Abstract  The toxicities and skin effects of plasticizers used in rubber and plastic industries were studied in laboratory animals and humans. Twenty five compounds used as plasticizers of synthetic resins were investigated. Rats were administered the compounds by various routes, and mortality was recorded. All animals were necropsied. The compounds were tested for skin irritancy and sensitization in rabbits and humans. Five compounds dioctyl-phthalate (117817), butylbenzyl-phthalate, santicizer-140 (66770443), santicizer-141 (1241947), and flexol-8N8 (61461776) were moderately toxic in doses of 0.6 to 2.4 grams per kilogram (g/kg), generally as a result of intraperitoneal administration. Toxic effects were usually seen in the erythrocytes, blood capillaries, and the central nervous system. The other 20 compounds were essentially nontoxic. All animals supported intraperitoneal injections of 6g/kg or more with no signs of toxic effects. Five compounds showed no skin irritation or sensitization in humans and rabbits: di-2-ethylhexyl-adipate (103231), dibutoxyethyl-diglycol-carbonate, dibutoxyethyl-phthalate (117839), dioctyl-sebacate (122623), and dibutyl-sebacate (109433). Seventeen plasticizers were slight or moderate skin irritants, three were severe skin irritants, and five were moderate sensitizers.

Abstract  The estrogenic activity of phthalate esters for dental use as plasticizers was concerned. To study the feasibility of candidate chemicals for phthalate tissue conditioners, three candidate plasticizers, di-n-butyl sebacate, acetyl tributyl citrate and tri-n-butyl phosphate together with conventional plasticizers were examined for estrogenic activity and cytotoxicity using three estrogenicity assays, human gingival fibroblasts and living skin equivalent. None of the three candidate plasticizers showed any estrogenic activity at the concentrations tested by the three assays. Di-n-butyl sebacate, acetyl tributyl citrate and their prototype tissue conditioners were weakly to negligibly cytotoxic, while tri-n-butyl phosphate and its prototype tissue conditioner yielded the strongest cytotoxicity among the six plasticizers tested. In particular, the cytotoxicities of di-n-butyl sebacate and its prototype tissue conditioners were significantly weaker than the others and the conventional plasticizers. The results suggested that di-n-butyl sebacate and acetyl tributyl citrate could be candidate chemicals for phthalate ester-free tissue conditioners.

Abstract  The CIR Expert Panel assessed the safety of dicarboxylic acids and their salts and esters as used in cosmetics. Most dicarboxylic acids function in cosmetics as pH adjusters or fragrance ingredients, but the functions of most of the salts in cosmetics are not reported. Some of the esters function as skin conditioning or fragrance ingredients, plasticizers, solvents, or emollients. The Expert Panel noted gaps in the available safety data for some of the dicarboxylic acid and their salts and esters in this safety assessment. The available data on many of the ingredients are sufficient, however, and similar structural activity relationships, biologic functions, and cosmetic product usage suggest that the available data may be extrapolated to support the safety of the entire group. The Panel concluded that the ingredients named in this report are safe in the present practices of use and concentration.

Abstract  This Public Health Statement is the summary chapter from the Toxicological Profile for Otto Fuel II. It is one in a series of Public Health Statements about hazardous substances and their health effects. A shorter version, the ToxFAQs™, is also available. This information is important because this substance may harm you. The effects of exposure to any hazardous substance depend on the dose, the duration, how you are exposed, personal traits and habits, and whether other chemicals are present. For more information, call the ATSDR Information Center at 1-888-422-8737.

