Epoxy Compounds—Olefin Oxides, Aliphatic Glycidyl Ethers and Aromatic Monoglycidyl Ethers

J. Waechter, L. Pottenger, G. Veenstra
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As a result of this strain, epoxy compounds are attacked by almost all nucleophilic substances to open the ring and form addition compounds. Agents reacting with epoxy compounds include halogen acids, thiosulfate, carboxylic acids, hydrogen cyanide, water, amines, aldehydes, and alcohols. \n \n \n \nA major portion of this chapter presents information on the two simplest olefin oxides, ethylene oxide and propylene oxide, both of which are produced in high volume and are largely used as intermediates in the production of many other products such as the glycol ethers, polyethylene glycols, ethanolamines, and hydroxypropylcellulose. These epoxides have minor uses as fumigants for furs and spices, and as medical sterilants. The other olefin oxides discussed are used as chemical intermediates (e.g., vinylcyclohexene mono- and dioxide), as gasoline additives, acid scavengers, and stabilizing agents in chlorinated solvents (butylene oxide) or in limited quantities as reactive diluents for epoxy resins. The discussion of the toxicology of certain olefinic oxides may be pertinent to their respective olefin precursors. However, it must be pointed out that the olefinic precursors of these different oxides demonstrate widely varying degrees of toxicity in mammalian models, mostly attributable to pharmacokinetic/metabolism differences in metabolic conversion of olefins to their respective oxide metabolites. For example, chronic bioassay results for olefins range from repeated negatives (ethylene, propylene) to clear positives (butadiene). A major use of the glycidyl ethers discussed in this chapter is as reactive diluents in epoxy resin mixtures. However, some of these materials are also used as intermediates in chemical synthesis as well as in other industrial applications. \n \n \n \nThe concept that epoxides can produce toxic effects through their binding to nucleophilic macromolecules such as DNA, RNA, and protein, is well established. However, the magnitude and nature of physiological disruption depend on factors such as the reactivity of the particular epoxide, its molecular weight, and its solubility, all of which may control its access to critical molecular targets. In addition, the number of epoxide groups present, the dose and dose-rate, the route of administration, and the affinity for enzymes that can detoxify or further activate the compound may affect the degree and nature of the physiological response. A key enzyme for epoxide detoxification is microsomal epoxide hydrolase (EH), which is widely distributed throughout the body, but can vary among different cell types and organs, and across species, and even strains. \n \n \n \nAcute toxic effects most commonly observed in animals have been dermatitis (either primary irritation or, for some, secondary to induction of sensitization), eye irritation, pulmonary irritation, and gastric irritation, which are found in these tissues after direct contact with the epoxy compound. Skin irritation is usually manifested by more or less sharply localized lesions that develop rapidly on contact, more frequently on the arms and hands. Signs and symptoms usually include redness, swelling, and intense itching. In severe cases, secondary infections may occur. Humans can show marked differences in sensitivity. \n \n \n \nMost of the glycidyl ethers in this chapter have shown evidence of delayed contact skin sensitization, in either animals or humans. The animal and human data available on skin sensitization of epoxy compounds do not assist in determining the structural requirements necessary to produce sensitization, but do provide some practical guidance for industrial hygiene purposes. \n \n \n \nAlthough all of the compounds described in this chapter were mutagenic to bacteria (excluding epoxidized glycerides) as well as positive in other in vitro genotoxicity assays, not all have demonstrated genotoxicity in in vivo studies by relevant exposure routes. \n \n \n \nA number of these