Measurement of polybrominated diphenyl ethers and metabolites in mouse plasma after exposure to a commercial pentabromodiphenyl ether mixture.BACKGROUND: Previous studies have shown that polybrominated diphenyl ethers Polybrominated diphenyl ethers or PBDE, are a flame retardant sub-family of the brominated flame retardant group. They have been used in a wide array of household products, including fabrics, furniture, and electronics. (PBDEs) behave as weak estrogens Estrogens Hormones produced by the ovaries, the female sex glands. Mentioned in: Acne, Polycystic Ovary Syndrome estrogens (es´trōjenz), n. in animal and cell culture bioassays. In vivo in vivo /in vi·vo/ (ve´vo) [L.] within the living body. in vi·vo adj. Within a living organism. in vivo adv. metabolites Metabolites Substances produced by metabolism or by a metabolic process. Mentioned in: Interactions of PBDEs are suspected to cause these effects. OBJECTIVES: To identify candidate metabolites, mouse plasma samples were collected after continuous oral and subcutaneous exposure to DE- de- word element [L.], down; from; sometimes negative or privative, and often intensive. de- pref. 1. Do or make the opposite of; reverse: decomposition. 2. 71, a widely used commercial pentabromodiphenyl ether product, for 34 days. METHODS: Samples were extracted, separated into neutral and phenolic phe·no·lic adj. Of, relating to, containing, or derived from phenol. n. Any of various synthetic thermosetting resins, obtained by the reaction of phenols with simple aldehydes and used as adhesives. fractions, and analyzed by gas chromatographic chro·mat·o·graph n. An instrument that produces a chromatogram. tr.v. chro·mat·o·graphed, chro·mat·o·graph·ing, chro·mat·o·graphs To separate and analyze by chromatography. mass spectrometry mass spectrometry or mass spectroscopy Analytic technique by which chemical substances are identified by sorting gaseous ions by mass using electric and magnetic fields. . RESULTS: In the plasma samples of orally treated animals, 2,2,4,4,5,5-hexabromodiphenyl ether (BDE-153) represented 52% of total measurable PBDEs, whereas it represented only 4.3% in the DE-71 mixture. This suggested that BDE-153 was more persistent than other congeners in mice. Several metabolites were detected and quantitated: 2,4-dibromophenol, 2,4,5-tribromophenol, and six hydroxylated PBDEs. The presence of the two phenols phenols (fēˑ·n  lz),n. suggested cleavage of the ether bond of 2,2,4,4-tetrabromodiphenyl ether (BDE-47) and 2,2,4,4,5-pentabromodiphenyl ether (BDE-99), respectively. The hydroxylated (HO)-PBDEs might come from hydroxylation hydroxylation addition of -OH groups to a molecule. or debromination/hydroxylation. Among the quantitated hydroxylated metabolites, the most abundant was 4-HO-2,2,3,4-tetra-BDE, which suggested that there was a bromine bromine (brō`mēn, –mĭn) [Gr.,=stench], volatile, liquid chemical element; symbol Br; at. no. 35; at. wt. 79.904; m.p. –7.2°C;; b.p. 58.78°C;; sp. gr. of liquid 3.12 at 20°C;; density of vapor 7. shift during the hydroxylation process. para-HO-PBDEs have been proposed to behave as endocrine disruptors. CONCLUSIONS: There seem to be three metabolic pathways: cleavage of the diphenyl diphenyl /di·phen·yl/ (di-fen´il) a toxic compound comprising two linked benzene rings, used as a fungistat in containers for shipping citrus fruits. di·phen·yl n. See biphenyl. ether bond, hydroxylation, and debromination/hydroxylation. The cleavage of the diphenyl ether bond formed bromophenols, and the other two pathways formed hydroxylated PBDEs, of which para-HOPBDEs are most likely formed from BDE-47. These metabolites may be the most thyroxine-like and/or estrogen-like congeners among the HO-PBDEs. KEY WORDS: BDE-153, bromophenols, DE-71, hydroxylated PBDEs, hydroxylation, polybrominated diphenyl ethers. Environ Health Perspect 115:1052-1058 (2007). doi:10.1289/ehp.10011 available via http://dx.doi.org/ [Online 6 April 2007] Polybrominated diphenyl ethers (PBDEs) are ubiquitous environmental contaminants that are found in both abiotic a·bi·ot·ic adj. Nonliving: The abiotic factors of the environment include light, temperature, and atmospheric gases. a and biotic biotic /bi·ot·ic/ (bi-ot´ik) 1. pertaining to life or living matter. 2. pertaining to the biota. bi·ot·ic adj. 1. Relating to life or living organisms. environmental samples (Hites 2004; Streets et al. 2006). PBDEs are used as flame retardants; the three main commercial types of PBDE PBDE Polybrominated Diphenyl Ether PBDE Pentabromodiphenyl Ether (flame retardant additive in plastics) PBDE Parallel Block-Decodable Encoder are penta-BDE, octa-BDE, and deca-BDE. DE-71, a widely used commercial penta-BDE product, is generally composed of 50-60% penta-BDE congeners, 24-38% tetra-BDE congeners, and 4-8% hexa-BDE congeners (Birnbaum and Staskal 2003). Since the 1970s, penta-BDE has been used as a flame retardant in polyurethane foam-containing consumer goods consumer goods Any tangible commodity purchased by households to satisfy their wants and needs. Consumer goods may be durable or nondurable. Durable goods (e.g., autos, furniture, and appliances) have a significant life span, often defined as three years or more, and such as carpet padding, sofas, and mattresses; this flame retardant can account for up to 30% by weight of the foam (Hale et al. 2002). DE-71 also has minor uses in phenolic resins, polyesters, and epoxy. Despite its relatively small global production and usage compared with deca-BDE, the congeners in penta-BDE, such as 2,2,4,4-tetrabromodiphenyl ether (BDE-47), 2,2,4,4,5pentabromodiphenyl ether (BDE-99), and 2,2,4,4,5,5-hexabromodiphenyl ether (BDE-153), are the most common PBDE congeners