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Musk xylene

April 13, 2024

Musk xylene is a synthetic musk fragrance which mimics natural musk. It has been used as a perfume fixative in a wide variety of consumer products, and is still used in some cosmetics and fragrances.

Musk xylene[1]
Names
Preferred IUPAC name
1-tert-Butyl-3,5-dimethyl-2,4,6-trinitrobenzene
Identifiers
  • 81-15-2 Y
3D model (JSmol)
  • Interactive image
ChEBI
  • CHEBI:77320 N
ChEMBL
  • ChEMBL228513 Y
ChemSpider
  • 56123 Y
ECHA InfoCard 100.001.210
EC Number
  • 201-329-4
KEGG
  • C19462 N
MeSH musk+xylene
  • 62329
UNII
  • 1ZAO16GU5K Y
UN number 2956
  • DTXSID1021405
  • InChI=1S/C12H15N3O6/c1-6-9(13(16)17)7(2)11(15(20)21)8(12(3,4)5)10(6)14(18)19/h1-5H3 Y
    Key: XMWRWTSZNLOZFN-UHFFFAOYSA-N Y
  • CC1=C(C(=C(C(C)=C1N(=O)=O)N(=O)=O)C(C)(C)C)N(=O)=O
Properties
C
12H
15N
3O
6
Molar mass 297.2640 g mol−1
Appearance Yellow crystals
Odor Musk-like
Melting point 110 °C (230 °F; 383 K)
150 ng dm−1
log P 4.369
Vapor pressure 9.7 mPa (at 40 °C)
Hazards
GHS labelling:
Danger
H201, H351, H410
P201, P202, P210, P230, P240, P250, P273, P280, P281, P308+P313, P370+P380, P372, P373, P391, P401, P405, P501
Flash point 2 °C (36 °F; 275 K)
305 to 341 °C (581 to 646 °F; 578 to 614 K)
Related compounds
Related nitro musks
 Musk ambrette
Related compounds
 Trinitrotoluene
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
N verify (what is YN ?)

Musk xylene was once the most widely used of the "nitro-musks", but its use has declined sharply since the mid-1980s due to safety and environmental concerns. Its explosive and carcinogenic hazards are recognized to be borderline, and musk xylene is a useful example of the lowest level of such risks which need to be taken into account. However, it is a very persistent and very bioaccumulative pollutant in the aquatic environment (vPvB substance), and is the first substance to be proposed as a "substance of very high concern" (SVHC) for these reasons alone under the European Union REACH Regulation. Since no company has applied for authorisation, it is banned in the EU.[2]

Production and use edit

Musk xylene is produced from meta-xylene (1,3-dimethylbenzene), by a Friedel–Crafts alkylation with tert-butyl chloride and aluminium chloride followed by nitration with fuming nitric acid or with a 70:30 mixture of nitric acid and sulfuric acid. The crude product is recrystallized from 95% ethanol.[3]

 

Use of musk xylene in various domestic products
Product Mass fraction (%)
Skin cream 0.0075
Deodorant 0.0075
Shampoo 0.01
Household detergents 0.02
Aftershave 0.03
Toilet soap 0.04
Air freshener 0.07
Cologne/eau de toilette 0.075
Fine fragrance 0.05–0.1
Sources: International Agency for Research on Cancer (1996); European Union Risk Assessment Report (2005).
NOTE: Use of musk xylene varies widely between different countries and manufacturers; these figures should be regarded as indicative maxima for the period 1990–present.

Musk xylene has been used in a wide variety of consumer products since the early 1900s, usually in very small quantities. World production of nitro musks in 1987 was about 2500 tonnes, but had fallen to about 1000 tonnes by the early 1990s: musk xylene made up roughly two-thirds of the production of nitro musks during this period. Production was concentrated in Western Europe, with the United Kingdom alone accounting for 28% of world production of nitro musks.[4][5]

Use of musk xylene continued to decline through the 1990s, as fragrance manufacturers voluntarily switched to alternative fragrance compounds.[6] For example, musk xylene has not been used in Japanese products (on a voluntary basis) since 1982,[4] and the Association of the German Toiletries and Detergents Industry (IKW) recommended the replacement of musk xylene by another compound in 1993.[7] Production of musk xylene in the European Union came to a halt and, by 2000 (the last year for which full data are available), imports to Europe were only 67 tonnes, with China as the most important source.[7] The estimated 2008 usage of musk xylene in the European Union was 25 tonnes.[8]

Musk xylene is still permitted for use in cosmetics products (except oral care products) in the European Union under the Cosmetics Directive. The permitted quantities are: up to 1% in fine fragrances; up to 0.4% in eau de toilette; up to 0.03% in other products.[9] European Union suppliers must inform their customers on request if a product contains more than 0.1% by weight of musk xylene.[10]

Safety edit

Musk xylene is an analogue of the explosive trinitrotoluene (TNT), so it is unsurprising that its safety characteristics have been studied in some detail. Indeed, the nitro musks were first discovered in an attempt to produce new high explosives. It has also been used – albeit in very small amounts – in mass-market consumer products for the last hundred years. The discovery of musk xylene residues in the environment prompted new concerns about its possible long-term toxicity, and led to the sharp decline in its use from the mid to late 1980s. The European Chemicals Agency has listed musk xylene as a "substance of very high concern" (SVHC) under the REACH Regulation, judging it to be "very persistent and very bioaccumulative" (vPvB) but not meeting the criteria for human or environmental toxicity to be of concern.[11]

