Respirator

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A respirator is a device designed to protect the wearer from inhaling hazardous atmospheres including lead fumes, vapors, gases and particulate matter such as dusts and airborne pathogens such as viruses. There are two main categories of respirators: the air-purifying respirator, in which respirable air is obtained by filtering a contaminated atmosphere, and the air-supplied respirator, in which an alternate supply of breathable air is delivered. Within each category, different techniques are employed to reduce or eliminate noxious airborne contaminants.

Air-purifying respirators range from relatively inexpensive, single-use, disposable face masks, known as filtering facepiece respirators, reusable models with replaceable cartridges called elastomeric respirators, to powered air-purifying respirators (PAPR), which use a pump or fan to constantly move air through a filter and supply purified air into a mask, helmet or hood.

HistoryEdit

Earliest records to 19th centuryEdit

The history of protective respiratory equipment can be traced back as far as the first century, when Pliny the Elder (Template:Circa–79) described using animal bladder skins to protect workers in Roman mines from red lead oxide dust.<ref>Template:Cite wikisource</ref> In the 16th century, Leonardo da Vinci suggested that a finely woven cloth dipped in water could protect sailors from a toxic weapon made of powder that he had designed.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Alexander von Humboldt introduced a primitive respirator in 1799 when he worked as a mining engineer in Prussia.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Julius Jeffreys first used the word "respirator" as a mask in 1836.<ref name="Zuck-1990">Template:Cite journal</ref>

In 1848, the first US patent for an air-purifying respirator was granted to Lewis P. Haslett<ref>Template:Cite book</ref> for his 'Haslett's Lung Protector,' which filtered dust from the air using one-way clapper valves and a filter made of moistened wool or a similar porous substance.<ref>Template:Cite patent Template:Webarchive</ref> Hutson Hurd patented a cup-shaped mask in 1879 which became widespread in industrial use.<ref>Template:Cite patent</ref>

Inventors in Europe included John Stenhouse, a Scottish chemist, who investigated the power of charcoal in its various forms, to capture and hold large volumes of gas. He built one of the first respirators able to remove toxic gases from the air, paving the way for activated charcoal to become the most widely used filter for respirators.<ref>Template:Cite book</ref> Irish physicist John Tyndall took Stenhouse's mask, added a filter of cotton wool saturated with lime, glycerin, and charcoal, and in 1871 invented a 'fireman's respirator', a hood that filtered smoke and gas from air, which he exhibited at a meeting of the Royal Society in London in 1874.<ref>Template:Cite journal</ref> Also in 1874, Samuel Barton patented a device that 'permitted respiration in places where the atmosphere is charged with noxious gases, or vapors, smoke, or other impurities.'<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref>Template:Cite patent Template:Webarchive</ref>

In the 1890s, the German surgeon Johannes Mikulicz began using a "mundbinde" ("mouth bandage") of sterilized cloth as a barrier against microorganisms moving from him to his patients. Along with his surgical assistant Wilhelm Hübener, he adapted a chloroform mask with two layers of cotton mull. Experiments conducted by Hübener showed that the "mouth bandage" or "surgical mask" (German: Operationsmaske, as Hübener called it) blocked bacteria.<ref>Template:Cite journal</ref><ref>Schlich T, Strasser BJ. Making the medical mask: surgery, bacteriology, and the control of infection (1870s–1920s). Medical History. 2022;66(2):116-134. doi:10.1017/mdh.2022.5</ref>

20th centuryEdit

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World War IEdit

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United StatesEdit

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In the 1970s, the successor to the United States Bureau of Mines and NIOSH developed standards for single-use respirators, and the first single-use respirator was developed by 3M and approved in 1972.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> 3M used a melt blowing process that it had developed decades prior and used in products such as ready-made ribbon bows and bra cups; its use in a wide array of products had been pioneered by designer Sara Little Turnbull.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