found in environmental samples, especially in biotic samples (Hites 2004), suggesting that these congeners are persistent and bioaccumulative. Although the toxicity of PBDEs is not well understood, these compounds may be neurotoxic neurotoxic pertaining to or emanating from a neurotoxin. neurotoxic state a case of poisoning by a neurotoxin. neurotoxic adjective , thyrotoxic, estrogenic, and carcinogenic carcinogenic having a capacity for carcinogenesis. (Siddiqi et al. 2003). Their toxicity might be due to hydroxylated PBDE metabolites (HO-PBDEs) formed in animals. Although HO-PBDEs are less persistent than PBDEs, they may have more severe biological effects. For example, HO-PBDEs have thyroxine-like and estrogen-like chemical structures (Meerts et al. 2001), and thyroid hormone-like HO-PBDE congeners have been shown to bind competitively with human transthyretin (TTR TTR Transthyretin TTR Ticket To Ride (World Snowboard Tour) TTR Transformer Turns Ratio (electric power transmission and distribution) TTR Time To Repair TTR Time to Read ), a transport protein for the thyroid hormones Thyroid Hormones Definition Thyroid hormones are artificially made hormones that make up for a lack of natural hormones produced by the thyroid gland. , thyroxine and thyronine (Meerts et al. 2000). The competitive binding of HO-PBDE to TTR provides a mechanism that can potentially result in disrupted thyroxine homeostasis homeostasis Any self-regulating process by which a biological or mechanical system maintains stability while adjusting to changing conditions. Systems in dynamic equilibrium reach a balance in which internal change continuously compensates for external change in a feedback . Putative PBDE metabolites are able to activate an estrogenresponsive luciferase luciferase (loosif´  rās´),n an enzyme present in certain luminous organisms that act to bring about the oxidation of luciferins; energy produced in the reporter gene construct (Meerts et al. 2001). Our research has shown that DE-71 acts as a weak estrogen in cultured human breast cancer cells and in ovariectomized mice (Mercado-Feliciano M, Bigsby RM, unpublished data). Cell proliferation was increased when MCF-7 cells were cultured in the presence of DE-71 for 10 days. When DE-71 was administered to mice for 34 days, the uterine weight, uterine epithelial height, and vaginal epithelial thickness increased slightly. However, short-term treatment of cultured cells or mice showed very little estrogenic effect. These observations suggest that accumulation of DE-71 metabolites may be involved in these estrogenic effects. Therefore, we conducted the present study to identify and quantify metabolites of DE-71 formed during in vivo treatment of mice. Based on these results, three metabolic pathways are proposed. Materials and Methods Chemicals. We obtained commercial DE-71 from the Great Lakes Chemical Corporation Great Lakes Chemical Corporation is a chemical research, production, sales and distribution company that produces specialty chemicals used for polymers, fire suppressants and retardants, pool and spa water purification systems and various other applications. (West Lafayette, IN). Dimethyl sulfoxide dimethyl sulfoxide (DMSO) Colourless, nearly odourless liquid organic compound. It mixes in all proportions with water, ethanol, and most organic solvents and dissolves a wide variety of compounds (but not aliphatic hydrocarbons). and [beta]-estradiol-3-benzoate were purchased from Sigma Chemical Co. (St. Louis, MO), and corn oil was purchased from ICN ICN International Council of Nurses. Biomedicals (Aurora, OH). We purchased all of the neutral standards (BDEs 28, 47, 71, 77, 85, 99, 100, 153, 154, 183, and 1,3,5-tribromobenzene) from AccuStandard (New Haven, CT). 4-HO2,2,4-Tri-BDE (4-HO-BDE-17); 2-HO- 2,4,4-tri-BDE (2-HO-BDE-28); 4-HO- 2,2,3,4-tetra-BDE (4-HO-BDE-42); 3-HO-2,2,4,4-tetra-BDE (3-HO-BDE-47); 5-HO-2,2,4,4-tetra-BDE (5-HO-BDE-47); 6-HO-2,2,4,4-tetra-BDE (6-HO-BDE-47); 4-HO-2,2,4,5-tetra-BDE (4-HO-BDE- 49); 2-HO-2,3,4,4-tetra-BDE (2-HOBDE- 66); and 2-HO-2,3,4,5-tetra-BDE (2-HO-BDE-68) were gifts from Goran Marsh (Stockholm University, Stockholm, Sweden), and were synthesized as described elsewhere (Marsh et al. 2004). 4-Methoxy2,2,3,4,5-penta-BDE (4-MeO-BDE-90); 5-methoxy-2,2,4,4,5-penta-BDE (5-MeOBDE- 99); 6-methoxy-2,2,4,4,5-penta-BDE (6-MeO-BDE-99); 2,3-dibromophenol (2,3-DBP); 2,5-DBP, 3,5-DBP; and 2,4,6- tribromophenol (2,4,6-TBP) were from AccuStandard. 2,4-DBP; 2,6-DBP; 2,4,5- TBP TBP To Be Provided/Published TBP TATA-Box-Binding Protein TBP Tau Beta Pi (National Engineers Honors Society) TBP The Black Parade TBP Tributylphosphate TBP To Be Printed TBP To Be Produced TBP True Boiling Point ; and 4-HO-2,2,3,4,5,5,6-hepta-BDE (4-HO-PCB-187) were from Cambridge Isotope Laboratories (Cambridge, MA). All of the phenolic compounds were methylated meth·yl·ate n. An organic compound in which the hydrogen of the hydroxyl group of methyl alcohol is replaced by a metal. tr.v. meth·yl·at·ed, meth·yl·at·ing, meth·yl·ates 1. with fresh diazomethane Diazomethane is the chemical compound CH2N2. In the pure form at room temperature, it is a yellow gas, but it is almost universally used as a solution in diethyl ether. It is one of the more common diazo compounds. It is also toxic and potentially explosive. , which was prepared from Diazald (Sigma Chemical Co.) (Black 1983). All the solvents used for the extraction and cleanup procedures were residue-analysis grade. Experimental design. All animal work was approved by the Institutional Animal Care and Use Committee Institutional Animal Care and Use Committees are of central importance to the application of laws to animal research in the