Explosive properties edit

Musk xylene is used as an example case in the United Nations Manual of Test Methods and Criteria as a substance which shows some explosive properties but which does not have to be transported as Class 1 dangerous goods under the Model Regulations.[12] It is transported as small flakes in plastic bags (maximum 50 kg net mass), which are themselves within cardboard drums to avoid tearing.[13][14] This does not count as "confinement" in the meaning of explosives tests: indeed, the special packing is intended to prevent over-confinement during transport.[15]

It will explode when detonated under confinement (UN gap test[16]) or when heated under confinement (Koenen test[17]), but does not explode under the BAM fallhammer test[18] (limiting impact energy 25 J) or the BAM friction test[19] (limiting load >360 N).[12] There is no ignition, explosion, self-heating or visible decomposition when musk xylene is heated (without confinement) to 75 °C for 48 hours.[12][20]

Nevertheless, musk xylene is classified in the European Union as an explosive under the Dangerous Substances Directive[21] and as a category 1.1 explosive under the CLP Regulation.[22] The European Union classification reflects the fact that hazardous heating under confinement cannot be excluded in the industrial use of musk xylene, as opposed to its transport, and so it is necessary to warn potential users of the risk.[23]

Carcinogenicity edit

Musk xylene also demonstrates some of the problems of classifying substances as carcinogens. It has been placed into Group 3 ("not classifiable as to their carcinogenicity to humans") by the International Agency for Research on Cancer (IARC),[4] and is classified in the European Union as category 3 carcinogen ("cause concern for man owing to possible carcinogenic effects but in respect of which the available information is not adequate for making a satisfactory assessment") under the Dangerous Substances Directive[21] and a category 2 carcinogen ("suspected human carcinogen") under the CLP Regulation.[22]

These classifications are based mainly on a single study of oral exposure to musk xylene in B6C3F1-strain mice.[24] The mice showed a highly significant increase in liver adenomas and carcinomas at median dietary intakes of 170 mg/kg body weight (males) and 192 mg/kg body weight (females), as well as significant increases in adenomas in the Harderian gland (male mice only) and in the liver at median dietary intakes of 91 mg/kg body weight (males) and 101 mg/kg body weight (females).[24]

The European Union Risk Assessment Report makes a number of observations about this study:[25]

  • it was conducted on a single species; no studies are available on, for example, rats;
  • B6C3F1-strain mice are known to be particularly prone to liver cancers;
  • the doses were high, and toxic effects (especially on the liver) were observed in the test animals;
  • the mechanism of tumour development is unclear.

Musk xylene is not genotoxic.[26] It has significant effects on liver function which are similar to those shown by phenobarbital, for example, induction of CYP2B6 and other cytochrome P450 enzymes.[27] The human carcinogenicity of phenobarbital has been the subject of debate,[28][29] but it is currently classified in group 2B by the IARC[29] and this appears to have been an important consideration in the classification of musk xylene as a category 3 carcinogen under the Dangerous Substances Directive.[30] Nevertheless, the European Union Risk Assessment Report admits that musk xylene is a "borderline case".[25]

A further complication is the metabolism of musk xylene. One route of metabolism is through reduction of one or more nitro groups by the intestinal microflora (gut bacteria) to produce aromatic amines such as p-NH2-musk xylene.[4] This metabolite has a different liver toxicity: in particular, it inhibits the CYP1B enzymes by covalent binding.[27]

Induction of cytochrome P450 enzymes, the most likely cause of rodent carcinogenicity, is a threshold phenomenon, with a no observed effect level (NOEL) of 10 mg/kg/day in mice and a lowest observed effect level (LOEL) of 10 mg/kg/day in rats. The lowest oral dose which caused cancer (LOAEL) in B6C3F1-mice was 70 mg/kg/day.[27] These are 1–3 orders of magnitude higher than human exposure, which is principally dermal rather than oral.[31]

Environmental concerns edit

The first concerns about musk xylene arose in the early 1980s, with the detection of musk xylene residues in fish from the Tama River near Tokyo,[32] and subsequently in the river water itself, especially at the outlets of sewage treatment plants. This led to a voluntary moratorium on the use of musk xylene in Japan from 1982.[4] Similar residues were subsequently found in European waters such as the Elbe, Stör and Ruhr rivers in Germany, the German Bight area of the North Sea and sewage treatment plant outlets in Sweden.[4][33] Typical concentrations were >0.001 µg/L in sea water, 0.001–0.01 µg/L in river water and 0.01–0.1 µg/L (sometimes higher) in the effluent from sewage treatment plants.

