In the last five years, research and development activities in the field of nanotechnology have shifted to include advanced nanomaterials. The main feature of advanced nanomaterials that distinguishes them from simpler nanomaterials, such as carbon black and nanoscale TiO2 used primarily as additives, is the ability of advanced nanomaterials to change or evolve properties during their use, as a result of intended and unintended reactions to the external environment. Examples of advanced nanomaterials include nanomaterials functionalized for specific applications, such as nanoscale gold used in cancer treatment therapies, quantum dots used in medical imaging of the body, and carbon nanotubes and graphene used in electronics. Depending on the type of nanomaterial and the conditions of exposure, such a change of properties may result in health risks to workers handling advanced nanomaterials if exposure is not adequately controlled.
Selected Category: Nanotechnology
Safe Handling of Advanced Nanomaterials
Categories: Nanotechnology
July 27th, 2012 11:54 am ET - Vladimir Murashov, PhD; Paul Schulte, PhD; John Howard, MD
Respiratory Protection for Workers Handling Engineered Nanoparticles
Categories: Nanotechnology, Respiratory health
December 7th, 2011 10:17 am ET - Ziqing Zhuang, PhD, and Dennis Viscusi
Introduction
Each day millions of workers in the United States use National Institute for Occupational Safety and Health (NIOSH) certified respirators to reduce exposure to harmful gases, vapors, and particulate hazards. NIOSH has certification, quality assurance, and auditing procedures in place (42 CFR Part 84) that assure purchasers and users that the products they are buying/using have been tested and manufactured to strict standards. When selected, maintained and used in the context of an Occupational Safety and Health Administration (OSHA)-compliant respiratory protection program, in which personal protective technology is part of the hierarchy of controls to protect the worker, respirator users can expect that their respirator is working and reducing the amount of hazards that they could potentially breathe. However, as new hazards emerge, the applicability of the science that NIOSH uses to base respirator test methods, performance requirements, and use recommendations needs to be continually reaffirmed, updated and improved to assure the expected level of protection is provided.
Pleuropulmonary disease in a polyacrylate facility
Categories: Chemicals, Nanotechnology, Respiratory health
July 26th, 2011 3:00 pm ET - Vladimir Murashov, PhD, Charles L Geraci, PhD, and David Weissman, MD
A reminder of the need to protect workers from hazardous dust
On June 24, 2011 the Indian Express, an on-line Indian news outlet, published an article reporting a “new” occupational lung disease and implicating a polyacrylate powder, which “seemed to be at the nano-level.”
The article is based on an investigation published by the Peoples Training and Research Center, a voluntary organization raising awareness and providing training on occupational safety and health. It reports a cluster of five cases of workers with severe pleural and pulmonary disease, which developed within 10–12 months of working at a factory that manufactures and processes polyacrylate and other polymers for use in pharmaceuticals. It is not entirely clear from the report, but it appears that two workers had interstitial lung disease with pneumothorax; one worker had interstitial lung disease associated with severe restrictive impairment; one worker had at least one pneumothorax; and one worker died after developing a symptom complex of fatigue, anorexia, and breathlessness, but no additional medical information was available.
Titanium Dioxide: A Changing Paradigm in Occupational Risk Management
Categories: Chemicals, Nanotechnology
May 9th, 2011 2:45 pm ET - Vladimir Murashov, PhD
A recently released NIOSH guidance document (NIOSH, 2011) on handling titanium dioxide (TiO2) powders in the workplace generated a high level of interest as it put forward an innovative approach that might have implications beyond TiO2. Specifically it may be the first document (originally released for external review as a draft in 2005) to recommend separate occupational exposure limits for the same material based on particle size. This document signifies increasing attention to evaluating and mitigating risks of emerging hazards in the workplace before adverse health effects occur in workers and could proactively be used for how other poorly soluble, low toxicity (PSLT) particles are controlled in the workplace.
What is the basis for this document?
Distinct exposure limits for distinct size fractions. NIOSH recommendations for TiO2, an insoluble white powder, used extensively in many commercial products, including paint, cosmetics, plastics, paper, and food, as an anticaking or whitening agent, go back to 1988 when it classified respirable dust of this material as a potential occupational carcinogen (NIOSH, 2002).
Older Posts
Pages
- [1]
- 2
Get email updates
To receive weekly email updates about this site, enter your email address:
Site Categories
- Agriculture, forestry, and fishing
- At-risk populations
- Bloodborne pathogens
- Cancer, reproductive and cardiovascular diseases
- Chemicals
- Construction
- Economics
- Emergency response
- Ergonomics
- Exposure
- Green
- Health care
- Hearing loss
- Media
- Mining
- Nanotechnology
- Oil and gas
- Outdoor work
- Personal protective equipment
- Policy and programs
- Prevention through Design
- Respiratory health
- Sleep
- Small Business
- Sports and entertainment
- Stress
- Technology
- Total Worker Health
- Training
- Transportation
- Uncategorized
- Vehicle safety
- Violence
- Young Workers
About this Site
Contact Us:
- Centers for Disease Control and Prevention
1600 Clifton Rd
Atlanta, GA 30333 - 800-CDC-INFO
(800-232-4636)
TTY: (888) 232-6348 - cdcinfo@cdc.gov