| Identification | More | [Name]
Tetrabromobisphenol A | [CAS]
79-94-7 | [Synonyms]
2,2',6,6'-tetrabromo-4,4'-isopropylidenediphenol
2,2',6,6'-TETRABROMO BISPHENOL A
2,2-BIS(3,5-DIBROMO-4-HYDROXYPHENYL)PROPANE
2,2-Bis(4'-hydroxy-3',5'-dibromophenyl)propane
3,3',5,5'-TETRABROMO-4,4-DIHYDROXY-2-2-DIPHENYLPROPANE
3,3',5,5'-TETRABROMOBISPHENOL A
4,4'-ISOPROPYLIDENEBIS(2,6-DIBROMOPHENOL)
4,4-ISOPROPYLIDENEBIS(2,6-DIBROMOPHENOL)
LABOTEST-BB LT00154611
SAYTEX RB-100
SAYTEX(R) RB-100 FLAME RETARDANT
TBA
TBBA
TETRABROMOBISPHENOL A
TETRABROMOBISPHENOL ''A''
2,2',6,6'-Tetrabromo-4,4'-isopropylidene phenol
2,2-bis(2,6-Dibromo-4-hydroxyphenyl)propane
3,5,3',5'-Tetrabromobisphenol A
3,5,3’,5’-tetrabromobisphenola
4,4’-(1-methylethylidene)bis(2,6-dibromo-pheno | [EINECS(EC#)]
201-236-9 | [Molecular Formula]
C15H12Br4O2 | [MDL Number]
MFCD00013962 | [Molecular Weight]
543.87 | [MOL File]
79-94-7.mol |
| Safety Data | Back Directory | [Hazard Codes ]
Xi | [Risk Statements ]
R36/37/38:Irritating to eyes, respiratory system and skin . | [Safety Statements ]
S26:In case of contact with eyes, rinse immediately with plenty of water and seek medical advice .
S36:Wear suitable protective clothing .
S37/39:Wear suitable gloves and eye/face protection . | [RIDADR ]
UN 3077 9/PG 3
| [WGK Germany ]
1
| [RTECS ]
SM0894500
| [TSCA ]
Yes | [HazardClass ]
9 | [PackingGroup ]
II | [HS Code ]
29081990 | [Hazardous Substances Data]
79-94-7(Hazardous Substances Data) | [Toxicity]
LD50 inhalation in guinea pig: > 500mg/m3/8H |
| Hazard Information | Back Directory | [General Description]
White powder. A monomer for flame-retardant epoxy, polyester and polycarboante resins. | [Reactivity Profile]
TETRABROMOBISPHENOL A(79-94-7) is monomer. | [Air & Water Reactions]
Insoluble in water. | [Hazard]
Moderately toxic by inhalation and skincontact. An eye irritant. | [Fire Hazard]
This compound is nonflammable. | [Chemical Properties]
Tetrabromobisphenol A is a white to pale cream or pale yellow crystalline with a moderately high molecular weight, low water solubility, and moderately high lipophilicity (as indicated by log Kow). Only about 4% of the particles are <15 μm in diameter, and thus, little (<4%) is expected to be respirable (<10 μm in diameter) and absorbed from the lung after inhalation exposure.
Tetrabromobisphenol A (TBBPA) is a brominated flame retardant used in a variety of reactive and additive applications. It is reacted (i.e., covalently bound) with epoxy, vinyl esters, and polycarbonate systems (e.g., high impact polystyrene (HIPS), and is used as an additive in acrylonitrile-butadiene-styrene (ABS) thermoplastic resins (Albemarle, 1999). Its primary application is in printed wire boards (PWBs) as a reactive flame retardant (BSEF, 2012).
| [Uses]
Tetrabromobisphenol A (TBBPA) is primarily used as a reactive
flame retardant in epoxy resin circuit boards. Both hydroxyl
groups on TBBPA can be reacted with epichlorohydrin under
basic conditions to form the diglycidyl ether, which is widely
used in epoxy resin formulations. TBBPA is also used in polycarbonate
and ether polyester resins and is used as a chemical
intermediate for the synthesis of tetra-bromobisphenol A
allyl ether, -bis(2-hydroxyethyl ether), -carbonate oligomer,
and -diglycidyl ether. TBBPA is also used as a flame retardant in
plastics, paper, and textiles, and as a plasticizer in adhesives and
coatings. Being covalently bound to the polymer limits exposure
to unbound excess chemical used in the manufacturing
process. | [Uses]
tetrabromobisphenol A is widely used as a reactive flame retardant to produce a bromine-containing epoxy resin and polycarbonate, and as intermediates for the synthesis of other complex flame retardant, also as an additive flame retardant for ABS, HIPS, unsaturated polyester rigid polyurethane foams, adhesives and coatings. | [Application]
The main use of TBBPA is as a reactive flame retardant in epoxy resins for printed circuit boards in computers, telecommunications equipment, industrial controls and automotive electronics. Both hydroxyl groups on TBBPA can be reacted with epichlorohydrin under basic conditions to form the diglycidyl ether, which is widely used in epoxy resin formulations. TBBPA is also used in polycarbonate and ether polyester resins and is used as a chemical intermediate for the synthesis of tetra-bromobisphenol A allyl ether, -bis(2-hydroxyethyl ether), -carbonate oligomer, and -diglycidyl ether. TBBPA is also used as a flame retardant in plastics, paper, and textiles, and as a plasticizer in adhesives and coatings. Being covalently bound to the polymer limits exposure to unbound excess chemical used in the manufacturing process. | [Definition]
ChEBI: A bromobisphenol that is 4,4'-methanediyldiphenol in which the methylene hydrogens are replaced by two methyl groups and the phenyl rings are substituted by bromo groups at positions 2, 2', 6 and 6'. It is a brominated flame retardant. | [Preparation]
Tetrabromobisphenol A is prepared by the bromination of bisphenol A in the presence of a solvent. This reaction may be conducted:
in the presence of a hydrocarbon solvent only or
with water, 50 % hydrobromic acid or aqueous alkyl monoethers.