1990sEdit

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21st centuryEdit

Continuing mesothelioma litigationEdit

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NIOSH certifies B Readers, people qualified to testify or provide evidence in mesothelioma personal injury lawsuits,<ref>Template:Cite journal</ref> in addition to regulating respirators. However, since 2000, the increasing scope of claims related to mesothelioma started to include respirator manufacturers to the tune of 325,000 cases, despite the primary use of respirators being to prevent asbestos and silica-related diseases. Most of these cases were not successful, or reached settlements of around $1000 per litigant, well below the cost of mesothelioma treatment.<ref name="rescue" />

One reason is due to the fact that respirator manufacturers are not allowed to modify a respirator once it is certified by NIOSH. In one case, a jury ruled against 3M for a respirator that was initially approved for asbestos, but was quickly disapproved once OSHA permissible exposure limits for asbestos changed. Combined with testimony that the plaintiff rarely wore a respirator around asbestos, the lack of evidence, and the limitation of liability from static NIOSH approval, the case was overturned.<ref name="rescue">Template:Cite journal</ref>

Nonetheless, the costs of litigation reduced the margins for respirators, which was blamed for supply shortages for N95 respirators for anticipated pandemics, like avian influenza, during the 2000s.<ref name="rescue" />

2020Edit

China normally makes 10 million masks per day, about half of the world production. During the COVID-19 pandemic, 2,500 factories were converted to produce 116 million daily.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

During the COVID-19 pandemic, people in the United States, and in a lot of countries in the world, were urged to make their own cloth masks due to the widespread shortage of commercial masks.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

2024Edit

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Summary of modern respiratorsEdit

All respirators have some type of facepiece held to the wearer's head with straps, a cloth harness, or some other method. Facepieces come in many different styles and sizes to accommodate all types of face shapes.

A full facepiece covers the mouth, nose and eyes and if sealed, is sealed round the perimeter of the face. Unsealed versions may be used when air is supplied at a rate which prevents ambient gas from reaching the nose or mouth during inhalation.

Respirators can have half-face forms that cover the bottom half of the face including the nose and mouth, and full-face forms that cover the entire face. Half-face respirators are only effective in environments where the contaminants are not toxic to the eyes or facial area.

An escape respirator may have no component that would normally be described as a mask, and may use a bite-grip mouthpiece and nose clip instead. Alternatively, an escape respirator could be a time-limited self-contained breathing apparatus.

For hazardous environments, like confined spaces, atmosphere-supplying respirators, like SCBAs, should be used.

A wide range of industries use respirators including healthcare & pharmaceuticals, defense & public safety services (defense, firefighting & law enforcement), oil and gas industries, manufacturing (automotive, chemical, metal fabrication, food and beverage, wood working, paper and pulp), mining, construction, agriculture and forestry, cement production, power generation, painting, shipbuilding, and the textile industry.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Respirators require user training in order to provide proper protection.

UseEdit

User seal checkEdit

Each time a wearer dons a respirator, they must perform a seal check to be sure that they have an airtight seal to the face so that air does not leak around the edges of the respirator. (PAPR respirators may not require this because they don't necessarily seal to the face.) This check is different than the periodic fit test that is performed using testing equipment. Filtering facepiece respirators are typically checked by cupping the hands over the facepiece while exhaling (positive pressure check) or inhaling (negative pressure check) and observing any air leakage around the facepiece. Elastomeric respirators are checked in a similar manner, except the wearer blocks the airways through the inlet valves (negative pressure check) or exhalation valves (positive pressure check) while observing the flexing of the respirator or air leakage. Manufacturers have different methods for performing seal checks and wearers should consult the specific instructions for the model of respirator they are wearing. Some models of respirators or filter cartridges have special buttons or other mechanisms built into them to facilitate seal checks.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref>Template:Harvnb</ref>

Fit testingEdit

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Contrast with surgical maskEdit

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Surgical N95Edit

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Respirator selectionEdit

Air-purifying respirators are respirators that draw in the surrounding air and purify it before it is breathed (unlike air-supplying respirators, which are sealed systems, with no air intake, like those used underwater). Air-purifying respirators filter particulates, gases, and vapors from the air, and may be negative-pressure respirators driven by the wearer's inhalation and exhalation, or positive-pressure units such as powered air-purifying respirators (PAPRs).

