1. Opportunities of nanomaterials and current state of knowledge about potential health and environmental risks – what regulators need to know. Rob Visser
Acting Director
Environment Directorate
OECD
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2. Nanotechnology development milestones (I) 1959: Nobel prize winner in physics Robert Feynman’s (US) “There’s plenty of room at the bottom”
1974: “Nanotechnology” concept proposed by Norio Taniguchi of the Tokyo University of Science
1984: Fullerenes discovered by Richard Smiley and colleagues at Rice University in the US
1986: Eric Drexler of the MIT in the US publishes “Engines of Creation: The Coming Era of Nanotechnology”
1986: Foresight Nanotech Institute established as the first one to educate society about the benefits and risks
1991: Carbon nanotubes discovered by Sumio Ijima of NEC, Japan
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3. Nanotechnology development milestones (II) 1990s: China adds nanotechnology to its S&T priorities in the 863 National High Technology Programme at MOST
2001: US National Nanotechnology Initiative launched
2002: The European Commission designated nanotechnology a priority area in the Sixth Framework Program
2005: The Japanese “Strategic Technology Roadmap” published
2006: The EU “Roadmaps at 2015 on Nanotechnology Application” published
2007: Russia announces USD 8 billion investment in nanotechnology from 2007-2015
2008: The US “Technology Roadmap for Productive Nanosystems” published
2008: Korean “Nanotechnology Roadmap” published
[Source: Adapted from True Nano, Kaiser (2006), various websites.] 3
4. Public R&D investments in nanotechnology globally Source: (Roco, 2007)� 4
5. Number of nanotechnology-related publications� Source: ISI Web of Knowledge database, January 2008� 5
6. �Share of nanotechnology and all patents by country from 2005� Source: OECD, Patent database, January 2008� 6
7. ��Selection of global market forecasts for nanotech-enabled products, billion USD��Source: Publicly available information on private market forecasts.� 7
8. Examples of nanotechnology applications� Electronics and communications
Data storage media
Semiconductors
(bio)molecular electronics,
Materials and construction
reinforced materials
“smart” magnetic fluids
scratch-proof or non-wettable surfaces,
self-cleaning and reactive eco-efficient windows.
Pharmaceuticals and health care
miniaturised diagnostics
nanoscale coatings (to improve the bioactivity and biocompatibility of implants)
ultra-precise nano-structured drug delivery systems
new materials for bone and tissue regeneration
Machinery and tools
extremely sensitive sensors (to detect incipient failures and actuators to repair problems)
chemical-mechanical polishing
self-assembling of structures from molecules
Energy
Batteries
artificial photosynthesis for clean energy
low-cost photovoltaic solar cells (e.g. solar “paint”)
safe storage of hydrogen for use as a clean fuel.
Environment and water
Enhanced membranes for water purification,
nanostructured filters for removing pollutants
improved remediation methods (e.g. photo-catalytic techniques).
[Source : OECD (2005), OECD (2008) and others.]
8 Electronics and communications
Data storage media with very high recording densities, new flat-panel plastic display technologies, new materials for semiconductors that increase processing speeds, the realisation of molecular or (bio)molecular electronics, spintronics and quantum computing.
Materials and construction
Use of nanoparticles and coatings for reinforced materials and machinery parts, super-hard and tough drill bits and cutting tools, “smart” magnetic fluids for vacuum seals and lubricants, scratch-proof or non-wettable surfaces, anti-bacterial construction material, self-cleaning and reactive eco-efficient windows.
Pharmaceuticals and health care
Potential applications include miniaturised diagnostics that could be implanted for the early diagnosis and monitoring of illnesses, nanoscale coatings to improve the bioactivity and biocompatibility of implants, ultra-precise nanostructured drug delivery systems, sensors for labs-on-a-chip, new materials for bone and tissue regeneration.
Machinery and tools
Nanopowders sintered into bulk materials giving special properties, extremely sensitive sensors to detect incipient failures and actuators to repair problems, chemical-mechanical polishing with nanoparticles, self-assembling of structures from molecules, bio-inspired materials and biostructures.
Energy
New types of batteries, artificial photosynthesis for clean energy, efficient low-cost photovoltaic solar cells (e.g. solar “paint”), safe storage of hydrogen for use as a clean fuel.
Environment and water
Enhanced membranes for water purification, nanostructured filters for removing pollutants from industrial effluents, improved remediation methods (e.g. photo-catalytic techniques). Electronics and communications
Data storage media with very high recording densities, new flat-panel plastic display technologies, new materials for semiconductors that increase processing speeds, the realisation of molecular or (bio)molecular electronics, spintronics and quantum computing.