These findings indicate that musk xylene is not completely removed from wastewater by the sewage treatment process. Two studies in Germany found compared musk xylene concentrations in incoming wastewater and sewage treatment plant effluent, and found removal rates of 82% and 58%.[34][35] However, they are not concentrations which are expected to be toxic to aquatic life. The European Union Risk Assessment Report reviewed more than a dozen studies of the toxicity of musk xylene to algae and to aquatic vertebrates and invertebrates, and all found no observed effect concentrations greater than 10 µg/L,[36] the chronic aquatic toxicity threshold in the EU REACH Regulation.[37]

The biodegradation of musk xylene in sea water and in mixed sea water/sediment systems was studied in laboratory simulations using carbon-14 labelled musk xylene, and the results discussed in an addendum to the European Union Risk Assessment Report.[11] The half-life in marine sediment was estimated to be 60 days or less, with biodegradation occurring by anaerobic reduction of the nitro groups. The half-life in sediment-free sea water was estimated to be more than 150 days, far above the "very persistent" threshold of 60 days.[37] The 2008 addendum also discussed the photolysis of musk xylene in water and in air, which are rapid: however, photolysis was not considered to be relevant in the persistence of musk xylene in the environment, and was not taken into account in classifying it as a "very persistent" substance.[11]

Several different primary bioaccumulation studies were reviewed in the European Union Risk Assessment Report, with bioaccumulation factors varying between 640 L/kg and 6740 L/kg.[38] Given that musk xylene has a very high octanol–water partition coefficient (log Kow = 4.9),[1] the higher bioaccumulation factors were considered to be the more significant. The 2008 addendum[11] considered a further laboratory study from the Japanese Ministry of International Trade and Industry which was not available to the authors of the original Risk Assessment Report and which also showed bioaccumulation factors in fish (Cyprinus carpio) that were higher than the REACH threshold[37] of 5000 L/kg for "very bioaccumulative" substances. Bioaccumulation factors of more than 5000 L/kg (wet weight basis) have also been found in carp (Carassius carassius) and eels (Anguilla anguilla) from a sewage treatment pond.[39]

References edit

  1. ^ a b Section 1.3, European Union Risk Assessment Report (2005), pp. 6–7.
  2. ^ . Archived from the original on 2015-06-16. Retrieved 2015-05-18.
  3. ^ Bedoukian (1986).
  4. ^ a b c d e f International Agency for Research on Cancer (1996).
  5. ^ Ippen (1994).
  6. ^ OSPAR Commission (2004).
  7. ^ a b Section 2, European Union Risk Assessment Report (2005), pp. 9–10.
  8. ^ RIVM–DHI–RPA (2008).
  9. ^ ATP (2004) to the Cosmetics Directive.
  10. ^ Article 31.3, REACH Regulation, at p. 108.
  11. ^ a b c d European Chemicals Agency (2008).
  12. ^ a b c Section 10.5, Part I, UN Manual of Tests and Criteria, pp. 23–28.
  13. ^ Section 4.1.1.2, European Union Risk Assessment Report (2005), p. 42.
  14. ^ Packing instruction P409, Section 4.1.4, Part 4, UN Model Regulations, at p. 59.
  15. ^ Special provision 133, Section 3.3.1, Part 3, UN Model Regulations, at p. 291.
  16. ^ Section 11.4, Part I, UN Manual of Tests and Criteria, pp. 32–34.
  17. ^ Section 11.5, Part I, UN Manual of Tests and Criteria, pp. 35–40.
  18. ^ Section 13.4.2, Part I, UN Manual of Tests and Criteria, pp. 76–83.
  19. ^ Section 13.5.1, Part I, UN Manual of Tests and Criteria, pp. 105–8.
  20. ^ Section 13.6, Part I, UN Manual of Tests and Criteria, pp. 117–19.
  21. ^ a b ATP (2004) to the Dangerous Substances Directive, at p. 121 (index no. 609-068-00-1).
  22. ^ a b CLP Regulation, at p. 615 (index no. 609-068-00-1).
  23. ^ Position document prepared for the European Chemicals Bureau (2002).
  24. ^ a b Maekawa et al. (1990).
  25. ^ a b Section 4.1.2.7.3, European Union Risk Assessment Report (2005), pp. 83–85.
  26. ^ Section 4.1.2.6, European Union Risk Assessment Report (2005), pp. 74–77.
  27. ^ a b c Section 4.1.2.7.1, European Union Risk Assessment Report (2005), pp. 77–83.
  28. ^ Williams & Whysner (1996).
  29. ^ a b International Agency for Research on Cancer (2001).
  30. ^ Meeting of the Commission Working Group on the Classification and Labelling of Dangerous Substances, 25 November 2002.
  31. ^ Sections 4.1.1.5 & 4.1.3.5, European Union Risk Assessment Report, pp. 57 and 109–110.
  32. ^ Yamagishi et al. (1981).
  33. ^ Section 3.1.2.4, European Union Risk Assessment Report (2005), pp. 21–24.
  34. ^ Eschke et al. (1994). Hahn (1993).
  35. ^ Later studies have found higher rates of removal of musk xylene by sewage treatment plants, around 95%: European Chemicals Agency (2008).
  36. ^ Section 3.2.1.1, European Union Risk Assessment Report (2005), pp. 31–34.
  37. ^ a b c Annex XIII, REACH Regulation, at pp. 383–85.
  38. ^ Section 3.1.1.2, European Union Risk Assessment Report (2005), pp. 12–15.
  39. ^ Gatermann et al. (2002).