According to the NIOSH Respirator Selection Logic, air-purifying respirators are recommended for concentrations of hazardous particulates or gases that are greater than the relevant occupational exposure limit but less than the immediately dangerous to life or health level and the manufacturer's maximum use concentration, subject to the respirator having a sufficient assigned protection factor. For substances hazardous to the eyes, a respirator equipped with a full facepiece, helmet, or hood is recommended. Air-purifying respirators are not effective during firefighting, in oxygen-deficient atmosphere, or in an unknown atmosphere; in these situations a self-contained breathing apparatus is recommended instead.<ref name=":8">Template:Cite journal</ref>

Types of filtrationEdit

Mechanical filterEdit

Main Article: Mechanical filter respirator (and regulatory ratings)

Mechanical filters remove contaminants from air in several ways: interception when particles following a line of flow in the airstream come within one radius of a fiber and adhere to it; impaction, when larger particles unable to follow the curving contours of the airstream are forced to embed in one of the fibers directly; this increases with diminishing fiber separation and higher air flow velocity; by diffusion, where gas molecules collide with the smallest particles, especially those below 100 nm in diameter, which are thereby impeded and delayed in their path through the filter, increasing the probability that particles will be stopped by either of the previous two mechanisms; and by using an electrostatic charge that attracts and holds particles on the filter surface.

There are many different filtration standards that vary by jurisdiction. In the United States, the National Institute for Occupational Safety and Health defines the categories of particulate filters according to their NIOSH air filtration rating. The most common of these are the N95 respirator, which filters at least 95% of airborne particles but is not resistant to oil.

Other categories filter 99% or 99.97% of particles, or have varying degrees of resistance to oil.<ref name="fact sheet">Template:Cite journal</ref>

In the European Union, European standard EN 143 defines the 'P' classes of particle filters that can be attached to a face mask, while European standard EN 149 defines classes of "filtering half masks" or "filtering facepieces", usually called FFP masks.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

According to 3M, the filtering media in respirators made according to the following standards are similar to U.S. N95 or European FFP2 respirators, however, the construction of the respirators themselves, such as providing a proper seal to the face, varies considerably. (For example, US NIOSH-approved respirators never include earloops because they don't provide enough support to establish a reliable, airtight seal.) Standards for respirator filtration the Chinese KN95, Australian / New Zealand P2, Korean 1st Class also referred to as KF94, and Japanese DS.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Canister or chemical cartridgeEdit

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Chemical cartridges and gas mask canisters remove gases, volatile organic compounds (VOCs), and other vapors from breathing air by adsorption, absorption, or chemisorption. A typical organic vapor respirator cartridge is a metal or plastic case containing from 25 to 40 grams of sorption media such as activated charcoal or certain resins. The service life of the cartridge varies based, among other variables, on the carbon weight and molecular weight of the vapor and the cartridge media, the concentration of vapor in the atmosphere, the relative humidity of the atmosphere, and the breathing rate of the respirator wearer. When filter cartridges become saturated or particulate accumulation within them begins to restrict air flow, they must be changed.<ref name="CartridgesReplacement">The document describes the methods used previously and currently used to perform the timely replacement of cartridges in air purifying respirators.</ref>Template:Primary source inline

If the concentration of harmful gases is immediately dangerous to life or health, in workplaces covered by the Occupational Safety and Health Act the US Occupational Safety and Health Administration specifies the use of air-supplied respirators except when intended solely for escape during emergencies.<ref name="Standard">OSHA standard 29 CFR 1910.134 Template:Webarchive "Respiratory Protection"</ref> NIOSH also discourages their use under such conditions.<ref name="Учебник-по-выбору-2004">Template:Cite book</ref> Template:Excerpt

Air-purifying respiratorsEdit

Filtering facepieceEdit

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ElastomericEdit

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Powered air-purifying respiratorsEdit

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Atmosphere-supplying respiratorsEdit

These respirators do not purify the ambient air, but supply breathing gas from another source. The three types are the self contained breathing apparatus, in which a compressed air cylinder is worn by the wearer; the supplied air respirators, where a hose supplies air from a stationary source; and combination supplied-air respirators, with an emergency backup tank.<ref name=":0">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Self-contained breathing apparatusEdit

