be�desirable�to�bring�some�or�all�of�the�global-level�functions�of�the
IPRA�into�a�WHO�with�more�reliable�finances�and�more�authority,�for�now�it
makes�sense�to�conceptualize�the�international�part�of�the�system�without�being
constrained�by�the�limitations�of�any�existing�international�organization.
The� International� Pathogens� Research� Authority� need� not� be� a� large
organization,�but�it�will�require�an�administrative�structure�that�reflects�its�mixed
character� as� a� security,� scientific,� and� public� health� organization.�� The� IPRA
should�be�established�with�the�legal�authority�to�perform�some�functions�itself�(a
direct�system�of�regulation)�and�to�set�requirements�for�the�performance�of�other
functions� by� its� States� Parties� (an� indirect� system� of� regulation).�� Like� most
international�organizations,�it�should�include�a�governing�body�comprised�of�all
member�states�that�would�meet�annually�to�set�guiding�principles�and�priorities,
approve�budgets,�and�make�other�authoritative�policy�decisions.�� It�would�also
need� a� smaller� executive� body� to� oversee� implementation� of� the� system,� the
seats�on�which�would�be�allocated�both�to�ensure�geographic�representation�and
to�reflect�the�global�distribution�of�relevant�industries�and�scientific�expertise.
The�IPRA�would�also�need�a�technical�secretariat,�as�well�as�several�standing
committees� that� include� policy� representatives� from� national� delegations,
specialists� from� the� technical� secretariat,� and� non-governmental� experts� as
needed.�� It� would� also� have� special� committees� of� internationally� respected
scientists� and� security� experts� who� would� be� responsible� for� peer� reviewing
research�of�extreme�concern�and�for�helping�define�the�research�activities�that
would�be�subject�to�oversight�at�each�level�of�the�system.61
To�achieve�the�requirements�of�an�advanced�oversight�arrangement,�the�BRSS
would�have�to�be�established�by�treaty�or�an�equivalent�legal�instrument�and
adherence�to�the�instrument�would�have�to�be�made�such�an�insistent�obligation
that� all� countries� would� be� under� enormous� pressure� to� ratify� it.�� The� IPRA
would�have�to�be�provided�with�an�assured�budget�tailored�to�its�responsibilities.
Under�an�advanced�conception,�the�IPRA�would�have�the�following�functions:
1. It�would�define�the�categories�of�research�activities�subject�to�oversight�and
establish�standards�for�review,�with�updates�as�required�to�keep�pace�with
scientific�advancement.
2. It�would�conduct�the�oversight�process�for�all�projects�involving�activities�of
extreme� concern,� including� initial� approval� of� the� individuals,� research
facilities�and�projects;�implementation�of�the�approved�research�plan;�and
dissemination�of�the�results.
3. It� would� determine� the� criteria� for� identifying� research� that� is� of� unusual
importance�for�reasons�of�global�protection�and�would�actively�encourage
and�fund�high�priority�projects�meeting�those�criteria,�whether�identified�by
the�organization�or�outside�researchers.
4. It� would� establish� reporting� requirements,� rules� for� access� to� sensitive
information,�and�protections�against�the�misuse�of�disclosed�information.
Controlling�Dangerous�Pathogens�Report 33
�5. It� would� provide� software� and� technical� support� for� a� secure� data
management�system�to�be�used�at�each�oversight�level�and�would�maintain�a
database�of�information,�including�strain�variations,�on�all�projects�reviewed
under�international�authority.
6. It�would�provide�scientific,�legal,�and�technical�assistance�upon�request�to
help�member�states,�local�review�committees,�and�individual�scientists�meet
their�national-�and�local-level�oversight�obligations.
7. It� would� assess� the� case� judgments� being� made� on� a� national� basis� for
research�meeting�the�criteria�for�activities�of�moderate�concern�and�potential
concern.
8. It�would�conduct�periodic�conferences�designed�to�encourage�harmonization
of� national� standards� and� case� judgments,� and� identify� any� major
discrepancies�that�appear�to�be�of�legitimate�international�concern.
In�order�to�perform�these�functions�in�a�world�of�irretrievably�divided�legal�and
political�jurisdiction,�the�IPRA�would�have�to�be�constituted�in�a�manner�that�is
globally� representative� and� explicitly� dedicated� to� providing� an� equitable
distribution�of�burden�and�benefit.��It�would�also�have�to�specify�procedures�that
assure�compliance�with�its�requirements�but�also�protect�against�misuse�of�its
authority.��� In� general,� it� must� be� given� the� mandate� to� be� equitable� and
sufficient�capacity�to�be�effective�but�not�the�ability�to�be�abusive.
Of�these�underlying�requirements,�the�incentive�to�be�equitable�should�be�the
least� controversial.�� Concern� about� the� misuse� of� advances� in� biology� is
currently�highest�in�more�economically�advanced�counties,�with�poorer�countries
focused� on� infectious� diseases� such� as� malaria,� tuberculosis� and� HIV/AIDS,
which� kill� millions� of� people� each� year.�� The� poor� provide� a� reservoir� for
emergent�diseases�that�also�pose�an�incipient�threat�to�more�affluent�populations,
but�lack�the�money�and�expertise�to�handle�the�problem�on�their�own.��Although
participation�in�the�BRSS�is�likely�to�impose�few�burdens�on�such�countries,
governments�already�stretched�thin�might�be�more�willing�to�participate�if�the
oversight�system�also�funded�research�on�some�of�the�human,�plant�or�animal
pathogens� that� pose� a� clear� threat� to� their� own� country’s� security� and� wellbeing.��Scientists�and�public�health�officials�in�the�developed�world�might�also
have� a� stronger� incentive� to� participate� in� the� oversight� system� if� it� also
included� a� positive� mission� aimed� at� contributing� to� the� global� fight� against
infectious� disease.�� Recent� international� cooperation� on� SARs� and� on� avian
influenza� demonstrates� the� importance� both� of� international� scientific
collaboration� and� of� ensuring� that� those� who� conduct� consequential� research
adhere�to�common�procedures�and�rules.
Of�course,�the�financial�costs�of�the�IPRA�would�need�to�be�shared�equitably�as
well.��If�the�IPRA’s�responsibilities�were�narrowly�restricted�to�the�mission�of
research�oversight,�an�appropriate�level�of�operations�might�fall�in�the�range�of
hundreds�of�millions�of�dollars�per�year.�� A�more�advanced�arrangement�that
included�the�mandate�to�address�the�most�destructive�of�the�current�infectious
diseases�might�well�require�billions�of�dollars�per�year�or�more.�� Those�would
be� large� increments� to� current� international� public� health� expenditures� but
comparable� to� the� additional� amounts� the� US� has� explicitly� directed� to
bioterrorism�research�in�the�aftermath�of�the�2001�anthrax�letters.
34 Controlling�Dangerous�Pathogens�Report
�Compliance�and�Verification
The� question� of� compliance,� a� term� that� involves� the� perennially� contentious
issue�of�verification,�is�likely�to�be�a�controversial�issue�in�the�development�of
any� oversight� system.�� Some� will� argue� that� the� threat� of� malicious� intent� is
virtually�the�entire�problem�and�that�those�dedicated�to�destructive�applications
of�biology�will�readily�evade�any�oversight�arrangements�acceptable�to�everyone
else.��When�applied�in�extreme�form�against�nation�states,�that�argument�makes
any�preventive�effort�intractable�in�principle�and�leaves�military�force�against
those� with� evil� intent� as� the� only� supposedly� realistic� option.�� Even� in� more
moderate�form,�the�argument�seeks�to�impose�a�heavy�burden�of�proof�on�the
expectation�of�compliance�and�the�feasibility�of�verification.��Although�tolerably
robust�compliance�provisions�have�been�demonstrated�in�what�would�appear�to
be� roughly� comparable� situations� –�financial�accounting,�for�example�–�in�its
formative� stages� an� advanced� oversight� arrangement� for� biotechnology� would
undoubtedly� have� to� labor� against� categorical� doubts� about� compliance� that
would�be�very�assertively�expressed.
The� constructive� case� for� the� feasibility� of� compliance� rests� on� a� number� of
arguments.�� The� first� holds� that� there� is� a� problem� of� innocent� misjudgment
serious� enough� to� justify� the� establishment� of� a� system� of� independent� peer
review�of�relevant�research.��Most�practicing�scientists�strongly�believe�in�their
own� good� intentions,� but� most� can� also� be� readily� induced� to� recognize� the
possibility� of� unpleasant� surprise.�� Many� also� are� distinctly� less� confident� of
their� colleagues� collectively� than� they� are� of� themselves.�� If� misjudgment� is
accepted� as� the� occupational� hazard� it� certainly� appears� to� be� and� not� as� a
character�flaw,�then�it�is�reasonable�to�expect�that�compliance�with�a�carefully
designed� oversight� process� can� be� established� as� a� professional� standard
endorsed,� practiced� and� enforced� by� virtually� all� practicing� researchers� as
protection�against�social�backlash�triggered�by�inadvertent�error.�� That�can�in
principle�be�made�an�integral�part�of�the�social�contract�and�a�routine�feature�of
professional�practice.�� That�would�not�preclude�willful�violation�but�it�would
make�it�unambiguously�illegitimate�and�much�riskier�as�a�practical�matter�than�it
currently�is.��Detection�of�violation�is�more�likely�to�occur�against�a�background
of�routine�disclosure�and�peer�review,�and�detected�violations�are�more�likely�to
be�prosecuted�if�clear�standards�of�compliance�are�set.�� In�general,�consensual
information� disclosure� ubiquitously� practiced� offers� far� more� consequential
protection� than� adversarial� forms� of� verification� evoked� only� in� instances� of
alleged�violation.
Officials� at� all� levels� of� the� oversight� system� are� likely� to� rely� heavily� on
information� gathering� and� analysis� mechanisms� to� assist� them� in� assessing
compliance.62��This�includes�reviewing�project�reports�for�internal�consistency,
cross-checking�information�provided�by�one�lab�with�submissions�from�others
with� which� it� interacted,� or� comparing� research� project� records� with� findings
published�in�academic�journals�and�patent�applications�for�bio-medical�products.
To�supplement�the�data�reported�formally�under�the�system,�information�could
also� be� obtained� from� unofficial� sources� such� as� non-governmental
organizations.�� Additional� information� could� come� from� periodic� visits� or
inspections,�which�many�laboratories�already�are�subject�to�on�a�national�basis
for�reasons�other�than�suspicion�of�wrongdoing.
Controlling�Dangerous�Pathogens�Report 35
�BRSS� member� states� can� also� enhance� confidence� in� compliance� by� being
responsive�to�questions�from�other�countries�about�their�implementation�of�their
oversight�obligations.�� This�could�be�done�at�the�annual�meetings�of�the�IPRA
where,� in� addition� to� approving� budgets� and� making� other� policy� decisions,
governments�could�answer�questions�from�other�participating�states.��They�could
also�consult�directly�with�other�member�states�if�they�had�a�question�or�concern,
following�established�consultation�and�clarification�procedures.
The�IPRA�could�also�require�additional�protective�measures�that�are�feasible�and
prudent� for� projects� undertaken� at� its� level.�� This� includes,� for� example,
allowing� activities� of� extreme� concern� only� to� be� carried� out� at� a� limited
number�of�designated�sites�that�would�have�access�controls�to�laboratory�work
areas� as� well� as� to� the� containers� in� which� dangerous� pathogens� are� stored.
That� would� create� a� detailed� record� of� access� and� enable� the� imposition� of
multiple� person� rules� analogous� to� those� applied� to� nuclear� weapons-related
work.��There�also�could�be�continuous�video�monitoring�of�the�work�areas�and
electronic�monitoring�of�the�equipment�to�assure�a�detailed�record�of�research
activity� as� well� as� basic� access.�� Rules� and� procedures� of� this� sort� are
provisionally� being� developed� in� some� places� but� not� yet� comprehensively
applied�and�managed.��If�they�were,�the�standard�of�protection�would�clearly�be
much�higher�than�it�currently�is.
Despite�these�mechanisms,�one�can�still�imagine�that�a�rogue�state�might�evade
the�oversight�system�by�exempting�its�national�and�local�review�bodies�from�the
agreed�requirements�or�by�refusing�to�establish�a�national�oversight�system�at
all.�� If�all�major�countries�endorsed�and�implemented�the�system,�however,�it
would�be�much�harder�for�a�rogue�state�to�defy�it.�� With�virtually�the�entire
international�community�adhering�to�the�system,�the�UN�Security�Council�might
more�readily�develop�a�supplementary�verification�process�capable�of�imposing
adversarial�inspections�on�suspect�facilities�believed�to�be�engaged�in�activities
that� threaten� international� peace� and� security,� including� international� public
health.�� Sustained� and� unresolved� issues� of� compliance� arising� within� the
oversight� system’s� more� cooperative� processes� could� be� made� the� trigger� of
assertive� verification.�� Many� of� the� standard� enforcement� provisions,� ranging
from�sanctions�to,�in�extreme�cases,�the�use�of�military�force,�could�be�credibly
brought�to�bear�if�basic�rules�of�behavior�were�set�and�broadly�practiced.��It�can
reasonably� be� argued� that� an� advanced� oversight� system� would� substantially
enhance�the�prospects�of�disciplining�a�tempted�rogue.�� That�supposition�is�at
least� as� plausible� as� the� contrary� assertion� that� rogues� are� inevitable� and
unpreventable.
In�fact,�despite�predictable�disputes�over�probable�levels�of�compliance,�assuring
appropriate� restraint� in� an� advanced� oversight� process� is� probably� the� more
demanding�problem�over�the�longer�term.��As�discussion�proceeds�and�the�basic
features�of�the�situation�are�absorbed,�most�people�are�likely�to�recognize�the
potential�power�of�systematic�information�disclosure�and�mandatory�peer�review
and�are�likely�to�be�insistently�interested�in�effective�protection�against�misuse
of� that� power� both� as� a� basic� legal� right� and� as� a� matter� of� administrative
procedure.
Since�the�functions�of�the�IPRA,�in�particular,�are�essentially�unprecedented,�it
seems� evident� that� substantial� legal� innovation� is� likely� to� be� required� to
establish� appropriate� safeguards.�� Rules� regulating� access� to� information
36 Controlling�Dangerous�Pathogens�Report
�disclosed� under� the� oversight� system,� specifying� both� legitimate� uses� and
prohibited�application,�would�be�needed.�� Civil�remedies�and�possibly�criminal
sanctions�would�have�to�be�allowed�in�national�jurisdictions�for�unauthorized
disclosures.��Within�the�United�States,�and�probably�within�many�other�countries
as� well,� a� decision� by� the� international� review� body� to� deny� approval� of� a
proposed�project�in�the�category�of�extreme�concern�would�have�to�be�subject�to
appeal�in�the�courts�as�a�matter�of�constitutional�right.��An�international�ruling
that�was�contested�and�not�upheld�in�a�national�court�system�could�create�an
operational�problem�for�the�oversight�system�as�a�whole.�� So�would�civil�suits
against�the�international�body�for�any�inadvertent�or�willful�mismanagement�of
the� information� it� gathers.�� Presumably� national� courts� would� be� reluctant� to
contest�international�rulings�on�scientific�grounds,�but�they�would�appropriately
demand� procedural� safeguards� protecting� the� rights� and� interests� of� those
subjected�to�oversight.��Concerns�about�due�process�would�be�minimized�to�the
extent�that�oversight�procedures�and�rules�have�been�harmonized�both�among
countries� and� between� the� national� and� the� international� level,� and� involve
similar�licensing�and�peer�review�requirements.
The�System�in�Practice
In�envisaging�how�the�oversight�process�might�work�in�practice,�it�is�helpful�to
begin� with� the� licensing� provisions� for� scientists� and� facilities.�� We� then
consider� the� project� peer� review� process� starting� from� the� lowest� level,� both
because�this�is�the�part�of�the�system,�if�any,�that�would�directly�affect�most
scientists,�and�because�this�is�the�point�at�which�all�projects�subject�to�oversight
would�initially�enter�the�system.��A�diagram�of�the�key�steps�in�the�peer�review
process�is�in�Figure�II�below.
