NIOSH Research Rounds

NIOSH Research Rounds is a monthly bulletin of selected research conducted by researchers at NIOSH and NIOSH-funded researchers at other institutions.

Volume 2, Number 12 (June 2017)

Inside NIOSH:
Preventing Heat Stress While Wearing Personal Protective Equipment

During severe disease outbreaks such as the 2014 Ebola virus epidemic in West Africa, wearing special gear can protect healthcare workers from exposure. This personal protective equipment covers the face and body to provide a physical barrier against germs. In addition, a respirator prevents the inhalation of airborne germs. Since many types of personal protective equipment worn during the Ebola response are made of heavy, fluid-resistant material, which can prevent sweat from evaporating and cooling the body, heat stress is a concern in hot weather.

At NIOSH, the safe use of personal protective equipment is a priority. Two studies recently published in the journal Disaster Medicine and Public Health Preparedness focused specifically on preventing heat stress while wearing this equipment in hot, humid environments. Volunteer study participants included six healthy, young men who received medical clearance by a licensed physician. To simulate working in the hot and humid conditions of West Africa, participants walked on a treadmill for 60 minutes in a special environmental chamber set to 90 degrees F (32 degrees C) and 92% relative humidity.

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Personal Protective Equipment Does Not Take the Heat Equally

After comparing three commonly used ensembles, NIOSH investigators found that different types of personal protective equipment were linked to increases in heart rate and body temperature during exertion.

The first ensemble tested included a face shield and a fluid-resistant surgical gown. The other, more elaborate, ensembles included goggles, coveralls, and a separate hood for the second one, and highly fluid-resistant coveralls, a separate hood, and a surgical mask cover over a NIOSH approved N95 respirator for the third one. Participants wore each of the ensembles over standard medical scrubs.

Compared to participants wearing the first ensemble, those wearing the second and third ensembles had significantly higher heart rates and body temperatures after exercising on the treadmill. In addition, participants wearing the second and third ensembles reported feeling hotter and more tired. These findings underscore the importance of training healthcare workers and regulating agencies in proper selection of personal protective equipment to prevent heat stress. In addition to training, it is important to balance work in hot conditions with adequate rest periods and to use heat-prevention strategies such as cooling vests.

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Cooling Vests Linked to Fewer Signs of  Heat Stress

Study participants wearing special vests fitted with ice packs, phase-change materials, or water hoses under personal protective equipment had fewer signs of heat stress than participants who did not wear the cooling devices, according to a related study. These results highlight the importance of cooling vests for healthcare workers wearing personal protective equipment in hot, humid environments.

For this study, participants tested four different styles of cooling vests that were are made of fabric and fitted with cooling packs or water-circulation hoses. Two of the vests contained cooling packs made of a special material designed to stay cold for long periods. One of these contained gel ice packs, and one contained a battery-operated pump and small hoses to deliver cold water throughout the vest. Participants wore the vests over standard medical scrubs and under personal protective equipment.

At the end of the treadmill tests, participants who were not wearing a cooling vest had significantly higher body temperatures and heart rates than did those who wore one. Furthermore, participants lost more weight during the exercise test when they were not wearing a cooling vest. Smaller increases in body temperatures and heart rates occurred among participants wearing the cooling vests with the gel ice packs and water hoses, compared to those wearing vests containing the special cooling material.

In addition to measuring body temperature, weight, and heart rate, the investigators used a questionnaire to measure five subjective feelings of exertion: heat sensation, thermal comfort, rating of perceived exertion, breathing comfort, and wetness. They found that three of the five feelings—heat sensation, rating of perceived exertion, and breathing comfort—improved when participants wore a cooling vest.

Investigators noted that future research should look at the effects of wearing cooling vests on posture, balance, and mobility and the physical effects of wearing circulating-water vests prior to wearing the personal protective equipment. In addition, further research with larger populations that include women is necessary.

More information is available:

• Physiological Evaluation of Personal Protective Ensembles Recommended for Use in West Africa
• Physiological Evaluation of Cooling Devices in Conjunction with Personal Protective Ensembles Recommended for Use in West Africa
• NIOSH Heat Stress
• NIOSH National Personal Protective Technology Laboratory

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Ambulance Crash Tests Promote Prevention through Design

Quickly maneuvering to the side of the road to allow a lights-flashing, sirens-blaring ambulance to pass, we may wonder about the medical emergency unfolding inside the racing vehicle. “That could be me or one of my family members,” we may think, a bit nervously, glad that the patient in the ambulance is receiving medical attention. What we may not consider as we sit safely in our cars is that medical care occurring while the ambulance is moving could place both the patient and the emergency medical services (EMS) workers at additional risk in the event of a crash.

In fact, vehicle crashes are the leading work-related cause of death in the United States, according to the U.S. Bureau of Labor Statistics. At especially high risk are EMS workers. Part of the problem is that ambulances, although outfitted with the latest medical equipment, may not adequately protect either workers or patients in a crash.

To protect EMS workers, NIOSH applies a technique known as prevention through design. The ultimate goal is to make ambulances safer by designing the interior so that EMS workers can remain seated and restrained while treating patients, who are also restrained for protection. Furthermore, safe ambulance design anchors heavy equipment to prevent it from becoming a dangerous missile if a crash does occur.

The first step in designing safer ambulances is to identify weak spots by studying what happens to an ambulance in a controlled crash test. Working with the U.S. Department of Homeland Security’s Science and Technology Directorate, with assistance from other agencies and ambulance manufacturers, NIOSH investigators recently completed 17 full-vehicle ambulance crash tests following the guidelines used by the automotive industry to test cars in front, rear, side, and rollover crashes. Using a front crash as an example, the investigators programmed an ambulance to crash into a concrete wall at 30 mph.

During each crash test, engineers measured the energy transferred through the vehicle from the impact point in the front to the patient compartment in the back. Engineers used those measurements to develop new tests for the body structure of the ambulance patient compartment, plus all of its major components, including the patient cot, seating systems, equipment mounts, and storage cabinets. The goal of crash testing was to make sure all parts of the ambulance would stay safely intact during a crash.

The Society of Automotive Engineers (SAE)—the leading organization for vehicle-safety consensus standards—published 10 new crash-test methods, also known as SAE Recommended Practices, based on this work. Now seat, cot, and ambulance manufacturers have test methods they can use to design and test new products that focus on improving safety and function for EMS workers and patients.

The next step is to encourage adoption of the crash-test methods into each of three nationally accepted bumper-to-bumper consensus standards used by state agencies when buying new ambulances.

In the meantime, the crash-test methods are highlighted in a new video series that manufacturers can use to design and build safer ambulances. The seven-part series provides information on topics ranging from the history of ambulance safety to specific crash test methods and is available on the NIOSH website or by clicking the links below:

1. Ambulance History, Injury Statistics & Standards
2. Crash Testing an Ambulance
3. Patient Compartment Seating & Restraint
4. Patient Cot, Cot Mount & Patient Restraint
5. Equipment Mount & Storage Device Testing
6. Building a Stronger Patient Compartment
7. Using the Ambulance Patient Compartment Human Factors Design Guidebook

More information is available:

• Improving EMS Worker Safety Through Ambulance Design and Testing
• NIOSH Continues Research to Improve Safety for Ambulance Service Workers and EMS Responders
• NIOSH Behind the Wheel at Work
• NIOSH Division of Safety Research
• NIOSH Prevention through Design