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Supplied air respiratorEdit

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Escape respiratorsEdit

Smoke hoodEdit

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Self-contained breathing apparatusEdit

Continuous-flowEdit

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Self-rescue deviceEdit

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IssuesEdit

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Under 30 CFR 11Edit

Template:Further In 1992, NIOSH published a draft report on the effectiveness of respirator regulations under the then-current 30 CFR 11. Particulate respirators back then were mainly classified as either DM, DFM, or HEPA.<ref>Template:Harvnb</ref>

Respirator risk modellingEdit

Assigned protection factors (APF) are predicated on the assumption that users are trained in the use of their respirators, and that 100% of users exceed the APF.<ref>"NIOSH has concluded that APFS based on APF definitions from Myers et al. and the Guy Committee are derived from WPF data that were obtained after each test subject has been properly fitted and trained"... Template:Harvnb</ref> This "simulated workplace protection factor" (SWPF) was said to be problematic:

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The ideal assumption of all respirator users exceeding the APF is termed the zero control failure rate by NIOSH. The term control failure rate here refers to the number of respirator users, per 100 users, that fail to reach the APF.<ref name="NIOSHp52">Template:Harvnb</ref> The risk of user error affecting the failure rate, and the studies quantifying it, was, according to NIOSH, akin to the study of contraception failure rates.<ref>Template:Harvnb</ref>

This is despite there being a "reasonable expectation, of both purchasers and users, [that] none of the users will receive less protection than the class APF (when the masks are properly selected, fit tested by the employer, and properly worn by the users)". NIOSH expands on the methods for measuring this error in Chapter 7 of the draft report.<ref name="NIOSHp52" />

Qualitative fit testingEdit

Qualitative fit testing with isoamyl acetate, irritant smoke, and saccharin were proposed as alternatives to quantitative fit testing in the 1980s, but doubts were raised as to its efficacy.<ref name="page35">Template:Harvnb</ref>

With regards to the effectiveness of fit testing in general, others have said:<ref name="page35" /> <templatestyles src="Template:Blockquote/styles.css" />

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Exercise protocolsEdit

With regards to fit test protocols, it was noted by NIOSH that "time pressures" resulted in the exclusion of intense exercises meant to simulate workplace use:<ref name="page37">Template:Harvnb</ref> <templatestyles src="Template:Blockquote/styles.css" />

Part of the original test procedure called for test subjects to be stressed by treadmill, while undergoing a quantitative respirator leak evaluation. The purpose of this stressing was to simulate actual workplace use of the respirators. We accordingly abandoned the "stress" portion of the exercises, and substituted a period to be spent in a hot humid chamber, to work up a sweat, as a substitute for physical activity.<ref>Template:Citation</ref>{{#if:|{{#if:|}}

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The exercise time limits are very short. The required exercises are sedentary and do not replicate movements of workers that may occur in workplaces.<ref>Template:Citation</ref>{{#if:|{{#if:|}}

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Noncompliance with regulationEdit

In spite of the requirement to fit test by OSHA, the following observations of noncompliance with respirator regulations were made by NIOSH and OSHA:<ref name="page45">Template:Harvnb</ref>

• Almost 80% of negative-pressure respirator wearers were not receiving fit testing.
• Over 70% of 123,000 manufacturing plants did not perform exposure-level monitoring, when selecting respirators to use in the plants.
• Noncompliance increased to almost 90% for the smallest plants.
• 75% of manufacturing plants did not have a written program.
• 56% of manufacturing plants did not have a professional respirator-program administrator (i.e., qualified individual supervising the program).
• Almost 50% of wearers in manufacturing plants did not receive an annual examination by a physician.
• Almost 50% of wearers in manufacturing plants did not receive respirator-use training.
• 80% of wearers in manufacturing plants did not have access to more than one facial-size mask, even though nearly all reusable masks were available in at least three sizes.<ref name="page45" />

These noncompliance errors make up what NIOSH calls the program protection factor:<ref name="page47">Template:Harvnb</ref><templatestyles src="Template:Blockquote/styles.css" />

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Adherence to the regulatory minimumEdit

