1. SAFETY PRECAUTIONS & TOXICITY RESEARCH NANOTECHNOLOGY

2. Defined as “the understanding and control of matter at dimensions of roughly 1 to 100 nanometers, where unique phenomena enable novel applications.” The Nanotechnology-Biology Interface: Exploring Models for Oversight

3. CHALLENGES IN NANOTECHNOLOGY 1.Melding inorganic with biological to be compatible Nanotoxicology concerns in health & environment 2.Benefiting society 3.Deployment of nanotechnology for solving global issues

4. HEALTH & ENVIRONMENTAL SAFETY Applications have a DUAL nature Example: The blood brain barrier delivers drugs by penetration but raises toxicity concerns Thus the UK advises against use until future, but the US doesn’t agree.

5. US GOVERNMENT FRAMEWORK Federal Organizations Specific regulations : Federal Plant Pest Act Federal Food, Drug & Cosmetic Act Toxic Substances Control Act

6. RISK MANAGEMENT Hazard Identification : Inhalation, dermal, injestion Exposure control : Substitution or elimination of nanoparticles to reduce its release Isolation in an enclosure or separate area Engineering controls are required depending on experiment: General Exhaust Ventilation, Local Exhaust Ventilation Administrative controls such as job rotation, placement of standard operating procedure, housekeeping procedure, spill prevention and control, proper labeling and storage of nanoparticles, and use of personal protective equipment

7. SAFETY PROCEDURES American research laboratories must follow specific OSHA standards : Bloodborne Pathogens [1910.1030] Laboratory Chemical Safety [1910.1450] Respiratory Protection [1910.134] Most institutions, such as University of Maryland and Rice University have the capacity for nanotechnology research, but safety only goes as far as general lab safety training for researchers.

8. RECOMMENDED LAB PRACTICES Other institutions have recommended lab practices For example, Princeton University: Conduct a thorough risk assessment and take conservative measures to prevent exposure Work with nanomaterials in liquid media whenever possible Wear impervious gloves, labcoats or cleanroom suits, chemical splash goggles Use enclosed control systems, such as a glovebox, for work with dry nanoparticles or when potential aerosol generation exists HEPA filtration and wet wiping methods are both effective means of removing nanoparticle contamination

9. RISK ASSESSMENT COMPLICATIONS Currently not enough information to characterize risks Differences in the exposure medium (i.e.. Food, water, air) Route of exposure (ie inhaled, consumed, contacted) Dose responses

10. SUSTAINABLE NANOTECHNOLOGY Sustainable Nanotechnology Research & development of nanomaterials that have economic & societal benefits with little to no environmental negative impacts

11. SUSTAINABLE NANOTECHNOLOGY ARTICLE Veronesi et al.

12. VERONESI ET AL. The Physicochemistry of Capped Nanosilver Predicts Its Biological Activity in Rat Brain Endothelial Cells (RBEC4) “Capping” nanosilver limits its oxidation/ aggregation & stabilizes its size/ shape This study measured aggregate size and zeta potential of AgNP of different sizes and different coatings and if those factors alter permeability, cellular, and genomic responses Conclusions: Pathways affected by both PVP were associated with NRF2- mediated oxidative stress response, endocytosis, and bioenergies Surface coating, aggregate size, & surface charge contribute to capped AgNP permeability & oxidative stress response in RBEC4 PVP coating, a less negative surface charge, and smaller size have high toxicity and reactivity to RBEC4