Any�scientist�wishing�to�carry�out�a�research�project�subject�to�oversight�under
the�BRSS�would�have�to�be�licensed�as�would�the�facility�where�the�proposed
work�would�take�place.�� In�order�to�obtain�a�personnel�license,�the�researcher
would�complete�a�new�user�questionnaire.��This�form�would�require�information
on� the� individual’s� academic� credentials� and� employment� history,� including
current�employer.�� In�order�to�obtain�a�facility�license,�the�institution�housing
the�laboratory�where�BRSS-covered�research�is�to�take�place�would�complete
both�a�new�institution�questionnaire�and�a�new�laboratory�questionnaire.�� The
former�would�require�general�information�about�the�institution�(name,�address),
the�activities�of�its�biosafety�and�other�review�bodies�(e.g.,�IBC,�IRB)�and�its
laboratory� inspection� and� hazardous� materials� handling� procedures.�� The� new
laboratory� questionnaire� would� require� information� specific� to� the� laboratory
where�the�BRSS�research�would�take�place,�including�the�agents�which�are�used
in�the�laboratory�and�the�individual�responsible�for�coordinating�agent�research.
Completion�of�the�new�laboratory�questionnaire�would�also�trigger�a�separate
questionnaire�on�security�measures,�which�would�require�detailed�information�on
measures�in�place�at�the�lab�for�preventing�unauthorized�access�to�dangerous
pathogens.��Once�a�project�that�was�subject�to�BRSS�oversight�was�proposed,�all
relevant�licensing�forms�would�be�provided�to�the�appropriate�peer�review�body
for� use� in� its� risk-benefit� assessment.�� A� complete� set� of� prototype� licensing
questionnaires�is�at�Appendix�D.
Controlling�Dangerous�Pathogens�Report 37
�Figure II: Peer Review Process
Step 1
Licensed researcher completes relevant questionnaires for proposed
project at a licensed facility.
Step 2
Research project is assigned to appropriate review body.
Local (LPRC): Activities of Potential Concern
National (NPRC): Activities of Moderate Concern
International (IPRC): Activities of Extreme Concern
Step 3
Review body decides whether the project should be approved and under
what conditions based on Criteria for Risk-Benefit Assessment:
Biosafety Issues; Evaluation of Research Plan;
Public Health Considerations; Biodefense Considerations;
Current Necessity, Potential Impact
Step 4
Approved project assessed for possible restrictions on dissemination based
on adaptation of Corson Panel conditions:
1.
2.
3.
4.
Technology developing rapidly?
Time between research result and application is short?
Technology has direct, identifiable military applications?
Technology transfer would give a BW proliferators a significant
near-term capability?
5. No other sources of information about the technology, or do all
potential sources have effective systems for securing the
information?
6. The duration and nature of proposed restrictions would not
seriously compromise the work of those directly responsible for
public health?
Step 5
Periodic and final reports by researcher to relevant review body.
38 Controlling�Dangerous�Pathogens�Report
�Institutional�Review�–�Activities�of�Potential�Concern
Proposed� research� activity� in� this� category� would� be� subject� to� institutional
review� and� approval� by�a� Local� Pathogens�Research�Committee.�� The� LPRC
would�be�similar�in�some�ways�to�the�Institutional�Biosafety�Committees�that
currently� exercise� local� oversight� of� much� recombinant� DNA� research,� but
would� need� to� meet� more� frequently� and� be� provided� with� more� resources,
including� compensation� for� the� committee� members’� time� and� administrative
support.��It�would�also�need�to�have�more�formalized�procedures�for�conducting
risk-benefit� assessments� and� for� documenting� its� deliberations� and� resulting
decisions.��The�LPRC�would�consist�of�no�fewer�than�five�voting�members�who
collectively�have�expertise�both�in�the�research�areas�subject�to�oversight�at�this
level� and� if� possible� on� security� matters.�� At� least� one� member� would� be
required� to� be� a� public� representative.�� Advisors� to� the� committee� could� be
appointed�on�an�ad�hoc�basis�if�additional�expertise�was�required�to�review�a
particular�project.
A� licensed� scientist� who� wanted� to� initiate� a� project� involving� activities� of
potential� concern� at� a� licensed� facility� would� start� by� logging� into� the� data
management� system� and� completing� a� new� project� questionnaire.�� The
questionnaire�would�require�a�description�of�the�proposed�project�(both�general
and�technical)�and�its�purpose,�as�well�as�information�on�the�agent�or�sequence
involved,�prior�relevant�work,�techniques�to�be�employed�(including�human�or
animal� experiments,� recombinant� DNA� work� or� aerosol� studies),� expected
benefits,�potential�risks�(including�impact�on�virulence,�environmental�stability
or� host-range),� biosafety� level,� and� whether� there� are� alternative� means� of
obtaining�the�same�information.�� It�would�also�require�a�certification�from�the
researcher�that�the�proposed�project�does�not�raise�BWC�compliance�concerns.
Completion�of�the�new�project�questionnaire�would�trigger�a�separate�personnel
security� questionnaire� identifying� the� scientists� participating� in� the� project� as
well� as� other� laboratory� personnel� and� a� laboratory� biosafety�questionnaire
containing�questions�on�biosafety-related�equipment�and�procedures�in�the�lab.
Other�questionnaires�would�have�to�be�completed�if�the�work�involved�the�use
of� recombinant� materials� or� pathogenic� microorganisms.�� If� the� data
management�system�was�being�used�to�meet�other�regulatory�requirements,�such
as�those�related�to�human�subject�or�animal�research,�questionnaires�pertaining
to� those� issues� would� be� completed� as� well.�� A� complete� set� of� prototype
project�questionnaires�is�at�Appendix�E.
The� institutional� biosafety� officer� would� be� responsible� for� ensuring� that� the
proposal�received�all�appropriate�reviews�before�work�began.��He�or�she�would
confirm�that�the�necessary�questionnaires�had�been�completed�by�the�researcher
and,�together�with�the�chairperson�of�the�Local�Pathogens�Research�Committee,
that�the�necessary�expertise�was�available�on�the�Committee�to�peer�review�the
proposed�project�for�its�dual-use�implications.��The�biosafety�officer�also�would
act�as�a�liaison�with�the�other�local�review�committees,�such�as�those�governing
human� subject� or� animal� research,� in� an� attempt� to� promote� expeditious� and
efficient�consideration�of�the�proposed�project�by�those�bodies.��This�would�be
facilitated�by�the�data�management�system,�which�in�our�prototype�includes�not
Controlling�Dangerous�Pathogens�Report 39
�only�the�questions�required�to�meet�BRSS�obligations�but�also�some�of�those
necessary�to�meet�other�regulatory�requirements.
When� deciding� whether� to� approve� a� project,� the� LPRC� would� consider� the
experience�of�the�principal�investigator�but�the�most�important�factor�would�be
the�results�of�its�risk-benefit�assessment�of�the�proposed�work.��A�standardized
protocol,�along�the�lines�of�the�one�described�earlier,�would�be�used�to�guide�the
Committee’s�deliberations�and�inform�its�decision.��The�LPRC�could�approve�a
proposal� as� submitted,� require� that� the� research� activities� be� redesigned� to
reduce� risks,� recommend� that� the� research� be� reviewed� and� conducted� at� a
different�facility�with�additional�biosafety�and�security�features,�or�elevate�the
proposal�to�the�National�Pathogens�Research�Authority�for�review.��� As�part�of
its�peer�review�of�the�project,�the�Committee�would�also�consider�the�possible
need�for�restrictions�on�the�dissemination�of�information�about�the�research�or
research� results,� based� on� standardized� criteria� like� those� discussed� above,
although� such� restrictions� generally� would� not� be� expected� at� this� level.�� If,
however,�a�project�produced�unexpected�results�that�met�the�criteria�for�research
activities�of�moderate�or�extreme�concern,�then�the�scientist�would�be�required
to�work�with�the�national�or�international�oversight�body�as�appropriate�on�a
plan� for� handling� any� sensitive� materials� or� information� that� had� been
developed.�� The� LPRC� would� be� required� to� reach� a� decision� on� the� project
within�45�days�of�receiving�a�completed�application�package.
Researchers� would� not� be� required� to� be� present� at� the� LPRC� meeting� when
their�project�is�discussed�although�they�would�be�encouraged�to�do�so�in�order
to� answer� any� questions� the� Committee� might� have.�� Minutes� of� the� LPRC
meetings�would�be�kept�confidential�but�would�be�made�available�to�the�NPRA
upon�request.��� These�minutes�would�need�to�include�the�meeting�participants,
decisions�reached�(including�the�number�voting�for,�against�or�abstaining),�the
basis�for�any�required�changes�in�or�disapproval�of�the�research,�and�a�summary
of�the�discussion.
At�the�discretion�of�the�chairperson�of�the�LPRC,�an�expedited�review�process
could�be�followed,�in�which�the�chairperson,�a�subset�of�the�Committee�or�the
entire�Committee�would�review�the�proposed�project�electronically�rather�than
during�a�formal�meeting.��Such�a�process�would�only�be�used�in�cases�involving
new� proposals� believed� to� pose� minimal� risk� or� minor� changes� to� previously
approved� proposals.�� A� written� record� of� the� risk-benefit� assessment� and� the
decision� would� be� prepared� and� circulated� to� other� LPRC� members� for� any
project�given�expedited�review.
Upon�completion�of�the�project,�the�principal�investigator�would�be�required�to
submit�a�brief�report�on�the�research�results.��This�report�would�be�included�in
the�institution’s�database�along�with�other�information�submitted�as�part�of�the
project�application.��Select�information�from�the�local�level�would�be�sent�to�the
national� review� body,� which� in� turn� would� forward� information� of� broader
international�relevance�in�an�annual�report�to�the�international�organization.
National�Review�–�Activities�of�Moderate�Concern
Research�activities�in�this�category�would�require�oversight�and�approval�by�the
National� Pathogens� Research� Authority.�� The� NPRA� would� also� periodically
40 Controlling�Dangerous�Pathogens�Report
�review� the� work� of� the� Local� Pathogen� Research� Committees� and� provide
guidance� on� how� to� handle� research� of� potential� concern� that� produced
unexpected� results� that,� if� misapplied,� could� have� serious� public� health
consequences.
The�National�Pathogens�Research�Authority�would�be�a�government�body�with
direct� authority� to� regulate� scientists� and� facilities� within� its� jurisdiction.�� It
could�be�established�within�an�existing�agency�such�as�the�National�Institutes�of
Health� in� the� US,� or� it� could� be� a� separate� government� agency,� perhaps
including�personnel�drawn�from�different�government�departments.��The�NPRA
would� include� one� or� more� review� committees� of� up� to� 20� members� with
expertise�on�both�the�scientific�issues�subject�to�oversight�at�this�level�and�on
security�issues.��Review�committee�members�would�be�highly�respected�leaders
in�their�respective�professional�communities�willing�to�devote�a�portion�of�their
time� to� reviewing� proposals� and� making� policy� recommendations.�� Review
committees� would� also� include� individuals� who� are� neither� scientists� nor
security�experts�but�who�have�other�relevant�forms�of�expertise�(e.g.�ethics)�or
whose�interests�would�be�affected�by�their�recommendations.��The�specific�form
of�this�input�could�vary�by�country.
One�of�the�toughest�challenges�for�the�NPRA�will�be�to�maintain�domestic�and
international� confidence� in� its� oversight� without� compromising� confidential
business� or� national� security� information.�� To� this� end,� the� NPRA� should� be
transparent�about�its�processes,�should�conduct�public�forums�to�promote�broad
debate� on� contentious� policy� questions,� and� should� publish� an� annual� report
summarizing� the� significance� of� research� proposals� approved,� modified,� or
rejected.��If�necessary�to�protect�sensitive�information,�the�report�should�include
a�special�annex�that�was�only�available�to�cleared�individuals�with�a�“need�to
know.”��All�NPRA�staff�and�review�committee�members�and�anyone�else�who
had�access�to�sensitive�commercial�and�national�security�information�through�the
NPRA�would�be�vetted�and�required�to�sign�strict�confidentiality�agreements.
Review� committee� meetings� would� not� be� conducted� publicly� nor� would
meeting� minutes� be� available� to� the� public.�� As� with� the� LPRC,� however,
detailed�meeting�records�would�be�kept.
The� National� Pathogens� Research� Authority� would� maintain� a� comprehensive
picture� of� high-consequence� research� within� its� jurisdiction� by� licensing� all
scientists,�technical�support�staff,�and�facilities�engaged�in�research�covered�by
the�Biological�Research�Security�System.�� The�NPRA�would�work�with�other
appropriate�government�agencies�to�conduct�background�checks�on�researchers
and�other�personnel�who�work�with�or�have�access�to�dangerous�pathogens�and
to�conduct�inspections�of�relevant�facilities.��Once�approved,�a�personnel�license
would�remain�valid�for�up�to�five�years,�as�long�as�annual�activity�reports�were
submitted�and�there�was�no�evidence�of�violations�of�other�relevant�regulations.
Facility� licenses� would� be� valid� for� up� to� 10� years� but� would� have� to� be
renewed�in�the�case�of�any�major�structural�changes.
Scientists�who�wished�to�pursue�research�activities�of�moderate�concern�would
be�required�to�submit�a�project�application�through�their�local�review�body�to
the� NPRA� for� consideration.�� Applications� for� research� at� this� level� would
require�a�signature�from�a�senior�official�at�the�institution�where�the�research
was� to� take� place� indicating� institutional� support� for� the� proposed� project.
Researchers�would�be�required�to�present�their�proposed�project�to�the�NPRA
Controlling�Dangerous�Pathogens�Report 41
�review� committee.�� The� committee� would� have� to� reach� a� decision� on� the
project�within�sixty�days�of�receiving�a�complete�application�package.�� If�the
results�of�the�research�might�be�subject�to�dissemination�restrictions,�the�NPRA
would�advise�the�principal�investigator�at�the�time�the�project�is�approved.���The
NPRA� could� also� determine� that� the� proposed� work� meets� the� definition� of
research�of�extreme�concern�and�therefore�should�be�submitted�for�international
review�by�the�IPRA.
Once� the� project� was� approved,� the� principal� investigator� would� receive� a
project� permit� to� conduct� only� the� activities� authorized.�� Although� minor
modifications� to� the� project� could� be� handled� through� an� expedited� process,
significant� changes� would� have� to� be� considered� under� the� regular� review
procedures.�� Upon� completion� of� the� project,� a� detailed� report� would� be
submitted�to�the�NPRA.��This�report�would�be�included�in�the�national�database
along�with�other�information�submitted�as�part�of�the�project�application.
As�discussed�above,�the�NPRA�could�use�a�wide�range�of�information�gathering
and�analysis�techniques�to�ensure�the�accuracy�and�completeness�of�information
that�has�been�disclosed�and�to�confirm�compliance�with�other�BRSS�obligations.
The�NPRA�could�also�request�help�from�other�national�regulatory�bodies�and
law�enforcement�agencies�as�well�as�from�the�IPRA�to�assist�it�in�meeting�its
oversight�requirements.
The� NPRA� would� report� annually� to� the� IPRA� about� its� implementation� of
BRSS�obligations.��This�would�include�a�basic�description�of�completed�research
projects�and�any�results�with�protective�implications�for�the�broader�international
community.�� This� would� facilitate� IPRA� efforts� to� promote� international
harmonization� of� national� implementation� activities.�� The� NPRA� would� also
report�on�national�compliance�issues�and�steps�taken�to�redress�them.
International�Review�–�Activities�of�Extreme�Concern
The� IPRA� would� perform� many� of� the� same� functions� that� the� National
Pathogens�Research�Authority�performs�for�research�activities�under�its�control.
Thus,�it�would�have�one�or�more�review�committees�of�up�to�15�scientists�and
security� experts� who� would� be� responsible� for� conducting� risk-benefit
assessments� of� projects� under� the� IPRA’s�jurisdiction.�� Other�IPRA�advisory
committees� would� provide� advice� on� the� types� of� high� priority� research� the
IPRA� should� support� and� help� define� and� update� the� categories� of� research
activities� subject� to� oversight� at� each� level� of� the� system.�� The� IPRA� would
have� the� discretion� to� select� additional� members� on� an� ad� hoc� basis� to
complement�the�expertise�on�these�standing�panels.
