1. Addressing the Issue of SH&E Management and Nanotechnology Presented by Robert C. Adams, MS, CIH, CSP
ENVIRON International Corporation
Princeton NJ
2. 2 Overview Nanotechnology Background
The Media and Nanotechnology
The Good News
The (Potential) Bad News
Regulatory Status
Considerations for Best Management Practices
3. 3 Nanotechnology Background Nanotechnology
Nanotechnology is the understanding and control of matter at dimensions of roughly 1 to 100 nanometers
In perspective; a nanometer is to a meter what a dime is to planet Earth
Nanotechnology involves imaging, measuring, modeling, and manipulating matter in this scale
Nanomaterial
Any material that has some dimension in the nanoscale (< 100 nm)
Examples:
Nanoparticles
Nanowire and Nanotubes
Nanocoating and Nanolayers
Quantum Dots
Nanoshells
4. 4 Nanotechnology Background
5. 5 Nanotechnology Background Nanoparticles follow the laws of quantum physics
The physics of the incredibly small
The classical laws of physics breakdown at this scale
Quantum physics describes how these materials can assume different physical, optical, electrical or magnetic properties
Engineered nanoparticles are intentionally produced
Natural nanoparticles exist as a result of combustion processes
Welding or diesel fume are two examples
Mechanical processes are not able to produce particles in this range
6. 6 Nanotechnology Background Macro particles have physical properties that are well known and understood
At the nanoscale this is generally not the case the properties are different and that gives rise to the interest in these materials
Copper nanoparticles smaller than 50 nm are considered super hard materials that do not exhibit the same malleability and ductility as larger forms of copper.
Nanoparticles have greater ratio of surface area to mass
Greater reactivity and more adsorption capacity than with macro substances
In environmental remediation, increased adsorption capacity of nanomaterials for some volatile organic compounds such as toluene has been demonstrated
7. 7 The Media and Nanotechnology
8. 8 The Media and Nanotechnology Magic Nano
Aerosol spray treatment to make glass/ceramic water and dirt repellent
Around 100 consumers reported respiratory difficulties
TUV Sued stamp "Production Inspected, Safety Approved used on product without approval
Product withdrawn from marketplace
Implications
Galvanizes groups opposed to nanotechnology
Hurts small business and startup sectors of nanotechnology Both sprays distributed under the name "Nano Magic used the TUV Sued stamp "Production Inspected, Safety Approved. According to the TUV Sued, this attribution was never given for the product under reference. "It is irresponsible to give the consumers a mistaken sense of security by falsifying stamps, said vzbv Chair Edda Müller. TUV Sued
Press Release
The basic takeaway message is that this is a perfect example of what not to do. The paper industry should take heed from bad product stewardship in this case.
EPA: http://es.epa.gov/ncer/nano/research/nano_fate_and_transport.html
Both sprays distributed under the name "Nano Magic used the TUV Sued stamp "Production Inspected, Safety Approved. According to the TUV Sued, this attribution was never given for the product under reference. "It is irresponsible to give the consumers a mistaken sense of security by falsifying stamps, said vzbv Chair Edda Müller. TUV Sued
Press Release
The basic takeaway message is that this is a perfect example of what not to do. The paper industry should take heed from bad product stewardship in this case.
EPA: http://es.epa.gov/ncer/nano/research/nano_fate_and_transport.html
9. 9 THE GOOD NEWS! The immense economic impact:
NSF estimates a $1 Trillion market by 2015
Lux Research estimates a $1 Trillion market by 2011-2012 for nanotechnology-enabled products
Rand estimates that revenues have already surpassed $10 billion
The potential for the development of advanced products that will have a remarkable impact on everyday life:
Improved optics, electronics, and optoelectronics
New medical imaging and treatment technologies
Production of advanced materials for high-efficiency energy storage and generation
10. 10 Nanotechnology Facts National Nanotechnology Initiative (NNI) was started in 2000 by President Clinton
Since 2000, the federal government has allocated over $2 billion for nanotechnology research
$480 million of venture capital went into nanotechnology startups in 2005
United Press International
11. 11 Predicted Growth $15 billion annual investment predicted within 10 years
50% of all products produced will be influenced by nano within 10 years
Employment in the nanotechnology sector is expected to grow to 2 million workers within the next decade (US Department of Labor)
12. 12 Applications for Nanoparticles Nanotechnology is still in the pre-competitive stage but
Nanoparticle research continues to receive intense scientific study, due to a wide variety of potential applications in biomedical, optical, and electronic fields
New material discoveries will spur further growth
Nanoparticles are here now!