Further reading edit

  • "ATP (2004) to the Cosmetics Directive": Commission Directive 2004/88/EC of 7 September 2004 amending Council Directive 76/768/EEC concerning cosmetic products for the purpose of adapting Annex III thereto to technical progress. OJEC L287, 8.9.2004, pp. 5–6.
  • "ATP (2004) to the Dangerous Substances Directive": Commission Directive 2004/73/EC of 29 August 2004 adapting to technical progress for the 29th time Council Directive 67/548/EEC on the approximation of the laws, regulations and administrative provisions relating to the classification, packaging and labelling of dangerous substances. OJEC L152, 30.04.2004, pp. 1–311.
  • Bedoukian, P. Z. (1986), Perfumery and Flavoring Synthetics (3rd ed.), Wheaton, IL: Allured Publishing, pp. 322–33, ISBN 0-931710-12-X
  • "CLP Regulation": Regulation (EC) No 1272/2008 of the European Parliament and of the Council of 16 December 2008 on classification, labelling and packaging of substances and mixtures, amending and repealing Directives 67/548/EEC and 1999/45/EC, and amending Regulation (EC) No 1907/2006. OJEC L353, 31.12.2008, pp. 1–1355.
  • Eschke, H. D.; Traud, J.; Dibowski, H. J. (1994), "Analytik und befunde kuenstlicher Nitromoschus-Substanzen in Oberflaechen- und Abwaessern sowie Fischen aus dem Einzugsgebiet der Ruhr", Vom Wasser, 83: 373–83. (in German)
  • European Chemicals Agency (8 October 2008), (PDF), archived from the original (PDF) on 6 March 2009.
  • European Union Risk Assessment Report (2005). "5-tert-butyl-2,4,6-trinitro-m-xylene (musk xylene)[permanent dead link]". 3rd Priority List, Volume 55.
  • Gatermann, R.; Biselli, S.; Hühnerfuss, H.; Rimkus, G. G.; Hecker, M.; Karbe, L. (2002), "Synthetic musks in the environment. Part 1: Species-dependent bioaccumulation of polycyclic and nitro musk fragrances in freshwater fish and mussels", Arch. Environ. Contam. Toxicol., 42 (4): 437–46, doi:10.1007/s00244-001-0041-2, PMID 11994785, S2CID 453184.
  • GHS: "Globally Harmonized System of Classification and Labelling of Chemicals" (pdf). 2021.
  • Hahn, J. (1993), "Untersuchungen zum Vorkommen von Moschus-Xylol in Fischen", Deutsche Lebensmittel-Rundschau, 89 (6): 175–77. (in German)
  • International Agency for Research on Cancer (1996), "Musk ambrette and musk xylene" (PDF), IARC Monographs on the Evaluation of Carcinogenic Risks to Humans, 65: 477–95, PMC 7681280, PMID 9097117
  • International Agency for Research on Cancer (2001), "Phenobarbital and its sodium salt" (PDF), IARC Monographs on the Evaluation of Carcinogenic Risks to Humans, 79: 161–288.
  • Ippen, Hellmut (1994), "Nitro musk", Int. Arch. Occup. Environ. Health, 66 (4): 283–85, doi:10.1007/BF00454368, PMID 7843840, S2CID 7854171.
  • Maekawa, A.; Matsushima, Y.; Onodera, H.; Shibutani, M.; Ogasawara, H.; Kodama, Y.; Kurokawa, Y.; Hayashi, Y. (1990), "Long-term toxicity/carcinogenicity of musk xylol in B6C3F mice", Food Chem. Toxicol., 28 (8): 581–86, doi:10.1016/0278-6915(90)90159-K, PMID 2242833.
  • Meeting of the Commission Working Group on the Classification and Labelling of Dangerous Substances (PDF), Ispra, Italy: European Chemicals Bureau, 25 November 2002, pp. 23–24, ECBI/42/02 Rev. 2[permanent dead link].
  • OSPAR Commission (2004), (PDF), archived from the original (PDF) on 2010-07-07. OSPAR background document.
  • Position document prepared for the European Chemicals Bureau (9 December 2002). .
  • "REACH Regulation": Regulation (EC) No 1907/2006 of the European Parliament and of the Council of 18 December 2006 concerning the Registration, Evaluation, Authorisation and Restriction of Chemicals (REACH), establishing a European Chemicals Agency. OJEU L396, 30.12.2006, pp. 1–849.
  • RIVMDHI–RPA (2008), (PDF), archived from the original (PDF) on 2009-02-05 {{citation}}: |author= has generic name (help). Technical report for the European Chemicals Agency.
  • "UN Manual of Tests and Criteria": UN Recommendations on the Transport of Dangerous Goods. Manual of Tests and Criteria (Fourth revised ed.), New York and Geneva: United Nations, 2002, ISBN 92-1-139087-7, ST/SG/AC.10/11/Rev.4
  • "UN Model Regulations": UN Recommendations on the Transport of Dangerous Goods. Model Regulations (Fifteenth ed.), New York and Geneva: United Nations, 2007, ISBN 978-92-1-139120-6, ST/SG/AC.10/1/Rev.15
  • Williams, G. M.; Whysner, J. (1996), "Epigenetic carcinogens: evaluation and risk assessment", Exp. Toxic. Pathol., 48 (2–3): 189–95, doi:10.1016/S0940-2993(96)80041-8, PMID 8672874
  • Yamagishi, Tatsunori; Miyazaki, Tomoyuki; Horii, Shozo; Kaneko, Seiji (1981), "Identification of musk xylene and musk ketone in freshwater fish collected from the Tama River, Tokyo", Bull. Environ. Contam. Toxicol., 26 (1): 656–62, doi:10.1007/BF01622152, PMID 7260436, S2CID 32533880.
  • Wiegel, Simone; Harms, Heinz; Stachel, Burkhard (2000), Synthetische Moschus-Duftstoffe in der Elbe (PDF), Hamburg: Arbeitsgemeinschaft für die Reinhaltung der Elbe. (in German)
  • Institut für Umweltmedizin der Stadt Wien (2000), (PDF), archived from the original (PDF) on 2016-03-03, retrieved 2009-04-05. Monograph 121. (in German)
  • European Chemicals Agency (2009a), (PDF), archived from the original (PDF) on 2009-02-05, 14 January 2009.
  • European Chemicals Agency (2009b), (PDF), archived from the original (PDF) on 2009-02-06, 14 January 2009.
  • European Commission Scientific Committee for Food (1997), "Nitro musk compounds in food" (PDF), Food Science and Techniques, 44: 1–4.
 
