Flame retardant

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Open-flame tests compare the flammability of untreated polyurethane foam (top) and an identical foam sample surface treated with a sandwich-like coating incorporating layered double hydroxides. By 90 seconds after ignition the untreated foam is completely consumed. Flame Retardant Research - LDH materials (16241017250).jpg
Open-flame tests compare the flammability of untreated polyurethane foam (top) and an identical foam sample surface treated with a sandwich-like coating incorporating layered double hydroxides. By 90 seconds after ignition the untreated foam is completely consumed.

Flame retardants are a diverse group of chemicals that are added to manufactured materials, such as plastics and textiles, and surface finishes and coatings. [1] Flame retardants are activated by the presence of an ignition source and prevent or slow the further development of flames by a variety of different physical and chemical mechanisms. They may be added as a copolymer during the polymerisation process, or later added to the polymer at a moulding or extrusion process or (particularly for textiles) applied as a topical finish. [2] Mineral flame retardants are typically additive, while organohalogen and organophosphorus compounds can be either reactive or additive.

Contents

Classes

Both reactive and additive flame retardants types can be further separated into four distinct classes: [1]

Retardation mechanisms

The basic mechanisms of flame retardants vary depending on the specific flame retardant and the substrate. Additive and reactive flame-retardant chemicals can both function in the vapor (gaseous) or condensed (solid) phase. [1]

Endothermic degradation

Some compounds break down endothermically when subjected to high temperatures. Magnesium and aluminium hydroxides are an example, together with various carbonates and hydrates such as mixtures of huntite and hydromagnesite. [3] [6] [7] The reaction removes heat from the substrate, thereby cooling the material. The use of hydroxides and hydrates is limited by their relatively low decomposition temperature, which limits the maximum processing temperature of the polymers (typically used in polyolefins for wire and cable applications). [11] [12] [13]

Thermal shielding (solid phase)

A way to stop spreading of the flame over the material is to create a thermal insulation barrier between the burning and unburned parts. [14] Intumescent additives are often employed; their role is to turn the polymer surface into a char, which separates the flame from the material and slows the heat transfer to the unburned fuel. Non-halogenated inorganic and organic phosphate flame retardants typically act through this mechanism by generating a polymeric layer of charred phosphoric acid. [8]

Dilution of gas phase

Inert gases (most often carbon dioxide and water) produced by thermal degradation of some materials act as diluents of the combustible gases, lowering their partial pressures and the partial pressure of oxygen, and slowing the reaction rate. [5] [7]

Gas phase radical quenching

Chlorinated and brominated materials undergo thermal degradation and release hydrogen chloride and hydrogen bromide or, if used in the presence of a synergist like antimony trioxide, antimony halides. These react with the highly reactive H· and OH· radicals in the flame, resulting in an inactive molecule and a Cl· or Br· radical. The halogen radical is much less reactive compared to H· or OH·, and therefore has much lower potential to propagate the radical oxidation reactions of combustion.

Materials

Flame retardant cotton

Flame retardant cotton is often used in oven mitts, pot holders, and other heat-adjacent accessories. Baking glove.jpg
Flame retardant cotton is often used in oven mitts, pot holders, and other heat-adjacent accessories.

Flame retardant cotton is cotton that has been treated to prevent or slow ignition by different treatments applied during the manufacturing process. Cotton is typically made flame-resistant by chemical applications of polymeric, nonpolymeric, and polymeric/nonpolymeric hybrids that are composed of one or more of the elements such as nitrogen, sodium, phosphorus, silicon, boron, or chlorine. [15]

Manufacturing

While non-organic fabrics are typically made flame-resistant by incorporating flame retardants into their matrices, surface modification is more convenient for organic fabrics like cotton. [16]

Use

Cotton fabrics have been frequently used worldwide because of their advantageous properties with regard to thermal insulation, biocompatibility and moisture absorption and breathability performance. These advantages indicate potential applications of cotton fabrics in protective clothing [17] and human health. However, natural cotton fabric is flammable and will rapidly burn. This drawback limits the use of cotton fabrics. [18] Therefore, treating cotton fabrics to obtain a fire-resistant fabric is important. [19]

Firefighters, or those exposed to flames on a regular basis, rely on flame-retardant cotton for both protection and comfort. Typically, their undergarments beneath the heavier fire-resistant gear are made of flame-retardant cotton or another breathable, organic fabric that has been treated to resist ignition. [20]

Polymers containing nitrogen, sodium, and phosphorus atoms can work as materials for fire-resistant cellulosic textiles, such as cotton or rayon. Specifically, organic polymers can work as a flame retardant due to the presence of one or all three types of these elements. These atoms can be in the original polymers, or they can be incorporated by chemical modification. [15] Flame retardant materials and coatings are being developed that are phosphorus and bio-based. [21]

Use and effectiveness

Fire safety standards

Flame retardants are typically added to industrial and consumer products to meet flammability standards for furniture, textiles, electronics, and building products like insulation. [22]

U.S. state of California

In 1975, California began implementing Technical Bulletin 117 (TB 117), which requires that materials such as polyurethane foam used to fill furniture be able to withstand a small open flame, equivalent to a candle, for at least 12 seconds. [22] [23] In polyurethane foam, furniture manufacturers typically meet TB 117 with additive halogenated organic flame retardants. Although no other US states have a similar standard, because California has such a large market many manufacturers meet TB 117 in products that they distribute across the United States. The proliferation of flame retardants, and especially halogenated organic flame retardants, in furniture across the United States is strongly linked to TB 117.

In response to concerns about the health impacts of flame retardants in upholstered furniture, in February 2013 California proposed modifying TB 117 to require that fabric covering upholstered furniture meet a smolder test and to eliminate the foam flammability standards. [24] Gov. Jerry Brown signed the modified TB117-2013 in November and it became effective in 2014. [25] The modified regulation does not mandate a reduction in flame retardants.

EU

In Europe, flame retardant standards for furnishings vary, and are their most stringent in the UK and Ireland. [26] Generally the ranking of the various common flame retardant tests worldwide for furniture and soft furnishings would indicate that the California test Cal TB117 - 2013 test is the most straightforward to pass, there is increasing difficulty in passing Cal TB117 -1975 followed by the British test BS 5852 and followed by Cal TB133. [27] One of the most demanding flammability tests worldwide is probably the US Federal Aviation Authority test for aircraft seating which involves the use of a kerosene burner which blasts flame at the test piece. The 2009 Greenstreet Berman study, carried out by the UK government, showed that in the period between 2002 and 2007 the UK Furniture and Furnishings Fire Safety Regulations accounted for 54 fewer deaths per year, 780 fewer non-fatal casualties per year and 1065 fewer fires each year following the introduction of the UK furniture safety regulations in 1988. [28]

Effectiveness

The effectiveness of flame retardant chemicals at reducing the flammability of consumer products in house fires is disputed. Advocates for the flame retardant industry, such as the American Chemistry Council's North American Flame Retardant Alliance, cite a study from the National Bureau of Standards indicating that a room filled with flame-retarded products (a polyurethane foam-padded chair and several other objects, including cabinetry and electronics) offered a 15-fold greater time window for occupants to escape the room than a similar room free of flame retardants. [29] [30] However, critics of this position, including the lead study author, argue that the levels of flame retardant used in the 1988 study, while found commercially, are much higher than the levels required by TB 117 and used broadly in the United States in upholstered furniture. [22]

Another study concluded flame retardants are an effective tool to reduce fire risks without creating toxic emissions. [31]

Several studies in the 1980s tested ignition in whole pieces of furniture with different upholstery and filling types, including different flame retardant formulations. [32] In particular, they looked at maximum heat release and time to maximum heat release, two key indicators of fire danger. These studies found that the type of fabric covering had a large influence on ease of ignition, that cotton fillings were much less flammable than polyurethane foam fillings, and that an interliner material substantially reduced the ease of ignition. [33] [34] They also found that although some flame retardant formulations decreased the ease of ignition, the most basic formulation that met TB 117 had very little effect. [34] In one of the studies, foam fillings that met TB 117 had equivalent ignition times as the same foam fillings without flame retardants. [33] A report from the Proceedings of the Polyurethane Foam Association also showed no benefit in open-flame and cigarette tests with foam cushions treated with flame retardants to meet TB 117. [35] However, other scientists support this open-flame test. [36] [37]

Compared with cotton, flame retardants increase fire toxicity. They have a large effect on bench-scale flammability tests, but a negligible effect on large scale fire tests. Furniture of naturally flame-retardant materials is much safer than foam with fire retardants. [38]

Environmental and health issues

The environmental behaviour of flame retardants has been studied since the 1990s. Mainly brominated flame retardants were found in many environmental compartments and organisms including humans, and some individual substances were found to have toxic properties. Therefore, alternatives have been demanded by authorities, NGOs and equipment manufacturers. The EU-funded collaborative research project ENFIRO (EU research project FP7: 226563, concluded in 2012) started out from the assumption that not enough environmental and health data were known of alternatives to the established brominated flame retardants. In order to make the evaluation fully comprehensive, it was decided to compare also material and fire performance as well as attempt a life-cycle assessment of a reference product containing halogen free versus brominated flame retardants. About a dozen halogen free flame retardants were studied representing a large variety of applications, from engineering plastics, printed circuit boards, encapsulants to textile and intumescent coatings.