epoxide compounds have been found to be carcinogenic in rodents, although there has been no clear epidemiologic evidence for cancer in the workplace. In rats and/or mice, many epoxy compounds produce a carcinogenic response in the tissues of first contact. These compounds include ethylene oxide, butylene oxide, propylene oxide, styrene oxide, allyl glycidyl ether, phenyl glycidyl ether, and neopentyl glycol diglycidyl ether. A few of them, such as ethylene oxide, butadiene diepoxide, and vinylcyclohexene diepoxide, have produced tumors at sites other than the “portal of entry.” \n \n \nKeywords: \n \nbutylene oxides; \ncresyl glycidyl ethers; \ndiglycidyl ethers; \nepoxidized linseed oil; \nepoxidized soya bean oil; \nethylene oxide; \nglycidyl ethers; \nolefin oxides; \npropylene oxide; \nphenyl glycidyl ethers; \nstyrene oxide; \nvinylcyclohexene monoxide; \nvinylcyclohexene dioxide","PeriodicalId":19820,"journal":{"name":"Patty's Toxicology","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2012-08-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Patty's Toxicology","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1002/0471435139.TOX082.PUB2","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0

Abstract

An epoxy compound is defined as any compound containing one or more oxirane rings. An oxirane ring (epoxide) consists of an oxygen atom linked to two adjacent (vicinal) carbon atoms. The term alpha-epoxide is sometimes used for this structure to distinguish it from rings containing more carbon atoms. The alpha does not indicate where in a carbon chain the oxirane ring occurs. The oxirane ring is highly strained and is thus the most reactive ring of the oxacyclic carbon compounds. The strain is sufficient to force the four carbon atoms nearest to the oxygen atom in 1,2-epoxycyclohexane into a common plane, whereas in cyclohexane the carbon atoms are in a zigzag arrangement or boat structure. As a result of this strain, epoxy compounds are attacked by almost all nucleophilic substances to open the ring and form addition compounds. Agents reacting with epoxy compounds include halogen acids, thiosulfate, carboxylic acids, hydrogen cyanide, water, amines, aldehydes, and alcohols. A major portion of this chapter presents information on the two simplest olefin oxides, ethylene oxide and propylene oxide, both of which are produced in high volume and are largely used as intermediates in the production of many other products such as the glycol ethers, polyethylene glycols, ethanolamines, and hydroxypropylcellulose. These epoxides have minor uses as fumigants for furs and spices, and as medical sterilants. The other olefin oxides discussed are used as chemical intermediates (e.g., vinylcyclohexene mono- and dioxide), as gasoline additives, acid scavengers, and stabilizing agents in chlorinated solvents (butylene oxide) or in limited quantities as reactive diluents for epoxy resins. The discussion of the toxicology of certain olefinic oxides may be pertinent to their respective olefin precursors. However, it must be pointed out that the olefinic precursors of these different oxides demonstrate widely varying degrees of toxicity in mammalian models, mostly attributable to pharmacokinetic/metabolism differences in metabolic conversion of olefins to their respective oxide metabolites. For example, chronic bioassay results for olefins range from repeated negatives (ethylene, propylene) to clear positives (butadiene). A major use of the glycidyl ethers discussed in this chapter is as reactive diluents in epoxy resin mixtures. However, some of these materials are also used as intermediates in chemical synthesis as well as in other industrial applications. The concept that epoxides can produce toxic effects through their binding to nucleophilic macromolecules such as DNA, RNA, and protein, is well established. However, the magnitude and nature of physiological disruption depend on factors such as the reactivity of the particular epoxide, its molecular weight, and its solubility, all of which may control its access to critical molecular targets. In addition, the number of epoxide groups present, the