Nsrc Guidance Doc
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The document provides guidance on safety practices for working with nanomaterials in research centers. It outlines potential novel toxicity risks from nanomaterials. It acknowledges a lack of regulations and standards for nanomaterials. The guidance aims to prevent exposures, detect health issues, control impacts, and respond to hazards. It recommends controls like ventilation systems, hygiene plans, protective equipment, monitoring, training, and medical exams. It also gives guidance on transporting, storing and disposing of nanomaterials and managing spills. The overall goal is to promote consistent safety practices across five Department of Energy Nanoscale Science Research Centers until more formal standards are established.
Nsrc Guidance Doc
- 1. Overview of the DOE Nanoscale Science Research Centers “Approach to Nanoscale Safety” Guidance Document American Chemical Society Meeting Safety in Nanotechnology Research Rick Kelly, MS, CIH Lawrence Berkeley National Laboratory
- 2. Five Department of Energy Nanoscale Science Research Centers
- 3. THE MOLECULAR FOUNDRY Nanoscale Science Research Center and User Facility
- 4. Potential for Novel Toxicity • Properties of nanoscale materials may be fundamentally different from bulk materials of same composition • Among the new properties of nanoscale materials may be: — ew toxicological N properties not seen in bulk material
- 5. Lack of Guidance • No EPA, OSHA, CPSC, DOT or state regulations • No national / international consensus standards • No exposure limits • No established sampling or analytical methods • Very limited toxicology, reactivity and environmental data • MSDSs are often not useful or misleading The NSRC Guidelines were developed to fill this void in the short term. The Guidelines may be modified or retired as consensus standards or regulations are published
- 6. Goals of The NSRC Document 1. Prevent exposure to nanomaterials 2. Detect early signs & symptoms of illness 3. Avoid environmental or community impact 4. Respond to perceived hazards 5. Control our own destiny Current version is revision 2 dated June, 2007 Available at http://orise.orau.gov/ihos/Nanotechnology/ nanotech_OSHrisks.html Or from Rick Kelly at rjkelly@lbl.gov
- 7. Contents • Introduction • Conceptual Foundations • Controls for R&D Laboratory Operations • Verifying Program Effectiveness • Transportation of Nanomaterials • Management of Nanomaterial-Bearing Waste Streams • Management of Nanomaterial Spills • Example Industrial Hygiene Sampling Protocol
- 8. Purpose and Limitations • Provide guidance to the five NSRCs for the development of safety controls — ot intended to be adopted verbatim N • Promote consistency among the five nanocenters • Does not preempt national, state or local regulations
- 9. Underlying Principle • “Prudent Practices for Handling Hazardous Chemicals in Laboratories” — reat “all new compounds, or those of T unknown toxicity, as through they could be acutely toxic in the short run and chronically toxic in the long run”
- 10. Work Planning • Review work with nanomaterials for EH&S concerns following an established safety-assessment process — evelop a well defined description of the work D — nvolve appropriate subject matter experts I • Industrial hygiene • Fire protection (for reactive materials) • Waste management — onsider hazards of precursors and equipment C • Goal is to establish engineered, administrative and personal protective controls
- 11. Hazard Banding 1. Solid materials with imbedded nanostructures 2. Solid nanomaterials fixed to a surface 3. Nanoparticles suspended in liquids 4. Free, dry dispersible nanoparticles
- 12. Engineered Controls • Work that could generate an aerosol should be conducted in a enclosed, ventilated system such as fume hood, glove box or glove bag — lternatively, use close capture system A — ilter/scrub exhaust air where nanoparticles may F be generated — o not recirculate exhaust air if possible D • Test and maintain these systems
- 13. Administrative Controls • Develop and implement a chemical hygiene plan specific to nanoscale work • Housekeeping — lean surfaces after each shift if contaminated C • Dedicated HEPA Vacuum • Wet wiping • Work practices — eep materials in closed containers except when K inside ventilated systems — inimize potential for aerosol and skin contact M
- 14. Posting and Labeling • Post signs at entrance to work area warning of nanomaterials • Label storage containers
- 15. Personal Protective Equipment • Wear PPE when failure of a single control could entail significant risk of exposure — Alternately, equip engineered controls with performance monitors • Typical wet chemistry PPE as needed — Closed toe, low permeability shoes — Long pants without cuffs — Gauntlet gloves or gloves with sleeve extenders — Lab coats (consider notifying vendor) — Eye protection • Respirators should be half mask P100 or better if used
- 16. Monitoring and Characterization • Minimally, use direct reading instrument to measure airborne nanoparticle level (TSI 3007) • Perform more sophisticated air sampling • GRIMM particle size analyzer • Filter collection with EM analysis — ther alternatives O • Other size selective nanoparticle counters • Surface area instruments
- 17. Worker Competency • Identify people potentially exposed to nanoparticles — egistry R • Provide appropriate nanosafety training • Provide awareness-level training to guests (users) • Provide written procedural requirements to guests
- 18. Medical Exams • Provide workers with “baseline” medical evaluations and nonspecific routine health monitoring program — orker who W • work with nanoparticles & may inhale them or get them on their skin, or • spend significant time in area where dispersible nanoparticle are handled, or • work on potentially contaminated equipment • Provide immediate exam for people exposed in an “incident” • Exempts non-resident people — uests, users G
- 19. Transportation of Nanomaterials • If classified as hazardous per 49 CFR must be packaged, marked and shipped per these regulations • If suspected to be hazardous, follow step above • If not hazardous per usual standards, still package in DOT PG 1 container — ealed container inner, S absorbent, exterior container http://www.nanotechbuzz.com/50226711/comic.jpg
- 20. Transportation of Nanomaterials • Label — Label nanomaterial sample containers • Provide an MSDS or equivalent information compiled by researcher • For on-site transfer — Follow the sites usual chemical transport policy, or — Follow DOT rules
- 21. Waste Management • If classified as hazardous per 40 CFR or state regulations, dispose of waste using standard hazardous waste procedures • If not classified as hazardous, send the waste to a RCRA permitted TSDF anyway — nclude instruction on how to dispose of material I • Do not permit nanomaterials to be shipped to researchers home institution for disposal
- 22. Waste Management • Applicability — ure nanomaterials P — tems contaminated with nanomaterials I • PPE, glassware, wipes, rinse water — iquid suspensions containing nanomaterials L — olid matrices with friable nanomaterials S attached to surface — oes not apply to fully imbedded D nanomaterials
- 23. Spills • Small spills cleaned up by lab personnel • Large spills cleaned up by hazmat team • Refer people exposed in incident for medical review • Clean up spill using wet methods/HEPA vacuuming • Treat all clean up equipment as “contaminated” • Dispose of waste appropriately
- 24. Questions?