Wikimedia Commons has media related to Nitro musks.

April 13, 2024
musk, xylene, synthetic, musk, fragrance, which, mimics, natural, musk, been, used, perfume, fixative, wide, variety, consumer, products, still, used, some, cosmetics, fragrances, namespreferred, iupac, name, tert, butyl, dimethyl, trinitrobenzeneidentifiersca. Musk xylene is a synthetic musk fragrance which mimics natural musk It has been used as a perfume fixative in a wide variety of consumer products and is still used in some cosmetics and fragrances Musk xylene 1 NamesPreferred IUPAC name 1 tert Butyl 3 5 dimethyl 2 4 6 trinitrobenzeneIdentifiersCAS Number 81 15 2 Y3D model JSmol Interactive imageChEBI CHEBI 77320 NChEMBL ChEMBL228513 YChemSpider 56123 YECHA InfoCard 100 001 210EC Number 201 329 4KEGG C19462 NMeSH musk xylenePubChem CID 62329UNII 1ZAO16GU5K YUN number 2956CompTox Dashboard EPA DTXSID1021405InChI InChI 1S C12H15N3O6 c1 6 9 13 16 17 7 2 11 15 20 21 8 12 3 4 5 10 6 14 18 19 h1 5H3 YKey XMWRWTSZNLOZFN UHFFFAOYSA N YSMILES CC1 C C C C C C1N O O N O O C C C C N O OPropertiesChemical formula C12 H15 N3 O6Molar mass 297 2640 g mol 1Appearance Yellow crystalsOdor Musk likeMelting point 110 C 230 F 383 K Solubility in water 150 ng dm 1log P 4 369Vapor pressure 9 7 mPa at 40 C HazardsGHS labelling PictogramsSignal word DangerHazard statements H201 H351 H410Precautionary statements P201 P202 P210 P230 P240 P250 P273 P280 P281 P308 P313 P370 P380 P372 P373 P391 P401 P405 P501Flash point 2 C 36 F 275 K Autoignitiontemperature 305 to 341 C 581 to 646 F 578 to 614 K Related compoundsRelated nitro musks Musk ambretteRelated compounds TrinitrotolueneExcept where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa N verify what is Y N Infobox references Musk xylene was once the most widely used of the nitro musks but its use has declined sharply since the mid 1980s due to safety and environmental concerns Its explosive and carcinogenic hazards are recognized to be borderline and musk xylene is a useful example of the lowest level of such risks which need to be taken into account However it is a very persistent and very bioaccumulative pollutant in the aquatic environment vPvB substance and is the first substance to be proposed as a substance of very high concern SVHC for these reasons alone under the European Union REACH Regulation Since no company has applied for authorisation it is banned in the EU 2 Contents 1 Production and use 2 Safety 2 1 Explosive properties 2 2 Carcinogenicity 2 3 Environmental concerns 3 References 3 1 Further readingProduction and use editMusk xylene is produced from meta xylene 1 3 dimethylbenzene by a Friedel Crafts alkylation with tert butyl chloride and aluminium chloride followed by nitration with fuming nitric acid or with a 70 30 mixture of nitric acid and sulfuric acid The crude product is recrystallized from 95 ethanol 3 nbsp Use of musk xylene in various domestic products Product Mass fraction Skin cream 0 0075Deodorant 0 0075Shampoo 0 01Household detergents 0 02Aftershave 0 03Toilet soap 0 04Air freshener 0 07Cologne eau de toilette 0 075Fine fragrance 0 05 0 1Sources International Agency for Research on Cancer 1996 European Union Risk Assessment Report 2005 NOTE Use of musk xylene varies widely between different countries and manufacturers these figures should be regarded as indicative maxima for the period 1990 present Musk xylene has been used in a wide variety of consumer products since the early 1900s usually in very small quantities World production of nitro musks in 1987 was about 2500 tonnes but had fallen to about 1000 tonnes by the early 1990s musk xylene made up roughly two thirds of the production of nitro musks during this period Production was concentrated in Western Europe with the United Kingdom alone accounting for 28 of world production of nitro musks 4 5 Use of musk xylene continued to decline through the 1990s as fragrance manufacturers voluntarily switched to alternative fragrance compounds 6 For example musk xylene has not been used in Japanese products on a voluntary basis since 1982 4 and the Association of the German Toiletries and Detergents Industry IKW recommended the replacement of musk xylene by another compound in 1993 7 Production of musk xylene in the European Union came to a halt and by 2000 the last year for which full data are available imports to Europe were only 67 tonnes with China as the most important source 7 The estimated 2008 usage of musk xylene in the European Union was 25 tonnes 8 Musk xylene is still permitted for use in cosmetics products except oral care products in the European Union under the Cosmetics Directive The permitted quantities are up to 1 in fine fragrances up to 0 4 in eau de toilette up to 0 03 in other products 9 European Union suppliers must inform their customers on request if a product contains more than 0 1 by weight of musk xylene 10 Safety editMusk xylene is an analogue of the explosive trinitrotoluene TNT so it is unsurprising that its safety characteristics have been studied in some detail Indeed the nitro musks were first discovered in an attempt to produce new high explosives It has also been used albeit in very small amounts in mass market consumer products for the last hundred years The