Scientists� from� member� states� who� wished� to� pursue� research� activities� of
extreme� concern� would� submit� a� project� application� through� their� local� and
national� review� bodies� to� the� IPRA� for� consideration.�� In� addition� to� the
relevant�questionnaires,�proposals�for�research�at�this�level�would�also�require�a
statement� of� support� from� the� relevant� national� review� body.�� All� senior
scientists�involved�in�the�proposed�project�would�have�to�be�present�during�the
IPRA� review� committee’s� consideration� of� the� proposal.�� As� the� volume� of
research�proposals�would�be�much�lower�than�at�the�other�levels�of�the�BRSS,
the� review� committee� would� be� expected� to� reach� a� decision� on� the� project
within� 45� days� of� receiving� a� complete� application� package.��� If� a� proposed
42 Controlling�Dangerous�Pathogens�Report
�project� raised� important� new� policy� questions,� however,� the� committee’s
recommendation�on�the�conduct�of�the�research�and�the�handling�of�the�results
would� have� to� be� approved� by� the� executive� body� of� the� international
organization.
Because� research� projects� at� this� level� generally� would� be� expected� to� be
important�to�global�health,�all�project�decisions�by�the�International�Pathogens
Research� Authority� would� be� reported� to� member� states.�� The� results� of� all
research� approved� by� the� IPRA� also� generally� would� be� disseminated� to� all
members.�� Whenever�possible,�the�IPRA�would�follow�the�model�of�openness
set�by�WHO�in�reviewing�proposed�research�projects�with�smallpox,�the�most
dangerous�existing�pathogen.�� WHO�meetings�to�review�proposed�projects�are
open� to� observers� from� WHO� member� states,� with� detailed� meeting� notes
available�on�the�WHO�website.��The�results�of�all�WHO-approved�projects�are
also� publicly� available,� although� there� can� be� a� delay� between� submission� to
WHO� and� publication.�� As� noted� above,� however,� in� rare� circumstances� the
IPRA�might�conclude,�on�the�basis�of�standardized�criteria�like�those�used�at
other�levels�of�the�system,�that�the�global�interest�was�best�served�by�restricting
access�to�the�details�of�a�research�project�under�its�jurisdiction�or�the�subsequent
results.
Researchers� carrying� out� projects� involving
activities� of� extreme� concern� would� be
required�to�submit�biannual�reports�to�IPRA,
outlining� proposed� changes� in� personnel;
detailed� experimental� results� and� plans� for
further� research;� proposed� changes� in
protocols;� the� status� of� agent� stocks;� safety
violations�or�security�breaches;�and�licensing
changes.�� As�at�other�levels�of�the�oversight
system,�minor�changes�could�be�approved�by
an�expedited�process�but�significant�changes
would�have�to�go�through�the�regular�review
procedures.�� Upon�completion�of�the�project,
the�principal�investigator�would�submit�a�final
report�to�the�IPRA�on�the�research�results,�the
disposition� of� any� recombinant� materials
(accounting�both�for�the�agents�consumed�in
experiments� and� destruction� of� excess
materials),�and�publication�plans.
IPRA-approved� research� facilities� would� be
monitored�to�ensure�that�the�work�was�done
in� accordance� with� protocols� authorized� by
the�IPRA.�� This�could�include�the�review�of
laboratory� notebooks,� interviews,� and
sampling.�� Any� irregularities� would� be
promptly�reported�and�scientists�who�strayed
substantially�from�their�proposed�work�would
be� subject� to� penalties� and� possibly
suspension�or�loss�of�their�right�to�participate
in�IPRA-level�projects.
In rare circumstances the
IPRA might conclude, on
the basis of standardized
criteria like those used at
other levels of the system,
that the global interest was
best served by restricting
access to the details of a
research project under its
jurisdiction or the
subsequent results.
Controlling�Dangerous�Pathogens�Report 43
�In� addition� to� its� work� directly� overseeing� projects� involving� activities� of
extreme� concern,� the� International� Pathogens� Research� Authority� would� also
establish� and� maintain� a� database� of� information� on� such� projects,� the
researchers� involved,� and� all� relevant� pathogen� strains.�� The� database� would
include� strong� firewalls� to� prevent� unauthorized� access� and� a� sophisticated
system� for� storing,� retrieving,� translating� and� cross-referencing� data.�� Access
would� be� limited� to� specified� employees� of� the� IPRA.�� Confidentiality
agreements�would�be�in�place�and�information�that�was�accessed�could�only�be
used�for�approved�purposes.
The� IPRA� would� also� engage� in� a� variety� of� activities� aimed� at� assisting
participating�countries�in�developing�the�capacity�to�meet�the�peer�review�and
oversight� requirements� at� the� heart� of� the� system.�� Such� capacity� building
measures�could�include�the�development�of�detailed�guidelines�outlining�bestpractices;�programs�to�train�national�officials�on�what�is�required�to�comply�with
the� oversight� system;�� formal� processes� for� sharing� information,� including
lessons�learned;�and�specific�assistance�on�national�implementation,�including
regulatory�requirements.�� It�would�also�assess�the�judgments�being�made�on�a
national�basis�on�research�of�potential�and�moderate�concern�and�hold�periodic
conferences� aimed� at� promoting� harmonization� of� national� implementation
activities.
44 Controlling�Dangerous�Pathogens�Report
�.�.�.�.�.�.�.�.�.�.
.�.�.�.�.
The Way Forward
The� advanced� oversight� system� that� has� been� outlined� would� involve� three
major� innovations� over� existing� oversight� arrangements:� it� would� subject� the
most�consequential�areas�of�research�to�international�jurisdiction;�it�would�apply
oversight� comprehensively� within� all� jurisdictions;� and� it� would� make� the
oversight�process�a�legal�obligation.��Those�provisions�are�suggested�in�order�to
assure�effective�protection.��It�is�doubtful�that�exclusive�national�jurisdiction�can
achieve� a� globally� harmonized� system.�� It� is� similarly� doubtful� that� adequate
protection� could� be� achieved� in� any� jurisdiction� if� oversight� is� partial� and
optional.��It�is�uncomfortably�probable�that�secretive�national�threat�assessment
programs�exempted�from�independent�oversight�will�ultimately�generate�hostile
emulation.�� Those� are� serious� considerations� that� can� be� said� to� reflect� the
imperatives� of� emerging� circumstance.�� They� do� clearly� defy,� however,� the
dominant�inclination�of�institutional�tradition�and�political�sentiment.
Legal� authority� and� political� affiliation� are� both
vested� primarily� in� national� governments
throughout�the�world,�and�those�governments�will
predictably� be� the� preferred� venue� for� exploiting
the�benefits�and�managing�the�dangers�of�advances
in�biology.��Moreover,�the�momentum�of�scientific
discovery�that�is�the�source�of�benefit�and�danger�is
based�on�freedom�of�inquiry,�and�the�autonomy�of
the� fundamental� research� process� will� predictably
be� defended� against� fears� of� perverse� regulatory
intrusion.�� The� practical� question� is� whether
acceptable� incremental� measures� can� be� devised
that� would� mitigate� these� objections� and� provide
meaningful� benefit� without� compromising� the
ultimate� achievement� of� an� advanced� oversight
system.
In� principle� that� is� clearly� possible.�� The� BRSS
would�be�based�on�national�and�local�oversight�and
would� subject� only� a� limited� set� of� especially
dangerous�activities�to�direct�global�jurisdiction.��A
survey�of�journal�articles�published�in�the�US�from
2000� to� mid-2005� indicates� that� some� 310� US
facilities� and� 2,574� US� researchers� would� have
been� subject� to� the� suggested� BRSS� oversight
procedures�had�they�been�in�effect.63�Less�than�1%
of� US� research� publications� involving� bacteria,
viruses�or�prions�would�have�been�affected�in�any
way.��Among�those�that�would�have�been�affected,
only�12�of�the�facilities�and�185�of�the�individuals
A survey of journal
articles published in the
US from 2000 to mid2005 indicated that
some 310 US facilities
and 2,574 US
researchers would have
been subject to the
suggested BRSS
oversight procedures
had they been in effect.
Controlling�Dangerous�Pathogens�Report 45
�would�have�been�assigned�to�international�jurisdiction�—�a�tiny�fraction�of�the
American� biomedical� research� community.�� Fourteen� facilities� and� 133
individuals�would�have�been�assigned�to�national�jurisdiction;�and�231�facilities
involving� 2119� individuals� would� have� fallen� under� local� jurisdiction.�� Fiftythree� facilities� and� 137� individuals� would� have� encountered� multiple
jurisdictions.��Those�numbers�suggest�that�independent�development�of�national
and�local�oversight�provisions�would�cover�most�of�what�an�advanced�system
would�eventually�involve�and�would�lay�the�foundation�for�such�a�system�as
long� as� the� national� and� local� provisions� are� based� on� globally� compatible
principles.
In� practice,� relevant� initiatives� already� are� being� undertaken.�� With
encouragement� from� the� US� National� Academy� of� Sciences� and� the� British
Royal� Society,� for� example,� individual� scientists� and� professional� scientific
organizations� are� discussing� applicable� scientific� codes.64� � Much� of� this
discussion�is�focused�on�ethical�codes,�which�describe�personal�and�professional
standards� or� codes� of� conduct,� which� provide� guidelines� on� appropriate
behavior.�� Virtually� no� attention� is� being� given� to� codes� of� practice,� which
outline�enforceable�procedures�and�rules.��Thus,�in�September�2001,�the�World
Medical�Association�issued�a�declaration�on�biological�weapons�which,�among
other�things,�called�on�“all�who�participate�in�biomedical�research�to�consider
the�implications�and�possible�applications�of�their�work�and�to�weigh�carefully
in� the� balance� the� pursuit� of� scientific� knowledge� with� their� ethical
responsibilities�to�society.”65��In�June�2004,�guidelines�to�prevent�the�malevolent
use�of�biomedical�research�were�adopted�by�the�American�Medical�Association
and� incorporated�in� the�AMA’s� Code�of� Medical�Ethics.66� �Other� codes�of
conduct� related� to� life� sciences� research� have� been� put� forward� by� the
International� Committee� of� the� Red� Cross67� and� by� Canadian� bioethicist� Margaret
Somerville�and�former�ASM�president�Ronald�Atlas.68��In�December�2005,�the
Inter-Academy�Panel,�an�association�of�over�80�national�academies�of�science,
released� a� set� of� general� principles� to� guide� the� development� of� codes� of
conduct�by�individual�scientists�and�local�scientific�communities.69��As�noted
earlier,�work�also�is�being�done�by�the�NSABB�in�the�United�States�on�the�issue
of�codes�of�conduct�for�scientists�and�laboratory�workers.
It�is�not�enough,�of�course,�to�simply�have�scientific�codes,�whatever�the�type.
Scientists�must�be�educated�about�the�details�of�such�codes�and�the�potential�for
misuse� of� their� work.�� They� also� must� be� informed� about� relevant� laws� and
regulations�governing�the�conduct�of�dual-use�research�and�provided�training�to
enable� them� to� meet� the� oversight� requirements� that� are� in� place.�� Such
education�and�training�programs�will�be�important�not�only�for�students�at�the
beginning� of� their� academic� studies� but� also� for� established� researchers� who
before�now�have�considered�the�potential�benefits�but�not�the�potential�risks�of
their�work.��A�prototype�biosecurity�course�for�students�has�been�posted�on�the
website� of� the� US� journal,� Politics� and� the� Life� Sciences.�� Additional
biosecurity� educational� modules� are� being� developed� by� the� Federation� of
American�Scientists�and�other�organizations.70
These�initiatives�could�be�significantly�reinforced�by�scientific�funding�agencies,
research� institutions� and� journals� if� they� required� all� those� with� whom� they
interact�on�a�professional�basis�to�adhere�to�relevant�scientific�codes,�laws�and
regulations.�� In� September� 2005,� the� UK’s� three� leading� bioresearch� funding
agencies,� the� Medical� Research� Council,� the� Wellcome� Trust,� and� the
46 Controlling�Dangerous�Pathogens�Report
�Biotechnology�and�Biological�Sciences�Research�Council,�announced�that�they
would� now� require� grant� applicants,� reviewers� and� funding� agency� board
members�to�all�consider�whether�the�proposed�research�could�be�misused�for
harmful� purposes.71� � Research� institutions,� especially� those� in� industry� or
government� that� might� initially� be� outside� the� scope� of� a� formal� oversight
arrangement,�could�impose�a�similar�requirement�for�individual�researchers�and
the�heads�of�the�laboratories�in�which�they�work�to�explicitly�consider�the�dualuse�implications�of�research�they�conduct�as�a�condition�of�employment.�� For
their�part,�scientific�journals�could�refuse�to�publish�manuscripts�submitted�by
researchers�who�did�not�follow�such�rules.
In�addition�to�these�measures,�other�interim�steps�could�be�taken�by�national
governments�that�could�more�directly�strengthen�oversight�of�dual-use�research.
In� the� United� States,� this� would� include� adding� the� categories� of� dual-use
research�and�the�risk-benefit�assessment�criteria�developed�by�the�NSABB�to�the
NIH� Guidelines,� consistent� with� the� Fink� Committee� recommendation.��� It
would�also�include�extending�the�scope�of�the� NIH� Guidelines�to�apply�to�all
relevant� research� facilities,� irrespective� of� whether� they� are� receiving
recombinant�DNA�funding�from�NIH,72�and�converting�the�Guidelines�from�a
voluntary�commitment�to�a�legally�binding�requirement.�� As�discussed�above,
the� US� has� already� taken� a� step� in� this� direction� by� requiring� government
approval� of� two� particular� classes� of� recombinant� DNA� experiments� if� they
involve�work�with�pathogens�on�the�select�agent�list.�� New�legal�authority�as
well�as�additional�funding�would�be�required�to�revamp�the�IBC�system�to�take
on�these�added�responsibilities�and�to�give�NIH�the�capacity�to�more�effectively
monitor,� through� IBC� reporting� and� periodic� inspections,� compliance� with� its
rules.��� IBC�as�well�as�NIH�oversight�would�also�be�enhanced�by�the�adoption
of�an�electronic�data�management�system�like�the�prototype�we�have�developed,
which�not�only�consolidates�various�biosecurity,�biosafety�and�other�reporting
requirements� but� also� facilitates� the� transfer� of� relevant� information� to� the
necessary�oversight�body.73
Outside�of�the�US,�other�countries�that�follow�the� NIH�Guidelines�or�that�have
similar� oversight� processes� for� recombinant� DNA� research� could� also� be
encouraged� to� include� specified� dual-use� research� activities� in� their� national
regulations�and�to�require�adherence�by�all�facilities�undertaking�such�work,�on
a� mandatory� basis.��� These� national� standards� and� regulations� could� then� be
harmonized�among�like-minded�countries,�perhaps�beginning�with�the�30�nations
(plus� the� European� Union)� that� comprise� the� Organization� for� Economic
Cooperation� and� Development� (OECD).�� This� would� be� consistent� with� the
O E C D ’s� efforts� since� 2001� to� develop� a� harmonized� approach� to� the
management�and�security�of�culture�collections�and�other�biological�resources74
as�well�as�its�more�recent�interest,�coming�out�of�the�September�2004�Frascati
conference,�in�promoting�responsible�stewardship�in�the�biological�sciences�and
preventing�abuse�of�research.75�The�OECD�could�develop�a�uniform�list�of�dualuse�research�activities�to�be�subject�to�oversight�as�well�as�standardized�criteria
for�assessing�the�risks�and�benefits�of�such�research.�� It�could�also�establish�a
process�for�periodic�reporting�on�national�implementation�of�these�measures�by
OECD�member�states.
