Considerations for Selecting Standard Materials for Occupational Safety and Health Vladimir Murashov, Ph.D. Special Assistant to the Director National Institute for Occupational Safety and Health Interagency Workshop on Standards for EHS Research Needs for Engineered Nanoscale Materials September 12-14, 2007 "The findings and conclusions in this presentation have not been formally disseminated by the National Institute for Occupational Safety and Health and should not be construed to represent any agency determination or policy."
2 Issues for Developing Standard Materials Identification of needs and candidate materials Standard methods to produce well-characterized materials Standard methods utilizing well-characterized materials Categories of certified and other types of reference materials
3 NIOSH-NIST Collaborations on Reference Materials for EHS
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5 1.Prioritize research based on the value of information. the extent to which information gained from investment in research funding will reduce uncertainty about both benefits and risks of nanomaterials; the extent to which information may lead to broad knowledge about properties and behavior of nanomaterials or classes of nanomaterials; the extent of use expected for a nanomaterial or groups of nanomaterials; potential of worker, consumer, or environmental exposure to nanomaterials. 2.Where appropriate, seek to leverage research funded by other governments and the private sector. 3.Use adaptive management for nanomaterial EHS research. NNI Prioritization Criteria for EHS Research Needs
6 Risk Assessment and Risk Management Framework Hazard identification Hazard characterization Risk characterization Exposure assessment Risk Management “Is there reason to believe this could be harmful?” “How and under what conditions could it be harmful?” “Is substance hazardous and will there be exposure?” “Will there be exposure in real-world conditions?” “Develop procedures to minimize exposures” 6 Re-evaluation “Are there new data?”
7 Standard-Material Matrix for Risk Assessment and Risk Management BasicApplied HazardExposureControlsHazardExposureControls Occupational General public Environment
8 Toxicity and Internal Dose Investigating and determining the physical and chemical properties (ex: size, shape, solubility) that influence the potential toxicity of nanoparticles Evaluating short and long-term effects that nanomaterials may have in organ systems and tissues (ex: lungs) Determining biological mechanisms for potential toxic effects Creating and integrating models to assist in assessing possible hazards Determining if a measure other than mass is more appropriate for determining toxicity Fire and Explosion Safety Identifying physical and chemical properties that contribute to dustiness, combustibility, flammability, and conductivity of nanomaterials. Recommending alternative work practices to eliminate or reduce workplace exposures to nanoparticles. NIOSH Nanotechnology Critical Topic Areas: Hazard
9 1.Basic: Factors influencing health hazards (toxicity, pharmacokinetics) and physical hazards (explosivity, flammability) 2.Applied: Work-related exposures (mixtures, impurities, distribution of nanomaterials properties) Criteria considerations for hazard assessment 28 days post exposure 40 g/mouse SWCNT 20 microns
10 Exposure Assessment Determining key factors that influence the production, dispersion, accumulation, and re-entry of nanomaterials into the workplace Assessing possible exposure when nanomaterials are inhaled or settle on the skin Determining how possible exposures differ by work process Determining what happens to nanomaterials once they enter the body Measurement Methods Evaluating methods of measuring mass of respirable particles in the air and determining if this measurement can be used to measure nanomaterials Developing and field-testing practical methods to accurately measure airborne nanomaterials in the workplace Developing testing and evaluation systems to compare and validate sampling instruments NIOSH Nanotechnology Critical Topic Areas: Exposure
11 1.Basic: Factors influencing generation (dustiness, sticking coefficient, agglomeration); routes of exposure; deposition and translocation models; exposure metric 2.Applied: Calibration of instrumentation (calibration reference material); method validation (matrix reference material) Criteria considerations for exposure assessment