Bumpers on cars
Paints and coatings
Stain-free clothing and mattresses
Burn and wound dressings
Ink
Protective and glare-reducing coatings for eyeglasses and windshields
Metal-cutting tools
Sunscreens and cosmetics
Longer-lasting tennis balls and light-weight, stronger tennis racquets
13. 13 Consumer Benefit One current application is the use of silver nanoparticles which can kill micro-organisms
Used on refrigerators and washing machines
Helps to ensure food will stay fresh for a very long time and clothes are cleaned thoroughly
14. 14 Nanotechnology and the Battle Against Cancer Nanoscale devices can serve as customizable, targeted drug delivery vehicles capable of sending large doses of anticancer agents into malignant cells without harming healthy cells
Overcome the many barriers that the body uses against traditional interventions
National Cancer Institute
15. 15 First Two Generations of Nanoproducts Passive nanomaterials (most current)
Constant properties/functions
Products are components (wires, nanotubes, etc.)
Examples include coatings, dispersions, patterns and bulk materials
Active nanomaterials (today to 10-years)
Changes states during operation
Products are devices (molecular machines, targeted drugs, transistors, etc.)
Examples include sensors, energy storage devices, nanoelectromechanical systems
Nanosystems (multiple interactive structures future!)
16. 16 The (Potential) Bad News Do engineered nanomaterials pose unique work-related health risks?
In what ways might employees be exposed to nanomaterials in manufacture and use?
In what ways might nanomaterials enter the body during those exposures?
Once in the body, where would the nanomaterials travel, and how would they interact physiologically and chemically with the bodys systems?
Will those interactions be harmless, or could they cause acute or chronic adverse effects?
What are appropriate methods for measuring and controlling exposures to nanometer-diameter particles and nanomaterials in the workplace?
17. 17 The (Potential) Bad News NGOs like ETC Group continue to call for a moratorium on the use of nanotechnology in products until more research is available on the safety and toxicity of these materials
October 17, 2005, RAND Corporation meeting with stakeholders identifies concerns among industry, government, labor and academia
Knowledge gaps related to health risks may create liabilities that could stymie the development of beneficial new nanomaterials
E?orts to address the occupational risks are being impeded by shortfalls in fundamental scientific knowledge
Resources allocated to occupational health and environmental risks are not keeping pace with development of new nanomaterials
Cooperation between the public and private sectors is needed
18. 18 Ethics in Nanotechnology The difficulty is that the potential toxicity of nano-engineered particles is subject to scientific uncertainty in a very fundamental way. Indeed the very definition of the toxicity of these particles is problematic. Furthermore, there are no clear views on how this toxicity, if defined, could be scientifically and indisputably tested. Finally, there are no scientific studies on the toxicity of many particles. One of the issues could be that such a toxicity may be slow to manifest itself, as was the case for asbestos. Therefore, the question of the applicability of the precautionary principle would need to be studied and discussed, and scientific uncertainty should not lead to skip the necessary debate. In this connection, issues of risk analysis and standardization require in-depth ethical, and not only scientific, consideration.
19. 19 Managing Uncertainty The Bottom Line Remains
Can we achieve the promises of nanotechnology while minimizing potential risks?
But we must also ask
Will nanotechnology development be permitted to go forward amid the calls to halt its development?
and
Will we be able to manage the ethical and scientific issues that nanotechnology will present?
20. 20 Health Risks Nanotechnology is an emerging field. As such, there are many uncertainties as to whether the unique properties of engineered nanomaterials (which underpin their commercial potential) also pose occupational health risks.
NIOSH
21. 21 Potential Exposures to Nanoparticles The exposure route of primary interest remains inhalation
Where the nanoparticles deposit in the lung will be a significant factor in the development of health effects
Ingestion of nanoparticles is also a concern
Little is known about possible adverse effects from the ingestion of nanoparticles
The potential for direct penetration through the skin has been reported
Some laboratory studies have suggested that carbon nanotubes can be absorbed and deposited in skin cells and potentially induce cellular toxicity Nanoparticles of titanium dioxide used in sunscreens do not penetrate beyond the epidermis
Nanoparticles of titanium dioxide used in sunscreens do not penetrate beyond the epidermis
22. 22 Effect of Particle Size Equivalent dose of smaller particles presents�a much larger surface area for reactions to take place
Potential for generation of free oxygen radicals DNA damage inflammation tissue damage cancer?