Efforts� such� as� this� by� the� OECD� or� other� like-minded� countries� could� be
facilitated� by� WHO,� which� has� a� long� history� of� providing� technical
information,�guidance�and�assistance�to�the�public,�healthcare�professionals�and
Controlling�Dangerous�Pathogens�Report 47
�policymakers� on� the� control� of� dangerous� pathogens.76�� WHO’s� Laboratory
Biosafety�Manual,�first�published�in�1983,�has�provided�practical�guidance�on
biosafety�techniques�for�use�in�laboratories�around�the�world.��� Since�the�2001
anthrax�letter�incidents�in�the�US,�WHO�has�also�been�developing�guidelines�for
enhancing�the�security�of�dangerous�pathogens�in�laboratory�environments.��And
it�has�been�helping�to�strengthen�global�public�health�preparedness�and�response
capabilities�for�natural,�accidental�or�deliberate�releases�of�biological�and�other
agents� that� affect� public� health� by� developing� networks� of� laboratories� and
experts� on� biological� agents,� providing� guidelines� for� assessing� national
capabilities,�and�disseminating�technical�information�on�specific�agents�that�pose
a�threat�to�public�health.���In�mid-2004�WHO�initiated�an�exploratory�project�on
the�governance�of�life�sciences�research�and�its�implications�for�public�health.77
Many�of�the�issues�that�were�highlighted�in�this�exploratory�work�are�now�being
considered�in�a�new�WHO�project�aimed�at�examining�the�implications�of�life
sciences�research�for�global�health�security.�� In�addition�to�raising�awareness
about�the�opportunities�and�risks�of�life�sciences�research,�this�project�could�also
lay�the�foundation�for�the�development�by�WHO,�in�partnership�with�FAO�and
OIE,�of�technical�guidelines�for�overseeing�dual-use�research.78
There� are� thus� a� variety� of� incremental� measures� that� can� be� pursued� by
scientists,� national� governments� and� international� organizations� that� can� help
prevent� life� sciences� research� from� being� used,� either� deliberately� or
inadvertently,� for� destructive� purposes.��� Some� of� these� measures,� such� as
ethical� codes� and� codes� of� conduct,� are� likely� to� have� a� very� limited� impact
unless�scientists�are�educated�about�the�potential�risks�of�their�work�and�their
responsibilities� to� society� and� funders,� employers� and� publishers� formally
require�them�to�comply�with�existing�rules,�whatever�their�form.�� Others,�such
as�national�oversight�systems�and�internationally�developed�technical�guidelines,
can�clearly�have�a�more�direct�and�positive�impact�on�efforts�to�manage�dualuse�research.���None�is�sufficient�but�all�of�them�can�help�lay�the�foundation�for
the�more�advanced�oversight�system�outlined�above.
48 Controlling�Dangerous�Pathogens�Report
�.�.�.�.�.�.�.�.�.�. Concluding Observations
.�.�.�.�.
Both�the�arguments�underlying�our�approach�to�the�dual-use�problem�and�the
specific� proposals� we� have� put� forward� in� this� monograph� and� in� other
publications� seem� distinctly� less� radical� today� than� when� we� first� began� this
project�in�2001.�� This�is�especially�true�in�the�United�States,�where�attitudes
among�the�scientific�elite�and�among�policy�experts�have�undergone�a�significant
change.��This�is�perhaps�best�exemplified�by�the�work�of�the�Fink�Committee,
which� in� its� initial� meetings� appeared� confident� that� the� existing� process� for
overseeing�recombinant�DNA�research�was�more�than�capable�of�handling�any
residual� concerns� about� biotechnology.�� In� its� final� report,� however,� the
Committee�painted�a�much�starker�picture�of�the�potential�threat�posed�by�dualuse�research�and�underscored�the�absence�of�national�and�international�oversight
mechanisms� to� address� the� problem.��� It� also� challenged� the� conventional
wisdom�that�dangerous�research�could�not�be�defined�and�explicitly�endorsed�the
adoption�of�a�tiered�peer�review�process�to�assess�such�research.��And�it�made
clear�that�any�serious�attempt�to�reduce�the�risks�associated�with�biotechnology
must�ultimately�be�international�in�scope.
Since� the� Fink� Committee� report� in� 2003,� other� leading� scientists� have
acknowledged�the�weaknesses�of�the�existing�IBC�system,79�as�documented�by
the� Sunshine� Project,� with� some� recommending� that� the� NIH� Guidelines� on
which� it� is� based� be� replaced� by� a� more� comprehensive,� legally� binding
requirement.80��Support�has�also�come�from�a�number�of�different�quarters�for
licensing� not� only� facilities� doing� work� with� dangerous� pathogens81� but� also
biologists�themselves.82��And�former�senior�officials�from�both�US�political
parties�have�recently�called�for�the�development�of�international�guidelines�for
reviewing,� approving� and� monitoring� dual-use� research,� and� urged� that� WHO
and�other�international�scientific�organizations�play�a�role�in�this�effort.83
At�the�moment�we�know�that�the�pace�of�scientific�discovery�is�rapid�and�that
the�accomplishments�are�truly�extraordinary.��We�do�not�know�what�the�ultimate
consequences�will�be�or�the�amount�of�time�over�which�they�will�emerge.��We
also�do�not�know�how�much�of�a�managerial�burden�will�be�imposed,�but�there
is�good�reason�to�assume�that�it�will�eventually�be�substantial�enough�to�change
even�deeply�entrenched�habits�and�practices.��As�we�evolve�carefully,�therefore,
and�do�what�is�immediately�acceptable,�we�should�strain�to�think�broadly�and
boldly.�� And� the� appropriate� we� in� this� situation� is� the� human� species� as� a
whole.��If�our�survival�is�not�literally�at�stake,�then�our�prosperity�very�likely�is
and�our�common�interest�much�stronger�than�we�have�yet�appreciated.�� If�so,
then�we�will�eventually�need�more�advanced�forms�of�protective�organization,
and�we�had�best�start�discussing�the�detailed�implications.
Controlling�Dangerous�Pathogens�Report 49
�50 Controlling�Dangerous�Pathogens�Report
�Appendix A
US-Based Project Workshop Participants
Affiliations�are�current�for�the�time�the�individual�participated�in�the�project�and
are�for�information�purposes�only.
Norma� Allewell
Dean,�College�of�Life�Sciences
University�of�Maryland
Jeffrey� Almond
Senior�VP�for�External�R&D�and
Discovery�Sciences
Aventis�Pasteur
Ron� Atlas
Dean,�Graduate�School
University�of�Louisville
Joseph� R.� Barnes
Brigadier�General�(Retired)
US�Army
Natalie� Barnett
Biosecurity�Systems�Analyst
Sandia�National�Laboratories
Kennette� Benedict
Director,�International�Peace�and
Security�Program
The�John�D.�and�Catherine�T.
MacArthur�Foundation
Leslie� Berlowitz
Executive�Officer
American�Academy�of�Arts�and
Sciences
Gregg� Bloche
Professor�of�Law
Georgetown�University
Orley� Bourland
Former�Official
Fort�Detrick
Allan� Cameron
Program�Manager,�National�Security
Program
Computer�Sciences�Corporation
Rocco� Casagrande
Private�Consultant
Shubha� Chakravarty
Software�Engineer
Brookings�Institution
Allison� Chamberlain
Program�Assistant,�National�Science
Advisory�Board�for�Biosecurity
National�Institutes�of�Health
Marie� Chevrier
Professor
University�of�Texas�at�Dallas
Eileen� Choffnes
Director,�Forum�on�Microbial�Threats
National�Academy�of�Sciences
Rashid� Chotani
Assistant�Professor
Johns�Hopkins�University
George� Church
Professor�of�Genetics
Harvard�Medical�School
Nancy� Connell
Professor
University�of�Medicine�and�Dentistry
of�New�Jersey
Derek� Cummings
Research�Associate,�Department�of
International�Health
Bloomberg�School�of�Public�Health
John�Hopkins�Universtiy
Malcolm� Dando
Professor,�Department�of�Peace
Studies
University�of�Bradford
Controlling�Dangerous�Pathogens�Report 51
�Christopher� Davis
Chief�Scientist�&�Director�of
Biomedical�Research
CUBRC
Neil� Davison
Department�of�Peace�Studies
University�of�Bradford
Paul� Doty
Mallinckrodt�Professor�of
Biochemistry,�Emeritus�Director
Harvard�University
Gregory� Douglass
Systems�Analyst,�Environmental
Safety
University�of�Maryland
Richard� Ebright
Investigator,�Howard�Hughes�Medical
Institute
Rutgers�University
Chris� Eldridge
Program�Officer,�Committee�on
International�Security�and�Arms
Control
National�Academy�of�Sciences
Gerald� Epstein
Senior�Fellow�for�Science�and
Security,�Homeland�Security�Program
Center�for�Strategic�and�International
Studies
Joshua� Epstein
Senior�Fellow
Brookings�Institution
David� Fidler
Professor�of�Law
Indiana�University
Gerald� Fink
Professor�of�Genetics
Massachusetts�Institute�of�Technology
Joe� Fitzgerald
Senior�Associate,�Center�for
Biosecurity
University�of�Pittsburgh�Medical
Center
52 Controlling�Dangerous�Pathogens�Report
David� Franz
Chief�Biological�Scientist
Midwest�Research�Institute
Arthur� Friedlander
Senior�Scientist
U.S.�Army�Medical�Research�Institute
of�Infectious�Diseases�(USAMRIID)
Claire� Fraser
President
The�Institute�for�Genomic�Research
Jennifer� Gaudioso
International�Biosecurity�Analyst
Sandia�National�Laboratories
Alex� Greninger
Medical�Student
University�of�California,�San
Francisco
Mary�E.�Groesch
Senior�Advisor�for�Science�Policy,
Office�of�Biotechnology�Activities
National�Institutes�of�Health
Gigi� Kwik� Gronvall
Fellow,�Center�for�Biosecurity
University�of�Pittsburgh�Medical
Center
Tim� Gulden
Research�Fellow,�School�of�Public
Policy
University�of�Maryland
Harlyn� Halvorson
Director,�Policy�Center�for�Marine
Bio-Sciences�and�Technology
University�of�Massachusetts,�Boston
Peggy� Hamburg
Vice�President�for�Biological
Programs
Nuclear�Threat�Initiative
Peter� Hammond
Head�of�Corporate�Affairs,�Centre�for
Emergency�Preparedness�and
Response,�Porton�Down
UK�Health�Protection�Agency
�Jason� Harenski
Architect
Insubstantial�Arts
Alastair� Hay
Professor,�Environmental�Toxicology,
School�of�Medicine
University�of�Leeds
Lucas� Haynes
Program�Officer,�International�Peace
and�Security�Program
The�John�D.�and�Catherine�T.
MacArthur�Foundation
Lisa� Hensley
Research�Microbiologist
U.S.�Army�Medical�Research�Institute
of�Infectious�Diseases�(USAMRIID)
Thomas� Holohan
Executive�Director,�National�Science
Advisory�Board�for�Biosecurity
National�Institutes�of�Health
James� Holt
Senior�Attorney�for�Office�of�the
General�Counsel
Centers�for�Disease�Control
Jo� Husbands
Senior�Project�Director,�Policy�and
Global�Affairs�Division
National�Academy�of�Sciences
Peter� Jahrling
Chief�Scientist
National�Institute�of�Allergies�and
Infectious�Diseases
Joseph� Jemski
Former�Official
Fort�Detrick
Anna� Johnson-Winegar
Consultant
Rebecca� Katz
Doctoral�Candidate
Woodrow�Wilson�School�of�Public
and�International�Affairs
Princeton�University
Carl� Kaysen
Skinner�Professor�of�Political
Economy,�Emeritus
Massachusetts�Institute�of�Technology
Barry� Kellman
Professor,�College�of�Law
DePaul�University
Gregory� Koblentz
Post-Doctoral�Fellow,�Security�Studies
Program
Massachusetts�Institute�of�Technology
David� Koplow
Director,�Center�for�Applied�Legal
Studies
Georgetown�University
Jens� Kuhn
Research�Fellow
Brigham�and�Women’s�Hospital
Edgar� Larson
Former�Official
Fort�Detrick
James� LeDuc
Director�of�Biological�and�Rickettsial
Diseases
Centers�for�Disease�Control
Milton� Leitenberg
Senior�Research�Scholar,�CISSM
University�of�Maryland
Shan�Lu
Associate�Professor
University�of�Massachusetts�Medical
School
Martin� Malin
Program�Director
Committee�on�International�Security
Studies
American�Academy�of�Arts�and
Sciences
Richard� Manchee
Director
Arjemptur�Technology�Limited
Controlling�Dangerous�Pathogens�Report 53
�Jessica� Mann
Research�Teaching�Specialist�&
Laboratory�Manager
Center�for�Emerging�Pathogens
University�of�Medicine�and�Dentistry
of�New�Jersey
Gene� Matthews
Legal�Advisor
Centers�for�Disease�Control
Alan� Pearson
Program�Director,�Biological�and
Chemical�Weapons�Program
Center�for�Arms�Control�and�NonProliferation
C.J.� Peters
Director,�Center�for�Biodefense
University�of�Texas�Medical�Branch
Caitronia� McLeish
Research�Fellow
University�of�Sussex
Janet� Peterson
Assistant�Director�and�Biological
Safety�Officer
University�of�Maryland
Jack� Melling
Senior�Science�Fellow
Center�for�Arms�Control�and�NonProliferation
James�B.�Petro
Chief,�Knowledge�Integration�Program
Office
Department�of�Homeland�Security
Peter� Merkle
Project�Manager,�Group�Collaboration
Technology�Development
Sandia�National�Laboratories
John� Polanyi
Department�of�Chemistry
University�of�Toronto
Matthew� Meselson
Thomas�Dudley�Cabot�Professor�of
the�Natural�Sciences
Harvard�University
Piers� Millet
Orchard�College
Thomas� Monath
Chief�Scientific�Officer
Acambis
Timothy� Ng
Associate�Vice�President�for�Research
University�of�Maryland
Patricia� Nicholas
Program�Associate,�International
Peace�and�Security
Carnegie�Corporation�of�New�York
Kathryn� Nixdorff
Professor,�Department�of
Microbiology�and�Genetics
Darmstadt�University�of�Technology
Paula� Olsiewski
Program�Director
Sloan�Foundation
54 Controlling�Dangerous�Pathogens�Report
Alexander� Rabodzey
Doctoral�Candidate,�Division�of
Microbiology�Engineering
Massachusetts�Institute�of�Technology
Bryan� Roberts
President
Parallel�Solutions,�Inc.
Christopher� Royse
Deputy�Task�Leader,�Biological
Weapons�Proliferation�Support�Team
Science�Applications�International
Corporation
Jennifer� Runyon
Research�Associate
Chemical�and�Biological�Arms
Control�Institute
Ben� Rusek
Research�Associate,�Committee�on
International�Security�and�Arms�Control
National�Academy�of�Sciences
David� Sabatini
Frederick�L.�Ehrman�Professor�and
Chairman,�Department�of�Cell
Biology
NYU�School�of�Medicine
�Reynolds� Salerno
Director,�Biosecurity�Program
Sandia�National�Laboratories
Alan� Schmaljohn
Virologist
Suzanne� E.� Spaulding
Chair,�Standing�Committee�on�Law
and�National�Security
Richard� Spertzel
Former�Head�of�Biological
Inspections, United�Nations�Special
Commission�(UNSCOM)
Robert� Sprinkle
Associate�Professor,�School�of�Public
Affairs,�University�of�Maryland
Dan� Stein
Professor,�Cell�Biology
University�of�Maryland
Eric� Stephen
Chemical�&�Biological�Medical
Countermeasures,�R&D�Coordination
Defense�Research�and�Development
Canada
Emmanuelle� Tuerlings
Technical�Officer,�Preparedness�for
Deliberate�Epidemics
World�Health�Organization
Sanford� Weiner
Research�Associate
Center�for�International�Studies
Massachusetts�Institute�of�Technology
Mark� Wheelis
Senior�Lecturer,�Microbiology
Department
University�of�California�at�Davis
Simon� Whitby
Department�of�Peace�Studies
University�of�Bradford
Patricia� Wrightson
Staff�Director
Roundtable�on�Scientific
Communication�and�National�Security
National�Academy�of�Sciences
Jenna� Young
Research�Assistant
Federation�of�American�Scientist
Controlling�Dangerous�Pathogens�Report 55
�56 Controlling�Dangerous�Pathogens�Report
�Appendix B
Regional Workshop Participants
Affiliations�are�current�for�the�time�the�individual�participated�in�the�project�and
are�for�information�purposes�only.