United States. Most research involving laboratory animals is funded by the United States National Institutes of Health or other federal agencies. at the Indiana University School of Medicine The Indiana University School of Medicine is the medical school of Indiana University, part of the Indiana University Purdue University at Indianapolis (IUPUI) campus located in Indianapolis, Indiana. Established in 1903, the school had an initial class of 25 students. , and the mice were treated humanely and with regard for alleviation of suffering in the experiment process. Adult BALB/c mice were ovariectomized at 6-8 weeks of age. Starting 3 weeks after the operation, the animals were treated five times per week for 34 days with vehicle or test compound. In brief, groups of five to six animals were treated by either subcutaneous (sc) injection or oral gavage gavage /ga·vage/ (gah-vahzh´) [Fr.] 1. forced feeding, especially through a tube passed into the stomach. 2. superalimentation. ga·vage n. 1. with vehicle control, 10 [micro]g/kg [beta]-estradiol-3-benzoate, or 45 mg/kg DE-71. Some groups were treated with both [beta]-estradiol-3-benzoate and DE-71 at the same time. Chemicals were first dissolved in dimethyl sulfoxide and then diluted in corn oil for a total dose volume of 0.1 mL for oral gavage and 10-20 [micro]L for sc injection. On the day after the last treatment, the animals were sacrificed by decapitation Decapitation See also Headlessness. Antoinette, Marie (1755–1793) queen of France beheaded by revolutionists. [Fr. Hist.: NCE, 1697] Argos lulled to sleep and beheaded by Hermes. [Gk. Myth. , and blood was collected by exsanguination exsanguination /ex·san·gui·na·tion/ (ek-sang?gwin-a´shun) extensive loss of blood due to internal or external hemorrhage. exsanguination extensive blood loss due to internal or external hemorrhage. . Blood was kept at 4[degrees]C for [less than or equal to] 20 hr before it was centrifuged at 10,000 x g for 10 min at 4[degrees]C. The supernatant supernatant /su·per·na·tant/ (-na´tant) the liquid lying above a layer of precipitated insoluble material. supernatant the liquid lying above a layer of precipitated insoluble material. plasma was collected and stored below -20[degrees]C until analysis. Because we focused only on the precursor congeners and metabolites of DE-71 in this study, we divided the plasma samples into three groups: oral gavage, sc injection, and controls (plasma samples from mice not treated with DE-71). Sample extraction and preparation. A previous method (Hovander et al. 2000; Malmberg et al. 2005) was modified slightly to accommodate the smaller mouse plasma samples in the present study. We transferred each sample (range, 0.028-0.213 g, with an average wet weight of 0.120 g) to a centrifuge centrifuge (sĕn`trəfy  j), device using centrifugal force to separate two or more substances of different density, e.g., two liquids or a liquid and a solid. tube with a Teflon-lined screw cap. Known amounts of BDE-77
and 4-HO-PCB-187 were added as surrogate standards to determine the
recovery of both neutral and phenolic target compounds. After adjustment
to 2 mL with 1% potassium chloride potassium chloride, chemical compound, KCl, a colorless or white, cubic, crystalline compound that closely resembles common salt (sodium chloride). It is soluble in water, alcohol, and alkalies. , each sample was denatured de·na·ture tr.v. de·na·tured, de·na·tur·ing, de·na·tures 1. To change the nature or natural qualities of. 2. with 0.5 mL hydrochloric acid hydrochloric acid: see hydrogen chloride. hydrochloric acid or muriatic acid Solution in water of hydrogen chloride (HCl), a gaseous inorganic compound. (6 M) and 3 mL 2-propanol. Samples were extracted with hexane hexane /hex·ane/ (hek´san) a saturated hydrogen obtained by distillation from petroleum. hex·ane n. :methyl tert-butyl ether Methyl tertiary-butyl ether (MTBE) is a chemical compound with molecular formula C5H12O. MTBE is a volatile, flammable and colorless liquid that is highly soluble in water. (1:1, vol/vol) three times by shaking the tube> 5 min each time. After blowing down the combined extracts, the phenolic compounds were separated from the neutrals by partitioning with potassium hydroxide potassium hydroxide, chemical compound with formula KOH. Pure potassium hydroxide forms white, deliquescent crystals. For commercial and laboratory use it is usually in the form of white pellets. (0.5 M in 50% ethanol). The aqueous phase aqueous phase n. The water portion of a system consisting of two liquid phases, one that is primarily water and a second that is a liquid immiscible with water. was reextracted with hexane twice more. After acidification acidification a technology used by processors to preserve foods by adding acids (such as acetic, citric, phosphoric, propionic and lactic acid) and thereby reduce the risk of growth of harmful bacteria. of the aqueous phase, the phenolic compounds were extracted three times with hexane:methyl tert-butyl ether (9:1, vol/vol). The neutral fraction was treated with concentrated sulfuric acid sulfuric acid, chemical compound, H2SO4, colorless, odorless, extremely corrosive, oily liquid. It is sometimes called oil of vitriol. Concentrated Sulfuric Acid , followed by alumina column chromatography column chromatography n. A form of partition chromatography in which a liquid phase flows down a column packed with a solid phase. (0.6 cm i.d. x 6 cm, with 0.5 cm anhydrous an·hy·drous adj. Without water, especially water of crystallization. anhydrous (anhī´drus), adj without water. anhydrous containing no water. sodium sulfate sodium sulfate, chemical compound, Na2SO4. It is a white, orthorhombic crystalline compound at