A large group of the studied flame retardants were found to have a good environmental and health profile: ammonium polyphosphate (APP), aluminium diethyl phosphinate (Alpi), aluminium hydroxide (ATH), magnesium hydroxide (MDH), melamine polyphosphate (MPP), dihydrooxaphosphaphenanthrene (DOPO), zinc stannate (ZS) and zinc hydroxstannate (ZHS). Overall, they were found to have a much lower tendency to bioaccumulate in fatty tissue than the studied brominated flame retardants.

The tests on the fire behaviour of materials with different flame retardants revealed that halogen free flame retardants produce less smoke and toxic fire emissions, with the exception of the aryl phosphates RDP and BDP in styrenic polymers. The leaching experiments showed that the nature of the polymer is a dominating factor and that the leaching behaviour of halogen free and brominated flame retardants is comparable. The more porous or “hydrophilic” a polymers is the more flame retardants can be released. However, moulded plates which represent real world plastic products showed much lower leaching levels than extruded polymer granules. The impact assessment studies reconfirmed that the improper waste and recycling treatment of electronic products with brominated flame retardants can produce dioxins which is not the case with halogen free alternatives. Furthermore, the United States Environmental Protection Agency (US EPA) has been carrying out a series of projects related to the environmental assessment of alternative flame retardants, the “design for environment” projects on flame retardants for printed wiring boards and alternatives to decabromodiphenyl ether and hexabromocyclododecane (HBCD).

In 2009, the US National Oceanic and Atmospheric Administration (NOAA) released a report on polybrominated diphenyl ethers (PBDEs) and found that, in contrast to earlier reports, they were found throughout the US coastal zone. [39] This nationwide survey found that New York's Hudson Raritan Estuary had the highest overall concentrations of PBDEs, both in sediments and shellfish. Individual sites with the highest PBDE measurements were found in shellfish taken from Anaheim Bay, California, and four sites in the Hudson Raritan Estuary. Watersheds that include the Southern California Bight, Puget Sound, the central and eastern Gulf of Mexico off the coast of Tampa and St. Petersburg, in Florida, and the waters of Lake Michigan near Chicago and Gary, Indiana, also were found to have high PBDE concentrations.

Health concerns

The earliest flame retardants, polychlorinated biphenyls (PCBs), were banned in the US in 1977 when it was discovered that they were toxic. [40] Industries used brominated flame retardants instead, but these are now receiving closer scrutiny. In 2004 and 2008 the EU banned several types of polybrominated diphenyl ethers (PBDEs). [41] Negotiations between the EPA and the two US producers of DecaBDE (a flame retardant that has been used in electronics, wire and cable insulation, textiles, automobiles and airplanes, and other applications), Albemarle Corporation and Chemtura Corporation, and the largest US importer, ICL Industrial Products, Inc., resulted in commitments by these companies to phase out decaBDE for most uses in the United States by December 31, 2012, and to end all uses by the end of 2013. [42] The state of California has listed the flame retardant chemical chlorinated Tris (tris(1,3-dichloro-2-propyl) phosphate or TDCPP) as a chemical known to cause cancer. [43] In December 2012, the California nonprofit Center for Environmental Health filed notices of intent to sue several leading retailers and producers of baby products [44] for violating California law for failing to label products containing this cancer-causing flame retardant. While the demand for brominated and chlorinated flame retardants in North America and Western Europe is declining, it is rising in all other regions. [45]

There is a potential association between the exposure to the Phosphorus Flame Retardants (PFR) in residential indoor dust and the development of allergies, asthma and dermatitis. A study was conducted in 2014 by Araki, A. et al. in Japan to assess this relationship. They found a significant association between the Tris (2-chloro-iso-propyl) phosphate (TCIPP) and atopic dermatitis with an odds ratio of 2.43. They also found that the Tributyl phosphate was associated with the development of allergic rhinitis and asthma with an odds ratio of 2.55 & 2.85 respectively. [46]

Another study conducted by Chevrier et al. 2010 [47] measured the concentration of 10 PBDE congeners, free thyroxine (T4), total T4, and thyroid-stimulating hormone (TSH) in 270 pregnant women around the 27th week of gestation. Associations between PBDEs and free and total T4 were found to be statistically insignificant. However, authors did find a significant association amongst exposure to PBDEs and lower TSH during pregnancy, which may have implications for maternal health and fetal development.

A prospective, longitudinal cohort study initiated after 11 September 2001, including 329 mothers who delivered in one of three hospitals in lower Manhattan, New York, was conducted by Herbstman et al. 2010. [48] Authors of this study analyzed 210 cord blood specimens for selected PBDE congeners and assessed neurodevelopmental effects in the children at 12–48 and 72 months of age. Results showed that children who had higher cord blood concentrations of polybrominated diphenyl ethers (PBDEs) scored lower on tests of mental and motor development at 1–4 and 6 years of age. This was the first study to report any such associations in humans.

A similar study was conducted by Roze et al. 2009 [49] in The Netherlands on 62 mothers and children to estimate associations between 12 Organohalogen compounds (OHCs), including polychlorinated biphenyls (PCBs) and brominated diphenyl ether (PBDE) flame retardants, measured in maternal serum during the 35th week of pregnancy and motor performance (coordination, fine motor skills), cognition (intelligence, visual perception, visuomotor integration, inhibitory control, verbal memory, and attention), and behavior scores at 5–6 years of age. Authors demonstrated for the first time that transplacental transfer of polybrominated flame retardants was associated with the development of children at school age.

Another study was conducted by Rose et al. in 2010 [50] to measure circulating PBDE levels in 100 children between 2 and 5 years of age from California. The PBDE levels according to this study, in 2- to 5-year-old California children was 10 to 1,000 fold higher than European children, 5 times higher than other US children and 2 to 10 times higher than US adults. They also found that diet, indoor environment, and social factors influenced children's body burden levels. Eating poultry and pork contributed to elevated body burdens for nearly all types of flame retardants. Study also found that lower maternal education was independently and significantly associated with higher levels of most flame retardant congeners in the children.

San Antonio Statement on Brominated and Chlorinated Flame Retardants 2010: [51] A group of 145 prominent scientists from 22 countries signed the first-ever consensus statement documenting health hazards from flame retardant chemicals found at high levels in home furniture, electronics, insulation, and other products. This statement documents that, with limited fire safety benefit, these flame retardants can cause serious health issues, and, as types of flame retardants are banned, the alternatives should be proven safe before being used. The group also wants to change widespread policies that require use of flame retardants.

Mechanisms of toxicity

Direct exposure

Many halogenated flame retardants with aromatic rings, including most brominated flame retardants, are likely thyroid hormone disruptors. [22] The thyroid hormones triiodothyronine (T3) and thyroxine (T4) carry iodine atoms, another halogen, and are structurally similar to many aromatic halogenated flame retardants, including PCBs, TBBPA, and PBDEs. Such flame retardants therefore appear to compete for binding sites in the thyroid system, interfering with normal function of thyroid transport proteins (such as transthyretin) in vitro [52] and thyroid hormone receptors. A 2009 in vivo animal study conducted by the US Environmental Protection Agency (EPA) demonstrated that deiodination, active transport, sulfation, and glucuronidation may be involved in disruption of thyroid homeostasis after perinatal exposure to PBDEs during critical developmental time points in utero and shortly after birth. [53] Disruption of deiodinase as reported in the Szabo et al., 2009 in vivo study was supported in a follow-up in vitro study. [54] The adverse effects on hepatic mechanism of thyroid hormone disruption during development have been shown to persist into adulthood. The EPA noted that PBDEs are particularly toxic to the developing brains of animals. Peer-reviewed studies have shown that even a single dose administered to mice during development of the brain can cause permanent changes in behavior, including hyperactivity.

