�� Nanomaterials�are�now�being�manufactured�and�used�in�many�products.�However,�our�knowledge�of�the�human�health�effects�and� environmental� or� occupational� exposures� to� engineered�nanomaterials�or�nanoparticles�is�incomplete.�
�� Major� research� efforts�must� be�made� to� provide� a� complete�toxicity�profile�of�every�type�of�nanoparticles�currently�in�use,�as�almost�1000�products�are�already�in�use�[4]�and�many�more�are�now�being�developed�in�the�medical�field�and�in�electronics.�
�� Nanotechnologies�are�evolving�rapidly�all�over�the�world;�this�is� why�we�must� focus� on� filling� strategically� the� knowledge�gaps�[see�Figure�1C].�Without�interpretation�of�the�toxicological�findings,� no� sound� risk� assessment� can� be� performed� and�the� level�on�uncertainty� is� too�great� for�comfort.�The�current�occupational�extent�of�the�exposure�in�manufacturing�facilities�and� laboratories� is�not� known�and�ought� to�be�prioritized� to�properly�determine�the�human�health�hazard�[3].
Tapin, D.3, Patenaude, J.1,2
�� A�literature�review�was�performed�in�order�to�better�evaluate�the�limited�toxicological,�epidemiologic�and�ecotoxicological�studies�[see�Figures�1A�and�1B].�
�� Nanotechnology� integrates� engineering� with� biology,�chemistry�and�physics.� It�describes�a� research�area�where�the� very� nanoscale� properties� are� explored� and� strategies�are�developed�to�exploit�the�new�functionalities�of�materials�in�term�of�health�applications�and�marketable�products�[2].�
Objectives and Methodology
�� Bearing�in�mind�the�complexity,�uncertainty�and�the�ambiguity�of�the�research�data�so�far�it�is�duly�recommended�to�avoid�undue�human�exposure,�especially�in�the�industrial�facilities�and�laboratories�working�environments�where�nanotechnologies�are�produced.��
�� Current��data�on�toxicological�risk�assessment�suggest�that�we�are�deeply�in�the�fields�of�hypothetical�risk,�partially�estimated�risk�and�perceived�risk.�
�� In�the�absence�of�hard�facts�about�the�use�and�the�risks�of�carbon�nanotubes�for�example,�people�and�stakeholders��make�decisions�based�on�value�judgements.�
�� Ultimately,�reflecting�on�the�transparency,�public�perception�and�confidence�in�the�risk�assessment�process�is�crucial�[3].
Conclusion
[1] Council of Canadian Academies, 2008. Report of the Expert Panel on Nanotechnology. Small is different: A science perspective on regulatory challenges of the nanoscale. Ottawa, p. 54-117.[2] Borm P., Robbins D, et al. 2006. The potential risks of nanomaterials: a review carried out for ECETOC (European Centre for Ecotoxicology and Toxicology of Chemicals). Particle and Fibre Toxicology 3(11): 1-35.[3] Handy RD, Shaw BJ, 2007. Toxic effects of nanoparticles and nanomaterials: Implications for public health, risk assessment and the public perception of nanotechnology. Health Risk & Society 9(2): 125-144.[4] Manach JM, Nanotechnologies : ce qui se vend. 2009 Oct. 9. Le Monde. Available from:http://www.lemonde.fr/technologies/article/2009/10/09/nanotechnologies-ce-qui-se-vend_1251924_651865.html [5] Oberdörster G, Maynard A, et al., 2005. Principles for potential human health effects from exposure to nanomaterials: Elements of a screening strategy. Particle and Fibre Toxicology 8: 8-42.[6] Smart SK, Cassady AI, et al. 2006. The biocompatibility of carbon nanotubes. Carbon 44(6): 1034-1047.
This� study� is� currently� funded� by� a� grant� from� the� Canadian�Institute� for� Health� Research� (IRSC)� entitled:� Development� of�an� interdisciplinary� reference� guide� to� facilitate� the� analysis� of�impacts�of�nanotechnologies�on�health�and�social�acceptance.�We�also�thank�Simon�Brière�and�Mélanie�Goddard�for�their�support.�J�Patenaude� is� funded�by� the�Fonds�de� la�Recherche�en�Santé�du�Québec� (FRSQ)�and�member�of� the�FRSQ-funded�Centre�de�recherche�clinique�Étienne-Le�Bel.