Lucia� Aleixo
Researcher,�Federal�University�of
Minas�Gerais,�Faculdade�de�Medicina,
BRAZIL
Philip� van� Dalen
Senior�Policy�Officer,�Communicable
Diseases�/�Bioterrorism,�Ministry�of
Public�Health,��NETHERLANDS
Jorge� Arevalo
Head�of�the�Molecular�Epidemiology
Research�Unit,�Instituo�de�Medicina
Tropical�“Alexander�von�Humboldt,”
PERU
Maria� Espona
Science�and�Technology�Professor
National�Defense�School
ARGENTINA
Antonio�de�Padua�Risolia�Barbosa
Deputy�Director�of�Production,�BioManguinhos�Oswaldo�Cruz
Foundation,�BRAZIL
Borut� Bohanec
Head�of�the�Center�for�Plant
Biotechnology,�University�of
Ljubljana,�SLOVENIA
B.P.�� Berdal
Head,�Institute�of�Microbiology
Armed�Forces�Medical�Services
NORWAY
Edmundo� Calva
Professor�of�Molecular�Microbiology
Instituto�de�Biotecnologia�UNAM,
MEXICO
Filippa� Corneliussen
Research�Fellow,�BIOS�Centre
London�School�of�Economics
UNITED�KINGDOM
Ottorino� Cosivi
Project�Leader,�Preparedness�for
Deliberate�Epidemics,�Dept�of
Epidemic�and�Pandemic�Alert�and
Response,�WHO
Emoke� Ferenczi
Department�of�Virology,�“Bela�Johan
National�Centre�for�Epidemiology,”
HUNGARY
Roberto� Fernandez
Chief�of�Biosafety,�Instituto�Pedro
Kouri,�CUBA
Ake� Forsberg
Research�Director,�FOI-NBC�Defense,
SWEDEN
Jozsef� Furesz
Scientific�Director,�Institute�of�Health
Protection,�Health�Services�of
Hungarian�Defence�Forces,
HUNGARY
Joxel� Garcia
Senior�VP�and�Senior�Medical
Advisor,�Maximus,�Inc.
Former�Deputy�Director,�PAHO
Natalia� Kostereva
State�Federal�Enterprise�for�Science
Research�Centre�for�Toxicology�&
Hygienic�Regulation�of
Biopreparations�at�Federal�MedicoBiological�Agency,�RUSSIA
Controlling�Dangerous�Pathogens�Report 57
�Vidal� Rodriguez� Lemoine
Professor�in�Genetics�and
Microbiology,�Faculty�of�Sciences,
Universidad�Central�de�Venezuela
VENEZUELA
Marcin� Niemcewicz
Senior�Research�Fellow,�Military
Institute�of�Hygiene�&�Epidemiology
Biological�Threat�Identification�and
Countermeasures�Center,��POLAND
Alemka� Markotic
Associate�Professor,�Head�of
Scientific�Unit,�University�Hospital
for�Infectious�Diseases,�CROATIA
Pericles� Palha� de� Oliveira
Deputy�Director,�Brazilian�Army
Institute�of�Biology,��BRAZIL
Leonardo� Mateu
President,�Instituto�de�Estudios
Avanzados,�VENEZUELA
Caitriona� McLeish
Research�Fellow,�Science�Policy
Research�Unit,�University�of�Sussex
UNITED�KINGDOM
Leda� C.S.�� Mendonca-Hagler
Professor�of�Microbiology
Universidade�Federal�do�Rio�de
Janeiro,��BRAZIL
Carlos� Alberto� Mendoza� Ticona
Infectious�Diseases�and�Tropical
Medicine,�Instituto�Nacional�de�Salud,
PERU
Gloria� Palma
Professor,�Department�of
Microbiology,�School�of�Health
Sciences,�Universidad�del�Valle,
Campus�San�Fernando,�COLOMBIA
Georg� Pauli
Head�of�the�Department�of�Biosafety
Robert�Koch�Institute,��GERMANY
Bogdan� Petrunov
Director,�National�Center�of�Infectious
and�Parasitic�Diseases,��BULGARIA
Gerard� Pouw
Senior�Policy�Officer,�Communicable
Diseases/Bioterrorism,�Ministry�of
Public�Health,��NETHERLANDS
Walter� Mendoza
Consultant,�United�Nations�Population
Fund,��PERU
Julius� Rajcani
Assistant�Professor,�Institute�of
Virology,�Academy�of�Sciences
SLOVAKIA
Roque� Monteleone-Neto
United�Nations�Secretariat
1540�Committee�Experts�Office
UNITED�NATIONS
Lajos� Rozsa
Animal�Ecology�Research�Group
Hungarian�Academy�of�Sciences
HUNGARY
Vivienne� Nathanson
Director�of�Professional�Activities
British�Medical�Associatioin
UNITED�KINGDOM
Guilherme� Santana
Superiintendente�de�Planejamento�e
Pesquisa,�Agência�Nacional�do
Petróleo,�Gás�Natural�e
Biocombustiveis,��BRAZIL
Kathryn� Nixdorff
Institut�für�Mikrobiologie�und�Genetik
Technische,�University�of�Darmstadt,
GERMANY
58 Controlling�Dangerous�Pathogens�Report
David� Sawaya
Bioeconomy�/�Biosecurity
International�Futures�Programme
OECD
�Simone� Scholze
Programme�Specialist,�Ethics�of
Science�and�Technology,�UNESCO
Vladimir� Sigaev
State�Federal�Enterprise�for�Science,
Research�Centre�for�Toxicology�and
Hygienic�Regulation�of
Biopreparations�at�Federal�MedicoBiological�Agency,��RUSSIA
N.J.� Silman
Group�Leader,�Centre�for�Emergency
Prepareness�and�Response,�Health
Protection�Agency,�Porton�Down
UNITED�KINGDOM
Karl� Simpson
President,�Benezech�–�Simpson
FRANCE
Geoffrey� Smith
Department�of�Virology,�Faculty�of
Medicine,�Imperial�College�London
UNITED�KINGDOM
Mario� Soberon
Head�of�Department�of�Molecular
Microbiology,�Instituto�de
Biotecnologia,�Universidad�Nacional
Autonoma�de�Mexico,��MEXICO
Ana� Tapajos
Head�of�Projects�Division,�Office�of
International�Affairs�(Minister’s
Cabinet),��BRAZIL
Judit� Vegh
National�Communications�Authority
HUNGARY
Rafael� Vicuna
Full�Professor,�Faculty�of�Biological
Sciences,�Pontifica�Universidad
Catolica�de�Chile,��CHILE
Dominique� Werner
Head,�Arms�Control�Unit
SPIEZ�Laboratory,��SWITZERLAND
Guillermo� Whittembury
Senior�Investigator�Emeritus,�Instituto
Venezolano�de�Investigaciones
Cientificas,��VENEZUELA
Controlling�Dangerous�Pathogens�Report 59
�60 Controlling�Dangerous�Pathogens�Report
�Appendix C
Prototype Data Management System: Overview
The�proposed�Biological�Research�Security�System�for�protective�oversight�of
research�with�dangerous�pathogens�rests�on�two�information-intensive�elements:
personnel� and� facility� licensing� and� independent� peer� review.�� Individual
researchers� and� academic,� corporate,� or� government� administrators� will� only
make�sensitive�information�available�to�outside�scrutiny�if�they�believe�that�the
benefits�of�disclosure�will�outweigh�the�inconvenience,�expense,�and�potential
for�misuse.��The�BRSS�has�been�designed�to�match�the�disclosure�requirements
with� the� degree� of� risk� involved� in� a� particular� line� of� research.�� Thus,� one
necessary� component� for� the� success� of� the� overall� BRSS� is� a� multi-level,
access-controlled� data� management� system� that� is� easy� to� use,� relatively
inexpensive,�highly�reliable,�and�extremely�secure.
No�such�data�system�for�tracking�research�with�dangerous�pathogens�currently
exists,�and�the�more�limited�systems�that�are�available�have�been�criticized�on
grounds�of�usability,�security,�and�privacy.��For�example,�U.S.�legislation�passed
in�May�2002�requires�all�facilities�that�possess�certain�human,�plant�or�animal
pathogens�to�register�with�the�Centers�for�Disease�Control�and�Prevention�or�the
Animal�and�Plant�Health�Inspection�Service.��It�also�directs�the�Departments�of
Health�and�Human�Services�and�Agriculture�to�develop�a�national�database�of
registered�persons�and�the�controlled�agents�they�possess,�including�strain�and
other�characterizing�information�if�available.��Scientists�and�administrators�have
reacted� to� this� limited� data� collection� effort� with� complaints� about� the
cumbersome� reporting� process,� questions� about� the� security� value� of� some
required� information,� and� uncertainty� about� who� could� access� the� reported
information�and�how�it�might�be�used.�� Clearly,�both�the�currently�mandated
data� collection� effort� and� our� more� ambitious� proposal� to� collect� information
about� research� activities� as� well� as� pathogen� holdings� would� benefit� from� a
more�systematic�effort�to�think�through�the�data�management�questions�from�the
perspectives�of�the�scientists,�administrators,�and�technical�support�staff�whose
cooperation�is�essential.
Prototype�Data�Management�System1
The�BRSS�is�essentially�a�set�of�rules�about�what�types�of�information�must�be
disclosed� by� whom,� to� whom,� when,� for� what� purposes,� and� with� what
protections.�� Accordingly,� we� have� approached� the� BRSS’s� prototype� data
��������������������������������������
1
��Jason�Harenski�developed�the�functional�specification�and�Gordon�McMillan�built�the
prototype�system,�with�assistance�from�Tim�Gulden.��The�questionnaires�were�developed�by
Jessica�Mann�McCormick.
Controlling�Dangerous�Pathogens�Report 61
�management� software� as� a� workflow� system�� A� workflow� system� passes
information� and� tasks� from� user� to� user� according� to� clearly� defined� internal
rules.�� Such�a�system�must�be�dynamic,�with�defined�procedures�for�updating
and� disseminating� its� internal� rule� sets� when,� for� example,� a� BRSS� policy
decision�is�made�to�add�new�research�activities�to�existing�oversight�procedures
or� to� require� additional� information� about� research� activities� at� an� existing
oversight�level.
Our�prototype�data�management�system�is�distributed�in�a�tree-shaped�structure,
with�each�locus�of�oversight�having�the�ability�to�operate�its�own�server�so�that
it�can�add�customized�questions�and�retain�direct�control�over�its�data.�� While
we�have�conceptualized�this�as�a�three�level�structure�with�local,�national,�and
international� level� nodes,� the� software� is� capable� of� supporting� an� arbitrary
number� of� levels.�� Every� end� user� (researcher,� administrator,� or� technical
support� staff)� is� a� “client”� who� communicates� exclusively� with� a� server� that
contains� the� relevant� rule� sets� and� retains� physical� control� over� records
associated� with� its� clients.�� The� data� management� system� could� operate� with
only� one� functioning� server� (the� root� node� at� the� international� level),� but
typically� the� servers� associated� with� the� broader� oversight� bodies� will� act� as
parent� nodes� for� child� nodes� that� possess� more� detailed� information� about� a
geographically�smaller�set�of�less�dangerous�activities.�� This�structure�provides
tremendous�flexibility�and�scalability.��For�example,�it�means�that�if�a�decision
was�made�to�start�the�BRSS�with�a�small�number�of�like-minded�countries�and
then�to�expand�it�over�time,�the�data�system�could�be�fully�functional�at�the
outset� and� grow� with� the� oversight� system.�� It� also� means� that� different
countries�can�organize�the�nodes�under�their�jurisdiction�into�different�patterns
depending� on� their� own� national� regulatory� structure,� economic� and
technological�circumstances,�and�amount�of�research�with�dangerous�pathogens.
We� have� built� the� prototype� data� management� system� using� open-source
software,�including�some�pre-existing�packages�that�have�been�integrated�with
custom-written�code.�� This�design�strategy�has�made�it�possible�to�satisfy�our
stringent�requirements�without�paying�for�unnecessary�and�expensive�features.
The�data�management�system�has�been�designed�so�that�no�license�fee�needs�to
be�paid�by�individual�users�or�server�nodes.��Thus,�decisions�about�participation
and� node� operation� can� be� made� on� the� merits� alone.�� Using� open-source
software�is�also�consistent�with�the�BRSS�philosophy�of�transparency,�reliability,
and� integrity.�� Before� entrusting� sensitive� information� to� the� system,� any
potential�user�can�check�the�complete�code�to�make�sure�that�the�software�will
do�what�it�is�supposed�to�do�and�nothing�more.
System� Description
The�prototype�BRSS�data�management�system�is�designed�to�demonstrate�the
key�features�of�such�a�system�and�to�provide�a�concrete�example�on�which�a
discussion� of� a� full-blown� system� can� be� based.�� These� features� include� the
ability�to:
•
•
•
establish�client/server�and�parent-node/child-node�relationships;
present�users�with�user-friendly�questionnaires�at�appropriate�times;
collect,� store,� manage,� and� transmit� information� between� databases
according�to�existing�internal�rules;
62 Controlling�Dangerous�Pathogens�Report
�•
•
•
change�internal�rules�and�disseminate�modified�questionnaires�to�reflect
new� BRSS� policy� decisions� or� additional� requirements� established� by
national�or�local�oversight�officials;
flag�situations��in�which�existing�rules�are�not�followed�or�new�rules�are
rejected,�so�that�the�situation�can�receive�appropriate�follow-up�at�the
appropriate�oversight�level;�and,
provide�financial-industry-grade�access�controls�and�information�security
at�all�times.
In�the�interest�of�security�and�deployment�simplicity,�we�have�chosen�a�“thin
client”� framework� where� all� processing� and� storage� is� conducted� on� server
nodes� that� users� access� via� a� web� browser� client.�� This� avoids� the� need� for
individual� users� to� install� custom� software� and� allows� client-server� security
protocols�to�be�handled�in�an�industry�standard�way.
The�prototype�system�uses�questionnaires�reflecting�BRSS�policies�as�a�basis�for
the� oversight� of� institutions,� laboratories,� users,� and� projects.� When� a� new
institution,� laboratory,� user,� or� project� is� created� in� the� system,� the� user
associated�with�this�newly�created�entity�is�prompted�(via�email)�to�log�into�the
system� and� respond� to� a� set� of� questions� regarding� the� new� entity� (a� new
project,� for� example).�� This� opening� questionnaire� gathers� basic� information
about�the�new�project�and�then�asks�a�series�of�questions�designed�to�determine
the�need�for�further�questions.��If,�for�example,�the�project�involves�the�use�of
recombinant� DNA� technology,� the� user� is� queued� a� follow-up� questionnaire
about�how�the�technology�will�be�used,�what�the�researcher�hopes�to�accomplish
through�its�use,�etc.��Answers�to�these�questions�may,�in�turn,�trigger�additional
questionnaires.
Working�in�conjunction�with�biosafety�officers�and�bench�scientists�in�the�area
of�pathogen�research,�we�have�developed�eleven�prototype�questionnaires�with�a
cascading� design� to� minimize� irrelevant� questions.�� Although� the� system
contains�many�questions�overall,�most�users�will�need�to�address�relatively�few
of�them�for�any�given�project.
Assigning� administrative� responsibilities� by� institution,� laboratory,� user,� and
project�also�allows�us�to�avoid�redundant�questions.��Questions�pertaining�to�an
institution� (e.g.� whether� it� has� an� institutional� biosafety� committee)� need� be
answered�only�once,�by�the�administrator�(most�likely,�the�biosafety�officer)�of
that� institution.�� The� system� will� prompt� this� administrator� to� update� these
answers�periodically,�so�individual�researchers�need�not�be�burdened�with�them
for� each� new� project� they� undertake.�� Similarly,� a� laboratory� administrator
(which� may� or� may� not� be� the� same� person� as� the� principle� investigator� on
projects�in�that�laboratory)�will�answer�and�update�questions�pertaining�to�his�or
her�laboratory,�but�will�not�need�to�answer�them�again�for�each�new�project.