discovery of musk xylene residues in the environment prompted new concerns about its possible long term toxicity and led to the sharp decline in its use from the mid to late 1980s The European Chemicals Agency has listed musk xylene as a substance of very high concern SVHC under the REACH Regulation judging it to be very persistent and very bioaccumulative vPvB but not meeting the criteria for human or environmental toxicity to be of concern 11 Explosive properties edit Musk xylene is used as an example case in the United Nations Manual of Test Methods and Criteria as a substance which shows some explosive properties but which does not have to be transported as Class 1 dangerous goods under the Model Regulations 12 It is transported as small flakes in plastic bags maximum 50 kg net mass which are themselves within cardboard drums to avoid tearing 13 14 This does not count as confinement in the meaning of explosives tests indeed the special packing is intended to prevent over confinement during transport 15 It will explode when detonated under confinement UN gap test 16 or when heated under confinement Koenen test 17 but does not explode under the BAM fallhammer test 18 limiting impact energy 25 J or the BAM friction test 19 limiting load gt 360 N 12 There is no ignition explosion self heating or visible decomposition when musk xylene is heated without confinement to 75 C for 48 hours 12 20 Nevertheless musk xylene is classified in the European Union as an explosive under the Dangerous Substances Directive 21 and as a category 1 1 explosive under the CLP Regulation 22 The European Union classification reflects the fact that hazardous heating under confinement cannot be excluded in the industrial use of musk xylene as opposed to its transport and so it is necessary to warn potential users of the risk 23 Carcinogenicity edit Musk xylene also demonstrates some of the problems of classifying substances as carcinogens It has been placed into Group 3 not classifiable as to their carcinogenicity to humans by the International Agency for Research on Cancer IARC 4 and is classified in the European Union as category 3 carcinogen cause concern for man owing to possible carcinogenic effects but in respect of which the available information is not adequate for making a satisfactory assessment under the Dangerous Substances Directive 21 and a category 2 carcinogen suspected human carcinogen under the CLP Regulation 22 These classifications are based mainly on a single study of oral exposure to musk xylene in B6C3F1 strain mice 24 The mice showed a highly significant increase in liver adenomas and carcinomas at median dietary intakes of 170 mg kg body weight males and 192 mg kg body weight females as well as significant increases in adenomas in the Harderian gland male mice only and in the liver at median dietary intakes of 91 mg kg body weight males and 101 mg kg body weight females 24 The European Union Risk Assessment Report makes a number of observations about this study 25 it was conducted on a single species no studies are available on for example rats B6C3F1 strain mice are known to be particularly prone to liver cancers the doses were high and toxic effects especially on the liver were observed in the test animals the mechanism of tumour development is unclear Musk xylene is not genotoxic 26 It has significant effects on liver function which are similar to those shown by phenobarbital for example induction of CYP2B6 and other cytochrome P450 enzymes 27 The human carcinogenicity of phenobarbital has been the subject of debate 28 29 but it is currently classified in group 2B by the IARC 29 and this appears to have been an important consideration in the classification of musk xylene as a category 3 carcinogen under the Dangerous Substances Directive 30 Nevertheless the European Union Risk Assessment Report admits that musk xylene is a borderline case 25 A further complication is the metabolism of musk xylene One route of metabolism is through reduction of one or more nitro groups by the intestinal microflora gut bacteria to produce aromatic amines such as p NH2 musk xylene 4 This metabolite has a different liver toxicity in particular it inhibits the CYP1B enzymes by covalent binding 27 Induction of cytochrome P450 enzymes the most likely cause of rodent carcinogenicity is a threshold phenomenon with a no observed effect level NOEL of 10 mg kg day in mice and a lowest observed effect level LOEL of 10 mg kg day in rats The lowest oral dose which caused cancer LOAEL in B6C3F1 mice was 70 mg kg day 27 These are 1 3 orders of magnitude higher than human exposure which is principally dermal rather than oral 31 Environmental concerns edit The first concerns about musk xylene arose in the early 1980s with the detection of musk xylene residues in fish from the Tama River near Tokyo 32 and subsequently in the river water itself especially at the outlets of sewage treatment plants This led to a voluntary moratorium on the use of musk xylene in Japan from 1982 4 Similar residues were subsequently found in European waters such as the Elbe Stor and Ruhr rivers in Germany the German Bight area of the North Sea and sewage treatment plant outlets in Sweden 4 33 Typical concentrations were gt 0 001 