dose and dose-rate, the route of administration, and the affinity for enzymes that can detoxify or further activate the compound may affect the degree and nature of the physiological response. A key enzyme for epoxide detoxification is microsomal epoxide hydrolase (EH), which is widely distributed throughout the body, but can vary among different cell types and organs, and across species, and even strains. Acute toxic effects most commonly observed in animals have been dermatitis (either primary irritation or, for some, secondary to induction of sensitization), eye irritation, pulmonary irritation, and gastric irritation, which are found in these tissues after direct contact with the epoxy compound. Skin irritation is usually manifested by more or less sharply localized lesions that develop rapidly on contact, more frequently on the arms and hands. Signs and symptoms usually include redness, swelling, and intense itching. In severe cases, secondary infections may occur. Humans can show marked differences in sensitivity. Most of the glycidyl ethers in this chapter have shown evidence of delayed contact skin sensitization, in either animals or humans. The animal and human data available on skin sensitization of epoxy compounds do not assist in determining the structural requirements necessary to produce sensitization, but do provide some practical guidance for industrial hygiene purposes. Although all of the compounds described in this chapter were mutagenic to bacteria (excluding epoxidized glycerides) as well as positive in other in vitro genotoxicity assays, not all have demonstrated genotoxicity in in vivo studies by relevant exposure routes. A number of these epoxide compounds have been found to be carcinogenic in rodents, although there has been no clear epidemiologic evidence for cancer in the workplace. In rats and/or mice, many epoxy compounds produce a carcinogenic response in the tissues of first contact. These compounds include ethylene oxide, butylene oxide, propylene oxide, styrene oxide, allyl glycidyl ether, phenyl glycidyl ether, and neopentyl glycol diglycidyl ether. A few of them, such as ethylene oxide, butadiene diepoxide, and vinylcyclohexene diepoxide, have produced tumors at sites other than the “portal of entry.” Keywords: butylene oxides; cresyl glycidyl ethers; diglycidyl ethers; epoxidized linseed oil; epoxidized soya bean oil; ethylene oxide; glycidyl ethers; olefin oxides; propylene oxide; phenyl glycidyl ethers; styrene oxide; vinylcyclohexene monoxide; vinylcyclohexene dioxide
环氧化合物-烯烃氧化物,脂肪族缩水甘油酯醚和芳香单缩水甘油酯醚
环氧化合物定义为含有一个或多个氧环的任何化合物。氧环(环氧化物)由一个氧原子与两个相邻的碳原子相连组成。这种结构有时被称为-环氧化物,以区别于含有更多碳原子的环。α并不表示氧环在碳链中的位置。氧环是高度应变的,因此是氧环碳化合物中最活泼的环。这种应变足以使1,2-环氧环己烷中离氧原子最近的四个碳原子形成一个共同的平面,而在环己烷中,碳原子呈之字形排列或船形结构。由于这种应变,环氧化合物受到几乎所有亲核物质的攻击,从而打开环并形成加成化合物。与环氧化合物反应的试剂包括卤素酸、硫代硫酸盐、羧酸、氰化氢、水、胺、醛和醇。本章的主要部分介绍了两种最简单的烯烃氧化物,环氧乙烷和环氧丙烷的信息,这两种氧化物都是大批量生产的,并且主要用作生产许多其他产品的中间体,如乙二醇醚、聚乙二醇、乙醇胺和羟丙基纤维素。这些环氧化物作为皮草和香料的熏蒸剂和医用消毒剂有次要用途。所讨论的其他烯烃氧化物用作化学中间体(例如,乙烯基环己烯一和二氧化二烯),作为汽油添加剂、酸清除剂和氯化溶剂(氧化丁烯)中的稳定剂,或作为环氧树脂的有限数量的活性稀释剂。对某些烯烃氧化物的毒理学的讨论可能与它们各自的烯烃前体有关。然而,必须指出的是,这些不同氧化物的烯烃前体在哺乳动物模型中表现出不同程度的毒性,这主要归因于烯烃向各自氧化物代谢物代谢转化的药代动力学/代谢差异。例如,烯烃的慢性生物测定结果从反复阴性(乙烯、丙烯)到明确阳性(丁二烯)不等。本章讨论的缩水甘油酯的主要用途是作为环氧树脂混合物中的活性稀释剂。然而,其中一些材料也用作化学合成和其他工业应用的中间体。环氧化物可以通过与亲核大分子(如DNA、RNA和蛋白质)结合而产生毒性作用,这一概念已得到充分证实。然而,生理破坏的程度和性质取决于诸如特定环氧化物的反应性、分子量和溶解度等因素,所有这些因素都可能控制其进入关键分子靶点。此外,存在的环氧化物基团的数量、剂量和剂量率、给药途径以及对解毒或进一步激活化合物的酶的亲和力可能影响生理反应的程度和性质。环氧化物解毒的关键酶是微粒体环氧化物水解酶(EH),它广泛分布于全身,但在不同的细胞类型和器官、物种甚至菌株之间存在差异。在动物中最常见的急性毒性作用是皮炎(要么是原发性刺激,要么是继发于诱导致敏)、眼睛刺激、肺刺激和胃刺激,这些都是在直接接触环氧化合物后在这些组织中发现的。皮肤刺激通常表现为或多或少尖锐的局部病变,接触后迅速发展,更常见的是手臂和手。体征和症状通常包括发红、肿胀和剧烈瘙痒。在严重的情况下,可能发生继发感染。人类在敏感性上可以表现出明显的差异。本章提到的大多数缩水甘油酯在动物或人类身上都显示出延迟接触皮肤致敏的证据。关于环氧化合物皮肤致敏性的动物和人类数据不能帮助确定产生致敏性所需的结构要求,但确实为工业卫生目的提供了一些实用指导。尽管本章中描述的所有化合物都对细菌具有诱变性(不包括环氧甘油),并且在其他体外遗传毒性试验中呈阳性,但并非所有化合物都通过相关暴露途径在体内研究中显示出遗传毒性。尽管没有明确的流行病学证据表明工作场所会致癌,但已经发现许多环氧化合物对啮齿动物具有致癌性。在大鼠和/或小鼠中,许多环氧化合物在第一次接触的组织中产生致癌反应。 这些化合物包括环氧乙烷、环氧丁烯、环氧丙烷、环氧苯乙烯、烯丙基缩水甘油醚、苯基缩水甘油醚和新戊二醇二缩水甘油醚。其中一些,如环氧乙烷、二氧化丁二烯和二氧化乙烯环己烯,在“入口”以外的部位产生肿瘤。关键词:环氧丁烯;甲酰缩水甘油酯;缩水甘油醚;环氧亚麻油;环氧大豆油;环氧乙烷;缩水甘油醚;氧化烯烃;氧化丙烯;苯缩水甘油酯;氧化苯乙烯;vinylcyclohexene一氧化碳;vinylcyclohexene二氧化碳
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