Each� user� will� answer� and� update� questions� about� their� own� training,� status,
activities,� etc.�� This� means� that� a� project� administrator� (usually� the� principle
investigator�for�that�project)�need�not�track�down�all�of�the�relevant�information
for�each�researcher�on�a�project.�� Instead,�the�system�will�make�it�clear�to�the
project� administrator� whether� the� researchers� involved� with� the� project� meet
existing�BRSS�requirements.
Questionnaires�propagate�automatically�down�the�tree�hierarchy�so�that�questions
which�are�approved�by�the�international�governing�body�can�be�entered�into�the
Controlling�Dangerous�Pathogens�Report 63
�data� system� at� the� international� node� and� automatically� copied� to� all� of� the
national�and�local�nodes.�� This�allows�the�system�to�ensure�that�the�questions
required� for� international� review� are� asked� in� a� uniform� manner.�� This� also
provides� a� mechanism� for� harmonizing� review� guidelines� among� nations� for
projects� that� will� not� be� subject� to� international� review.�� Where� there� is
international� agreement� on� questions� that� should� be� asked� of� all� projects
undergoing� national-� or� local-level� review,� they� can� be� asked� in� a� uniform
fashion.��It�is�also�possible�for�national�(or�lower)�level�nodes�to�add�questions
of� their� own� that� would� apply� only� to� nodes� under� their� supervision.�� One
objective�of�the�prototype�is�to�demonstrate�that�a�single�software�approach�can
support�a�range�of�decisions�in�this�area.
Answers�to�questions�about�a�proposed�project�are�sent�to�a�review�committee
comprised�of�scientists,�security�and�public�health�experts.��These�reviewers�are
initially�anonymous�relative�to�the�investigator�but�are�known�to�one�another.
As�the�questionnaires�are�completed,�the�reviewers�are�prompted�(by�email)�to
log�into�the�system�and�review�them.�� If�the�proposal�has�been�determined�by
the�relevant�review�committee�chairperson�to�pose�minimal�risk�or�to�involve
minor�changes�to�a�previously�approved�project�the�reviewers�can�approve�the
project�electronically.�� Otherwise�the�proposal�would�be�reviewed�in�a�formal
meeting,� which� the� senior� scientists� involved� in� the� project� generally� would
attend.�The�reviewers�can�approve,�disapprove,�or�elevate�the�project�to�a�higher
oversight� level.�� Decision� making� in� this� prototype� is� by� consensus,� with
approval�required�from�all�reviewers�before�a�project�can�proceed.��A�procedure
roughly� analogous� to� this� project� review� procedure� is� used� for� licensing
institutions,�laboratories,�and�users.
If� the� reviewers� choose� to� elevate� the� project,� the� questionnaires� and� related
documents� pertaining� to� the� project� are� shared� with� the� parent� node.�� For
example,� if� reviewers� at� a� university� determine� that� a� project� falls� into� the
category�of�“moderate�concern”�and�thus�requires�national�oversight,�they�can
elevate�the�project�for�review�by�the�national�node.��Review�at�the�national�node
proceeds�as�it�did�at�the�local�level.�� If,�in�turn,�these�reviewers�find�that�the
project� fits� the� criteria� for� activities� of� “extreme� concern,”� they� can� further
elevate�it�for�review�at�the�international�level.
If�at�any�point�in�the�process�a�node�would�like�outside�input�–�either�from�an
expert� at� a� peer� institution� or� from� someone� at� one� of� the� higher� (or� lower)
level�nodes,�the�system�allows�an�outside�expert�who�meets�BRSS�obligations�to
“visit”� another� node� at� the� invitation� of� the� host� node.�� This� provides� a
mechanism�by�which�institutions�can�supplement�their�internal�expertise�while
retaining�control�over�projects�which�do�not�require�elevation�to�a�higher�review
level.�� This�mechanism�also�provides�limited�support�for�collaborative�projects
which�involve�researchers�from�several�institutions,�though�a�full-scale�system
might�need�more�elaborate�mechanisms�in�this�area.
The�system�uses�multiple�levels�of�encryption�to�ensure�secure�handling�of�data.
All�user�interactions�with�the�system�are�conducted�using�the�HTTPS�protocol,
which� is� the� industry� standard� means� of� transmitting� sensitive� financial
information�to�and�from�web�browsers.�� The�server�nodes�use�state�of�the�art,
open-source�security�standards�which�provide�a�unique�balance�of�security�on
the�one�hand,�and�transparency�in�the�means�of�achieving�that�security�on�the
64 Controlling�Dangerous�Pathogens�Report
�other.�� Finally,�stored�data�is�encrypted,�ensuring�that�even�if�an�intruder�were
to�breach�the�system�security,�he�could�not�retrieve�any�meaningful�information.
By�providing�a�secure�and�systematic�framework�to�facilitate�the�development,
distribution,� and� review� of� questionnaires� relating� to� the� institutions,
laboratories,� persons� and� projects� involved� with� high� consequence� pathogens
research,� this� prototype� provides� a� concrete� example� of� how� the� information
flow�associated�with�a�full-scale�BRSS�might�work.��While�the�prototype�does
not�address�every�concern�that�a�full-blown�system�might�raise,�we�believe�that
it� is� a� valuable� platform� for� demonstrating� the� information� management
techniques�that�would�be�needed�for�a�real�system�and�for�advancing�discussion
from�abstract�issues�toward�concrete�policies.
Controlling�Dangerous�Pathogens�Report 65
�66 Controlling�Dangerous�Pathogens�Report
�Appendix D
Prototype Licensing Questionnaire
New User
1. What is your name?
Text
6. What is your current address?
Long Text
2. Please enter your Social Security
Number. If you do not have one, list
your visa information.
Text
7. What is your current phone
number?
Text
3. What is the highest academic
degree you have obtained?
8. Please enter your work contact
information.
Long Text
Bachelors degree (BA,BS, etc.) |
Masters degree (MA, MS, etc.) |
PhD | MD |
No post secondary school
9. Please upload the most recent
copy of your Curriculum Vitae.
4. From what institution did you
obtain this degree?
Text
5. What is the name of your current
employer?
Text
Upload Document
10. For which role are you applying?
Investigator| Reviewer| Compliance
Officer| Site Administrator|
Lab Manager|
Technician | Other
New Institution
1. Is this application:
A new institution |
A renewal of an existing license |
An amendment to an existing license
8. Current CDC registration number,
issue date, and expiration date (if
applicable):
Text
2. Institution name:
Text
3. Address of institution:
Text
9. Current APHIS registration number,
issue date, and expiration date (if
applicable):
Text
4. City:
Text
10. Responsible Official:
5. State:
Text
6. Zip code:
Text
11. Name of Alternate Responsible
Official:
Text
7. Type of Institution:
Academic | Government |
Commercial | Private | Other
Text
12. Does your institution have an
Institutional Biosafety Committee?
Yes No
Controlling�Dangerous�Pathogens�Report 67
�13. Please list the name and title of
the Chairperson of the IBC:
Text
22. Are routine lab inspections
performed?
Yes No
14. How often does your IBC meet?
23. How are records of these
inspections maintained? How
frequent are the inspections? Long Text
Text
15. How is the procedure conducted
for the review of protocols? Long Text
16. Pease upload all approved and
pending IBC applications for
infectious materials and rDNA for the
past 12 months:
Upload Document
17. Does your institution have an
Institutional Animal Care and Use
Committee (IACUC)?
Yes No
18. Please list the name and title of
the Chairperson of the IACUC: Text
19. How often does the IACUC meet?
Text
20. Please attach all approved and
pending applications pertaining to
animal research for the past 12
months:
Upload Document
21. Which department in your
institution is responsible for biosafety
and chemical hygiene?
Text
24. Attach a copy of the inspection
checklist:
Upload Document
25. Does your institution have a
chemical hygiene plan?
Yes No
26. Does your institution have a
standard procedure for handling
hazardous materials?
Yes No
27. Does your institution have an
Institutional Review Board (IRB)?
Yes No
28. Please list the name and title of
the Chairperson of the IRB:
Text
29. How often does your IRB meet?
Text
30. Please attach the applications and
consent form templates used by your
IRB:
Upload Document
New Laboratory
7. Type of laboratory:
1. Is this application:
A new laboratory |
A renewal of an existing license |
An amendment to an existing license
2. Laboratory Name:
Text
3. Address of laboratory:
Text
4. City:
Text
5. State:
Text
6. Zip code:
Text
68 Controlling�Dangerous�Pathogens�Report
Academic | Government |
Commercial | Private | Other
8. If "other" please explain:
Long Text
9. Which listed agents are used in
your laboratory?
Dropdown list of listed agents
(see attached)
�10. Is there a coordinator of all listed
agent related research in your
laboratory?
Yes No
11. If yes to question 10, please list
the name and title of the person
coordinating this research.
Dropdown list of
individuals at this institution
12. Upload a copy of the laboratory
floorplan.
Upload Document
13. Please choose all from the
following list that describe your
HVAC system.
Single-pass | Re-circulated |
Dedicated exhaust | Shared exhaust |
Constant air volume | Variable air volume|
Redundant exhaust fans |
Emergency Power Backup
14. Which class of Bio-Safety Cabinet
is being used in this laboratory?
I | II, Type A1 | II, Type A2 |
II, Type B1 | II, Type B2 | III
15. How is the Bio-Safety Cabinet
connected to the HVAC System?
Duct |Thimble | Re-circulating |
none of the above
16. How often is the Bio-Safety
Cabinet Certified?
Six months | one year
17. Upload a description of the
alarms and other monitors in your
laboratory that are connected to the
HVAC system. Explain each alarm
and what it signals, as well as the
repair efforts for each alarm type.
Upload Document
18. Does laboratory have eyewash?
Yes No
19. How often is the eyewash tested?
Weekly | every two weeks |
every three weeks | once per month
20. Does this laboratory have a biosafety manual?
Yes No
21. MSDS
workers?
forms
available
for
Yes No
22. Upload a copy of your
Emergency Response Plans.
Upload Document
23 Please upload a copy of all first
responder assurance forms.
Upload Document
24 Please summarize training
methods for the Emergency Response
Plan.
Long Text
25 Have employees been provided
with Bloodborne Pathogens Training
in the past year?
Yes No
Security Measures
1. Which of the following barriers are
present at your laboratory?
Card Swipe | Pin Numbers |
Locks on doors |
Locks on incubators, refrigerators, etc. |
Video cameras/Motion sensors | Other
2. Are security guards present at the
entrance to the building in which
your laboratory is located?
Yes No
3. Is there a sign in/out book? Yes No
4. Explain how stored pathogens are
coded (if at all):
Long Text
5. Do you maintain inventories on all
agents contained in your laboratory?
Yes No
Controlling�Dangerous�Pathogens�Report 69
�6. How are the inventory records for
listed agents maintained?
Long Text
10 Upload the current security plan
for your laboratory: Upload Document
7. How is loss/theft of agents
detected?
Long Text
11 Summarize training plans for your
security plan:
Long Text
8 How many people have access to
the agents?
Text
12 Has your laboratory undergone a
threat/vulnerability assessment?
Yes No
9 Please explain the steps that
persons wanting access to select
agents must complete as well as
measures in place to protect the
select agents from theft.
Long Text
70 Controlling�Dangerous�Pathogens�Report
13 Which agencies have performed
threat/vulnerability assessments for
your laboratory?
Long Text
�Appendix E
PROTOTYPE PROJECT QUESTIONNAIRES
New Project
1. Please describe the purpose and
provide background information as to
the reason for this project. Long Text
2. Explain your project in lay
terms.
Long Text
3. Please explain your project in
detail in scientific terms.
Long Text
4. What is your hypothesis? Long Text
5. Where will this project be
conducted?
Dropdown list of laboratories
at the institution
12. If yes to question 11, please list
the agent name (genus, species). Text
13. Does the agent(s) used in this
project have any recognized or
anticipated pathogenic, toxigenic or
virulence potential for humans, plants
or animals?
Yes No
14. If yes to question 13, please
explain in detail.
Long Text
15. What Bio-Safety Level will be
used?
BSL1 | BSL2 | BSL3 | BSL4
16. Could these experiments increase
virulence or environmental stability?
Yes No
6. Please explain why you are
qualified to perform this research.
Long Text
7. Will research on listed agents be
included in this project?
Yes No
8. Select organism(s) you will be
working with:
17. Could the host range be
expanded as a result of these
experiments?
Yes No
18. Could the host range of the agents
used in this project be expanded due
to natural processes?
Yes No
Dropdown list of select
organisms (see attached)
19. Will these experiments be
performed in animal models? Yes No
9. Will you be working with an agent
related to a listed agent?
Yes No
20. Will you be utilizing human
subjects?
Yes No
10. If yes to question 9, please list the
agent name (genus and species). Text
21. Will
conducted?
11 Will you be working with a nonlisted agent?
Yes No
22 Will work on recombinant
materials (prions, DNA, replicating
RNA, etc) be conducted?
Yes No
aerosol
studies
be
Yes No
Controlling�Dangerous�Pathogens�Report 71
�23 Will genome transfer, genome
replacement, de novo synthesis, or
cellular reconstitution of an agent be
performed?
Yes No
multiple institutions?
Yes No
27. If yes to question 26, please list
the other participating institutions.
Long Text
24. Please upload a detailed
description as to the possible risks of
this research as well as the possible
benefits. In the discussion include a
risk versus benefit comparison.
Upload Document
25. Is an alternative method for
conducting this experiment available
that would achieve the same results?
If so, would the alternative approach
be safer?
Long Text
26. Will this project be conducted at
28. Are projects similar to the one
proposed being conducted at other
institutions?
Yes No
29. The Biological Weapons
Convention (BWC) prohibits
developing, producing, stockpiling of
biological agents and toxins of types
and in quantities that have no
justification for prophylactic,
protective or other peaceful purposes.
I certify that I am in compliance with
this international treaty.
Yes No
Pathogenic Organisms
1. What is the name and strain
designation of the pathogenic
organism to be used in this project? If
it is not the wildtype strain, please
explain how it differs from the wild
type.
Long Text
use?
Yes No
9. If yes to question 8, by what
method?
Text
10. Do you concentrate the organism
in your protocol?
Yes No
2. Does this pathogen infect:
Humans | Animals | Plants
3. Is the organism attenuated? Yes No
11. If yes to question 10, what
concentration will be used (in cfu/ml
or pfu/ml) in experiment.
Text
4. If the organism is not attenuated
and is a listed agent, why must it used
in the virulent form?
Long Text
12. Method of concentration:
5. Is a toxin produced?
13. Source of organism:
Yes No
6. If a toxin will be produced, will the
project work with the toxin? Yes No
centrifugation | precipitation |
filtration | other | not applicable
14. Amount of acquisition:
Long Text
Text
15. CDC permit # for acquisition, if
applicable.
Text
7. Is drug resistance expressed?
8. Is the organism inactivated prior to
72 Controlling�Dangerous�Pathogens�Report
16. APHIS permit # for acquisition, if
applicable.
Text
�17. Will this organism require human
blood, human or primate cells for
growth?
Yes No
30. Please list the antibiotics that are
able to be used to treat possible
infections with this pathogenic
organism.
Long Text
18. If yes to question 17, list the cell
line used in this project, when
pertaining to this organism. Long Text
31. Is there a vaccine available
against this agent?
Yes No
19. Are cultures, stocks, and items
decontaminated prior to disposal?
32. If yes to question 31, please list
recommended vaccines.
Long Text
Yes No
20. If yes to question 19, by what
method?
autoclave | chemical disinfectant |
other | not applicable
21. If other, specify method:
Text
22. Will the organism be aerosolized?
33. If no to question 31, is a vaccine
currently being developed? Yes No
34. Will the strains be vaccine
resistant?
Yes No
35. Is medical surveillance necessary
when working with this organism?
Yes No
Yes No
23. If the organism will be
aerosolized, please upload detailed
protocols to ensure personnel safety
as well as experimental protocols for
the production of aerosolized
particles.
Upload Document
36. Have all potentially exposed
employees received the Hepatitis B
vaccine or proven immunity? Yes No
24. Will these experiments increase
the environmental stability or
virulence of the organism?