Based on in vitro laboratory studies, several flame retardants, including PBDEs, TBBPA, and BADP, likely also mimic other hormones, including estrogens, progesterone, and androgens. [22] [55] Bisphenol A compounds with lower degrees of bromination seem to exhibit greater estrogenicity. [56] Some halogenated flame retardants, including the less-brominated PBDEs, can be direct neurotoxicants in in vitro cell culture studies: By altering calcium homeostasis and signalling in neurons, as well as neurotransmitter release and uptake at synapses, they interfere with normal neurotransmission. [55] Mitochondria may be particularly vulnerable to PBDE toxicity due to their influence on oxidative stress and calcium activity in mitochondria. [55] Exposure to PBDEs can also alter neural cell differentiation and migration during development. [55]

Degradation products

Many flame retardants degrade into compounds that are also toxic, and in some cases the degradation products may be the primary toxic agent:

  • Halogenated compounds with aromatic rings can degrade into dioxins and dioxin-like compounds, particularly when heated, such as during production, a fire, recycling, or exposure to sun. [22] Chlorinated dioxins are among the highly toxic compounds listed by the Stockholm Convention on Persistent Organic Pollutants.
  • Polybrominated diphenyl ethers with higher numbers of bromine atoms, such as decaBDE, are less toxic than PBDEs with lower numbers of bromine atoms, such as pentaBDE. [57] However, as the higher-order PBDEs degrade biotically or abiotically, bromine atoms are removed, resulting in more toxic PBDE congeners. [58] [59]
  • When some halogenated flame retardants such as PBDEs are metabolized, they form hydroxylated metabolites that can be more toxic than the parent compound. [52] [56] These hydroxylated metabolites, for example, may compete more strongly to bind with transthyretin or other components of the thyroid system, can be more potent estrogen mimics than the parent compound, and can more strongly affect neurotransmitter receptor activity. [52] [55] [56]
  • Bisphenol-A diphenyl phosphate (BADP) and tetrabromobisphenol A (TBBPA) likely degrade to bisphenol A (BPA), an endocrine disruptor of concern. [60] [61]

Routes of exposure

People can be exposed to flame retardants through several routes, including diet; consumer products in the home, vehicle, or workplace; occupation; or environmental contamination near their home or workplace. [62] [63] [64] Residents in North America tend to have substantially higher body levels of flame retardants than people who live in many other developed areas, and around the world human body levels of flame retardants have increased over the last 30 years. [65]

Exposure to PBDEs has been studied the most widely. [22] As PBDEs have been phased out of use due to health concerns, organophosphorus flame retardants, including halogenated organophosphate flame retardants, have frequently been used to replace them. In some studies, indoor air concentrations of phosphorus flame retardants has been found to be greater than indoor air concentrations of PBDEs. [8] The European Food Safety Authority (EFSA) issued in 2011 scientific opinions on the exposure to HBCD and TBBPA and its derivates in food and concluded that current dietary exposure in the European Union does not raise a health concern. [66] [67]

Exposure in the general population

The body burden of PBDEs in Americans correlates well with the level of PBDEs measured in swabs of their hands, likely picked up from dust. [68] [69] Dust exposure may occur in the home, car, or workplace. Levels of PBDEs can be as much as 20 times higher in vehicle dust as in household dust, and heating of the vehicle interior on hot summer days can break down flame retardants into more toxic degradation products. [70] However, blood serum levels of PBDEs appear to correlate most highly with levels found in dust in the home. [69] 60-80% of exposures are due to dust inhalation or ingestion. [71] [72] In addition to this, 20% to 40% of US adult exposure to PBDEs is through food intake as PBDEs bioaccumulate in the food chain. High concentration can be found in meat, dairy and fish [73] with the remaining exposure largely due to dust inhalation or ingestion. [71] [72] Individuals can also be exposed through electronic and electrical devices. [74] Young children in the United States tend to carry higher levels of flame retardants per unit body weight than do adults. [75] [76] Infants and toddlers are particularly exposed to halogenated flame retardants found in breast milk and dust. Because many halogenated flame retardants are fat-soluble, they accumulate in fatty areas such as breast tissue and are mobilized into breast milk, delivering high levels of flame retardants to breast-feeding infants. [72] PBDEs also cross the placenta, meaning infants are exposed in utero. [77] Mothers thyroid hormone (T4) level can be disrupted [78] and exposure in utero in rat studies has been demonstrated to alter motor control, delay sensory development and puberty. [79]

Another reason for high levels of exposure in young children are due to aging consumer products age, small particles of material become dust particles in the air and land on surfaces around the home, including the floor. Young children crawling and playing on the floor frequently bring their hands to their mouths, ingesting about twice as much house dust as adults per day in the United States. [80] Children also have a higher food intake per kilogram of bodyweight compared to adults. Young children are also exposed to flame retardants through their clothing, car seats and toys. The introduction of these chemicals came about after the tragic death of children wearing brushed rayon fabric that would ignite easily. The US enacted the Flammable Fabrics Act passed in 1953 after which, flame retardants were mandated to be added to many children's items, including pajamas. While flame retardants are shown to decrease the risk of burn injuries in children, the risks of thyroid disruption as well as physical and cognitive developmental delays, are not outweighed.

A study was conducted by Carignan in 2013, C. et al. found that gymnasts are exposed to some flame-retardant products such as PentaBDE and TBB more than the general population in the United States. After testing hand-wipe samples before and after the exercise, they found that the BDE-153 concentration was four to over six times greater among gymnasts than the United States population. Also, the PentaBDE concentration was higher up to three times after exercise compared to the level before; indicating a higher level of the flame-retardants on the training equipment. Moreover, they also found several flame-retardant products with different concentrations in the air and dust that were higher in the gym than residencies. [81] However, the study was performed on a small sample size; and further studies are recommended to assess the association.

Occupational exposure

Some occupations expose workers to higher levels of halogenated flame retardants and their degradation products. A small study of US foam recyclers and carpet installers, who handle padding often made from recycled polyurethane foam, showed elevated levels of flame retardants in their tissues. [64] Workers in electronics recycling plants around the world also have elevated body levels of flame retardants relative to the general population. [74] [82] Environmental controls can substantially reduce this exposure, [83] whereas workers in areas with little oversight can take in very high levels of flame retardants. Electronics recyclers in Guiyu, China, have some of the highest human body levels of PBDEs in the world. [74] A study conducted in Finland determined the occupational exposure of workers to brominated flame retardants and chlorinated flame retardants (TBBPA, PBDEs, DBDPE, HBCD, Hexabromobenzene and Dechlorane plus). In 4 recycling sites of waste electrical and electronic equipment (WEEE), the study concluded that control measures implemented on site significantly reduced the exposure. [84] Workers making products that contain flame retardants (such as vehicles, electronics, and baby products) may be similarly exposed. [85] US firefighters can have elevated levels of PBDEs and high levels of brominated furans, toxic degradation products of brominated flame retardants. [86]

Environmental exposure

Flame retardants manufactured for use in consumer products have been released into environments around the world. The flame retardant industry has developed a voluntary initiative to reduce emissions to the environment (VECAP) [87] by promoting best practices during the manufacturing process. Communities near electronics factories and disposal facilities, especially areas with little environmental oversight or control, develop high levels of flame retardants in air, soil, water, vegetation, and people. [85] [88]

Organophosphorus flame retardants have been detected in wastewater in Spain and Sweden, and some compounds do not appear to be removed thoroughly during water treatment. [89] [90] Organophosphorus flame-retardants were also found in tap and bottled drinking water in China. [91] Likewise in the Elbe river in Germany. [92]

Disposal

When products with flame retardants reach the end of their usable life, they are typically recycled, incinerated, or landfilled. [22]

Recycling can contaminate workers and communities near recycling plants, as well as new materials, with halogenated flame retardants and their breakdown products. Electronic waste, vehicles, and other products are often melted to recycle their metal components, and such heating can generate toxic dioxins and furans. [22] When wearing Personal Protection Equipment (PPE) and when a ventilation system is installed, exposure of workers to dust can be significantly reduced, as shown in the work conducted by the recycling plant Stena-Technoworld AB in Sweden. [93] Brominated flame retardants may also change the physical properties of plastics, resulting in inferior performance in recycled products and in “downcycling” of the materials. It appears that plastics with brominated flame retardants are mingling with flame-retardant-free plastics in the recycling stream and such downcycling is taking place. [22]

Poor-quality incineration similarly generates and releases high quantities of toxic degradation products. Controlled incineration of materials with halogenated flame retardants, while costly, substantially reduces release of toxic byproducts. [22]

Many products containing halogenated flame retardants are sent to landfills. [22] Additive, as opposed to reactive, flame retardants are not chemically bonded to the base material and leach out more easily. Brominated flame retardants, including PBDEs, have been observed leaching out of landfills in industrial countries, including Canada and South Africa. Some landfill designs allow for leachate capture, which would need to be treated. These designs also degrade with time. [22]

Regulatory opposition

Shortly after California amended TB117 in 2013 to require only flame-resistant furniture coverings (without restriction on the interior components), furniture manufacturers across the US heard increased demands for flame-retardant-free furniture. Of note, smolder-resistant fabrics used in flame-resistant coverings do not contain PBDEs, organophosphates, or other chemicals historically associated with adverse effects on human health. A number of decision-makers in the health sector - which accounts for nearly 18% of the US GDP [92] - are committed to purchasing such materials and furniture. Early adopters of this policy included Kaiser Permanente, Advocate Health Care, Hackensack University Hospital, and University Hospitals. All together, furniture purchasing power of these hospitals totalled $50 million. [94] All of these hospitals and hospital systems ascribe to the Healthier Hospitals Initiative, which has over 1300 member hospitals, and promotes environmental sustainability and community health within the healthcare industry.