when methanol is used as the solvent, methyl bromide is formed as a by-product. The production process is largely conducted in closed systems (WHO/IPCS, 1995). | [Flammability and Explosibility]
Nonflammable(100%) | [Environmental Fate]
Its physicochemical properties suggest that it will partition to all compartments (i.e., water, sediment, and soil), predominantly to sediment and soil through binding to the organic fraction of a particulate matter. Available environmental fate studies indicated that TBBPA is persistent in water (half-life [t1/2] 182 days), soil (t1/2 182 days), and sediment (t1/2 365 days) (Canada, 2013).It lacks functional groups that are expected to undergo hydrolysis (Canada, 2013). A number of laboratory studies (ECHA, 2013) showed that it can degrade to bisphenol A under aerobic conditions (Canada, 2013).
Tetrabromobisphenol A is identified as a persistent, bioaccumulative, and toxic (PBT) compound under the U.S. Environmental Protection Agency s Toxic Release Inventory (EPA, 2013). It was also placed on the State of Washington s Department of Ecology s PBT List (DOC, 2013). However, Environment Canada and Health Canada concluded that TBBPA did not meet their criteria for bioaccumulation (i.e., bioaccumulation factor >5000) (Canada, 2013). This conclusion was based on TBBPA s low bioaccumulation potential from its physicochemical properties (e.g., maximum diameter of 1.3 1.4 nm, ionization at environmentally relevant pH, and variable logKOW), as well as from studies that showed TBBPA is rapidly metabolized and excreted in aquatic and terrestrial organisms (Canada, 2013). | [Toxicity evaluation]
Studies of the effects of TBBPA on the function of biological
membranes showed that it resulted in hemolysis of human erythrocytes and the uncoupling of oxidative phosphorylation
in rat mitochondria. In addition, TBBPA exposure resulted in the
inhibition of calcium accumulation in isolated mitochondria
that was associated with an increase in potassium release and
latent ATPase activity. These studies suggest that the primary
activity of TBBPA in vitro is to change the permeability of biological
membranes disrupting normal ion transport and respiration
of cells. TBBPA has also been shown to weakly induce
liver microsomal enzymes in vitro. In the E-Screen assay, TBBPA
expressed weak receptor-mediated estrogenic activity with an
estrogenic potency w5–6 orders of magnitude lower than that
of the native ligand, 17b-estradiol. No effect was observed with
respect to sex hormone synthesis in the H295R cellular
steroidogenesis model. TBBPA has been shown to bind to
human transthyretin in vitro with a 10 times greater potency than
thyroxin, the natural ligand. However, in a study with pregnant
rats, TBBPA did not bind to transthyretin and did not alter
thyroid hormone concentration in the exposed animals. The
differences between in vitro and in vivo studies may have been
because of toxicokinetic factors that altered the effective
concentrations at the site of action. In female rats, an intragastric
dose of 250 mg kg-1 for 28 days resulted in the alteration of
several serum enzymes, including several indicators of porphyrogenic
action. These results suggest that TBBPA is capable of
disturbing heme metabolism in rats.
In vitro studies have revealed immunotoxic, immunosuppressive,
and inflammatory responses as a result of TBBPA
treatment. Immunotoxicity was via inhibition of CD45
expression, a cell surface receptor required for proliferation of
activated T cells; immunosuppression was mediated by
a reduction of lytic properties of natural killer T cells, the first
line of defense against foreign infections and endogenous
cancerous cells; inflammatory response was elicited by upregulation
of prostaglandin E2 production and an elevation in
Cox-2 expression and cytokine (TNF-a, IL-6, and IL-1b)
production. TBBPA was shown to interfere with neurotransmitter
uptake in the synapse in cellular models, although it
seems to have no neurological or motor effects in vivo. |
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