Yes No
25. If yes to question 24, please
explain how.
Long Text
26. Is this strain resistant to any
antibiotics?
Yes No
27. If yes to question 26, list.Long Text
28. Will strains be constructed to be
antibiotic resistant?
Yes No
29. If yes to question 28, please
explain which antibiotic resistance
gene(s) will be added.
Long Text
37. Is there an additional
recommended vaccination for
workers when handling this
organism?
Yes No
38. What other means will be taken
to monitor workers health when
handling this organism? (i.e. serum
banking, tuberculin skin testing,
temperature taking)
Long Text
39. If an accidental release of this
organism were to occur, either from a
theft or a breach in engineering
controls, please explain possible
consequences to public health.
Please also describe possible
economic impacts including those on
agriculture and livestock.
Long Text
Controlling�Dangerous�Pathogens�Report 73
�Recombinant Materials
1. Provide a brief description of the
proposed recombinant research. This
should include any parts of the
project in which recombinant
materials enable the propagation of
phenotypes as well as parts involving
DNA, replicating RNA, and prions.
10. Does the insert contain more than
2/3 of a eukaryotic viral genome?
YES NO
11. Is a helper virus used?
Yes No
12. If yes to question 11, please
specify its type:
Text
Long Text
13. Is it a retrovirus?
2. Specify the source and nature of
the DNA sequence(s) to be inserted
(genus, species, gene name): Long Text
3. Will the
expressed?
inserted
gene
be
Yes No
4. If yes to question 3, what are the
gene product effects? (specifically, its
toxicity, physiological activity,
allergenicity, oncogenic potential or
ability to alter cell cycle.)
Long Text
5. Describe the virus, phage and/or
plasmid used for constructing your
recombinants(prokaryotic, eukaryotic)
Long Text
6. Identify host cell(s) or packaging
cell line in which recombinant vector
will be amplified:
Long Text
7. Is the
competent?
vector
8. Are any viral
sequences present?
replication
Yes No
components/
Yes No
9. Specify the function and nature of
any viral components specified in
question 8:
Long Text
74 Controlling�Dangerous�Pathogens�Report
Yes No
14. Describe the cell line or species
that will be exposed to the
recombinant?
Long Text
15. Will animals be exposed to
rDNA?
Yes No
16. If yes to question 15, please
specify animal:
Text
17. Will the work involve transgenic
animals?
Yes No
18. Will human subjects be exposed
to rDNA?
Yes No
19. Does the donor rDNA, RNA,
cDNA source or its vector have any
recognized or anticipated pathogenic,
toxigenic or virulence potential for
animals, plants, or humans?
Yes No
20. If yes to question 19, please
explain:
Long Text
21. What quantity of material will be
used? < 1 Liter | 1-10 Liters | > 10 Liters
�Human Subjects
1. Select all categories of subjects you
will be using for this research.
Minors | Non-English Speaking |
Minorities | Females | Genetic Materials |
Pregnant Females | Fetuses | Abortuses |
Healthy Volunteers | Students or
Employees | Psychiatrially impaired |
Cognitively impaired | Prisoners | Other
2. Number of subjects to be enrolled
at this site
Text
3. Is this a multicenter study? Yes No
4. If this is a multicenter study, please
enter the names of all sites. Long Text
5. If this is a multi-center study,
please list the total number of human
subjects
for
the
project,
encompassing all sites.
Text
10. Please give an outline of the
proposed study, including plans for
analysis and inclusion/exclusion
criteria.
Long Text
11. What are the potential benefits to
subjects or others?
Long Text
12. What are the potential risks to
subjects and the incidence of these
risks?
Long Text
13. What
treatments?
are
the
alternative
Long Text
14. Will you recruit your own
patients for this study?
Yes No
15. Please outline the recruitment
process.
Long Text
6. Is there a Clinical Trial Agreement
or Letter of Indemnification? Yes No
16. If using a flier or email text to
recruit subjects, please upload a copy
here.
Upload Document
7. If yes to question 6, upload a copy
of the Clinical Trial Agreement or
Letter of Indemnification and a
budget.
Upload Document
17. If non-English speaking subjects
are being recruited, has the consent
form been translated?
Yes No
8. Please upload a copy of the
Human Subjects Protection Training
and Examination certificate for all
those listed as PIs, co-Investigators,
study coordinators or other personnel
on this project
Upload Document
9. What procedures and/or processes
will be used during this project that
affect the subject? Examples:
phletbotomy, amount of blood
drawn, bone marrow aspiration,
exact procedure used and how much
sample is taken.
Long Text
18. If the consent form was not
translated please provide the
rationale.
Long Text
19. During the consent process, at
what times will the subjects be asked
if they have questions?
before |during | after
signing | before procedure
20. Will subjects receive a copy of
the signed consent form?
Yes No
21. How will the consent process be
documented?
Long Text
Controlling�Dangerous�Pathogens�Report 75
�22. Upload a copy of the current
consent form.
Upload Document
31. Will specimens be stored for
future use?
Yes No
23. Please explain where the signed
consent forms will be kept as well as
efforts to maintain subject
confidentiality.
Long Text
32. If yes to question 31, please list
the specimens stored, and how
confidentiality will be protected.
24. Who will obtain consent?
33. Will the storage of specimens
serve as a database or repository?
Yes No
PI | co-PI | Co-Inv | Study
Coordinator | Other
25. Please list the names of all those
who will be charged with obtaining
consent.
Long Text
26. Is there a data safety monitoring
board for this project?
Yes No
Long Text
34. Will an investigational drug be
administered?
Yes No
35. If yes to question 34, please list
the IND# for the drug being
administered.
Text
27. Describe what educational
activities or scientific knowledge, if
any, will be furthered by this study.
36. Will an investigational device be
used in this study?
Yes No
Long Text
37. If yes to question 36, please
supply the IDE# for the device. Text
28 Will patient charts or medical
records be reviewed?
Yes No
29. If personal medical history will be
obtained from the subjects, please
upload the blank medical history
sheet.
Upload Document
38. Is this a clinical trial? If yes,
please choose the type of trial:
Phase 1| Phase 2| Phase
3| Phase 4 Post Marketing
39. What is the status of this project
with your institution's IRB:
Denied | Submitted via this form
30. If questionnaires will be used,
please upload them. Upload Document
Animal Use
1. Will materials be administered to
animals?
Yes No
4. Is the
pathogen?
2. If yes to question 1, please list the
animal species:
Text
5. Is the material a human pathogen?
3. What kind of material will be
administered to the animal?
Text
6. Is it possible for the agent to be
transmitted from animals to humans
in the laboratory environment?Yes No
76 Controlling�Dangerous�Pathogens�Report
material
an
animal
Yes No
Yes No
�7. Will the material or organism be
inactivated prior to use in animals?
16. What disinfectant will be used?
Text
Yes No
8. By what route will the material be
administered?
Text
17. Describe your procedure for
changing bedding and papers. How
will these be disposed?
Long Text
9. In what volume will it be
administered?
Text
18. Describe disposal method for
animal carcasses:
Long Text
10. At what
administered?
19. Describe routine cleaning/
decontamination of animal cages:
titer
will
it
be
Text
Long Text
11. Please explain this choice of
route, volume and titer:
Long Text
20. What Animal Biosafety level has
been requested?
Text
12. Will microisolator cages be used?
Yes No
13. Will barrier housing be used?
Yes No
14. What special procedures will be
used for containment?
Long Text
15. Will work be done in a biosafety
cabinet?
Yes No
21. What is the status of this project
with your institution's IACUC:
Approved | Pending Approval |
Denied | Submitted via this form
22. Please provide IACUC number,
IACUC approval date, and IACUC
approval expiration date. (specify if
pending)
Long Text
Laboratory Biosafety & Engineering Controls
1. Please list the building/room in
which experiments will be
performed.
Text
2. Please list the building/room
location in which the bacteria/virses
will be stored.
Text
3. At what biosafety level will the
work be done? (Reference CDC/NIH
BMBL4th Edition. www.cdc.gov
1|2|3|4
4. What engineering controls are
available to control significant
aerosol generating steps for work
requiring BL-2 containment or higher
(e.g. centrifugation, vortexing,
sonification, egg harvesting):
Class I Biological Safety Cabinet (BSC) |
Class II BSC | Centrifuge safety cups |
Containment Suite | Other
5. If other, please describe: Long Text
6. Will sharps (syringes, scalpels,
glass) be used?
Yes No
7. Has the research protocol been
reviewed to minimize the use of
sharps where possible?
Yes No
8. Will sharps with integrated safety
devices be used?
Yes No
Controlling�Dangerous�Pathogens�Report 77
�9. If yes to question 8, please
describe these devices (type, model,
brand):
Long Text
10. What personal protective
equipment is recommended and
available for this work (select all that
apply):
Lab Coat | Nitrile Gloves | Non-powdered
Latex Gloves | Vinyl Gloves | Safety
Glasses w/side shields | Respiratory
Protection | Other
11. What disinfectant(s) will be used
to for routine cleanup?
1/10 bleach | 70% ethanol |
povidone-iodine | phenolic product|
chlorine dioxide product | quaternary
ammonium product | other
12. What disinfection method(s) will
be used for solid waste?
1/10 bleach | 70% ethanol |
povidone-iodine | phenolic product|
chlorine dioxide product|
quaternary ammonium product | other
13. What disinfection method will be
used for liquid waste?
1/10 bleach | 70% ethanol |
povidone-iodine | phenolic product|
chlorine dioxide product|
quaternary ammonium product | other
Personnel Security
1. Please select the approved
individuals who will be involved with
this project.
4. Has anyone in your laboratory
been denied approval?
Yes No
Dropdown list of licensed
individuals at this institution
5. If yes to question 4, please list the
name, social security number and/or
DOJ number, and the reason given
for denial for each person who has
been denied approval.
Long Text
2. Are there any individuals in your
laboratory currently awaiting
approval?
Yes No
3. If yes to question 2, please list the
name and social security and/or DOJ
number for each person awaiting
approval.
Long Text
6. Is anyone awaiting approval or
who has been denied approval
currently working on a different
aspect of this project?
Yes No
7. If yes to question 6, please explain.
Long Text
78 Controlling�Dangerous�Pathogens�Report
�End Notes
��������������������������������������
1
�See,�for�example,�Ronald�J.�Jackson�et�al.,�“Expression�of�Mouse�Interleukin-4�by�a�Recombinant
Ectromelia�Virus�Suppresses�Cytolytic�Lymphocyte�Responses�and�Overcomes�Genetic�Resistance�to
Mousepox,”�Journal�of�Virology�(February�2001):�1205-1210�and�Jeronimo�Cello�et�al.,�“Chemical
Synthesis�of�Poliovirus�cDNA:�Generation�of�Infectious�Virus�in�the�Absence�of�Natural�Template,”
Sciencexpress�(July�11,�2002),�available�at�www.sciencemag.org/cgi/content/abstract/1072266v1.
2
�National�Research�Council,�“Biotechnology�Research�in�an�Age�of�Terrorism,”�(Washington,�DC:
National�Academies�Press,�2003),�available�at�http://www.nap.edu/books/0309089778/html/;�and,�Royal
Society,�“Do�no�harm:�reducing�the�potential�for�the�misuse�of�life�sciences�research,”�RS�policy�document
29/04,�October�2004.
3
�In�addition�to�basic�research,�these�figures�also�cover�construction�of�new�biosafety�laboratories�and
development�of�medical�countermeasures.��Department�of�Health�and�Human�Services,�“Budget�in�Brief,
Fiscal�Year�2007,”�available�at�www.hhs.gov/budget/07budget/2007/BudgetInBrief.pdf.
4
��US�Department�of�Homeland�Security�and�US�Army�Garrison,�“Final�Environmental�Impact�Statement:
Construction�and�Operation�of�the�National�Biodefense�Analysis�and�Countermeasures�Center�(NBACC)
Facility�by�the�Department�of�Homeland�Security�at�Fort�Detrick,�MD,”�December�23,�2004.��For�a�critical
analysis�of�the�BTCC’s�potential�role,�see�Milton�Leitenberg,�James�Leonard,�Richard�Spertzel,
“Biodefense�crossing�the�line,”�Politics�and�the�Life�Sciences�22,�no.�2�(May�17,�2004).
5
�US�Department�of�Homeland�Security�and�US�Army�Garrison,�“Final�Environmental�Impact�Statements”
(23�December�2004).
6
�The�final�document�from�the�Sixth�Review�Conference�is�available�at
www.unog.ch/80256EDD006B8954/(httpAssets)/ICEE7A27069559C5C125723E00647FBF/$file/BWC+CON
F.VI+CRP.4-altered+as+ammended.pdf.
7
�This�discussion�draws�on�Graham�S.�Pearson�and�Malcolm�R.�Dando,�“Strengthening�the�Biological
Weapons�Convention,�Briefing�Paper�No�6:�Article�X:��Some�Building�Blocks,”�March�1998,�available�at
www.brad.ac.uk/acad/sbtwc.��See�also�the�University�of�Bradford�Genomics�Gateway�website,�available�at
www.brad.ac.uk/acad/sbtwc/gateway/.
8
�For�a�copy�of�the�Code,�see�http://binas.unido.org/binas/regulations/unido_codes.pdf
9
�The�Convention�uses�the�term�“living�modified�organisms.”�For�the�text,�see�http://www.biodiv.org.
10
�The�UNEP�Guidelines�are�available�at�http://www.unep.org/unep/program/natres/biodiv/irb/unepgds.htm.
11
�World�Health�Organization.��Laboratory�Biosafety�Manual,�Third�Edition�(Geneva:�World�Health
Organization,�2004).
12
��NSDM�35,�November�25,�1969;�and�U.S.�Department�of�Defense,�Office�of�the�Special�Assistant�for
Gulf�War�Illnesses,�Medical�Readiness,�and�Military�Deployments,�“Nuclear,�Biological�and�Chemical
Warfare�Defense,”�January�8,�2002,�available�at�http://deploymentlink.osd.mil/faq/faq_nbc.shtml.
13
��P.L.�104-132,�April�24,�1996,�Section�511.
14
��P.L.�107-56,�October�26,�2001,�Section�817.
15
��P.L.�107-188,�June�12,�2002.
16
��For�the�final�regulations,�see�42�CFR�73.12�and�9�CFR�121.12;��for�the�BMBL,�see�US�Department�of
Health�and�Human�Services,�“Biosafety�in�Microbiologial�and�Biomedical�Laboratories,�Fourth�Edition,”
(Washington,�DC:�USGPO,�1999).
17
�IBCs�are�responsible�for�ensuring�the�safety�of�recombinant�DNA�research,�while�IRBs�focus�on�the
safety�of�research�involving�human�subjects.
18
��See,�for�example,�Ronald�M.�Atlas,�“Applicability�of�the�NIH�Recombinant�DNA�Advisory�Committee
Paradigm�for�Reducing�the�Threat�of�Bioterrorism,”�April�2002.
Controlling�Dangerous�Pathogens�Report 79
����������������������������������������������������������������������������������������������������
19
��Sunshine�Project,�“Mandate�for�Failure:��The�State�of�Institutional�Biosafety�Committees�in�an�Age�of
Biological�Weapons�Research,�October�2004,�available�at�http://www.sunshineproject.org/biodefense/ibcreport.html.
20
��NIH�Guidelines,�April�2002,�available�at�http://www4.od.nih.gov/oba/rac/guidelines/guidelines.html.
21
��42�CFR�73.13�and�9�CFR�121.13.
22
�National�Research�Council,�“Biotechnology�Research�in�an�Age�of�Terrorism,”�(Washington,�DC:
National�Academies�Press),�October�2003,�available�at�http://www.nap.edu/books/0309089778/html/
23
��Information�on�the�NSABB,�including�copies�of�presentations�given�at�its�public�meetings,�are�available
at�http://www.biosecurityboard.gov/
24
�The�draft�guidance�documents�from�the�three�NSABB�working�groups�are�available�at
www.biosecurityboard.gov.
25
�See,�“Conceptualizing�an�Oversight�Framework�for�Dual-Use�Research,”�October�25,�2006,�available�at
www.biosecurityboard.gov.