Further legislation in California has served to educate the public about flame retardants in their homes, in effect reducing consumer demand for products containing these chemicals. According to a law (Senate Bill, 1019) signed by Governor Jerry Brown in 2014, all furniture manufactured after January 1, 2015 must contain a consumer warning label stating whether it does or does not contain flame retardant chemicals [94]

As of September 2017, the topic reached federal regulatory attention in the Consumer Product Safety Commission, which voted to put together a Chronic Hazard Advisory Panel focused on describing certain risks of various consumer products, specifically baby and childcare products (including bedding and toys), upholstered home furniture, mattresses and mattresses and mattress pads, and plastic casings surrounding electronics. This advisory panel is charged specifically to address the risks of additive, non-polymeric organohalogen flame retardants (OFRs). Although these chemicals have not been banned, this ruling sets in motion an in-depth consumer safety investigation which could eventually lead to complete removal of these substances from consumer manufacturing. [95]

Pursuant with the Toxic Substances Control Act of 1976, the Environmental Protection Agency is also actively evaluating the safety of various flame retardants, including chlorinated phosphate esters, tetrabromobisphenol A, cyclic aliphatic bromides, and brominated phthalates. [96] Further regulations depend on EPA findings from this analysis, though any regulatory processes could take several years.

National Bureau of Standards testing

In a 1988 test program, conducted by the former National Bureau of Standards (NBS), now the National Institute of Standards and Technology (NIST), to quantify the effects of fire retardant chemicals on total fire hazard. Five different types of products, each made from a different type of plastic were used. The products were made up in analogous fire-retardant (FR) and non-retarded variants (NFR). [97]

The impact of FR (flame retardant) materials on the survivability of the building occupants was assessed in two ways:

First, comparing the time until a domestic space is not fit for occupation in the burning room, known as "untenability"; this is applicable to the occupants of the burning room. Second, comparing the total production of heat, toxic gases, and smoke from the fire; this is applicable to occupants of the building remote from the room of fire origin. [97]

The time to untenability is judged by the time that is available to the occupants before either (a) room flashover occurs, or (b) untenability due to toxic gas production occurs. For the FR tests, the average available escape time was more than 15-fold greater than for the occupants of the room without fire retardants.

Hence, with regard to the production of combustion products, [97]

Thus, in these tests, the fire retardant additives decreased the overall fire hazard. [97]

Global demand

In 2013, the world consumption of flame retardants was more than 2 million tonnes. The commercially most import application area is the construction sector. It needs flame retardants for instance for pipes and cables made of plastics. [45] In 2008 the United States, Europe and Asia consumed 1.8 million tonnes, worth US$4.20-4.25 billion. According to Ceresana, the market for flame retardants is increasing due to rising safety standards worldwide and the increased use of flame retardants. It is expected that the global flame retardant market will generate US$5.8 billion. In 2010, Asia-Pacific was the largest market for flame retardants, accounting for approximately 41% of global demand, followed by North America, and Western Europe. [98]

See also

Related Research Articles

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<span class="mw-page-title-main">Organophosphate</span> Organic compounds with the structure O=P(OR)3

In organic chemistry, organophosphates are a class of organophosphorus compounds with the general structure O=P(OR)3, a central phosphate molecule with alkyl or aromatic substituents. They can be considered as esters of phosphoric acid. Organophosphates are best known for their use as pesticides.

A bromide ion is the negatively charged form (Br) of the element bromine, a member of the halogens group on the periodic table. Most bromides are colorless. Bromides have many practical roles, being found in anticonvulsants, flame-retardant materials, and cell stains. Although uncommon, chronic toxicity from bromide can result in bromism, a syndrome with multiple neurological symptoms. Bromide toxicity can also cause a type of skin eruption, see potassium bromide. The bromide ion has an ionic radius of 196 pm.

Brominated flame retardants (BFRs) are organobromine compounds that have an inhibitory effect on combustion chemistry and tend to reduce the flammability of products containing them. The brominated variety of commercialized chemical flame retardants comprise approximately 19.7% of the market. They are effective in plastics and textile applications like electronics, clothes, and furniture.

<span class="mw-page-title-main">Polybrominated biphenyl</span> Group of chemical compounds

Polybrominated biphenyls (PBBs), also called brominated biphenyls or polybromobiphenyls, are a group of manufactured chemicals that consist of polyhalogenated derivatives of a biphenyl core. Their chlorine analogs are the PCBs. While once widely used commercially, PBBs are now controlled substances under the Restriction of Hazardous Substances Directive, which limits their use in electrical and electronic products sold in the EU.

<span class="mw-page-title-main">Fire retardant</span> Substance reducing flammability

A fire retardant is a substance that is used to slow down or stop the spread of fire or reduce its intensity. This is commonly accomplished by chemical reactions that reduce the flammability of fuels or delay their combustion. Fire retardants may also cool the fuel through physical action or endothermic chemical reactions. Fire retardants are available as powder, to be mixed with water, as fire-fighting foams and fire-retardant gels. Fire retardants are also available as coatings or sprays to be applied to an object.

<span class="mw-page-title-main">Decabromodiphenyl ether</span> Chemical compound

Decabromodiphenyl ether is a brominated flame retardant which belongs to the group of polybrominated diphenyl ethers (PBDEs). It was commercialised in the 1970s and was initially thought to be safe, but is now recognised as a hazardous and persistent pollutant. It was added to Annex A of the Stockholm Convention on Persistent Organic Pollutants in 2017, which means that treaty members must take measures to eliminate its production and use. The plastics industry started switching to decabromodiphenyl ethane as an alternative in the 1990s, but this is now also coming under regulatory pressure due to concerns over human health.

Pentabromodiphenyl ether is a brominated flame retardant which belongs to the group of polybrominated diphenyl ethers (PBDEs). Because of their toxicity and persistence, their industrial production is to be eliminated under the Stockholm Convention, a treaty to control and phase out major persistent organic pollutants (POP).

Octabromodiphenyl ether is a brominated flame retardant which belongs to the group of polybrominated diphenyl ethers (PBDEs).

<span class="mw-page-title-main">Tetrabromobisphenol A</span> Chemical compound

Tetrabromobisphenol A (TBBPA) is a brominated flame retardant. The compound is a white solid, although commercial samples appear yellow. It is one of the most common flame retardants.

<span class="mw-page-title-main">Triphenyl phosphate</span> Chemical compound

Triphenyl phosphate (TPhP) is the chemical compound with the formula OP(OC6H5)3. It is the simplest aromatic organophosphate. This colourless solid is the ester (triester) of phosphoric acid and phenol. It is used as a plasticizer and a fire retardant in a wide variety of settings and products.

Organobromine chemistry is the study of the synthesis and properties of organobromine compounds, also called organobromides, which are organic compounds that contain carbon bonded to bromine. The most pervasive is the naturally produced bromomethane.

A polyhalogenated compound (PHC) is any compound with multiple substitutions of halogens. They are of particular interest and importance because they bioaccumulate in humans, and comprise a superset of which has many toxic and carcinogenic industrial chemicals as members. PBDEs, PCBs, dioxins (PCDDs) and PFCs are all polyhalogenated compounds. They are generally non-miscible in organic solvents or water, but miscible in some hydrocarbons from which they often derive.

<span class="mw-page-title-main">Tris(1,3-dichloro-2-propyl)phosphate</span> Chemical compound

Tris(1,3-dichloroisopropyl)phosphate (TDCPP) is a chlorinated organophosphate. Organophosphate chemicals have a wide variety of applications and are used as flame retardants, pesticides, plasticizers, and nerve gases. TDCPP is structurally similar to several other organophosphate flame retardants, such as tris(2-chloroethyl) phosphate (TCEP) and tris(chloropropyl)phosphate (TCPP). TDCPP and these other chlorinated organophosphate flame retardants are all sometimes referred to as "chlorinated tris".

