All Hands on Deck: a primer on protective gloves
Research with animals presents more than a fair share of hazards. From the inevitable bites, scratches, and even kicks, to the handling of metal cages, cage racks, and cage washers, there is danger at almost every turn. In addition to these physical hazards, you then add those risks common to a research environment such as chemicals and flammable solvents. It is no wonder the single most common item of personal protection in these laboratories, including animal research labs, is the glove. Yet, the glove is also most likely to receive the least amount of thought or consideration and may be the most misunderstood. In the animal laboratory, when we need to protect our hands, we often reach for whatever is closest, put it on, and think we are good to go. We are protected from.… anything, everything. Whoever put that box of gloves on the shelf must have known the hazards faced and selected the proper type. Right? Why else would they be there?
Not so fast. You might remember the terrible fatality of the New Hampshire researcher in 1997 working with dimethyl mercury. While transferring material only a few small drops spilled onto her latex gloved left hand. She died from mercury poisoning almost three hundred days post-exposure and after three months of aggressive treatment. 1,2 Latex offers no protection for this organic substance and glove permeation occurred in about fifteen seconds. In addition, the American Industrial Hygiene Association has compiled a host of lab accidents stemming from using the wrong glove or no gloves at all.3 So, do not assume those gloves sitting on the shelf are the right ones for your particular task.
Assess the Job and the Risks
Granted these tragic accidents are extreme examples and not expected in animal research labs, but thousands of accidents occur every year due to improper hand protection. Given the myriad of glove types and materials it is imperative that both employees and supervisors know which gloves are suitable for the task at hand (no pun intended). This brings us to the first step in a good hand protection program—conduct a detailed and thorough glove audit and job hazard analysis (JHA).We have written articles on JHA previously, but it boils down to simply identifying the hazard and the employees at risk, then selecting the right control measures, which includes personal protective equipment, for the job. Things to keep in mind when performing the audit and hazard analysis are questions like:
- Can the procedure or process be changed to prevent or eliminate the hazard?
- Can a less hazardous material or substance be substituted?
- Will personal protective equipment solve the problem?
- Is the risk acceptable?
Identify the Hazard(s)
Hazards faced in an animal laboratory are broad and varied. Physical hazards such as bites and scratches and cuts or punctures from broken glassware or burns from hot equipment or containers demand a much different protective glove than for chemical hazards such as dermatitis, corrosive burns, or absorption. Fortunately, innovations in materials and technology have produced a huge selection of protective gloves for nearly any purpose. Advanced polymers and fibers provide superior protection from abrasion, punctures, and lacerations compared to the old standbys cotton and leather. These new materials provide even more protection when various coatings are applied.
When we enter the realm of the typical animal research laboratory though, resistance to chemicals is needed frequently. Chemicals take all forms—liquids, dusts, or powders, gases and vapors, and selecting the right glove will require a little homework. Lucky for us there are excellent manufacturer’s websites available to help. (A few of these resources are given at the end of the article.) But, before we leap into cyberspace we should know the terminology or lingo so we can decipher the mountain of information out there. Here are the most important ones:
Contamination: occurs when the inside of the glove is contaminated either prior to or during donning (putting the glove on). Manufacturers cannot prevent this. Only careful and conscientious employees can. Make sure everyone is trained and follows good, safe housekeeping procedures.
Penetration: happens when a substance passes through a seam or damaged glove, e.g. a pinhole or tear. Employees must be very attentive. Double-glove when handling extremely hazardous materials. Change to fresh gloves at the first sign of a problem or if in doubt about integrity.
Degradation: happens when the chemical breaks down or damages the glove material. Manufacturers usually provide a rating over time. Selecting the best or most appropriate glove material, i.e. the highest rating for the longest time, is key to preventing exposures from degradation.
Permeation: occurs when the substance passes through the intact glove material at the molecular level. This is commonly referred to as “breakthrough” and usually given in minutes. The larger the number the longer the glove material can be in contact with the chemical before breakthrough.