ordinary temperatures; above 100°C; it assumes a monoclinic structure, and above about 250°C; it assumes a hexagonal structure. on top). The column was eluted with 8 mL hexane followed by 8 mL hexane:dichloromethane (3:2, vol/vol); the PBDE congeners eluted in the second fraction. After concentration, BDE-71 was added as an internal standard for gas chromatographic mass spectrometry (GC/MS GC/MS Gas Chromatograph/Mass Spectrometer GC/MS Gas Chromatograph/Mass Spectrometry GC/MS Gas Chromatograph/Mass Spectrograph ) analysis. The phenolic fraction was concentrated, and the solvent was changed to hexane. To methylate methylate /meth·yl·ate/ (meth´i-lat) 1. a compound of methyl alcohol and a base. 2. to add a methyl group to a substance. meth·yl·ate v. 1. the hydroxyl group hydroxyl group (hīdrŏk`sĭl), in chemistry, functional group that consists of an oxygen atom joined by a single bond to a hydrogen atom. An alcohol is formed when a hydroxyl group is joined by a single bond to an alkyl group or aryl group. , the samples were treated with an excess of a diazomethane solution at room temperature for 3 hr, and the solvent was removed by blowing it down to near dryness. The samples were dissolved in dichloromethane and purified on a column with 0.5 g sulfuric acid-impregnated silica gel, using 8 mL dichloromethane as the mobile phase. After replacement of dichloromethane with hexane, internal standards (1,3,5-tribromobenzene for the methylated bromophenols and BDE-71 for the methylated HO-PBDEs) were added for GC/MS analysis. In each batch of samples, at least two blank samples (phosphate-buffered saline) or control samples (plasma from untreated mice) were prepared. To prevent photodegradation, during the entire process the centrifuge tubes remained wrapped with aluminum foil, or amber vials were used. Instrumental analysis. We analyzed both neutral and methylated phenolic fractions using GC/MS [Agilent 6890/5973, with an electron capture negative ionization ionization: see ion. ionization Process by which electrically neutral atoms or molecules are converted to electrically charged atoms or molecules (ions) by the removal or addition of negatively charged electrons. (ECNI) ion source (Agilent Technologies, Santa Clara, CA)]. We used ECNI-selected ion monitoring of m/z 79 and 81 for quantitation. GC injections (1 [micro]L) were made in the pulse splitless mode, with a purge time of 2.0 min. Both the injection port and the transfer line were held at 285[degrees]C. A 15-m DB-5-MS capillary column (250 [micro]m i.d., 0.25 [micro]m film thickness; J&W Scientific, Folsom, CA) was used for the neutral fraction, with the following GC oven temperature program: held at 100[degrees]C for 1 min; 20[degrees]C/min to 200[degrees]C; 8[degrees]C/min to 270[degrees]C; 25[degrees]C/min to 300[degrees]C; held for 3 min. The same instrument, but with a longer (60-m) column, was used for the methylated phenolic fraction, with the oven temperature program as follows: held at 60[degrees]C for 1 min; 3[degrees]C/min to 160[degrees]C; 15[degrees]C/min to 250[degrees]C; 2[degrees]C/min to 300[degrees]C; held for 10 min. We used GC/MS with an electron impact ion source and with a 30-m DB-5-MS column to obtain electron impact mass spectra of target compounds in the full-scan mode. Results and Discussion We detected and quantified all of the main congeners in DE-71 (BDEs 47, 85, 99, 100, 153, and 154) and trace amounts of BDE-28 in the neutral fraction of the mouse plasma samples. No methoxylated PBDEs (MeOPBDEs) were detected in the neutral fraction. In the phenolic fraction, three bromophenols (2,4-DBP, 2,4,5-TBP, and 2,4,6-TBP) and six HO-PBDEs (4-HO-BDE-17, 2-HOBDE28, 4-HO-BDE-42, 3-HO-BDE-47, 6-HO-BDE-47, and 4-HO-BDE-49) were identified and quantified. 4-HO-BDE-90 was identified but not quantified because of co-elution with another peak. Several other potential phenolic metabolites (5-HOBDE- 47, 2-HO-BDE-68, 6-HO-BDE- 99, 5-HO-BDE-99, 2,3-DBP, 2,5-DBP, 2,6-DBP, and 3,5-DBP) were not detected. The concentration data for the neutral and phenolic compounds are presented in Table 1. By using a nonpolar nonpolar not having poles; not exhibiting dipole characteristics. capillary column (such as DB-5) to separate the methylated HO-PBDEs, 2-HO-BDE-66 will co-elute with 3-HO-BDE-47 (Marsh et al. 2006). However, based on its mass spectrum, the GC peak we observed should be mainly the methyl derivative of 3-HO-BDE-47. Marsh et al. (2006) also reported that the concentration of 2-HO-BDE-66 was much lower than that of 3-HO-BDE-47 in rat feces after rats were exposed to BDE-47. Thus, in this study we did not determine the concentration of 2-HO-BDE-66. The amounts of most target compounds in the blank samples were negligible except for 2,4,6-TBP, for which the blank average concentration was> 50% of that measured in the exposed samples. Relatively high blank concentrations of 2,4,6-TBP are reasonable because this compound is the most common TBP isomer isomer (ī`səmər), in chemistry, one of two or more compounds having the same molecular formula but different structures (arrangements of atoms in the molecule). Isomerism is the occurrence of such compounds. . The recoveries (mean [+ or -] SD) of surrogate standards were 96 [+ or -] 7% for BDE-77 and 96 [+ or -] 5% for 4-HO-PCB-187. Neutral compounds. DE-71 is commercial penta-BDE, and its main components are BDE-47 and BDE-99 in about equal amounts. Some other significant congeners, such as BDEs 100, 153, and 154 (Table 1), are also present in this commercial product. To evaluate the behavior of these congeners in mouse blood, we normalized their concentrations to that of BDE-99 in DE-71 and in mouse plasma as shown in Figure 1.