26
��7�CFR�340.3;�7�CFR�340.4;�and�9�CFR�122.2.
27
��40�CFR�172.45;�40�CFR�725.255;�40�CFR�725.234;�and�40�CFR�725.238.
28
�Information�on�NEPA�is�available�at�http://www.epa.gov/compliance/nepa/
29
��Army�Regulation�385-69,�Biological�Defense�Safety�Program;�and�32�CFR�627.
30
��Statutory�Instrument�2001�(No.�4019)�The�Anti-terrorism,�Crime�and�Security�Act�2001
(Commencement�No.�1�and�Consequential�Provisions),�available�at�http://www.opbw.org/.
31
��Donald�Fredrickson,�The�Recombinant�DNA�Controversy,�A�Memoir:�Science,�Politics,�and�the�Public
Interest,�1974-1981�(Washington�DC:�ASM�Press,�2001),�40-41,�101.
32
�Statutory�Instrument�2000�(No�2831)�The�Genetically�Modified�Organisms�(Contained�Use)�Regulations,
available�at�http://www.opbw.org/.
33
��An�amendment�to�the�2000�regulation�allows�information�provided�in�notifications�or�otherwise�part�of
the�public�register�to�be�kept�confidential�for�national�security�reasons.��Statutory�2002�(No.�63)�The
Genetically�Modified�Organisms�(Contained�Use)�(Amendment)�Regulations,�available�at
http://www.opbw.org/.
34
��Statutory�Instrument�1992�(No.�3280)�The�Genetically�Modified�Organisms�(Deliberate�Release)
Regulations;�Statutory�Instrument�2002�(No.�2443)�The�Genetically�Modified�Organisms�(Deliberate
Release)�Regulations,�available�at�http://www.opbw.org/.
35
�These�are�discussed�in�more�detail�in�Graham�S.�Pearson�and�Malcolm�R.�Dando,�“Strengthening�the
Biological�Weapons�Convention,�Briefing�Paper�No�7:�Article�X:�Further�Building�Blocks,”�March�1998,
available�at�www.brad.ac.uk/acad/sbtwc.
36
��Statutory�Instrument�2002�(No.2677)�The�Control�of�Substances�Hazardous�to�Health�Regulations,
available�at�http://www.opbw.org/.
37
��This�is�discussed�in�Pearson�and�Dando,�“Briefing�Paper�No�7,”�pp.�6-7.
38
��The�1980�regulation�is�discussed�in�Pearson�and�Dando,�“Briefing�Paper�No.�7,”�pp.�4-5;�Statutory
Instrument�1998�(No.�463)�The�Specified�Animal�Pathogens�Order,�available�at�http://www.opbw.org/.
39
�See�Parliamentary�Office�of�Science�and�Technology,�“GM�Animals,”�Postnote,�Number�157,�June�2001
available�at�http://www.parliament.uk/post/pn157.pdf.����The�Act�is�available�at
http://www.homeoffice.gov.uk/animalsinsp/reference/legislation/index.htm.��Information�on�local�review�is
available�at�http://www.homeoffice.gov.uk/animalsinsp/reference/erp/erp_statement.htm.
40
��This�discussion�of�advisory�committees�draws�from�Graham�S.�Pearson�and�Malcolm�R.�Dando,
“Strengthening�the�Biological�Weapons�Convention,�Briefing�Paper�No�4:�National�Implementation
Measures,”�January�1998,�available�at�www.brad.ac.uk/acad/sbtwc.
41
��Information�available�at�http://www.hse.gov.uk/aboutus/hsc/iacs/acgm.
42
��Information�available�at�http://www.defra.gov.uk/environment/acre.
43
��Information�available�at�http://www.doh.gov.uk/acdp.
44
��See,�for�example,�Royal�Society,�“Paper�for�UN�Foundation�meeting�on�the�individual�and�collective
role�scientists�can�play�in�strengthening�international�treaties,”�RS�policy�document�05/04,�April�2004;
Royal�Society,�“Do�no�harm:�reducing�the�potential�for�the�misuse�of�life�sciences�research,”�RS�policy
document�29/04,�October�2004;�and�Royal�Society,�“The�role�of�scientific�codes�in�preventing�the�misuse
of�scientific�research,”�RS�policy�document�03/05,�May�2005.
80 Controlling�Dangerous�Pathogens�Report
����������������������������������������������������������������������������������������������������
45
�This�discussion�draws�on�Jonathan�Tucker�and�Stacy�Okutani,�“Global�Governance�of�‘Contentious’
Science:�The�Case�of�the�World�Health�Organization’s�Oversight�of�Smallpox�Virus�Research.”�The
Weapons�of�Mass�Destruction�Commission�(December�2004),�Paper�#18.
46
�World�Health�Organization,�“Smallpox�eradication:�destruction�of�variola�virus�stocks,”�Ninth�Plenary
Meeting,�WHA52.10.,�24�May�1999.
47
WHO,�“Report�of�the�meeting�of�the�Ad�Hoc�Committee�on�Orthopoxvirus�Infections,”�(Geneva,
Switzerland:�WHO,�9�September�1994).
48
�A�scientific�subcommittee�reviews�all�research�proposals.��Okutani�interview�with�Dr.�Riccardo�Wittek,
Lausanne,�Switzerland�(May�2004).
49
�World�Health�Organization,�WHO�Advisory�Committee�on�Variola�Virus�Research,�“Report�of�a�WHO
Meeting,”�Geneva:�6-9�December,�1999,�WHO/CDS/CSR/2000.1
50
�World�Health�Organization,�WHO�Advisory�Committee�on�Variola�Virus�Research,�“Report�of�the�Sixth
Meeting,”�Geneva�(4-5�November�2004),�WHO/CDS/CSRARO/2005.4
51
�Martin�Enserink,�“WHA�Gives�Yellow�Light�for�Variola�Studies,”�Science�308�(May�27,�2005):�1235.
52
�Robert�H.�Sprinkle,�“The�Biosecurity�Trust,”�BioScience�53,�no.�3�(March�2003).
53
�This�issue�is�explored�in�Alex�Greninger,�“The�Definition�and�Measurement�of�Dangerous�Research,”
July�2004,�available�at�http://www.cissm.umd.edu/documents/Greninger%20Paper%2007-16-04.pdf.
54
��This�is�discussed�in�more�detail�in�Kathryn�Nixdorff,�Neil�Davison,�Piers�Millet,�and�Simon�Whitby,
“Technology�and�Biological�Weapons:�Future�Threats,”�available�at
http://www.brad.ac.uk/acad/sbtwc/ST_Reports/ST_Report_No_2.pdf
55
��National�Research�Council,�“Biotechnology�Research�in�an�Age�of�Terrorism,”�p.�5.
56
�This�can�be�found�at�http://ohsr.od.nih.gov/irb/protocol.html
57
��The�following�projects�were�peer�reviewed�by�some�twenty�scientists�and�security�experts:��Cloning�of
MHC�I�Immunomodulators�into�Vaccinia�Virus;�Enhancement�of�Virulence�and�Transmissibility�of
Influenza�Virus;�Immunosuppression�and�Immuno-Transition�in�Plague-Mouse�Model;�Manipulation�of
Temperate�Sensitivity�in�Pospiviroidae;�and,�Exploring�New�Non-Lethal�Incapacitation�Options.��
58
�See�Royal�Society,�“The�role�of�scientific�codes�in�preventing�the�misuse�of�scientific�research,”�RS
policy�document�03/05,�May�2005.
59
�US�National�Academies�of�Science,�“Scientific�Communication�and�National�Security,”�(Washington,
DC:�National�Academy�Press),�1982,�available�at�http://www.nap.edu/books/0309033322/html/
60
�Martin�Ensirenk,�“Entering�the�Twilight�Zone�of�What�Material�to�Censor,”�Science,�November�22,
2002.
61
��The�IAEA’s�Standing�Advisory�Group�on�Safeguards�Implementation,�which�provides�impartial�advice
on�the�efficacy�of�safeguards,�might�be�a�useful�model�for�this�latter�group.
62
�This�is�discussed�in�Barry�Kellman,�“Mechanisms�for�Impelling�Compliance�with�the�BRSS,”�March
2005.
63
�As�the�working�paper�makes�clear,�these�are�rough�estimates�only,�as�the�author�did�not�screen�for�all�of
the�categories�of�research�involving�non-listed�agents�because�of�the�overall�number�of�papers�and�the
absence�of�a�suitable�search�strategy.��The�figures�also�do�not�reflect�the�broader�definition�of�de�novo
synthesis�used�in�the�final�version�of�the�Research�Categories�Table.��At�the�same�time,�the�author�almost
certainly�included�some�scientists�and�facilities�that�were�part�of�research�projects�outside�of�the�US,
simply�because�they�were�American�or�affiliated�with�an�American�research�facility.��Although�it�is
difficult�to�estimate,�these�factors�could�well�increase�the�number�of�projects�subject�to�local�oversight,�in
particular,�by�a�hundred�or�more.��See�Jens�H.�Kuhn,�“Qualitative�and�Quantitative�Assessment�of�the
‘Dangerous�Activities’�Categories�defined�by�the�CISSM�Controlling�Dangerous�Pathogens�Project,”
CISSM�Working�Paper,�December�2005.
64
�See�Brian�Rappert,�“Towards�a�Life�Sciences�Code:�Countering�the�Threat�from�Biological�Weapons,”
Bradford�Briefing�Paper�(2nd�series)�No.�13,�2004,�available�at
http://www.brad.ac.uk/acad/sbtwc/briefing/BP_13_2ndseries.pdf;�and�Royal�Society,�“The�role�of�scientific
codes�in�preventing�the�misuse�of�scientific�research,”�RS�policy�document�03/05,�May�2005.
65
�World�Medical�Association,�“Declaration�of�Washington�on�Biological�Weapons,”�Document�17.400,
September�2001,�available�at�http://www.wma.net/e/policy/b1.htm
66
�American�Medical�Association,�“Opinion�of�the�Council�on�Ethical�and�Judicial�Affairs:�Guidelines�to
Prevent�Malevolent�Use�of�Biomedical�Research,”�CEJA�Opinion�1-I-04,�available�at�http://www.amaassn.org/ama1/pub/upload/mm/465/cejo1i04.doc
Controlling�Dangerous�Pathogens�Report 81
����������������������������������������������������������������������������������������������������
67
�International�Committee�of�the�Red�Cross,�“Principles�of�Practice,”�in�“Preventing�Hostile�Use�of�the
Life�Sciences:��From�ethics�and�law�to�best�practice,”�November�11,�2004.
68
�Margaret�A.�Somerville�and�Ronald�M.�Atlas,�“Ethics:�A�Weapon�to�Counter�Bioterrorism,”�Science,
vol.�307,�March�25,�2005,�available�at
http://www.sciencemag.org/cgi/content/full/307/5717/1881?maxtoshow=&HITS=10&hits=10&RESULTFOR
MAT=&fulltext=atlas%2Band%2Bsomerville&searchid=1120837341834_5746&stored_search=&FIRSTIND
EX=0#ref6
69
�InterAcademy�Panel,�“IAP�Statement�on�Biosecurity,”��November�7,�2005,�available�at
http://www4.nationalacademies.org/iap/iaphome.nsf/weblinks/WWWW6JPDTY/$file/IAP_Biosecurity.pdf?OpenElement
70
��The�Politics�and�Life�Sciences�course�is�available�at
http://www.politicsandthelifesciences.org/Biosecurity_course.html;��Information�on�the�FAS�modules�is
available�at�http://www.fas.org/main/content.jsp?formAction=297&contentId=150
71
�Medical�Research�Council,�“Organizations�address�biomedical�research�misuse�threat,”�Media�Release,
September�8,�2005,�available�at��http://www.mrc.ac.uk/prn/public-press_08_sept_2005��The�Medical
Research�Council�appears�to�be�using�the�Fink�Committee’s�seven�experiments�of�concern�to�define�the
types�of�research�that�should�be�reviewed�for�dual-use�risks,�but�it�is�unclear�whether�the�other�UK
funding�agencies�are�taking�a�similar�approach.��The�MRC�statement�is�available�at
http://www.mrc.ac.uk/doc-bioterrorism_biomedical_research.doc
72
�Harvard�Professor�Matthew�Meselson�has�made�a�similar�proposal,�suggesting�that�local�oversight�bodies
be�established�at�all�institutions�conducting�consequential�life�sciences�research.
73
��We�intend�to�work�with�various�institutions�to�test�our�data�management�software�in�the�hope�that�their
adoption�of�our�prototype�will�help�lay�the�groundwork�for�the�type�of�comprehensive�oversight
arrangement�outlined�in�this�monograph.
74
�For�a�brief�discussion�of�OECD�activities�in�this�area,�see�Jonathan�Tucker,�“Biosecurity:�Limiting
Terrorist�Access�to�Deadly�Pathogens,”�US�Institute�of�Peace,�November�2003.
75
�A�summary�of�the�discussion�at�the�Frascati�meeting�can�be�found�at
http://www.oecd.org/dataoecd/30/56/33855561.pdf;��the�organization’s�biosecurity�website�is�at
http://www.biosecuritycodes.org
76
�For�information�on�WHO’s�activities�on�the�health�aspects�of�biological�weapons,�see
http://www.who.int/csr/delibepidemics/en/
77
�See�World�Health�Organization,�“Life�sciences�research:��opportunities�and�risks�for�public�health,”
WHO/CDS/CSR/LYO/2005.20,�2005�available�at
http://www.who.int/csr/resources/publications/deliberate/WHO_CDS_CSR_LYO_2005_20.pdf
78
�This�was�also�one�of�the�priority�areas�identified�by�a�scientific�working�group�convened�by�WHO�in
October�2006.��See,�World�Health�Organization,�“Summary�Report�from�the�Scientific�Working�Group
Meeting�on�Life�Sciences�Research�and�Global�Health�Security�(Draft).”�December�2006.
79
�See�“Issues�in�Biosecurity�and�Biosafety,”�Science�308,�no.�5730,�June�24,�2005�for�a�letter�signed�by
eleven�scientists.
80
�Philip�Chandler,�the�chair�of�the�Medical�College�of�Georgia�IBC,�has�been�quoted�as�saying�that�the
NIH�Guidelines�give�institutions�too�much�“poetic�license”�and�replacing�them�with�a�law�would�“remove
the�inconsistencies”�and�more�effectively�discourage�people�from�flouting�the�rules.���Kelly�Field,
“Biosafety�Committees�Come�Under�Scrutiny,”�Chronicle�of�Higher�Education�51,�Issue�34,�April�29,
2005.
81
�Jonathan�Tucker�has�endorsed�facility�licensing�as�part�of�his�proposal�for�strengthening�controls�on
access�to�dangerous�pathogens.��See,�Jonathan�Tucker,�“Biosecurity:�Limiting�Terrorist�Access�to�Deadly
Pathogens,”�US�Institute�of�Peace,�November�2003.
82
�Gigi�Kwik�Gronvall�of�the�UPMC�Center�for�Biosecurity�has�endorsed�licensing�biologists�in�a�number
of�public�appearances�in�recent�years.���Outside�of�the�US,�the�British�Medical�Association�called�for
licensing�biologists�in�a�presentation�in�Geneva�in�June�2005�as�did�the�journal�Nature�in�an�editorial�the
following�month.��See�“Rules�of�Engagement,”�Nature�436,�No�7047,�July�7,�2005.
83
�See,�United�States�Institute�of�Peace,�“American�Interests�and�UN�Reform:��Report�of�the�Task�Force�on
the�United�Nations,”�Washington,�DC,�2005,�available�at�http://www.usip.org/un/report/usip_un_report.pdf
The�Task�Force,�which�was�chaired�by�former�Speaker�of�the�House�Newt�Gingrich�and�former�Senator
George�Mitchell,�recommended�doing�this�under�the�auspices�of�a�new�UN�organization�for�biological
weapons�issues.
82 Controlling�Dangerous�Pathogens�Report
��The Center for International and
Security Studies at Maryland (CISSM)
School of Public Policy
University of Maryland
College Park, Maryland 20742
Telephone: 301.405.7601
Fax: 301.403.8107
cissm.umd.edu
�
Elisa Harris