Polyurethanes, Miscellaneous Organic Polymers, and Silicones

Patty's Toxicology Pub Date : 2012-08-17 DOI:10.1002/0471435139.TOX093.PUB2

S. Cragg

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引用次数: 3

Abstract

The toxicity of the polymers discussed in this chapter may be generally attributed to the residual monomers, catalysts, and other additives present rather than the polymer per se. The cured polymer itself may be of high molecular weight and, consequently, more or less toxicologically inert. Carefully manufactured, highly refined polymers contain few residual toxic chemicals. However, some of the polymers discussed in this chapter, at least in some applications, go through an intermediate stage consisting of “prepolymers” (sometimes referred to as “resins”) that react further to achieve their final, cured form. An example is a polyurethane system for making foam cushions. To manufacture polyurethane foam for cushions, workers combine diisocyanate molecules with a polyol prepolymer. Such “systems” inherently have more potential for exposure of workers if not the general public to toxic monomers or other reactive chemicals. The exposure potential of glues, paints, and coatings may extend more broadly to the consumer. Thus, examination of the toxicity of the polymers discussed in this chapter focuses on monomers and prepolymers. This is not always so. Some of polymers in this chapter are used in biomedical devices or in a way that puts them in intimate contact with humans. Here, the issue of biodegradation becomes important because of potential toxicity from breakdown products of the polymer, or rejection may ensue if the polymer is incompatible with the surrounding tissues. Keywords: Polyurethanes; Foams; Elastomers; Coating adhesives; Fibers; Combustion toxicity; Amino plastics; Phenol-formaldehyde resins; Urea-formaldehyde; Melamine-formaldehyde; Furan polymers; Polybenzimidazole; Silicone elastomers

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采购产品聚氨酯，杂项有机聚合物，和有机硅

本章讨论的聚合物的毒性通常归因于残留的单体、催化剂和其他添加剂，而不是聚合物本身。固化聚合物本身可能具有高分子量，因此或多或少具有毒性惰性。精心制造，高度精炼的聚合物含有很少残留的有毒化学物质。然而，本章中讨论的一些聚合物，至少在某些应用中，要经过一个由“预聚物”(有时称为“树脂”)组成的中间阶段，这些预聚物进一步反应以达到最终的固化形式。一个例子是用于制造泡沫垫的聚氨酯系统。为了制造用于坐垫的聚氨酯泡沫，工人们将二异氰酸酯分子与多元醇预聚物结合在一起。这种“系统”本身就更有可能使工人接触到有毒单体或其他反应性化学物质，如果不是普通公众的话。胶水、油漆和涂料的潜在暴露范围可能会扩大到更广泛的消费者。因此，本章所讨论的聚合物毒性的检查主要集中在单体和预聚体上。但情况并非总是如此。本章中的一些聚合物用于生物医学设备或与人类密切接触的方式。在这里，生物降解问题变得很重要，因为聚合物分解产物的潜在毒性，或者如果聚合物与周围组织不相容，可能会发生排斥反应。关键词:聚氨酯;泡沫;弹性体;涂料粘合剂;纤维;燃烧毒性;氨基塑料;酚醛树脂;脲醛;三聚氰胺甲醛;呋喃聚合物;聚苯并咪唑;有机硅弹性体

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Patty's Toxicology

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