<span class="mw-page-title-main">Susan Shaw (conservationist)</span> American scientist, explorer, conservationist, author (1943–2022)

Susan D. Shaw was an American environmental health scientist, marine toxicologist, explorer, ocean conservationist, and author. A Doctor of Public Health, she was a professor in the Department of Environmental Health Sciences at the School of Public Health at the State University of New York at Albany, and Founder/President of the Shaw Institute, a nonprofit scientific institution with a mission to improve human and ecological health through innovative science and strategic partnerships. Shaw is globally recognized for pioneering high-impact environmental research on ocean pollution, climate change, oil spills, and plastics that has fueled public policy over three decades. In 1983, with landscape photographer Ansel Adams, she published Overexposure, the first book to document the health hazards of photographic chemicals. Shaw is credited as the first scientist to show that brominated flame retardant chemicals used in consumer products have contaminated marine mammals and commercially important fish stocks in the northwest Atlantic Ocean. She became the first scientist to dive into the Gulf of Mexico oil slick following the 2010 BP Deepwater Horizon oil rig explosion to investigate the impacts of chemical dispersants used in response to the spill.

The Shaw Institute, formerly the Marine & Environmental Research Institute, is a 501(c)(3) nonprofit scientific research organization based in Blue Hill, Maine and New York City. The institute conducts research into ocean pollution, flame retardants, microplastics and plastic pollution, sentinel species and climate change.

<span class="mw-page-title-main">Decabromodiphenyl ethane</span> Chemical compound

Decabromodiphenyl ethane is a chemical compound used as a brominated flame retardant. It was commercialised in the 1990s as an alternative for decabromodiphenyl ether, following safety concern over that compound. The two molecules are chemically very similar, which gives them a similar application profile. Decabromodiphenyl ethane is now also coming under regulatory pressure.

<span class="mw-page-title-main">Bis(2-ethylhexyl)tetrabromophthalate</span> Chemical compound

Bis(2-ethylhexyl)tetrabromophthalate (or TBPH), is a brominated phthalate derivative with the formula C24H34Br4O4 commonly used as a brominated flame retardant (BFR).

<span class="mw-page-title-main">Tetrabromobisphenol A diglycidyl ether</span> Chemical compound

Tetrabromobisphenol A diglycidyl ether is an epoxy resin consisting of tetrabromobisphenol A with ether linkages to two epichlorohydrin groups. An alernative structural comparison is as brominated form of bisphenol A diglycidyl ether. It is a brominated aromatic chemical used principally for giving flame retardant properties to materials. It is TSCA and REACH registered and has the molecular formula C21H20Br4O4. The IUPAC name is 2-{[2,6-dibromo-4-(2-{3,5-dibromo-4-[(oxiran-2-yl)methoxy]phenyl}propan-2-yl)phenoxy]methyl}oxirane.