Choose the Best Glove for the Job
As mentioned above, the internet resources provided will help you select the best glove and provide the most protection. For chemical mixtures or multiple hazards, pick the glove with the highest resistance to the most toxic substance or consider a double-glove protocol. If you are in doubt do not hesitate to call the manufacturer’s representative for technical assistance. To get you started, here is a brief summary of the major glove materials.
Nitrile is a synthetic polymer made from acrylonitrile, butadiene, and any one of many carboxylic acids. It is a very good substitute for natural rubber, vinyl, and neoprene. Nitrile gives excellent protection from many corrosives, solvents, oils, and grease. Nitrile is generally more resistant to cuts, snags, punctures, and abrasions than neoprene or PVC gloves of the same thickness. Nitrile gloves do not contain latex, the source for many allergic reactions. Dexterity is considered very good.
Polyvinylchloride gloves are typically resistant to petroleum hydrocarbons, oils, acids, and caustics. They also may provide protection from alcohols and glycol ethers, but not ketones, aldehydes, or aromatics. They provide very good abrasion resistance, but dexterity is poor to fair depending on the specific product.
Butyl rubber is a copolymer of isobutylene (usually 98%) and isoprene. It was first developed for tire inner tubes as this material generally has the highest permeation resistance to gases and water vapors. Butyl rubber provides good chemical resistance to alcohols, aldehydes, amines, bases, and glycol ethers. Butyl rubber does not do well against halogenated compounds, aliphatic, or aromatic hydrocarbons. Flex and dexterity can be very good with the right product.
Viton® is a Dupont trademark for a fluoroelastomeric material. Viton was developed specifically for handling chlorinated and aromatic solvents. Viton gloves are also reported to provide excellent resistance to PCBs. Abrasion resistance is very good as is flexibility and dexterity.
Silver Shield® is a tradename for a flexible laminate made of polyethylene/ ethylene-vinyl alcohol. This material offers resistance against permeation and breakthrough for the widest range of hazardous and toxic chemicals. Silver Shield material is excellent against aromatics, chlorines, esters, and ketones. Abrasion resistance is very good. Dexterity and flexibility are fair to good depending on the product.
Choosing the right protective glove for the job is critical to safe handling of animals as well as hazardous and toxic chemicals and other laboratory tasks. The descriptions above should be used for general guidance. We must stress that you match the individual glove by manufacturer and style to the required task and exposure particulars. No single glove will protect against all harmful substances. Nor will one glove suit all applications. No matter which glove is used, they all can potentially leak or become punctured or torn. No glove can offer 100%protection either as permeation and degradation take their toll during use. To ensure the highest level of protection train employees to know the hazards of the substances they handle and the estimated breakthrough times for the gloves selected. Always handle toxic and hazardous chemicals with utmost care.
- Dimethyl Mercury Hazard Information Bulletin, OSHA. March 1998. http://www.osha.gov/dts/hib/hib_data/hib19980309.html
- Nierenberg, David W., et.al. Delayed Cerebellar Disease and Death after Accidental Exposure to Dimethylmercury. New England Journal of Medicine. June 1998. http://content.nejm.org/cgi/content/full/338/23/1672?ijkey=576 bbde99ab04c2945a8286ebe7b275c6c057a72&keytype2=tf_ipse csha
- John, Jeff. Chemical Exposure to Burns. Laboratory Health and Safety Committee, American Industrial Hygiene Association. Fairfax, Virginia. 2010. www.aiha.org
- Ansell - http://ansellpro.com/specware/index.asp
- Showa-Best - http://www.bestglove.com/site/chemrest/default.aspx
- HexAmour - http://www.hexarmor.com/industries/ animal-handling-vets/
- Kimberly Clark - http://www.kcprofessional.com/us/Product-Catalog/Gloves/LaboratoryGloves.asp
- Mapa - http://www.mapaglove.com/ChemicalSearch.cfm?id=0
- Microflex - http://www.microflex.com/
- Saf-T-Gard - http://www.saftgard.com/products.htm
- North Safety - http://ezguide.northsafety.com/
Vince McLeod is an American Board of Industrial Hygiene Certified Industrial Hygienist and the senior IH with the University of Florida’s Environmental Health and Safety Division. He has 22 years experience in all facets of occupational health and safety and specializes in conducting exposure assessments and health hazard evaluations.