Table 1. Concentrations (ng/g wet weight) of neutral and phenolic compounds in mouse plasma.
Oral gavage
samples (n = 15)
Compound/congener Mean [+ or -] SD Percent of total
Neutral compounds (a)
BDE-28 (0.3) 4.4 [+ or -] 1.1 0.2
BDE-47 (36) 390 [+ or -] 100 18
BDE-85 (2.6) 57 [+ or -] 19 2.6
BDE-99 (44) 410 [+ or -] 120 19
BDE-100 (9.1) 140 [+ or -] 40 6.4
BDE-153 (4.3) 1,100 [+ or -] 380 52
BDE-154 (3.3) 22 [+ or -] 7 1.0
Total 2,150 [+ or -] 410 100
Phenolic compounds
2,4-DBP 72 [+ or -] 23 15
2,4,5-TBP 79 [+ or -] 29 16
2,4,6-TBP 5.3 [+ or -] 3.4 1.1
4-HO-BDE-17 17 [+ or -] 10 3.5
2-HO-BDE-28 11 [+ or -] 6 2.3
4-HO-BDE-42 180 [+ or -] 120 38
3-HO-BDE-47 53 [+ or -] 25 11
6-HO-BDE-47 22 [+ or -] 12 4.6
4-HO-BDE-49 42 [+ or -] 22 8.7
Total 480 [+ or -] 130 100
sc injection
samples (n = 14)
Compound/congener Mean [+ or -] SD Percent of total
Neutral compounds (a)
BDE-28 (0.3) 5.3 [+ or -] 1.6 0.5
BDE-47 (36) 360 [+ or -] 77 31
BDE-85 (2.6) 32 [+ or -] 5 2.8
BDE-99 (44) 330 [+ or -] 70 29
BDE-100 (9.1) 110 [+ or -] 20 9.2
BDE-153 (4.3) 290 [+ or -] 80 25
BDE-154 (3.3) 20 [+ or -] 4 1.7
Total 1,150 [+ or -] 130 100
Phenolic compounds
2,4-DBP 62 [+ or -] 25 17
2,4,5-TBP 86 [+ or -] 40 24
2,4,6-TBP 6.0 [+ or -] 6.0 1.6
4-HO-BDE-17 11 [+ or -] 7 3.0
2-HO-BDE-28 5.2 [+ or -] 2.5 1.4
4-HO-BDE-42 120 [+ or -] 88 32
3-HO-BDE-47 33 [+ or -] 17 9.1
6-HO-BDE-47 8.5 [+ or -] 4.0 2.3
4-HO-BDE-49 34 [+ or -] 19 9.3
Total 360 [+ or -] 104 100
Blank and control
samples (n = 19)
Compound/congener Mean [+ or -] SD
Neutral compounds (a)
BDE-28 (0.3) 0.6 [+ or -] 0.8
BDE-47 (36) 3.0 [+ or -] 6.3
BDE-85 (2.6) ND
BDE-99 (44) 2.3 [+ or -] 3.9
BDE-100 (9.1) 0.4 [+ or -] 1.3
BDE-153 (4.3) 0.6 [+ or -] 0.8
BDE-154 (3.3) 0.1 [+ or -] 0.2
Total
Phenolic compounds
2,4-DBP 1.4 [+ or -] 3.8
2,4,5-TBP 0.3 [+ or -] 0.6
2,4,6-TBP 3.3 [+ or -] 3.2
4-HO-BDE-17 ND
2-HO-BDE-28 0.1 [+ or -] 0.2
4-HO-BDE-42 1.1 [+ or -] 2.7
3-HO-BDE-47 ND
6-HO-BDE-47 ND
4-HO-BDE-49 0.3 [+ or -] 0.8
Total
ND, not detected.
(a) Congeners (percentages) found in DE-71.