12 Engineering Controls and PPE Evaluating the effectiveness of engineering controls in reducing occupational exposures to nanoaerosols and developing new controls where needed Evaluating and improving current personal protective equipment Developing recommendations to prevent or limit occupational exposures (ex: respirator fit testing) Evaluating suitability of control banding techniques where additional information is needed; and evaluating the effectiveness of alternative materials NIOSH Nanotechnology Critical Topic Areas: Controls
13 1.Basic: Factors influencing transport/penetration and precipitation (aerodynamic diameter and drag, diffusion coefficient, sticking coefficient, agglomeration) 2.Applied: PPE and respirator testing; testing of engineering controls Criteria considerations for exposure controls Nanoscale alumina on cotton fabric
14 Proposed Selection Criteria: Mission Oriented CriteriaBasicApplied What are we trying to achieve? Provide the foundation for protective and predictive models Provide information relevant to existing and emerging materials, processes, instruments, and methods How can we achieve this given the uncertainties? Focus on materials that will support expert level understanding and expert judgment skills that can be generalized Survey the industry: Amounts of materials Conduct health surveillance: Adverse effects Engage stakeholders
15 Proposed Selection Criteria: Feasibility Considerations CriteriaBasicApplied Do we have or can we get this material? Sufficient availability Stability of generation method Stability and uniformity of material Actual applications Stability of process environment Stability and uniformity of material Is or can this material be properly and adequately characterized? Broad range of parameters Application-critical parameters By whom and how extensively will this reference material be used? Costs Market (researchers) Costs Market (production and EHS professionals)
16 1.OSH TR: chemistry and dimensionality based grouping Carbonaceous Oxides Metals Semiconductors Organic polymeric Bio-inspired 2.TR on Physical-chemical properties for toxicology studies 3.Standards for Nano-silver particle generation for toxicology studies Nano EHS Standards in ISO Allotropes of carbon
17 Nanoparticle Occupational Safety and Health (NOSH) Consortium Generate well-characterized aerosol nanoparticles of various chemistries < 100 nm various chemistries: TiO 2, SiO 2, carbon black, silver, latex reference material, citric acid materials of interest to consortia members aerosol synthesis methods (in situ and re-aerosolization) Applications Develop a portable air sampling method for daily monitoring of R&D and manufacturing settings Measure filtration efficiency of filter media to specific engineered nanoparticles Michele Ostraat, DuPont
18 PhiX174 bacteriophage Small size Spherical or polyhedral Environmental stability Low or non-human infectivity High assay sensitivity Rapid growth High titer ASTM F Standard Test Method for resistance of materials used in protective clothing to penetration by blood-borne pathogens using Phi-X174 bacteriophage penetration H.-W. Ackermann, Laval University, Quebec 100 nm
19 Criteria A representative matrix reference material Commonly used CNT- production method An adequate amount for calibration, quality assurance, and inter-comparison studies Validation of product quality, purity and consistency Toxicity studies Calibration and validation of EHS methods SWCNT-bearing Reference Material (candidate NIST RM 8475) NIST-NIOSH-and others collaboration
20 BeO Powder Standard Reference Material (candidate SRM 1877) Criteria A continuing safety and health concern (chronic beryllium disease) Well characterized respirable powder of common commercial form Meets requirements for uniformity, physical form, other measured quantities Stability of production protocol Continued availability Morphology Clusters of primary particles Composition High purity BeO Primary particles - Powder: 190 nm - Workplace particles: 220 nm NIST-NIOSH-DOE collaboration
21 1.What are critical research and workplace EHS needs requiring reference materials? 2.Is a candidate material critical for addressing an EHS research priority and/or for ensuring safety and health in the workplace? Will the demand for this material be sufficiently* high? 3.Does the candidate material represent a widely produced nanomaterial or a broad class of nanomaterials? 4.Is this material available in sufficient* quantities and of sufficient* homogeneity as a one-time batch or through a stable, reproducible process to be a reference material? 5.Can this material be sufficiently* characterized? 6.What financial model will be used and will the material be affordable? Criteria for Discussion *dependent upon the intended uses of the reference material