µg L in sea water 0 001 0 01 µg L in river water and 0 01 0 1 µg L sometimes higher in the effluent from sewage treatment plants These findings indicate that musk xylene is not completely removed from wastewater by the sewage treatment process Two studies in Germany found compared musk xylene concentrations in incoming wastewater and sewage treatment plant effluent and found removal rates of 82 and 58 34 35 However they are not concentrations which are expected to be toxic to aquatic life The European Union Risk Assessment Report reviewed more than a dozen studies of the toxicity of musk xylene to algae and to aquatic vertebrates and invertebrates and all found no observed effect concentrations greater than 10 µg L 36 the chronic aquatic toxicity threshold in the EU REACH Regulation 37 The biodegradation of musk xylene in sea water and in mixed sea water sediment systems was studied in laboratory simulations using carbon 14 labelled musk xylene and the results discussed in an addendum to the European Union Risk Assessment Report 11 The half life in marine sediment was estimated to be 60 days or less with biodegradation occurring by anaerobic reduction of the nitro groups The half life in sediment free sea water was estimated to be more than 150 days far above the very persistent threshold of 60 days 37 The 2008 addendum also discussed the photolysis of musk xylene in water and in air which are rapid however photolysis was not considered to be relevant in the persistence of musk xylene in the environment and was not taken into account in classifying it as a very persistent substance 11 Several different primary bioaccumulation studies were reviewed in the European Union Risk Assessment Report with bioaccumulation factors varying between 640 L kg and 6740 L kg 38 Given that musk xylene has a very high octanol water partition coefficient log Kow 4 9 1 the higher bioaccumulation factors were considered to be the more significant The 2008 addendum 11 considered a further laboratory study from the Japanese Ministry of International Trade and Industry which was not available to the authors of the original Risk Assessment Report and which also showed bioaccumulation factors in fish Cyprinus carpio that were higher than the REACH threshold 37 of 5000 L kg for very bioaccumulative substances Bioaccumulation factors of more than 5000 L kg wet weight basis have also been found in carp Carassius carassius and eels Anguilla anguilla from a sewage treatment pond 39 References edit a b Section 1 3 European Union Risk Assessment Report 2005 pp 6 7 Are there safer alternatives ECHA Archived from the original on 2015 06 16 Retrieved 2015 05 18 Bedoukian 1986 a b c d e f International Agency for Research on Cancer 1996 Ippen 1994 OSPAR Commission 2004 a b Section 2 European Union Risk Assessment Report 2005 pp 9 10 RIVM DHI RPA 2008 ATP 2004 to the Cosmetics Directive Article 31 3 REACH Regulation at p 108 a b c d European Chemicals Agency 2008 a b c Section 10 5 Part I UN Manual of Tests and Criteria pp 23 28 Section 4 1 1 2 European Union Risk Assessment Report 2005 p 42 Packing instruction P409 Section 4 1 4 Part 4 UN Model Regulations at p 59 Special provision 133 Section 3 3 1 Part 3 UN Model Regulations at p 291 Section 11 4 Part I UN Manual of Tests and Criteria pp 32 34 Section 11 5 Part I UN Manual of Tests and Criteria pp 35 40 Section 13 4 2 Part I UN Manual of Tests and Criteria pp 76 83 Section 13 5 1 Part I UN Manual of Tests and Criteria pp 105 8 Section 13 6 Part I UN Manual of Tests and Criteria pp 117 19 a b ATP 2004 to the Dangerous Substances Directive at p 121 index no 609 068 00 1 a b CLP Regulation at p 615 index no 609 068 00 1 Position document prepared for the European Chemicals Bureau 2002 a b Maekawa et al 1990 a b Section 4 1 2 7 3 European Union Risk Assessment Report 2005 pp 83 85 Section 4 1 2 6 European Union Risk Assessment Report 2005 pp 74 77 a b c Section 4 1 2 7 1 European Union Risk Assessment Report 2005 pp 77 83 Williams amp Whysner 1996 a b International Agency for Research on Cancer 2001 Meeting of the Commission Working Group on the Classification and Labelling of Dangerous Substances 25 November 2002 Sections 4 1 1 5 amp 4 1 3 5 European Union Risk Assessment Report pp 57 and 109 110 Yamagishi et al 1981 Section 3 1 2 4 European Union Risk Assessment Report 2005 pp 21 24 Eschke et al 1994 Hahn 1993 Later studies have found higher rates of removal of musk xylene by sewage treatment plants around 95 European Chemicals Agency 2008 Section 3 2 1 1 European Union Risk Assessment Report 2005 pp 31 34 a b c Annex XIII REACH Regulation at pp 383 85 Section 3 1 1 2 European Union Risk Assessment Report 2005 pp 12 15 Gatermann et al 2002 Further reading edit ATP 2004 to the Cosmetics Directive Commission Directive 2004 88 EC of 7 September 2004 amending Council Directive 76 768 EEC concerning cosmetic products for the purpose of adapting Annex III thereto to technical progress OJEC L287 8 9 2004 pp 5 6 ATP 2004 to the Dangerous Substances Directive Commission Directive 2004 73 EC of 29 August 2004 adapting to technical progress for the 29th time Council Directive 67 548 EEC on the approximation of the laws regulations and administrative provisions relating