References

  1. 1 2 3 Beard, Adrian; Battenberg, Christian; Sutker, Burton J. (2021). "Flame Retardants". Ullmann's Encyclopedia of Industrial Chemistry. pp. 1–26. doi:10.1002/14356007.a11_123.pub2. ISBN   9783527303854. S2CID   261178139.
  2. U.S. Environmental Protection Agency (2005). Environmental Profiles of Chemical Flame-Retardant Alternatives for Low-Density Polyurethane Foam (Report). EPA 742-R-05-002A. Archived from the original on 2013-10-18. Retrieved 2013-04-04.
  3. 1 2 Hollingbery, LA; Hull TR (2010). "The Thermal Decomposition of Huntite and Hydromagnesite". Thermochimica Acta. 509 (1–2): 1–11. doi:10.1016/j.tca.2010.06.012. Archived from the original on 2015-04-03. Retrieved 2013-05-14.
  4. Hollingbery, LA; Hull TR (2010). "The Fire Retardant Behaviour of Huntite and Hydromagnesite - A Review". Polymer Degradation and Stability. 95 (12): 2213–2225. doi:10.1016/j.polymdegradstab.2010.08.019. Archived from the original on 2015-06-27. Retrieved 2013-05-22.
  5. 1 2 Hollingbery, LA; Hull TR (2012). "The Fire Retardant Effects of Huntite in Natural Mixtures with Hydromagnesite". Polymer Degradation and Stability. 97 (4): 504–512. doi:10.1016/j.polymdegradstab.2012.01.024. Archived from the original on 2012-07-13. Retrieved 2013-05-14.
  6. 1 2 Hollingbery, LA; Hull TR (2012). "The Thermal Decomposition of Natural Mixtures of Huntite and Hydromagnesite". Thermochimica Acta. 528: 45–52. Bibcode:2012TcAc..528...45H. doi:10.1016/j.tca.2011.11.002. Archived from the original on 2014-10-16. Retrieved 2013-05-14.
  7. 1 2 3 Hull, TR; Witkowski A; Hollingbery LA (2011). "Fire Retardant Action of Mineral Fillers". Polymer Degradation and Stability. 96 (8): 1462–1469. doi:10.1016/j.polymdegradstab.2011.05.006. S2CID   96208830. Archived from the original on 2014-03-28. Retrieved 2013-05-14.
  8. 1 2 3 4 van der Veen, I; de Boer, J (2012). "Phosphorus flame retardants: Properties, production, environmental occurrence, toxicity and analysis". Chemosphere. 88 (10): 1119–1153. Bibcode:2012Chmsp..88.1119V. doi:10.1016/j.chemosphere.2012.03.067. PMID   22537891.
  9. Weil, ED; Levchik, SV (2015). Flame Retardants for Plastics and Textiles: Practical Applications. Munich: Carl Hanser Verlag. p. 97. ISBN   978-1569905784. Archived from the original on 2024-08-08. Retrieved 2016-10-28.
  10. Wu X, Yang CQ (2009). "Flame Retardant Finishing of Cotton Fleece Fabric: Part IV-Bifunctional Carboxylic Acids". Journal of Fire Sciences. 27 (5): 431–446. doi:10.1177/0734904109105511. S2CID   95209119.
  11. "What is polymer degradation?". Coolmag. 2022-03-09. Archived from the original on 2023-10-30. Retrieved 2023-10-25.
  12. Fredi, Giulia; Dorigato, Andrea; Fambri, Luca; Lopez-Cuesta, José-Marie; Pegoretti, Alessandro (2019-01-01). "Synergistic effects of metal hydroxides and fumed nanosilica as fire retardants for polyethylene". Flame Retardancy and Thermal Stability of Materials. 2 (1): 30–48. doi: 10.1515/flret-2019-0004 . hdl: 11572/280010 . ISSN   2391-5404.
  13. Dorigato, Andrea; Fredi, Giulia; Fambri, Luca; Lopez-Cuesta, José-Marie; Pegoretti, Alessandro (2019). "Polyethylene-based single polymer laminates: Synergistic effects of nanosilica and metal hydroxides". Journal of Reinforced Plastics and Composites. 38 (2): 62–73. doi:10.1177/0731684418802974. ISSN   0731-6844. S2CID   139604028.
  14. "Tecmos | Un enfoque sustentable a los actuales desafíos globales" (PDF). Archived (PDF) from the original on 2023-10-30. Retrieved 2023-10-24.
  15. 1 2 "Cotton-based flame-retardant textiles: A review :: BioResources". bioresources.cnr.ncsu.edu. Archived from the original on 2022-01-20. Retrieved 2021-10-15.
  16. Li, Ping; Wang, Bin; Xu, Ying-Jun; Jiang, Zhiming; Dong, Chaohong; Liu, Yun; Zhu, Ping (2019-10-29). "Ecofriendly Flame-Retardant Cotton Fabrics: Preparation, Flame Retardancy, Thermal Degradation Properties, and Mechanism". ACS Sustainable Chemistry & Engineering. 7 (23): 19246–19256. doi:10.1021/acssuschemeng.9b05523. ISSN   2168-0485. S2CID   208749600. Archived from the original on 2024-08-08. Retrieved 2021-12-17.
  17. "How Flame Resistant Clothing Saved an Army Apache Pilot". Massif. Archived from the original on 2023-12-21. Retrieved 2023-12-21.
  18. Trovato, Valentina; Sfameni, Silvia; Ben Debabis, Rim; Rando, Giulia; Rosace, Giuseppe; Malucelli, Giulio; Plutino, Maria Rosaria (2023). "How to Address Flame-Retardant Technology on Cotton Fabrics by Using Functional Inorganic Sol–Gel Precursors and Nanofillers: Flammability Insights, Research Advances, and Sustainability Challenges". Inorganics. 11 (7): 306. doi: 10.3390/inorganics11070306 . hdl: 10446/261135 .
  19. Yu, Zhicai; Suryawanshi, Abhijeet; He, Hualing; Liu, Jinru; Li, Yongquan; Lin, Xuebo; Sun, Zenghui (2020-06-01). "Preparation and characterisation of fire-resistant PNIPAAm/SA/AgNP thermosensitive network hydrogels and laminated cotton fabric used in firefighter protective clothing". Cellulose. 27 (9): 5391–5406. doi:10.1007/s10570-020-03146-1. ISSN   1572-882X. S2CID   214808883. Archived from the original on 2024-08-08. Retrieved 2021-12-17.
  20. Sun, G.; Yoo, H.S.; Zhang, X.S.; Pan, N. (2000-07-01). "Radiant Protective and Transport Properties of Fabrics Used by Wildland Firefighters". Textile Research Journal. 70 (7): 567–573. doi:10.1177/004051750007000702. ISSN   0040-5175. S2CID   136928775. Archived from the original on 2024-08-08. Retrieved 2021-12-17.
  21. Naiker, Vidhukrishnan E.; Mestry, Siddhesh; Nirgude, Tejal; Gadgeel, Arjit; Mhaske, S. T. (2023-01-01). "Recent developments in phosphorous-containing bio-based flame-retardant (FR) materials for coatings: an attentive review". Journal of Coatings Technology and Research. 20 (1): 113–139. doi:10.1007/s11998-022-00685-z. ISSN   1935-3804. S2CID   253349703. Archived from the original on 2023-07-24. Retrieved 2023-02-15.
  22. 1 2 3 4 5 6 7 8 9 10 11 12 13 Shaw, S.; Blum, A.; Weber, R.; Kannan, K.; Rich, D.; Lucas, D.; Koshland, C.; Dobraca, D.; Hanson, S.; Birnbaum, L. (2010). "Halogenated flame retardants: do the fire safety benefits justify the risks?". Reviews on Environmental Health. 25 (4): 261–305. doi:10.1515/REVEH.2010.25.4.261. PMID   21268442. S2CID   20573319.
  23. Technical Bulletin 117: Requirements, test procedure and apparatus for testing the flame retardance of resilient filling (PDF) (Report). California Department of Consumer Affairs, Bureau of Home Furnishings. 2000. pp. 1–8. Archived from the original (PDF) on 2014-06-11.
  24. "Notice of Proposed New Flammability Standards for Upholstered Furniture/Articles Exempt from Flammability Standards". Department of Consumer Affairs, Bureau of Electronic and Appliance Repair, Home Furnishings and Thermal Insulation. Archived from the original on 2013-05-24.
  25. "Calif. law change sparks debate over use of flame retardants in furniture". PBS Newshour. 2014-01-01. Archived from the original on 2017-08-24. Retrieved 2014-11-01.
  26. Guillame, E.; Chivas, C.; Sainrat, E. (2000). Regulatory issues and flame retardant usage in upholstered furniture in Europe (PDF) (Report). Fire Behaviour Division. pp. 38–48. Archived from the original (PDF) on 2011-05-25. Retrieved 2013-04-12.
  27. "Archived copy" (PDF). Archived (PDF) from the original on 2023-10-30. Retrieved 2023-10-24.{{cite web}}: CS1 maint: archived copy as title (link)
  28. A statistical report to investigate the effectiveness of the Furniture and Furnishings (Fire) (Safety) Regulations 1988 (PDF) (Report). Greenstreet Berman Ltd. December 2009. Archived from the original (PDF) on 2013-10-08. Retrieved 2014-10-26. The study was carried out for the UK Department of Business and Innovation skills (BIS).
  29. North American Flame Retardant Alliance. "Do flame retardants work?". Archived from the original on 2013-04-28. Retrieved 2013-04-12.
  30. Babrauskas, V.; Harris, R.; Gann, R.; Levin, B.; Lee, B.; Peacock, R.; Paabo, M.; Twilley, W.; Yoklavich, M.; Clark, H. (1988). NBS Special Publication 749: Fire hazard comparison of fire-retarded and non-fire-retarded products (Report). National Bureau of Standards, Center for Fire Research, Fire Measurement and Research Division. pp. 1–86. Archived from the original on 2013-11-13. Retrieved 2013-04-12.
  31. Blais, Matthew (2013). "Flexible Polyurethane Foams: A Comparative Measurement of Toxic Vapors and Other Toxic Emissions in Controlled Combustion Environments of Foams With and Without Fire Retardants". Fire Technology. 51: 3–18. doi: 10.1007/s10694-013-0354-5 .
  32. "Archived copy" (PDF). Archived (PDF) from the original on 2023-08-04. Retrieved 2023-10-24.{{cite web}}: CS1 maint: archived copy as title (link)