Materials and construction
Use of nanoparticles and coatings for reinforced materials and machinery parts, super-hard and tough drill bits and cutting tools, “smart” magnetic fluids for vacuum seals and lubricants, scratch-proof or non-wettable surfaces, anti-bacterial construction material, self-cleaning and reactive eco-efficient windows.
Pharmaceuticals and health care
Potential applications include miniaturised diagnostics that could be implanted for the early diagnosis and monitoring of illnesses, nanoscale coatings to improve the bioactivity and biocompatibility of implants, ultra-precise nanostructured drug delivery systems, sensors for labs-on-a-chip, new materials for bone and tissue regeneration.
Machinery and tools
Nanopowders sintered into bulk materials giving special properties, extremely sensitive sensors to detect incipient failures and actuators to repair problems, chemical-mechanical polishing with nanoparticles, self-assembling of structures from molecules, bio-inspired materials and biostructures.
Energy
New types of batteries, artificial photosynthesis for clean energy, efficient low-cost photovoltaic solar cells (e.g. solar “paint”), safe storage of hydrogen for use as a clean fuel.
Environment and water
Enhanced membranes for water purification, nanostructured filters for removing pollutants from industrial effluents, improved remediation methods (e.g. photo-catalytic techniques).
9. ��OECD Conference on � Potential Environmental Benefits of Nanotechnology: Fostering Safe Innovation-Led Growth� � 9
10. � Key Points: Applications �
Clearly, nanotechnology is set to have a major impact on many industries
An early forecast suggests that 2 million nano-related jobs could be created by 2015
Currently, mainly impacts on consumer products (e.g. cosmetics, clothing, personal care, sports equipment)
Could address global challenges (e.g. energy constraints, climate change, affordable health care, access to clean water)
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11. �Much information derived from OECD projects of the Working Party of Nanotechnology� Statistical framework for nanotechnology
Monitoring and benchmarking nanotechnology developments
Addressing challenges in the business environment specific to nanotechnology
Fostering nanotechnology to address global challenges (e.g. cleaner water)
Fostering international scientific co-operation in nanotechnology
Policy roundtables on key policy issues related to nanotechnology
www.oecd.org/sti/nano
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12. But there are regulatory challenges: �Are nanomaterials safe? �
To determine safety information is needed on:
The effects of nanomaterials (testing)
Exposure determination (occupational, consumers and environment)
Hazard assessment
Risk assessment 12
13. Focus on Safety Testing
What information currently exists?
Are existing test methods (e.g. OECD test guidelines) suitable for nanomaterials?
How can comparability of testing be verified?
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14. ���� 120 Internationally agreed OECD’s guidelines for the testing of chemicals covering:
Physical Chemical Properties
Effects on Biotic Systems
Degradation and Accumulation
Health Effects
Other Test Guidelines
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15. ��Why are OECD Test Guidelines important? (cont’d)���
The use of OECD Test Guidelines
+
OECD Principles for Good Laboratory practice
=
Mutual Acceptance of Data
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16. OECD’s Work of OECD’s Working Party on Manufactured Nanomaterials Who participates?
30 OECD Member Countries and the European Commission
Non-member economies: A5; EE; Singapore, and Thailand.
Inter-governmental organizations: (IOMC)
International Standards Organisation (ISO TC229)
Other stakeholders: business/ industry; organized labour; environmental NGOs, and animal welfare organizations 16
17. Focus on �Safety Testing: do existing methods work? Objective: To test an agreed representative set of manufactured nanomaterials using appropriate test methods.
Aim: To understand the types of information on intrinsic properties that may be relevant to exposure and the effects assessment of MNs.
[In close co-ordination with other OECD work on Chemical Safety: Test Guidelines, Mutual Acceptance of Data]
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18. 18 What information already exists:
Database launched , 1 April 2009
Shows completed, current and planned research on human health and environmental safety
Projects’search based on:
Name of the nanomaterial
OECD Test Guideline used; and
endpoints
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20. Manufactured Nanomaterials and Test Guidelines
Preliminary conclusions from the review of the OECD Test Guidelines:
Most test guidelines (though not all) are appropriate for nanomaterials
Some may need adjustment
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21. Manufactured Nanomaterials and Test Guidelines Recommendations from the review of the OECD Test Guidelines:
There is a strong need to develop guidance on:
Sample Preparation and Dosimetry (as a top priority)
Also, the need for a comparison of Instillation vs. Inhalation studies
[Both under preparation by OECD WPMN] 21
22. �Alternative Methods in Nano Toxicology to reduce Animal Testing�� Status:
Review of currently validated in vitro methods to evaluate their applicability for testing nanomaterials
Integration with other OECD projects
Testing needs to be considered during sponsorship programme
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23. Sponsorship Programme �Implementation - Two Stages Stage 1
Agreement on:
i) A list of MNs (based on materials which are now, or soon to enter, commerce) ; and
ii) A list of endpoints for which these MNs should be tested.