23. 23 Other Factors Affecting Toxicity Coatings
Hydrophilic surface coating on TiO2 induced greater inflammatory response than hydrophobic coating
Chemistry
Certain nanomaterials may contain varying types and levels of metals used as catalysts
Differences in toxicity of various nanotubes that have different metal contents
Structure or shape
C60 Fullerenes are more reactive than carbon particles or carbon nanotubes
24. 24 Direct Transport to Brain?
25. 25 Dermal Penetration? Lack of dermal penetration for nano TiO2; few studies report dermal penetration
Penetration of 0.5-1.0 ľM-sized fluorospheres and Be sensitization in human skin flexing experiments
Oxidative stress, toxicity, and loss of viability of human skin cells - HaCaT cells - carbon nanotubes
Reactivity with sunlight?
26. 26 The Bottom Line Existing toxicity information can provide a baseline for anticipating the possible adverse health effects that may occur from exposure to nanoparticles
Not possible to set health protective limits without assumptions about toxicity relative to that of the same macro-scale material Experimental studies in rats have shown that at equivalent mass doses, tested insoluble ultrafine particles are more potent than larger particles of similar composition in causing pulmonary inflammation, tissue damage, and lung tumors
Existing toxicity information about a given material can provide a baseline for anticipating the possible adverse health effects that may occur from exposure to that same material on the nanoscale
Not possible to set health protective limits without assumptions about toxicity relative to that of the same macro-scale material
Experimental studies in rats have shown that at equivalent mass doses, tested insoluble ultrafine particles are more potent than larger particles of similar composition in causing pulmonary inflammation, tissue damage, and lung tumors
Existing toxicity information about a given material can provide a baseline for anticipating the possible adverse health effects that may occur from exposure to that same material on the nanoscale
Not possible to set health protective limits without assumptions about toxicity relative to that of the same macro-scale material
27. 27 Toxicity Data Gaps Remain No studies greater than 3 months duration
Absorption, Distribution, Metabolism & Excretion (ADME) studies very limited
No dose-response data
No developmental/reproductive studies
No chronic bioassays
More research needed to address the uncertainty
28. 28 "New technologies introduce new occupational health and safety hazards, and nanotechnology is no exception. Materials and devices are under development are so far from our current understanding that we can not easily apply existing paradigms to protecting workers. Dr. John Howard (NIOSH Director)
29. 29 Exposures to Nanoparticles There are still very few studies of occupational exposures to nanoparticles
Largely due to the lack of available monitoring equipment and lack of exposure metrics for comparison
Most studies that are available are being conducted in research settings and not in industrial facilities under actual working conditions
Most SHE professionals are not equipped to conduct the monitoring that would be needed
30. 30 Exposures to Nanoparticles Situations that are likely to create significant exposures include:
Working with nanomaterials without adequate protection
Working with nanomaterials during pouring or mixing operations,
Working with nanomaterials where there is a high degree of agitation
Generating nanoparticles in the gas phase in non-enclosed systems
Handling nanostructured powders could increase aerosolization
Maintenance of equipment and processes used to produce or fabricate nanomaterials
Cleaning of dust collection systems can pose a potential for both skin and inhalation exposure
These situations are not unlike the types of situations encountered in industry that historically create significant exposures
31. 31 Lack of Exposure Metrics Remains Nanoparticles may not be suitable for comparison to traditional exposure metrics
Mass based metrics may understate exposures
Larger particles will mask nanoparticles
Mass and bulk chemistry are believed to be less important
Particle size, particle number and/or surface area (or reactivity) metrics are still considered to be more reliable indicators of exposure
Research is still ongoing but there is still no definite answer
Metric to be used will depend on availability of sampling equipment or instruments
32. 32 Exposure Monitoring Until more information is available on the mechanisms underlying nanoparticle toxicity, it is uncertain as to what measurement technique should be used to monitor exposures in the workplace.
