Controlling Personal Exposure To Nanomaterials

Several factors affect exposure to nanomaterials: 

The concentration, duration, and frequency of exposure to nanoparticles all affect user exposure. 

In addition, the ability of nanoparticles to be easily dispersed as a dust (e.g. a powder) or an airborne spray or droplets will impact exposure of the users.

Use of protective measures such as engineering controls (e.g. fume hoods) and personal protective equipment (e.g. gloves) can reduce user exposure.

Job-related activities may also influence user exposure:

Active handling of nanomaterials as powders on the benchtop pose the greatest risk for inhalation exposure; NIOSH recommends the use of HEPA filters, either in respirators or local ventilation equipment to control such powders

Tasks that generate aerosols of nanomaterials from slurries, suspensions, or solutions pose a potential for both inhalation and dermal exposure. In some cases, it has been found that nanomaterials have penetrated both gloves and skin.

Clean-up and waste disposal of nanomaterials may result in exposure if not properly handled. Maintenance and cleaning of production systems or dust collection systems may result in exposure if deposited nanoparticles are disturbed.

Machining, sanding, drilling, or other mechanical disruptions of materials containing nanomaterials may lead to aerosolization.

Measurement of Nanomaterials

Traditional industrial hygiene sampling methods such as airborne dust measurements have been used to measure airborne nanomaterials. However, these methods require careful interpretation. Scientists are developing more sensitive and specific sampling techniques to evaluate occupational exposures. Sampling in the workplace should include background measurements and measurements before, during, and after production or handling of these materials. These measurements can determine if emissions and possible exposures are occurring.

Exposure Controls

Elimination or substitution of a less hazardous substance is a basic principle of laboratory safety and health. Certain aspects of a process may be changed and result in a less hazardous situation to exist.   

Reducing user exposures to nanomaterials can be achieved by Engineering Controls such as source enclosure (isolating the generation source from the user) and local exhaust ventilation systems. Exhaust ventilation systems that use high-efficiency particulate air (HEPA) filters are very effective in removing nanomaterials. In Table 16.1 (provided by NIOSH), recommendations of installing control measures depending on the nanomaterial used in specific activities are presented.

By means of engineering controls, operational procedures, such as reducing the time the employee is handling the material, specifying good housekeeping and other good work practices, training employees, and implementing proper labeling and storage of materials, limit the exposure to nanomaterials.

If engineering and administrative controls cannot control exposures, personal protective equipment, such as respirators and appropriate gloves and coveralls, should be considered.

Recommended safety procedures for handling nanomaterials:

• Use good general laboratory safety practices as found in Chemical and Biological Safety sections of this handbook and individual laboratory operating procedures. Wear gloves, lab coats, safety glasses, face shields, closed-toed shoes. Avoid getting nanoparticles in eyes, mucous membranes, on skin, or in respiratory tract.
• Wash your hands BEFORE you leave the lab. 
• Be sure to consider the hazards of precursor materials in evaluating process hazards.  (For example, some powders are more dangerous until they are mixed into a solution, whereby they become safer to handle and there is less possibility of inhalation of floating particles.)
• Avoid skin contact with nanoparticles or nanoparticle-containing solutions by using appropriate personal protective equipment. Do not handle nanoparticles with your bare skin.
• Handle nanoparticles only inside a HEPA-filtered powered-exhaust laminar flow hood, wear appropriate respiratory protection. If this is not possible, consult with LSS on obtaining respiratory protection.
• Use fume hoods to expel fumes from tube furnaces or chemical reaction vessels.
• Place the waste that contains nanoparticles in puncture-proof sealable containers, or double bag in 6 mL plastic, clearly mark with contents, and disposed of through hazardous waste channels. 
• Clean up spilled nanoparticles accomplished with a HEPA-filtered vacuum or call LSS. 
• Become familiar with the SDS associated with the basic material; be alert for the onset of any symptoms associated with the chronic effects of these materials.

No certain set of rules will cover all situations. 

Given the differing synthetic methods and experimental goals, no blanket recommendation can be made regarding aerosol emissions controls. This should be evaluated on a case-by-case basis.

Consideration should be given to the high reactivity of some nanopowder materials with regard to potential fire and explosion hazards (Table 16.1).

Table 7.1 Biosafety levels
Biosafety Level	1	2	3	4
Infectious Agents	Unlikely to cause  disease in healthy  workers or animals   Low individual and community risk	Can cause human  or animal disease but  unlikely to be  a serious hazard   Moderate individual risk, limited community risk   Effective treatments  available	Cause serious human  or animal disease but not ordinarily spread by casual contact   High individual risk,  low community risk	Cause very  serious human  or animal disease,  often untreatable  and transmitted   High individual risk,  high community risk
Examples of infectious  agents in this risk level		E. coli,  California encephalitis viruses,  many influenza viruses	Anthrax, Q fever, tuberculosis, Hantaviruses, human  immuno-deficiency viruses	Ebola viruses,  Herpes B virus (Monkey virus), foot and mouth disease
Facilities	Standard well-designed experimental animal and laboratory facilities	Level 1 plus:  Separate laboratory,  room surfaces  impervious and readily cleaned,  biohazard sign	Level 2 plus:  Controlled access  double door entry and  body shower, air pressure  must be negative  at all times,  no recirculation,  HEPA filtration,  backup power	Specialized, secure,  completely self-contained  unit with  specialized ventilation, fully monitored;  air lock entry and exit,
Safety Equipment	Handwashing facilities, laboratory coats	Level 1 plus: autoclave,  HEPA-filtered  class I or II  biological safety cabinet,  personal protective  equipment	Level 2 plus: Autoclave,  HEPA-filtered class II  biological safety cabinet, personal protective  equipment to include  solid front laboratory  clothing, head covers,  dedicated footwear,  and gloves, appropriate respiratory protection	Class III  biological safety cabinets,  positive pressure  ventilated suits
Procedures	Basic safe laboratory practices	Use of personal protective equipment laboratory  coat worn only in the laboratory, gloves, decontamination	Users fully trained, written protocols; showers, wastes disposed of as contaminated,  use of biological safety  cabinets, personal  protective devices	Access only to  certified staff, rigorous sterilization/decontamination  procedures

Adopted from The University of North Carolina at Chapel Hill, Environmental Health & Safety Department. 

References and sources for information from the relevant websites and documentation of different universities, NGOs and government agencies used in the preparation of this website are provided at references.