APFs may be based on the filtration performance from one or two manufacturers that barely pass the regulation. When the DM and DFM respirator filter standards at the time were found to have an unacceptably high filter leakage, NIOSH proposed lowering the APF for DM respirators from 10 to 2. On this scale, 1 is a completely ineffective respirator. Some respirator manufacturers, like 3M, complained that DM and DFM respirators with superior filtration, that would normally receive an APF well above 2, were being "held hostage" by poorly-performing respirators.<ref>Template:Harvnb</ref> While NIOSH acknowledged the predicament poorly-performing respirators were having on superior respirators in the same class, they concluded that the APFs, for respirator classes like DFM halfmask respirators, should be lowered to at least 6, despite APFs of 6 through 10 being allowed previously for DFM halfmasks.<ref>Template:Harvnb</ref>

ANSI suggested additional contaminant monitoring by employers to allow for the use of DM and DFM respirators, when the mass median aerodynamic diameter of dusts in contaminated workplaces is such that DM and DFM respirators could work. However, NIOSH pointed out that the poor adherence to OSHA regulations on exposure-level monitoring by employers, as well as lack of expertise in interpreting the collected data, would likely result in more workers being put at risk.<ref>Template:Harvnb</ref> In addition, NIOSH pointed out that the ANSI recommendations would effectively mandate the use of expensive Part 11 HEPA filters under Part 11 regulations,<ref>Template:Harvnb</ref> due to lack of adherence to exposure-level monitoring rules.<ref>Template:Harvnb</ref>

Hierarchy of Controls point of view under 42 CFR 84Edit

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The Hierarchy of Controls, noted as part of the Prevention Through Design initiative started by NIOSH with other standards bodies, is a set of guidelines emphasizing building in safety during design, as opposed to ad-hoc solutions like PPE, with multiple entities providing guidelines on how to implement safety during development<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> outside of NIOSH-approved respirators. US Government entities currently and formerly involved in the regulation of respirators follow the Hierarchy of Controls, including OSHA<ref name="twonine" /> and MSHA.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

However, some HOC implementations, notably MSHA's, have been criticized for allowing mining operators to skirt engineering control noncompliance by requiring miners to wear respirators instead if the permissible exposure limit (PEL) is exceeded, without work stoppages, breaking the hierarchy of engineering controls. Another concern was fraud related to the inability to scrutinize engineering controls,<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> unlike NIOSH-approved respirators, like the N95, which can be fit tested by anyone, are subject to the scrutiny of NIOSH, and are trademarked and protected under US federal law.<ref name="counterfeit">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> NIOSH also noted, in a 2002 video about TB respirator use, that "engineering controls, like negative pressure isolation rooms may not control the TB hazard completely. The use of respirators is necessary".<ref>Template:Cite wikisource</ref>

Respirator non-complianceEdit

Template:See also With regards to people complying with requirements to wear respirators, various papers note high respirator non-compliance across industries,<ref>Template:Cite journal</ref><ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> with a survey noting non-compliance was due in large part due to discomfort from temperature increases along the face, and a large amount of respondents also noting the social unacceptability of provided N95 respirators during the survey.<ref>Template:Cite journal</ref> For reasons like mishandling, ill-fitting respirators and lack of training, the Hierarchy of Controls dictates respirators be evaluated last while other controls exist and are working. Alternative controls like hazard elimination, administrative controls, and engineering controls like ventilation are less likely to fail due to user discomfort or error.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

A U.S. Department of Labor study<ref name="Обзор-2001">Template:Cite book</ref> showed that in almost 40 thousand American enterprises, the requirements for the correct use of respirators are not always met. Experts note that in practice it is difficult to achieve elimination of occupational morbidity with the help of respirators:

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BeardsEdit

Certain types of facial hair can reduce fit to a significant degree. For this reason, there are facial hair guidelines for respirator users.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Counterfeiting, modification, and revocation of regulated respiratorsEdit