NIOSH
33. 33 Exposure Monitoring There are limited air sampling methods or instruments
Real time particle counters / particle sizers
Size-fractionated aerosol sampling with impactors in the nanoparticle range
High resolution TEM
Surface area estimation
NIOSH is funding research on air sampling techniques
Many instruments that are available are still limited to research (i.e.; not portable)
34. 34
35. 35 Exposure Control Prudent practice suggests that in the absence of available toxicity data, exposures to nanomaterials must be minimized
Nanoparticle behavior
Behave more like gases
migrate from areas of highest concentration
Tend to agglomerate
Gravitational settling slower than macro particles
Will widely disperse
Can be re-suspended easily
36. 36 Exposure Control In general, control techniques such as source enclosure and local exhaust ventilation systems are considered to be effective for capturing airborne nanoparticles
37. 37 Exposure Control Challenges still remain:
Effectiveness of filtration is still not confirmed
NIOSH is conducting research to validate the efficiency of HEPA filter media
Design of hoods and enclosures have not been specified for nanoparticles
Apply current ACGIH design criteria for the control of fine particulate matter
Capture and transport velocities have not been specified
Again, ACGIH criteria are expected to be sufficient for nanoparticle control
38. 38 Exposure Control Respiratory protection research continues
There have been no specific recommendations on the types of respirators applicable for exposure to nanoparticles
Respirators are tested against particles around 300 nm
In theory, a respirator filter that is effective for larger particles should be effective for the smaller scale particle
NIOSH is still undertaking studies to validate this
Nanoparticles still present the following challenges
Criticality of facial seal for negative pressure respirators
Effectiveness of positive pressure respirators
Appropriateness of fit factors or protection factors
Fit testing methods may require further improvements
39. 39 Exposure Control Dermal protection
There are no current recommendations on types of clothing that will be effective for prevention of dermal absorption
No dermal exposure standards
Small sized particles may penetrate traditional knit clothing
Penetration efficiencies for nanoparticles have not been studied
Existing ASTM standards incorporate testing with nanometer-sized particles
Modern PPE materials of construction will likely provide some protection but the efficacy of that protection is still unclear
Ocular protection still presents some additional challenges and may represent the more significant risk
40. 40 Exposure Control Good work practices can help minimize worker exposure to nanomaterials
Efforts should focus on:
Good housekeeping and maintenance programs
Good hygiene and sanitation
Restrictions on the consumption of food and beverages in work areas
Facilities for hand and face washing
Facilities for showering and changing clothes
41. 41 Safety Issues Fire / Explosion/Catalytic Hazards
There has been little research on the potential safety hazards of nanoparticles
From current information, concerns most likely involve catalytic effects or fire and explosion hazards
Nanoscale powders or combustible material could present a higher risk than a similar quantity of coarser material
Increased surface area = more easily ignited?
Nanoscale Al/MoO3 thermites ignite more than 300 times faster than corresponding micrometer-scale material
Can nanomaterials initiate catalytic reactions that would not otherwise be anticipated from their chemical composition alone?
42. 42 Will Nanomaterials Behave the Same as Common Environmental Pollutants? Likely but additional research is ongoing due to unique chemical/physical properties of nanomaterials
Fate and transport of nanomaterial releases and wastes
Mobility of nanoparticles in the air, soil and water
Surface chemistry of mineral oxide and carbon nanoparticles
Degradation of materials containing nanoparticles
Mechanisms of nanoparticle degradation
Nanoparticle bioaccumulation
Applicability of technologies to control nanoparticle releases and to treat nanoparticle wastes
43. 43 Regulatory Framework A realistic regulatory framework will ultimately be needed
NIOSH is currently in the forefront on workforce matters
NIOSH is pursuing strategic, multidisciplinary research that will help practitioners, with greater certainty, to apply the well-established principles of occupational safety and health to workplace exposures involving nanomaterials.
NIOSH is evaluating the unique benefits that nanotechnology may bring to improving occupational safety and health.
44. 44 NIOSH Activities on Nanotechnology NIOSH is currently investigating the following areas (FY 2006):
Survey of uses and workers involved on nanotechnology industries
Measurement studies of nanoparticles in the workplace
Evaluate control banding options to reduce worker exposures
Analyses of filter efficiency for nanomaterials
Nanoparticle Information Library
Solicits and disseminates information on all types of nanoparticles in products
45. 45 Regulatory Framework EPA
TSCA is one of the statutes under which commercial applications will likely be regulated
Key question - Is a nanoparticle of a chemical which is intended to impart new chemical and/or physical properties, to be considered:
a new chemical;
a significant new use of an existing chemical;
a modified but not significant new use of an existing chemical; or
none of the above?