As shown in Figure 1, the congener congener /con·ge·ner/ (kon´je-ner) something closely related to another thing, as a member of the same genus, a muscle having the same function as another, or a chemical compound closely related to another in composition and exerting ratios of BDEs 47, 100, and 154 are about the same in mouse plasma as in DE-71. However, BDE-153 behaved quite differently. The ratio of BDE-153 to BDE-99 was< 10% in DE-71; however, this ratio increased to 88 [+ or -] 24% in plasma samples following sc injection, and it increased to 270 [+ or -] 93% after oral gavage. BDEs 47, 99, and 153 represented 18, 19, and 52%, respectively, of total measurable PBDEs in oral gavage samples, whereas they represented 36, 44, and 4.3% of the total in the DE-71 mixture (Table 1). The increased ratio of BDE-153 suggests that this compound was poorly metabolized or otherwise highly persistent in mice. In orally exposed mice, two factors might influence the concentration of PBDEs in blood: uptake efficiency and removal rate. Burreau et al. (1997) reported uptake efficiencies of 90, 60, and 40% for BDEs 47, 99, and 153, respectively, in pike (Esox lucius) fed a mixture of these compounds. Other researchers also showed that BDE-153 was less absorbed than BDE-47 and BDE-99 in rats and mice following gavage (Chen et al. 2006; Sanders et al. 2006a, 2006b). The uptake efficiency for BDE-153 was lower than that of BDE-47 and BDE-99, probably because of its larger size. Two processes are able to remove PBDEs from blood: distribution between blood and other tissue (mainly adipose tissue adipose tissue (ăd`əpōs'): see connective tissue. adipose tissue or fatty tissue Connective tissue consisting mainly of fat cells, specialized to synthesize and contain large globules of fat, within a ) and metabolism. Because adipose tissue is the main tissue sink of BDE-153 in mice (Staskal et al. 2006) and because others have found either similar BDE-99 and BDE-153 distributions to adipose tissue (Sanders et al. 2006b) or higher adipose tissue distribution for BDE-153 than for BDE-99 or BDE-47 (Staskal et al. 2006) in exposed rodents, it seems that sequestration sequestration In law, a writ authorizing a law-enforcement official to take into custody the property of a defendant in order to enforce a judgment or to preserve the property until a judgment is rendered. to tissues cannot explain the higher blood concentration of BDE-153 compare to BDE-99. Furthermore, both uptake and distribution are biophysical processes, which are likely to have little isomer selectivity. For example, BDE-154 and BDE-153 should have almost the same absorption and distribution behavior because these two isomers isomers (ī´sōmurz), n.pl 1. organic compounds having the same empirical formula–i.e. are close in structure and in their physicochemical physicochemical /phys·i·co·chem·i·cal/ (fiz?i-ko-kem´ik-il) pertaining to both physics and chemistry. phys·i·co·chem·i·cal adj. 1. Relating to both physical and chemical properties. properties, especially their Kow values (Braekevelt et al. 2003). We found no relative increase of BDE-154 in mouse plasma samples compared with its relative concentration in DE-71 (Table 1, Figure 1); therefore, differential metabolism is the more likely explanation for the accumulation of BDE-153 in mice. Metabolic enzymes, which might have high isomer selectivity, could determine the concentration pattern of congeners in tissues, as well as their fate and potential toxicity (Hakk and Letcher 2003). In mammals, the liver is the main site where xenobiotic xen·o·bi·ot·ic adj. Foreign to the body or to living organisms. Used of chemical compounds. n. A xenobiotic chemical. xenobiotic any substance, harmful or not, that is foreign to the animal's biological system. chemicals are metabolized. High concentrations of BDE-153 in blood might suggest that BDE-153 was resistant to enzyme degradation in mouse liver. Sanders et al. (2006b) reported that when rats were exposed to a mixture of BDE-47, BDE-99, and BDE-153, the concentration of BDE-153 in liver was three times higher than that of BDE-47 and BDE-99. BDE-153 was only a minor component in both commercial penta-BDE and octa-BDE technical mixtures (Birnbaum and Staskal 2004). In field samples, such as sediment and ambient and indoor air, no obvious evidence of BDE-153 accumulation was found when compared to BDE-47 and BDE-99 (Hites 2004). This is expected for congeners that have comparable environmental fates; that is, they have similar physicochemical pathways from their sources to the environmental media from which they are sampled. Conversely, relatively high concentrations of BDE-153 have been measured in samples from some wild animals WILD ANIMALS. Animals in a state of nature; animals ferae naturae. Vide Animals; Ferae naturae. and humans, especially in liver and blood (plasma or serum) samples. Voorspoels et al. (2006) reported that, in the liver of red foxes from Belgium, the concentration of BDE-153 was> 10 times higher than that of BDE-99 and 3 times higher than that of BDE-47. Recently, relatively high concentrations of BDE-153 were also observed in human sera, especially from the Netherlands and Sweden (Weiss et al. 2004, 2006). Although it has been proposed that debromination of BDE-209 may be a source of BDE-153 (Weiss et al. 2006), at present there is no evidence to support this hypothesis. When carp were exposed to BDE-209, the congeners BDE-154, BDE-155, and another unidentified hexa-BDE were the three main hexabrominated products (Stapleton et al. 2006a), suggesting that BDE-153 was not preferentially formed from BDE-209, at least in fish. In the present study, BDE-209 was not present to serve as a precursor of BDE-153. Therefore, resistance to enzyme degradation is likely to be the most important cause of the increased relative concentration of BDE-153 observed in various animals. Phenolic compounds. HO-PBDEs are metabolites of PBDEs in animals, and they can also occur in marine environments as natural products (Malmvarn et al. 2005a). These compounds have been observed in animals from in vivo experiments (Malmberg et al. 2005; Marsh et al. 2006) and in field samples (sometime in the form of methylated derivatives) (Malmvarn et al. 2005a, 2005b; Marsh et al. 2004; Stapleton et al. 2006b; Valters et al. 