  33. 1 2 Babrauskas, V. (1983). "Upholstered furniture heat release rates: Measurements and estimation". Journal of Fire Sciences. 1: 9–32. doi:10.1177/073490418300100103. S2CID   110464108. Archived from the original on 2013-11-13. Retrieved 2013-04-12.
  34. 1 2 Schuhmann, J.; Hartzell, G. (1989). "Flaming combustion characteristics of upholstered furniture". Journal of Fire Sciences. 7 (6): 386–402. doi:10.1177/073490418900700602. S2CID   110263531.
  35. Talley, Hugh. "Phase 1, UFAC Open Flame Tests". Polyurethane Foam Association. Archived from the original on 2014-10-26. Retrieved 2013-04-12.
  36. "Key Facts: The Need for an Open Flame Test". Archived from the original on 2014-10-26.
  37. "Viewpoints: State flammability rule change poses a fiery risk to consumers - Viewpoints - the Sacramento Bee". Archived from the original on 2013-06-09. Retrieved 2014-10-26.
  38. McKenna, Sean T.; Birtles, Robert; Dickens, Kathryn; Walker, Richard G.; Spearpoint, Michael J.; Stec, Anna A.; Hull, T. Richard (2018). "Flame retardants in UK furniture increase smoke toxicity more than they reduce fire growth rate" (PDF). Chemosphere. 196: 429–439. Bibcode:2018Chmsp.196..429M. doi:10.1016/j.chemosphere.2017.12.017. PMID   29324384. Archived (PDF) from the original on 2024-02-17. Retrieved 2024-01-24.
  39. NOAA. (2009). An Assessment of Polybrominated Diphenyl Ethers (PBDEs) in Sediments and Bivalves of the U.S. Coastal Zone. Free full text Archived 2010-05-27 at the Wayback Machine . Press release. Archived May 27, 2010, at the Wayback Machine
  40. "ToxFAQs™ for Polychlorinated Biphenyls (PCBs)". Agency for Toxic Substances and Disease Registry. CDC.gov. July 2014. Archived from the original on 2024-02-26. Retrieved 2023-12-29.
  41. Betts, KS (May 2008). "New thinking on flame retardants". Environ. Health Perspect. 116 (5): A210–3. doi:10.1289/ehp.116-a210. PMC   2367656 . PMID   18470294.
  42. U.S. Environmental Protection Agency. 2010. DecaBDE Phase-out Initiative. Available: EPA.gov Archived 2010-01-18 at the Wayback Machine
  43. "tris(1,3-dichloro-2-propyl) phosphate (TDCPP) Listed Effective October 28, 2011 as Known to the State to Cause Cancer". oehha.ca.gov. Archived from the original on 2012-11-08. Retrieved 2012-12-26.
  44. "First-Ever Legal Action Targets Cancer-Causing Flame Retardant Found in Children's Products - Center for Environmental Health". ceh.org. Archived from the original on 2012-12-11.
  45. 1 2 "Market Study Flame Retardants 3rd ed". Ceresana Research. Archived from the original on 2015-02-15. Retrieved 2015-02-03.
  46. Araki, A., Saito, I., Kanazawa, A., Morimoto, K., Nakayama, K., Shibata, E., . . . Kishi, R. (2014). Phosphorus flame retardants in indoor dust and their relation to asthma and allergies of inhabitants. Indoor Air, 24(1), 3-15. doi:10.1111/ina.12054.
  47. Chevrier, J; Harley, KG; Bradman, A; Gharbi, M; Sjödin, A; Eskenazi, B (2010). "Polybrominated Diphenyl Ether (PBDE) Flame Retardants and Thyroid Hormone during Pregnancy". Environ Health Perspect. 118 (10): 1444–1449. doi:10.1289/ehp.1001905. PMC   2957927 . PMID   20562054.
  48. Herbstman, JB; Sjödin, A; Kurzon, M; Lederman, SA; Jones, RS; Rauh, V; Needham, LL; Tang, D; et al. (2010). "Prenatal Exposure to PBDEs and Neurodevelopment". Environ Health Perspect. 118 (5): 712–719. doi:10.1289/ehp.0901340. PMC   2866690 . PMID   20056561.
  49. Roze, E; Meijer, L; Bakker, A; Van Braeckel, KN; Sauer, PJ; Bos, AF (2009). "Prenatal Exposure to Organohalogens, Including Brominated Flame Retardants, Influences Motor, Cognitive, and Behavioral Performance at School Age". Environ Health Perspect. 117 (12): 1953–1958. doi:10.1289/ehp.0901015. PMC   2799472 . PMID   20049217.
  50. Rose, M; Bennett, DH; Bergman, A; Fängström, B; Pessah, IN; Hertz-Picciotto, I (2010). "PBDEs in 2- 5-year-old children from California and associations with diet and indoor environment". Environ. Sci. Technol. 44 (7): 2648–2653. Bibcode:2010EnST...44.2648R. doi:10.1021/es903240g. PMC   3900494 . PMID   20196589.
  51. DiGangi, J; Blum, A; Bergman, Å; de Wit, CA; Lucas, D; Mortimer, David; Schecter, Arnold; Scheringer, Martin; Shaw, Susan D.; Webster, Thomas F. (2010). "2010 San Antonio Statement on Brominated and Chlorinated Flame Retardants". Environ Health Perspect. 118 (12): A516–8. doi:10.1289/ehp.1003089. PMC   3002202 . PMID   21123135.
  52. 1 2 3 Meerts IA, van Zanden JJ, Luijks EA, van Leeuwen-Bol I, Marsh G, Jakobsson E, Bergman A, Brouwer A (2000). "Potent competitive interactions of some brominated flame retardants and related compounds with human transthyretin in vitro". Toxicological Sciences. 56 (1): 95–104. doi: 10.1093/toxsci/56.1.95 . PMID   10869457.
  53. Szabo DT, Richardson VM, Ross DG, Diliberto JJ, Kodavanti PR, Birnbaum LS (2009). "Effects of perinatal PBDE exposure on hepatic phase I, phase II, phase III, and deiodinase 1 gene expression involved in thyroid hormone metabolism in male rat pups". Toxicol. Sci. 107 (1): 27–39. doi:10.1093/toxsci/kfn230. PMC   2638650 . PMID   18978342.
  54. Butt, C; Wang D; Stapleton HM (2011). "Halogenated phenolic contaminants inhibit the in vitro activity of the thyroid-regulating deiodinases in human liver". Toxicological Sciences. 124 (2): 339–47. doi:10.1093/toxsci/kfr117. PMC   3216408 . PMID   21565810.
  55. 1 2 3 4 5 Dingemans, MML; van den Berg M; Westerink RHS (2011). "Neurotoxicity of Brominated Flame Retardants: (In)direct Effects of Parent and Hydroxylated Polybrominated Diphenyl Ethers on the (Developing) Nervous System". Environmental Health Perspectives. 119 (7): 900–907. doi:10.1289/ehp.1003035. PMC   3223008 . PMID   21245014.
  56. 1 2 3 Meerts, IA; Letcher RJ; Hoving S; Marsh G; Bergman A; Lemmen JG; van der Burg B; Brouwer A (2001). "In vitro estrogenicity of polybrominated diphenyl ethers, hydroxylated PDBEs, and polybrominated bisphenol A compounds". Environmental Health Perspectives. 109 (4): 399–407. doi:10.1289/ehp.01109399. PMC   1240281 . PMID   11335189. Archived from the original on 2001-06-24. Retrieved 2013-04-26.
  57. Rahman, F; Langford, KH; Scrimshaw, MD; Lester, JN (2001). "Polybrominated diphenyl ether (PBDE) flame retardants". Science of the Total Environment. 275 (1–3): 1–17. Bibcode:2001ScTEn.275....1R. doi:10.1016/S0048-9697(01)00852-X. PMID   11482396.
  58. Stapleton, H; Alaee, M; Letcher, RJ; Baker, JE (2004). "Debromination of the flame retardant decabromodiphenyl ether by juvenile carp (Cyprinus carpio) following dietary exposure". Environmental Science & Technology. 38 (1): 112–119. Bibcode:2004EnST...38..112S. doi:10.1021/es034746j. PMID   14740725.
  59. Stapleton, H; Dodder, N (2008). "Photodegradation of decabromodiphenyl ether in house dust by natural sunlight". Environmental Toxicology and Chemistry. 27 (2): 306–312. doi:10.1897/07-301R.1. PMID   18348638. S2CID   207267052.
  60. Department of Ecology, Washington State; State of Washington Department of Health (2008). Alternatives to Deca-BDE in Televisions and Computers and Residential Upholstered Furniture (Report). 09-07-041. Archived from the original on 2013-12-03. Retrieved 2013-04-26.
  61. McCormick, J; Paiva MS; Häggblom MM; Cooper KR; White LA (2010). "Embryonic exposure to tetrabromobisphenol A and its metabolites, bisphenol A and tetrabromobisphenol A dimethyl ether disrupts normal zebrafish (Danio rerio) development and matrix metalloproteinase expression". Aquatic Toxicology. 100 (3): 255–62. Bibcode:2010AqTox.100..255M. doi:10.1016/j.aquatox.2010.07.019. PMC   5839324 . PMID   20728951.
  62. Lorber, M. (2008). "Exposure of Americans to polybrominated diphenyl ethers". Journal of Exposure Science & Environmental Epidemiology. 18 (1): 2–19. Bibcode:2008JESEE..18....2L. doi: 10.1038/sj.jes.7500572 . PMID   17426733.
  63. Johnson-Restrepo, B.; Kannan, K. (2009). "An assessment of sources and pathways of human exposure to polybrominated diphenyl ethers in the United States". Chemosphere. 76 (4): 542–548. Bibcode:2009Chmsp..76..542J. doi:10.1016/j.chemosphere.2009.02.068. PMID   19349061.
  64. 1 2 Stapleton, H.; Sjodin, A.; Jones, R.; Niehuser, S.; Zhang, Y.; Patterson, D. (2008). "Serum levels of polybrominated diphenyl ethers (PBDEs) in foam recyclers and carpet installers working in the United States". Environmental Science & Technology. 42 (9): 3453–3458. Bibcode:2008EnST...42.3453S. doi:10.1021/es7028813. PMID   18522133.
  65. Costa, L.; Giordano, G. (2007). "Developmental neurotoxicity of polybrominated diphenyl ether (PBDE) flame retardants". NeuroToxicology. 28 (6): 1047–1067. Bibcode:2007NeuTx..28.1047C. doi:10.1016/j.neuro.2007.08.007. PMC   2118052 . PMID   17904639.
  66. "Scientific Opinion on Hexabromocyclododecanes (HBCDDs) in Food". EFSA Journal. 9 (7). EFSA Panel on Contaminants in the Food Chain. 2011-07-28. doi: 10.2903/j.efsa.2011.2296 .