46. 46 Regulatory Framework Most likely, TSCA will apply at some level
EPA probably will not treat nanoparticles as new chemical substances
EPA probably will treat each new category of nanoparticles as a significant new use
Recent White Paper (December 2, 2005)
Important recommendations include:
Pollution Prevention, Stewardship, and Sustainability
Research
Risk Assessment
Collaboration and Leadership
Cross-Agency Workgroup
Training
47. 47 Recent Developments in TSCA Natural Resources Defense Council
Has frequently commented to the EPA that it must consider all nanomaterials as new substances
Outcome of Public Meetings on Nanotechnology and TSCA
Being converted into Nanoscale Materials Stewardship Program
Some nanomaterials have already been approved
Carbon nanotubes have been issued a LoREx exemption
48. 48 OSHA Position on Nanotechnology No change since last year
Reliant on present set of regulations to answer questions:
Hazard communication 1910.1200
Occupational exposure to hazardous chemicals in laboratories - 1910.1450
Respiratory protection 1910.134
Personal protective equipment 1910.132
New OSHA Head has commented on need to address nanotechnology
49. 49 OSHA Position on Nanotechnology
OSHA is participating in initiatives led by the White House to address issues related to nanotechnology, such as risk assessment and safety and health research. As information becomes available, OSHA plans to develop guidance for employers and employees engaged in operations involving nanomaterials, and OSHA is also working with NIOSH as they conduct research in this area.
Edwin G. Foulke Jr. (Assistant Secretary of Labor for Occupational Safety and Health)
50. 50 ASTM E56 Formed in 2005
Addresses issues related to standards and guidance materials for nanotechnology & nanomaterials,
Includes subcommittees on Environmental & Occupational Health & Safety and Standards of Care/Product Stewardship
No specific work products have been produced
51. 51 A Concept for Best Management
52. 52 Best Management Practices Development of standard operating procedures and best management practices
Development of work procedures that emphasize the prevention of inadvertent exposures
Use of job safety analysis and other risk assessment techniques to identify potential exposures routes and identify control approaches
Reduce unnecessary exposures (consider the use of controlled access areas)
53. 53 Best Management Practices Development of standard operating procedures and best management practices (cont)
Develop standards for construction of nanomaterials work areas
Develop procedures for responding to unexpected releases or spills
Provide up to date hazard information to the workforce including MSDS and other substance specific information
Develop a process to identify the workers that would have potential for exposures to nanomaterials
54. 54 Application of Control Banding Control banding is a technique for managing materials where there is uncertainty as to the risks posed by the materials
Establish a minimum level of containment based on the potential for exposures, volume of material used and potential hazard of the material
Lowest level would involve the use of standard safe handling practices and general ventilation
Highest level would involve the use of state of the art containment systems that would eliminate any direct contact with the material (100% closed system)
55. 55 Application of Control Banding
56. 56 Application of Control Banding NIOSH has been investigating the potential for the application of control banding methods to nanotechnology
The technique has promise as a control approach for addressing the potential risks that might be present until such time as better toxicity data becomes available
57. 57 The Future There is still much work to be done in the area of nanotechnology and SH&E
Limited available science will not deter development of effective safeguards
Build on existing models (JSA; control banding; ALARA; or potent compounds)
Utilize safe handling practices and minimize potential for contact (think BMP)
Use prudent precautions for protection of the workforce -- Err conservatively
Multidisciplinary approaches will be needed
58. 58 Conclusions Regulations will lag but continuing efforts are underway, particularly at EPA, that will have an impact
Toxicology and epidemiology continue to lag behind the developments of nanomaterials
Communication of both risks and safety critical in an environment susceptible to sensationalism
Substantiated through science and practice
There is no single or simple answer
Not limited to scientific community must include others such as economists, sociologists, and ethicists
Nanotechnology will challenge conventional approaches to addressing occupational safety and health risk
59. 59 Websites for More Information National Nanotechnology Initiative
http://www.nano.gov/
NIOSH Nanotechnology Home Page
http://www.cdc.gov/niosh/topics/nanotech/default.html
USEPA White Paper
http://es.epa.gov/ncer/nano/publications/whitepaper12022005.pdf
United Kingdom Health and Safety Executive
http://www.hse.gov.uk/horizons/nanotech/index.htm
ASTM Committee E56 on Nanotechnology
http://www.astm.org/cgi-bin/SoftCart.exe/COMMIT/COMMITTEE/E56.htm?L+mystore+kueb3031
60. Thank You badams@environcorp.com
609.243.9848