Another disadvantage of respirators is that the onus is on the respirator user to determine if their respirator is counterfeit or has had its certification revoked.<ref name="counterfeit" /> Customers and employers can inadvertently purchase non-OEM parts for a NIOSH-approved respirator which void the NIOSH approval and violate OSHA laws, in addition to potentially compromising the fit of the respirator.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> Template:Wikisource-multi {{#invoke:Gallery|gallery}}

Issues with fit testingEdit

If respirators must be used, under 29 CFR 1910.134, OSHA requires respirator users to conduct a respirator fit test, with a safety factor of 10 to offset lower fit during real world use.<ref name="twonine">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> However, NIOSH notes the large amount of time required for fit testing has been a point of contention for employers.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Other opinions concern the change in performance of respirators in use compared to when fit testing, and compared to engineering control alternatives:

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Issues with respirator designEdit

Extended or off-label use of certain negative-pressure respirators, like a filtering facepiece respirator paired with a surgical mask,<ref name="npptl">"...as compared with FFRs without SM [surgical mask], higher average inhaled CO2 were observed in four of six workloads among FFRs with SM". Template:Cite journal</ref> can result in higher levels of carbon dioxide from dead space and breathing resistance (pressure drop) which can impact functioning and sometimes can exceed the PEL.<ref name="npptl" /><ref name="Roberge-2010">Template:Cite journal</ref><ref name="Смит">Template:Cite journal</ref> This effect was significantly reduced with powered air purifying respirators.<ref>Template:Cite journal</ref> In various surveys among healthcare workers, headaches,<ref>Template:Cite journal</ref> dermatitis and acne have been reported.<ref name="Goh-2006">Template:Cite journal</ref>

Complaints have been leveled at early LANL NIOSH fit test panels (which included primarily military personnel) as being unrepresentative of the broader American populace.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> However, later fit test panels, based on a NIOSH facial survey conducted in 2003, were able to reach 95% representation of working US population surveyed.<ref>Template:Cite journal</ref> Despite these developments, 42 CFR 84, the US regulation NIOSH follows for respirator approval, allows for respirators that don't follow the NIOSH fit test panel provided that: more than one facepiece size is provided, and no chemical cartridges are made available.<ref>§135, §198, and §205. {{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Issues with lack of regulationEdit

Respirators designed to non-US standards may not be subject to as much or any scrutiny:

• In China, under GB2626-2019, which includes standards like KN95, there is no procedure for fit testing.<ref>{{#invoke:citation/CS1|citation

|CitationClass=web }}</ref> Some jurisdictions allow for respirator filtration ratings lower than 95%, respirators which are not rated to prevent respiratory infection, asbestos, or other dangerous occupational hazards. These respirators are sometimes known as dust masks for their almost exclusive approval only against dust nuisances:

• In Europe, regulation allows for dust masks under FFP1, where 20% inward leakage is allowed, with a minimum filtration efficiency of 80%.<ref>{{#invoke:citation/CS1|citation

|CitationClass=web }}</ref>

• South Korea allows 20% filter leakage under KF80.

In the US, NIOSH noted that under standards predating the N95, 'Dust/Mist' rated respirators could not prevent the spread of TB.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

RegulationEdit

The choice and use of respirators in developed countries is regulated by national legislation. To ensure that employers choose respirators correctly, and perform high-quality respiratory protection programs, various guides and textbooks have been developed:

For standard filter classes used in respirators, see Mechanical filter (respirator)#Filtration standards.

Voluntary respirator useEdit

United StatesEdit

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See alsoEdit

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ReferencesEdit

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Works cited on this pageEdit

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Further readingEdit

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• A Sideline Mushroomed - Summary of LANL involvement in respirators
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• NIOSH-Approved Disposable Particulate Respirators (Filtering Facepieces)
• TSI Application note ITI-041: Mechanisms of Filtration for High Efficiency Fibrous Filters Template:Webarchive
• British Standard BS EN 143:2000: Respiratory protective devices – Particle filters – Requirements, testing, marking
• British Standard BS EN 149:2001: Respiratory protective devices – Filtering half masks to protect against particles – Requirements, testing, marking

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External linksEdit

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• Mine Safety Appliance Company (MSA) Respirator Classification Guide MSA.com
• OSHA videos on respiratory protection Template:Webarchive osha.gov

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