Accompanying�Nanotechnological�Developments:�NE3LS�Perspectives
NANOSCALE�MATERIALS:�SCIENTIFICALLY�BASED�OR�JUDGEMENTAL�RISK�ASSESSMENT
1 2 3
�� Are�nanoscale�materials�already�in�use�dangerous?�In�order�to�address�their�potential�human�health�risks�and�environmental�impacts,�customized�nanotechnology�protocols� for� toxicity�testing�are�urgently�needed�and�should�be�developed.�
�� Current�human�health�and�ecological�risk�assessment�protocols�are�rigorous,�but�their�application�to�nanomaterials�requires�new�ways�of�measuring�exposure,�dose�and�response.�Long-term�studies�are�not�available�and�the� lack�of� toxicological�data�results�in�our�inadequacy�to�perform�clear�quantitative�risk�assessments�on�existing�and�emerging�nanomaterials.�
�� The� aim� of� this� study� is� to� outline� existing� toxicological�risk�data� regarding� current� and� emerging�nanoparticles�or�nanomaterials�in�order�to�report�on�the�actual�scientific�gaps�and�uncertainty�related�to�human�health�risk�assessment.
�� Moreover,�one�of�our�objectives�is�to�measure�the�effectiveness�of� the� current� risk� assessment� and� risk� management�process� in� order� to� determine� the� type� of� governance�required�to�accompany�the�introduction�of�any�cutting-edge�nanotechnology.
Background and Research Problem
Incomplete Data on Nanoparticle Characterization and Properties
No Data on Human or Environmental Exposure
Incomplete Data on Lung Toxicity Studies
No Data on Dermal Exposures
E�ect of CNT Properties on Cytotoxicity - Relevance of Impurities
Absorption, Distribution and Excretion - No Data Into the Ability of CNT (Carbon Nanotubes) to Migrate or Accumulate In Vivo
E�ciency of Chemical Functionalization - CNT Functionalized for drug or vaccine delivery exhibit lower toxicity. Further research
needed to con�rm toxicity
HEALTH EFFECTS DATAIn VitroToxicityStudies
In VivoToxicityStudies
EpidemiologyDose
ResponsePharmacokinetics
(PBPK)
EXPOSURE DATA
Contaminant EmissionEnvironmentalExposure
OccupationalExposure
HEALTH RISK ASSESSMENT
UNCERTAINTY
Engineered Carbon Nanotube
Toxicology Research
Engineered Carbon Nanotube
Toxicology Research
Lung Toxicity Studies
Skin Irritation
Macrophage Response
In Vivo Absorption,Distribution and
Excretion
Properties on Cytotoxicity
E�ciency of ChemicalFunctionalization
A B
C
Figure�1.�A) Engineered Nanotube Current Toxicology Studies [3, 5, 6]B) CNT Toxicological Data Needed for Sound Risk Assessment [3, 5, 6]C) Nanoparticles Quantitative Health Risk Assessment [3, 5, 6]
�� Nanotechnology:� The� intentional� manipulation� of� matter�at� the� nanoscale,� to� create� materials� and� products� with�nanostructure-dependent�properties.
�� Nanoparticle:�A�single�particle�that�is�approximately�between�1�nm�and�100�nm�in�all�three�dimensions.
�� Engineered nanoparticle:� A� nanoparticle� that� has� been�produced�in�a�manufacturing�process�or�naturally�occurring�nanoparticles�that�have�been�processed�prior�to�being�used�as�a�commercial�product.
�� Nanomaterial:� � A� material� having� one� or� more� external�dimensions�in�the�nanoscale�or�material�that�is�nano-structured�including�nanoparticles,�nanofibres�and�nanotubes,�composite�materials�and�nano-structured�surfaces.
�� Nanoproduct:�Any�product�that�incorporates�nanotechnology�like� semiconductor� chips;� textiles� coated�with� nanometre-thick�films;�sunscreens�containing�engineered�nanoparticles,�and�any�biomedical�nanoproduct.
Nano Lexicon [1,2]
NE Inter ³LSGroupe de Recherche InterdisciplinaireInterdisciplinary Research GroupNano-E³LS
Preliminary Results
ReferencesAcknowledgements