  67. "Scientific Opinion on Tetrabromobisphenol A (TBBPA) and its derivatives in food". 2011-12-19. Archived from the original on 2018-04-28. Retrieved 2018-04-27.
  68. Stapleton, H.; Eagle, S.; Sjodin, A.; Webster, T. (2012). "Serum PBDEs in a North Carolina toddler cohort: Associations with handwipes, house dust, and socioeconomic variables". Environmental Health Perspectives. 120 (7): 1049–1054. doi:10.1289/ehp.1104802. PMC   3404669 . PMID   22763040.[ verification needed ]
  69. 1 2 Watkins, D.; McClean, M.; Fraser, A.; Weinberg, J.; Stapleton, H.; Sjodin, A.; Webster, T. (2012). "Impact of dust from multiple microenvironments and diet on PentaBDE body burden". Environmental Science & Technology. 46 (2): 1192–1200. Bibcode:2012EnST...46.1192W. doi:10.1021/es203314e. PMC   3268060 . PMID   22142368.[ verification needed ]
  70. Besis, A.; Samara, C. (2012). "Polybrominated diphenyl ethers (PBDEs) in the indoor and outdoor environments--a review on occurrence and human exposure". Environmental Pollution. 169: 217–229. Bibcode:2012EPoll.169..217B. doi:10.1016/j.envpol.2012.04.009. PMID   22578798.[ verification needed ]
  71. 1 2 Lorber, M. (2008). "Exposure of Americans to polybrominated diphenyl ethers". Journal of Exposure Science & Environmental Epidemiology. 18 (1): 2–19. Bibcode:2008JESEE..18....2L. doi:10.1038/sj.jes.7500572. PMID   17426733. S2CID   27473105.[ verification needed ]
  72. 1 2 3 Johnson-Restrepo, B.; Kannan, K. (2009). "An assessment of sources and pathways of human exposure to polybrominated diphenyl ethers in the United States". Chemosphere. 76 (4): 542–548. Bibcode:2009Chmsp..76..542J. doi:10.1016/j.chemosphere.2009.02.068. PMID   19349061.[ verification needed ]
  73. Schecter, A., Harris, T. R., Shah, N., Musumba, A., & Papke, O. (2008). Brominated flame retardants in US food. Mol Nutr Food Res, 52(2), 266-272. doi:10.1002/mnfr.200700166
  74. 1 2 3 Bi X, Thomas GO, Jones KC, Qu W, Sheng G, Martin FL, Fu J (2007). "Exposure of electronics dismantling workers to polybrominated diphenyl ethers, polychlorinated biphenyls, and organochlorine pesticides in South China". Environmental Science & Technology. 41 (16): 5647–5653. Bibcode:2007EnST...41.5647B. doi:10.1021/es070346a. PMID   17874768.
  75. Sjodin A, Wong LY, Jones RS, Park A, Zhang Y, Hodge C, Dipietro E, McClure C, Turner W, Needham LL, Patterson DG Jr (2008). "Serum concentrations of polybrominated diphenyl ethers (PBDEs) and polybrominated biphenyl (PBB) in the United States population: 2003-2004". Environmental Science & Technology. 42 (4): 1377–1384. Bibcode:2008EnST...42.1377S. doi:10.1021/es702451p. PMID   18351120.[ verification needed ]
  76. Lunder, S.; Hovander, L.; Athanassiadis, I.; Bergman, A. (2010). "Significantly higher polybrominated diphenyl ether levels in young U.S. children than in their mothers". Environmental Science & Technology. 44 (13): 5256–5262. Bibcode:2010EnST...44.5256L. doi:10.1021/es1009357. PMID   20540541.[ verification needed ]
  77. Zhao, Y., Ruan, X., Li, Y., Yan, M., & Qin, Z. (2013). Polybrominated diphenyl ethers (PBDEs) in aborted human fetuses and placental transfer during the first trimester of pregnancy. Environ Sci Technol, 47(11), 5939-5946. doi:10.1021/es305349x
  78. Leonetti, C.; Butt, C. M.; Hoffman, K.; Hammel, S. C.; Miranda, M. L.; Stapleton, H. M. (2016). "Brominated flame retardants in placental tissues: associations with infant sex and thyroid hormone endpoints". Environ Health. 15 (1): 113. Bibcode:2016EnvHe..15..113L. doi: 10.1186/s12940-016-0199-8 . PMC   5123327 . PMID   27884139.
  79. Castorina, R.; Bradman, A.; Stapleton, H. M.; Butt, C.; Avery, D.; Harley, K. G.; Eskenazi, B. (2017). "Current-use flame retardants: Maternal exposure and neurodevelopment in children of the CHAMACOS cohort". Chemosphere. 189: 574–580. Bibcode:2017Chmsp.189..574C. doi:10.1016/j.chemosphere.2017.09.037. PMC   6353563 . PMID   28963974.
  80. U.S. Environmental Protection Agency (2011). Exposure Factors Handbook: 2011 Edition (PDF) (Report). p. 5-5. EPA/600/R-090/052F. Archived (PDF) from the original on 2015-09-24.[ verification needed ]
  81. Carignan, C. C., Heiger-Bernays, W., McClean, M. D., Roberts, S. C., Stapleton, H. M., Sjodin, A., & Webster, T. F. (2013). Flame retardant exposure among collegiate United States gymnasts. Environ Sci Technol, 47(23), 13848-13856. doi:10.1021/es4037868.
  82. Thomsen, C.; Lundanes, E.; Becher, G. (2001). "Brominated flame retardants in plasma samples from three different occupational groups in Norway". Journal of Environmental Monitoring. 3 (4): 366–370. doi:10.1039/b104304h. PMID   11523435.
  83. Thuresson, K.; Bergman, K.; Rothenbacher, K.; Hermann, T.; Sjolin, S.; Hagmar, L.; Papke, O.; Jakobsson, K. (2006). "Polybrominated diphenyl ether exposure to electronics recycling workers--a follow up study". Chemosphere. 64 (11): 1855–1861. Bibcode:2006Chmsp..64.1855T. doi:10.1016/j.chemosphere.2006.01.055. PMID   16524616.
  84. Exposure to Flame Retardants in Electronics Recycling Sites, Rosenberg, Christina; Haemeilae, Mervi; Tornaeus, Jarkko; Saekkinen, Kirsi; Puttonen, Katriina; Korpi, Anne; Kiilunen, Mirja; Linnainmaa, Markku; Hesso, Antti, Annals of Occupational Hygiene (2011), 55(6), 658-665
  85. 1 2 Wang, C.; Lin, Z.; Dong, Q.; Lin, Z.; Lin, K.; Wang, J.; Huang, J.; Huang, X.; He, Y.; Huang, C.; Yang, D.; Huang, C. (2012). "Polybrominated diphenyl ethers (PBDEs) in human serum from Southeast China". Ecotoxicology and Environmental Safety. 78 (1): 206–211. Bibcode:2012EcoES..78..206W. doi:10.1016/j.ecoenv.2011.11.016. PMID   22142821.
  86. Shaw, S.; Berger, M.; Harris, J.; Yun, S. H.; Wu, Q.; Liao, C.; Blum, A.; Stefani, A.; Kannan, K. (2013). "Persistent organic pollutants including polychlorinated and polybrominated dibenzo-p-dioxins and dibenzofurans in firefighters from Northern California". Chemosphere. 91 (10): 1386–94. Bibcode:2013Chmsp..91.1386S. doi:10.1016/j.chemosphere.2012.12.070. PMID   23395527.
  87. "VECAP - Welcome". Archived from the original on 2014-12-18. Retrieved 2014-10-28.
  88. Wong M, Wu SC, Deng WJ, Yu XZ, Luo Q, Leung AOW, Wong CSC, Luksemburg WJ, Wong AS (2007). "Export of toxic chemicals - a review of the case of uncontrolled electronic-waste recycling". Environmental Pollution. 149 (2): 131–140. Bibcode:2007EPoll.149..131W. doi:10.1016/j.envpol.2007.01.044. PMID   17412468. Archived from the original on 2021-04-27. Retrieved 2019-07-07.
  89. Rodil, R.; Quintana, J.; Concha-Graña, E.; López-Mahía, P.; Muniategui-Lorenzo, S.; Prada-Rodríguez, D. (2012). "Emerging pollutants in sewage, surface and drinking water in Galicia (NW Spain)". Chemosphere. 86 (10): 1040–1049. Bibcode:2012Chmsp..86.1040R. doi:10.1016/j.chemosphere.2011.11.053. PMID   22189380.
  90. Marklund, A.; Andersson, B.; Haglund, P. (2005). "Organophosphorus flame retardants and plasticizers in Swedish sewage treatment plants". Environmental Science & Technology. 39 (10): 7423–7429. Bibcode:2005EnST...39.7423M. doi:10.1021/es051013l. PMID   16245811.
  91. Li, J.; Yu, N.; Zhang, B.; Jin, L.; Li, M.; Hu, M.; Yu, H. (2014). "Occurrence of organophosphate flame retardants in drinking water from China". Water Res. 54: 53–61. doi:10.1016/j.watres.2014.01.031. PMID   24556230.
  92. 1 2 Wolschke, H., Suhring, R., Xie, Z., & Ebinghaus, R. (2015). Organophosphorus flame retardants and plasticizers in the aquatic environment: A case study of the Elbe River, Germany. Environ Pollut, 206, 488-493. doi:10.1016/j.envpol.2015.08.002
  93. "Stena Recycling – It starts here!". www.stenarecycling.com. 2021-12-16. Archived from the original on 2024-06-28. Retrieved 2024-06-28.
  94. 1 2 Westervelt, Amy. California law sparks nationwide demand for flame-retardant-free furniture. The Guardian. September 20, 2104.
  95. "Flame Retardants". 2017-12-21. Archived from the original on 2018-03-19. Retrieved 2018-03-19.
  96. "Fact Sheet: Assessing Risks from Flame Retardants". 2015-09-14. Archived from the original on 2018-03-19. Retrieved 2018-03-19.
  97. 1 2 3 4 PD-icon.svg This article incorporates public domain material from the National Institute of Standards and Technology Babrauskas, V.; Harris, R. H.; Gann, R. G; et al. (July 1989), "Fire Hazard Comparison of Fire-Retarded and Non-Fire-Retarded Products" (Free PDF download available), NBS Special Publication 749, U.S. Commerce Dept. National Bureau of Standards (NBS), archived from the original on 2013-11-13, retrieved 2014-05-30
  98. Market Study Flame Retardants 2nd ed. Archived 2015-02-15 at the Wayback Machine , Ceresana, 07/11

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