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Changes in the classification of carcinogenic chemicals in the work area (1998)

Neumann, Hans-Günter ; Vamvakas, Spyridon ; Thielmann, Heinz Walter ; [et al.]

Springer

International archives of occupational and environmental health 71 (1998), S. 566-574

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ISSN: 1432-1246

Keywords: Key words Chemical carcinogens ; List of MAK and BAT Values ; Cancer risk

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Carcinogenic chemicals in the work area are currently classified into three categories in section III of the German List of MAK and BAT Values (list of values on maximum workplace concentrations and biological tolerance for occupational exposures). This classification is based on qualitative criteria and reflects essentially the weight of evidence available for judging the carcinogenic potential of the chemicals. It is proposed that these categories – IIIA1, IIIA2, IIIB – be retained as Categories 1, 2, and 3, to correspond with European Union regulations. On the basis of our advancing knowledge of reaction mechanisms and the potency of carcinogens, these three categories are supplemented with two additional categories. The essential feature of substances classified in the new categories is that exposure to these chemicals does not contribute significantly to risk of cancer to man, provided that an appropriate exposure limit (MAK value) is observed. Chemicals known to act typically by nongenotoxic mechanisms and for which information is available that allows evaluation of the effects of low-dose exposures, are classified in Category 4. Genotoxic chemicals for which low carcinogenic potency can be expected on the basis of dose-response relationships and toxicokinetics, and for which risk at low doses can be assessed are classified in Category 5. The basis for a better differentiation of carcinogens is discussed, the new categories are defined, and possible criteria for classification are described. Examples for Category 4 (1,4-dioxane) and Category 5 (styrene) are presented.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s004200050325

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Metal-Metal Bonding in Paramagnetic Chromium(III) Complexes - An MO-Theoretical Case Study (1993)

Janiak, Christoph ; Silvestre, Jérǒme ; Theopold, Klaus H.

Weinheim : Wiley-Blackwell

Berichte der deutschen chemischen Gesellschaft 126 (1993), S. 631-643

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ISSN: 0009-2940

Keywords: Chromium(III) alkyls ; Paramagnetism ; Calculations, MO ; Metal - Metal bonding ; Chemistry ; Inorganic Chemistry

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Chemistry and Pharmacology

Notes: The electronic structures of the edge-sharing bioctahedral chromium(III) dimers {C5H5Cr(CH3)(μ1-Cl)}2 (2) and {Me5C5Cr(CH3)(μ1-CH3)}2 (4* (Cp* derivative), 4 (Cp derivative)), the trinuclear complex {C5H5Cr(μ1-Cl)}3(μ1-CH) (3), and the face-sharing bioctahedral chromium(III) compounds {Me5C5Cr}2(μ1-CH2) (6*, 6) [{Me5C5Cr}2(μ1-CH3)3]+ (7*, 7) have been studied MO-theoretically by the extended Hückel method. Proceeding from 2 over 3 to 4*, or from 6* to 7* a 3-center/4-electron chloride or methylene bridge is replaced by a 3-center/2-electron methyl group (a methylidyne cap in the trimer). The 3c/2e bridges give rise to an increased metal - metal overlap population due to Cr - Cr bonding within the core levels. In the series of 2 - 3 - 4* this is accompanied by a decrease in the Cr - Cr distance (329 - 284 - 260 pm) and effective magnetic moment, μeff (2.53 - 2.05 - 1.53 μB per Cr at room temp.). The latter can be ascribed to an increased splitting within the chromium d-block because of the shorter metal-metal separation. The bioctahedra 6* and 7* feature even shorter Cr - Cr contacts than 4* (239 and 242 pm), primarily because of their face-sharing geometry. However, their effective magnetic moments (per Cr) are 2.33 and 1.32 μB at room temp. The high magnetic moment for 6* can be understood from the orbital interactions in the frontier orbital metal d block: A face-sharing bioctahedron shows one σ, two δ, and no π type overlap, while an edge-sharing bioctahedron (4) has σ, π, and δ interaction between the metals. In the former this destabilizes only σ* sufficiently to prevent occupation by electrons (leaving five orbitals for six electrons, possible spin multiplicities S=0, 1, 2) while for the latter both σ* and π* are destabilized beyond electron occupation (leaving four MOs for six electrons, possible spin multiplicities S=0, 1). 4*, 6* and 7* are unusual examples of metal - metal bonded complexes containing octahedral CrIII ions.

Additional Material: 8 Ill.