Stage 2�Development of a sponsorship programme to test MNs for human health and environmental safety
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24. Sponsorship Programme Stage 1:�List of Manufactured Nanomaterials (14) Fullerenes (C60)
Single-walled carbon nanotubes (SWCNTs)
Multi-walled carbon nanotubes (MWCNTs)
Silver nanoparticles
Iron nanoparticles
Carbon black
Titanium dioxide
Aluminium oxide
Cerium oxide
Zinc oxide
Silicon dioxide
Polystyrene
Dendrimers
Nanoclays
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25. Sponsorship Programme Stage 1: List of Endpoints Nanomaterial Information/Identification (9 endpoints)
Physical-Chemical Properties and Material Characterization (16 endpoints)
Environmental Fate (14 endpoints)
Environmental Toxicology (5 endpoints)
Mammalian Toxicology (8 endpoints)
Material Safety (3 endpoints) 25
26. Stage 2: Sponsorship Programme The sponsorship programme is an international effort to share the testing of an agreed set of manufactured nanomaterials selected by the WPMN.
Two phases:
Phase 1: To test selected MNs for the selected endpoints (official launch of phase 1: November 2007)
Phase 2: consideration of those cross-cutting issues or tests that are identified by phase 1 by the WPMN
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27. Sponsorship Programme for testing manufactured Nanomaterials:�Steps to date Launched November 2007
OECD Secretariat is the clearing house to ensure co-ordination
Publication of a guidance manual for sponsors to guide the testing
10 Draft Dossier Development Plans were considered by the 5th WPMN (March 2009)
Discussion of the phase 2 at the 6th WPMN (28-30 October 2009)
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28. *Asterisk indicates countries, which will conduct integrate alternative testing.
Note:
The table sponsors for phase 1 is updated every time that a delegations join the programme.
The phrase “representative nanomaterials” was intended to mean those manufactured nanomaterials (MNs) now or soon to enter into commerce.
Lead Sponsor(s) assume responsibility for conducting or coordinating all of the testing.
Co- Sponsor(s) conduct some of the testing determined to be appropriate and feasible.
A Contributor provides test data, reference or testing materials or other relevant information to the lead and co-Sponsors.
*Asterisk indicates countries, which will conduct integrate alternative testing.
Note:
The table sponsors for phase 1 is updated every time that a delegations join the programme.
The phrase “representative nanomaterials” was intended to mean those manufactured nanomaterials (MNs) now or soon to enter into commerce.
Lead Sponsor(s) assume responsibility for conducting or coordinating all of the testing.
Co- Sponsor(s) conduct some of the testing determined to be appropriate and feasible.
A Contributor provides test data, reference or testing materials or other relevant information to the lead and co-Sponsors.
29. WPMN projects: Summary/ Next steps (I) Project 1: Database on Human Health and Environmental Safety Research: Launched in April 1st, 2009
Project 2: Research Strategy(ies) on Human Health and Environmental Safety Research: Review of current research programmes has identified research themes which already have wide coverage globally and those less well covered
Project 3: Testing a Representative Set of Manufactured Nanomaterials (MN): Sponsorship programme for the testing of 14 MNs for 53 endpoints
Project 4: Manufactured Nanomaterials and Test Guidelines: Development of guidance on sample preparation and dosimetry for the testing of manufactured nanomaterials 29
30. WPMN projects: Summary/ Next steps (II) Project 5: Co-operation on Voluntary Schemes and Regulatory Programmes: Analysis of national information gathering programmes
Project 6: Co-operation on Risk Assessment: Review of existing risk assessment schemes and their relevance to nanomaterials
Project 7: The Role of Alternative Methods in Nanotoxicology: Reviewing alternative test methods which will avoid animal tests and which will be applicable to manufactured nanomaterials.
Project 8: Exposure Measurement and Exposure Mitigation: Recommendations on exposure and measurement techniques in the workplace, consumers and environment.
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31. Summary Nanotechnology presents many opportunities across a wide-range of economic sectors;
At the same time, there are many challenges related to safety;
Many areas are currently being addressed.
It is a global challenge, and there is time to address this in an inclusive way with all the stakeholders involved
SAICM/ UNITAR/ OECD/ IOMC are engaged to address the challenge in developing countries.
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32. More information E-mail: nanosafety@oecd.org
Public website: http://www.oecd.org/nanosafety/
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