to the classification packaging and labelling of dangerous substances OJEC L152 30 04 2004 pp 1 311 Bedoukian P Z 1986 Perfumery and Flavoring Synthetics 3rd ed Wheaton IL Allured Publishing pp 322 33 ISBN 0 931710 12 X CLP Regulation Regulation EC No 1272 2008 of the European Parliament and of the Council of 16 December 2008 on classification labelling and packaging of substances and mixtures amending and repealing Directives 67 548 EEC and 1999 45 EC and amending Regulation EC No 1907 2006 OJEC L353 31 12 2008 pp 1 1355 Eschke H D Traud J Dibowski H J 1994 Analytik und befunde kuenstlicher Nitromoschus Substanzen in Oberflaechen und Abwaessern sowie Fischen aus dem Einzugsgebiet der Ruhr Vom Wasser 83 373 83 in German European Chemicals Agency 8 October 2008 Support Document for Identification of 5 tert Butyl 2 4 6 trinitro m xylene as a Substance of Very High Concern PDF archived from the original PDF on 6 March 2009 European Union Risk Assessment Report 2005 5 tert butyl 2 4 6 trinitro m xylene musk xylene permanent dead link 3rd Priority List Volume 55 Gatermann R Biselli S Huhnerfuss H Rimkus G G Hecker M Karbe L 2002 Synthetic musks in the environment Part 1 Species dependent bioaccumulation of polycyclic and nitro musk fragrances in freshwater fish and mussels Arch Environ Contam Toxicol 42 4 437 46 doi 10 1007 s00244 001 0041 2 PMID 11994785 S2CID 453184 GHS Globally Harmonized System of Classification and Labelling of Chemicals pdf 2021 Hahn J 1993 Untersuchungen zum Vorkommen von Moschus Xylol in Fischen Deutsche Lebensmittel Rundschau 89 6 175 77 in German International Agency for Research on Cancer 1996 Musk ambrette and musk xylene PDF IARC Monographs on the Evaluation of Carcinogenic Risks to Humans 65 477 95 PMC 7681280 PMID 9097117 International Agency for Research on Cancer 2001 Phenobarbital and its sodium salt PDF IARC Monographs on the Evaluation of Carcinogenic Risks to Humans 79 161 288 Ippen Hellmut 1994 Nitro musk Int Arch Occup Environ Health 66 4 283 85 doi 10 1007 BF00454368 PMID 7843840 S2CID 7854171 Maekawa A Matsushima Y Onodera H Shibutani M Ogasawara H Kodama Y Kurokawa Y Hayashi Y 1990 Long term toxicity carcinogenicity of musk xylol in B6C3F mice Food Chem Toxicol 28 8 581 86 doi 10 1016 0278 6915 90 90159 K PMID 2242833 Meeting of the Commission Working Group on the Classification and Labelling of Dangerous Substances PDF Ispra Italy European Chemicals Bureau 25 November 2002 pp 23 24 ECBI 42 02 Rev 2 permanent dead link OSPAR Commission 2004 Musk xylene and other musks PDF archived from the original PDF on 2010 07 07 OSPAR background document Position document prepared for the European Chemicals Bureau 9 December 2002 Classification and labelling of musk xylene REACH Regulation Regulation EC No 1907 2006 of the European Parliament and of the Council of 18 December 2006 concerning the Registration Evaluation Authorisation and Restriction of Chemicals REACH establishing a European Chemicals Agency OJEU L396 30 12 2006 pp 1 849 RIVM DHI RPA 2008 Data on Manufacture Import Export Uses and Releases of Musk Xylene CAS No 81 15 2 as well as Information on Potential Alternatives to its Use PDF archived from the original PDF on 2009 02 05 a href Template Citation html title Template Citation citation a author has generic name help Technical report for the European Chemicals Agency UN Manual of Tests and Criteria UN Recommendations on the Transport of Dangerous Goods Manual of Tests and Criteria Fourth revised ed New York and Geneva United Nations 2002 ISBN 92 1 139087 7 ST SG AC 10 11 Rev 4 UN Model Regulations UN Recommendations on the Transport of Dangerous Goods Model Regulations Fifteenth ed New York and Geneva United Nations 2007 ISBN 978 92 1 139120 6 ST SG AC 10 1 Rev 15 Williams G M Whysner J 1996 Epigenetic carcinogens evaluation and risk assessment Exp Toxic Pathol 48 2 3 189 95 doi 10 1016 S0940 2993 96 80041 8 PMID 8672874 Yamagishi Tatsunori Miyazaki Tomoyuki Horii Shozo Kaneko Seiji 1981 Identification of musk xylene and musk ketone in freshwater fish collected from the Tama River Tokyo Bull Environ Contam Toxicol 26 1 656 62 doi 10 1007 BF01622152 PMID 7260436 S2CID 32533880 Wiegel Simone Harms Heinz Stachel Burkhard 2000 Synthetische Moschus Duftstoffe in der Elbe PDF Hamburg Arbeitsgemeinschaft fur die Reinhaltung der Elbe in German Institut fur Umweltmedizin der Stadt Wien 2000 Abwasser und Klarschlammuntersuchungen in der Pilotklaranlage Entsorgungsbetriebe Simmering PDF archived from the original PDF on 2016 03 03 retrieved 2009 04 05 Monograph 121 in German European Chemicals Agency 2009a Prioritisation and Annex XIV Background Information PDF archived from the original PDF on 2009 02 05 14 January 2009 European Chemicals Agency 2009b Justification for the Draft Recommendation of Inclusion in Annex XIV PDF archived from the original PDF on 2009 02 06 14 January 2009 European Commission Scientific Committee for Food 1997 Nitro musk compounds in food PDF Food Science and Techniques 44 1 4 nbsp Wikimedia Commons has media related to Nitro musks Retrieved from https en wikipedia org w index php title Musk xylene amp oldid 1201014275, wikipedia, wiki, book, books, library,

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