2005). In the present study, we identified many phenolic metabolites, limited only by the availability of standards. Based on the metabolites we measured, there seem to be three main metabolic pathways for PBDEs in mice: cleavage of the diphenyl ether bond, hydroxylation, and debromination/hydroxylation. Table 1 lists the phenolic compounds measured in the mouse plasma samples, including their concentrations in animals dosed by oral gavage and by sc injection. All of these metabolites were identified not only by comparing their retention times to those of authentic standards but also from their mass spectra, which were obtained using GC/MS with an electron impact ion source operating in full-scan mode. Cleavage of the diphenyl ether bond. Most recent research has focused on the hydroxylated PBDE metabolites, but few articles have reported diphenyl ether bond cleavage. Omitting 2,4,6-TBP because of blank interferences, we have identified two bromophenol metabolites (2,4-DBP and 2,4,5-TBP), which could only be obtained through the cleavage of the diphenyl ether bond. These bromophenols were detected at concentrations higher than most of the two-ring hydroxylation products (Table 1), suggesting that diphenyl ether bond cleavage is an important metabolic pathway for PBDEs in mice. Previous studies have reported the cleavage of the diphenyl ether bond of PBDEs in the gas phase (Raff and Hites 2006) and of a PBDE-like thyropropionic acid in solution (Matsuura et al. 1971). The mechanism proposed for such reactions involves a HO radical attacking the carbon-oxygen bond. A similar mechanism has been reported to cleave cleat, cleave claw of any cloven-footed animal. the thyroxine diphenyl ether bond in vitro in vitro /in vi·tro/ (in ve´tro) [L.] within a glass; observable in a test tube; in an artificial environment. in vi·tro adj. In an artificial environment outside a living organism. by incubation with rat liver homogenates (Balsam balsam (bôl`səm), fragrant resin obtained from various trees. The true balsams are semisolid and insoluble in water, but they are soluble in alcohol and partly so in hydrocarbons. et al. 1983). In the case of PBDEs, the intermediate product then cleaves into a brominated phenol phenol (fē`nōl), C6H5OH, a colorless, crystalline solid that melts at about 41°C;, boils at 182°C;, and is soluble in ethanol and ether and somewhat soluble in water. and a phenoxy radical, which can abstract hydrogen to form another brominated phenol. In this potential pathway, 2,4,5-TBP could come mainly from BDE-99, whereas 2,4-DBP could come from both BDE-47 and BDE-99; therefore, the concentration of 2,4-DBP would be expected to be greater than that of 2,4,5-TBP. However, our measurements showed a concentration ratio of 2,4-DBP to 2,4,5-TBP of 0.89 (the molecular ratio was 1.2), which is near the concentration ratio of BDE-47 to BDE-99 in DE-71 (0.82; the molecular ratio was 0.96). Although the ratio of 2,4-DBP to 2,4,5-TBP might be influenced by different residence times of these two compounds in blood, this ratio could also suggest the occurrence of another metabolic step in animals that does not occur in the gas phase or in solution. For example, BDE-99 could produce one molecule of 2,4,5-TBP and one molecule of 3,5-dibromocatechol (3,5-DBC) through an arene oxide intermediate (Chen et al. 2006), and BDE-47 could produce 2,4-DBP and 3,5-DBC, as shown in Figure 2. The same degradation pathway was proposed by Schmidt et al. (1993) when halogenated halogenated pertaining to a substance to which a halogen is added. halogenated salicylanilides see rafoxanide, clioxanide. diphenyl ethers were degraded by the bacterium Sphingomonas sp. Strain SS3. In fact, the bacterial scission scis·sion n. 1. A separation, division, or splitting, as in fission. 2. See cleavage. of ether bonds is an important degradation pathway for compounds with ether linkages in the environment, including diphenyl ethers (White et al. 1996). We suggest that this pathway is important not only in bacterial degradation but also in mammals. However, at present there are no reports in the literature of bromocatechol as a PBDE metabolite metabolite, organic compound that is a starting material in, an intermediate in, or an end product of metabolism. Starting materials are substances, usually small and of simple structure, absorbed by the organism as food. in rodents or in other animals. Because there was no standard available for 3,5-DBC, we did not measure this compound. Identification of 3,5-DBC as an animal metabolite in future studies will help further our understanding of the cleavage of the diphenyl ether bond in PBDEs. Hydroxylation. Hydroxylation is an important metabolic pathway for PBDEs in animals. We identified and quantitated almost all possible HO-tetra-BDE peaks in mouse plasma (Table 1). If we assume that all HOtetraPBDEs came from arene oxide intermediates of BDE-47 and that all of these HO-PBDEs have the same residence time in mouse blood, then we can propose a metabolic pathway and estimate the product proportions as shown in Figure 3. Another potential metabolite, 2-HOBDE68, was not detected, suggesting that there was no possible way to form this compound from BDE-47 (Figure 4). We suspect that hydroxylation of PBDEs is mediated by cytochrome cytochrome (sī`təkrōm'), protein containing heme (see coenzyme) that participates in the phase of biochemical respiration called oxidative phosphorylation. P450 enzymes, which can account for direct hydroxylation or hydroxylation via a 1,2-shift. The 1,2-shift mechanism proceeds via an arene oxide intermediate (Guroff et al. 1967; Jerina and Daly 1974). Obviously, 4-HO-BDE-42 and 4-HO-BDE-49 must have been formed through a 1,2-shift. The methylated products of 4-HO-BDE-42 and 4-HO-BDE-49 have also been measured in field samples (Valters et al. 2005). It is notable that these para-HOPBDEs in our samples totaled> 75% of the total measurable HO-tetra-BDE metabolites. This suggests that when the hydroxylation of BDE-47 occurred, the HO group was more likely to transfer to the para position of the phenyl phenyl (fĕn`əl), C6H5, organic free radical or alkyl group derived from benzene by removing one hydrogen atom. ring with a 1,2-shift of the original para-bromine atom. 6-HO-BDE-47 was present at a low abundance (6%), and 5-HOBDE47 was not detected. Overall, our results suggest that hydroxylation has a preference for the para position as opposed to the ortho or meta positions. The high proportion of some HO-PBDEs, such as 4-HO-BDE-42, suggests that either they were preferentially formed or were more persistent in mouse blood. These metabolites might have a substantial biological effect. For example, three HO-PBDE congeners (4-HOBDE42, 4-HO-BDE-49, and 3-HO-BDE- 47) were shown to have up to a four times stronger affinity to TTR than does thyroxine (Malmberg et al. 2005). This suggested that para-HO-PBDEs might be the most thyroxinelike HO-PBDEs. In any case, the preferential formation and/or persistence of para-HOPBDEs in mice suggests these compounds should receive more toxicologic attention. As discussed above, we assumed that HO-tetra-BDEs result from the hydroxylation of BDE-47. HO-PBDEs could also result from debromination/hydroxylation reactions of BDE-99, but these reactions may be less important than hydroxylation alone. Moreover, by comparing the structure of HO-tetra-BDEs, such as 4-HO-BDE-42, with BDE-47 and BDE-99, it is apparent that these HO-tetra-BDEs more likely come from hydroxylation of BDE-47 rather than from debromination/hydroxylation of BDE-99 (Figure 5). In addition to the mono-hydroxylated tetra-BDEs, one dihydroxylated tetra-BDE was identified through its mass spectrum, but we were unable to determine its substitution pattern. Others have made a similar observation (Malmberg et al. 2005). For the three HO-penta-BDE isomers for which we had standards (5-HO-BDE-99, 6-HO-BDE-99, and 4-HO-BDE-90), only 4-HO-BDE-90 was detected, but we found two other relatively abundant GC peaks corresponding to other HO-penta-BDEs, which together could represent the most abundant HO-penta-BDEs (Figure 6). The electron impact mass spectra of these two peaks indicated that the hydroxyl group was in the meta-position of the phenyl ring. We observed ions due to [[M].sup.+], [[M-2Br].sup.+], and [[M-2Br-[CH.sub.3]].sup.+], which were consistent with a methylated derivative of a meta-HO-BDE structure as described by Malmberg et al. (2005). The preferential formation of metaHO-BDEs from a penta-BDE, presumably pre·sum·a·ble adj. That can be presumed or taken for granted; reasonable as a supposition: presumable causes of the disaster. BDE-99, was quite different from the hydroxylation of BDE-47, for which para-HO-BDEs were the major metabolites. Debromination/hydroxylation. The metabolic pathway of debromination/ hydroxylation has also been observed in other studies. When rats were exposed to BDE-47, three kinds of HO-tri-BDE were found in feces (Marsh et al. 2006). In the present study, we found and quantitated two HO-tri-BDEs (4-HO-BDE-17 and 2-HO-BDE-28). Although we found trace amounts of BDE-28in commercial DE-71 and it was detected in mouse plasma, the concentration of BDE-28 was much lower than those of 4-HO-BDE-17 and 2-HO-BDE-28 (Table 1). It is more reasonable to believe that these two isomers were formed by the debromination/hydroxylation of a more abundant congener, such as BDE-47, rather than by hydroxylation of BDE-28 (Figure 7). Moreover, although there might be a 1,2-shift during the hydroxylation process and bromine could shift to the adjacent position on the phenyl ring, at present there is no indication that bromine can shift from a para position to an ortho position. In other words Adv. 1. in other words - otherwise stated; "in other words, we are broke" put differently , 4-HO-BDE-17 could not be formed from BDE-28, leaving debromination/ hydroxylation of a more brominated BDE See Borland Database Engine. (such as BDE-47) as the more likely pathway (Figure 7). Compared with those metabolites formed through direct hydroxylation, the concentration of metabolites formed by debromination/ hydroxylation was low (Table 1), which suggests that hydroxylation is a more important process than debromination/hydroxylation, at least for tetra-BDE. Conclusion BDE-153 accumulates in the blood of mice exposed to commercial DE-71, suggesting that this compound might be resistant to enzymatic degradation. 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Environ Sci Technol 40:2937-2943; doi:10.1021/es060081k [Online 25 March 2006]. Weiss J, Meijer L, Sauer P, Linderholm L, Athanassiadis I, Bergman [ANGSTROM]. 2004. PBDE and HBCDD levels in blood from Dutch mothers and infants--analysis of a Dutch Groningen infant cohort. Organohalogen Compounds 66:2677-2682. Weiss J, Wallin E, Axmon A, Jonsson BAG, Akesson H, Janak K, et al. 2006. Hydroxy-PCBs, PBDEs, and HBCDDs in serum from an elderly population of Swedish fisherman's wives and associations with bone density. Environ Sci Technol 40:6282-6289; doi:10.1021/es0610941 [Online 9 September 2006]. Xinghua Qiu (1), Minerva, Mercado-Feliciano (2),Robert M. Bigsby (3), and Ronald A. Hites (1) (1)School of Public and Environmental Affairs, Indiana University, Bloomington, Indiana, USA; (2)Department of Pharmacology and Toxicology, School of Medicine, Indiana University, Bloomington, Indiana, USA; (3)Department of Obstetrics and Gynecology obstetrics and gynecology Medical and surgical specialty concerned with the management of pregnancy and childbirth and with the health of the female reproductive system. , School of Medicine, Indiana University, Indianapolis, Indiana, USA. White GF, Russell NJ, Tidswell EC. 1996. Bacterial scission of ether bonds. Microbiol Rev 60:216-232. Address correspondence to R.A. Hites, School of Public and Environmental Affairs, Indiana University, 1315 E. 10th St., Bloomington, IN 47405 USA. Telephone: (812) 855-0193. Fax: (812) 855-1076. E-mail: HitesR@indiana.edu We thank G. Marsh, who provided most of the HO-PBDE standards used in this research. This study was supported by grant ES013341 from the National Institute of Environmental Health Sciences The National Institute of Environmental Health Sciences (NIEHS) is one of 27 Institutes and Centers of the National Institutes of Health (NIH),which is a component of the Department of Health and Human Services (DHHS). The Director of the NIEHS is Dr. David A. Schwartz. (M.M.F.). The authors declare they have no competing financial interests. Received 18 December 2006; accepted 6 April 2007. |
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