Abstract  This chapter presents information on esters of mono‐, di‐, and tricarboxylic acids with monoalcohols from 1 to over 10 carbons in either a straight chain or branched configuration. In general, the properties (chemical and functional) change with the carbon length of the alcohol. Properties shift from higher water solubility and lower boiling point to lower water solubility and higher boiling point for esters of a particular acid group. There is insufficient information to conclude that the carbon length of the acid group influences the properties significantly. Also included are esters of the trialcohol, glycerol, with monocarboxylic acids. These substances are included for the sake of completeness. All esters are subject to hydrolysis, especially enzymatic hydrolysis. Most esters in biotic systems hydrolyze primarily to the carboxylic acid and alcohol. There are some exceptions such as esters of phthalic acid that form relatively stable monoesters in biotic systems, which can be further oxidized. The uses of various esters are reviewed below and they vary with the acid. The simple aliphatic esters of benzoic acid are liquids that are used as solvents, flavors, or perfumes. Benzyl benzoate is used as a miticide or as a plasticizer. In general, these compounds have a low order of toxicity. The primary effects expected from the ingestion of moderate amounts of benzoates are gastrointestinal (GI) irritation, gastric pain, nausea, and vomiting. Available data indicate a low order of skin absorbability, and the undiluted materials may be either slight or moderate skin irritants. In rabbits, the degree of skin irritation caused by alkyl benzoates increases with an increase in molecular weight. The salicylates are used as flavorants, perfumes, or analgesics. The most commonly used member of this class of compounds is methyl salicylate. Ingestion of relatively small quantities of methyl salicylate may cause severe, rapid‐onset salicylate poisoning. The lower alkyl esters of p‐ or 4‐hydroxybenzoic acid (C1–C4), also named the methyl‐, ethyl‐, propyl‐, and butyl parabens, are high‐boiling liquids that decompose on heating. They are widely used in the food, cosmetic, and pharmaceutical industries as preservatives, bacteristats, and fungistats. Parabens also have been used therapeutically in the treatment of moniliasis, a Candida albicans infection. By the oral route, parabens are rapidly absorbed, metabolized, and excreted. The lower paraben homologues have low potential for acute or chronic systemic toxicity and are therefore approved as human food additives. Cinnamates (phenyl acrylates and phenylpropenoic acid esters) are mainly used as fragrances in the perfume industry. Cinnamates appear to have low to moderate toxicity in mammals. In humans, dermal exposure to allyl cinnamate may cause skin irritation. Some p‐aminobenzoic acid (PABA) esters occur naturally, because the free compound, PABA, that is utilized for their synthesis, is an intricate part of the vitamin B complex. PABA esters exhibit a low order of acute toxicity in experimental animals. In humans, cases of methemoglobinemia after topical benzocaine or procaine use have been reported. Sunscreen agents containing PABA esters may occasionally produce allergic photosensitization. The o‐aminobenzoates (anthranilates) are less irritating and less likely to cause sensitization than do the p‐aminobenzoates, but have less therapeutic usefulness. They are used in some sunscreen lotions. Anthranilates have low toxicity potential. Long‐chain fatty acids of glycerides may be replaced by one or more acetyl groups to produce mono‐, di‐, or triacetin. Acetins, propionates, and butyrates serve as food additives, solvents or plasticizers, and surface‐active agents. Available evidence indicates that these agents exhibit a low order of toxicity. Normally, no irritant effects occur upon inhalation or direct dermal contact. The higher glycerides of fatty acids with odd‐numbered carbon chains (C5–C11) are found naturally in very small quantities in diverse organisms, and the even‐numbered (C12–C24) esters are common nutritional constituents. They are used as emulsifiers for foods, industrial raw materials, or nonacid detergent components. Some toxicity data are available for the C5 and C8 compounds. The even‐numbered C12–C18 glycerides are nontoxic. Little toxicological information is available about resorcinol ester compounds. Gallates are chemically trihydroxybenzoic acid esters. They serve generally as antioxidants, and the propyl, octyl, and dodecyl gallates have been approved as food additives. The gallates exhibit low acute and chronic toxicity in experimental animals. The bulk of evidence suggests that they are not carcinogenic or teratogenic. Oxalates, malonates, glutarates, and succinates are high‐flash, high‐boiling fluids. Oxalates and malonates are mainly used as solvents for resins or as chemical intermediates. The general industrial use of these materials has not been associated with any particular toxicity problem. Diethyl oxalate, which can exert typical local solvent and systemic effects, may present an exception. In humans, diethyl oxalate may cause irritation to skin and mucous membranes. Chemical and physical data for alkyl and alkoxy adipates, azelates, and sebacates are summarized. These compounds are important chemical intermediates and are used extensively as plasticizers. Some of these agents are used in food packaging materials. They possess low acute toxicities, and their irritant effects on the skin and eyes are very slight. Available evidence suggests that the lower alkyl adipates (dimethyl, diethyl, and dibutyl) are reproductive and/or fetal toxicants. Maleic acid esters (cis‐2‐butenoates), fumarates (trans‐2‐butenoates), and itaconates have been utilized as plasticizers, raw materials for chemical syntheses, or preservatives for fats and oils. The esters of alkenyl dicarboxylic acids are of low acute toxicity. They have a tendency to cause skin or eye irritation in rabbits. Allergic dermatitis has occurred in humans exposed to dibutyl maleate. Chronic and subacute toxicity data for these compounds are limited. The aromatic o‐dicarboxylic acid (phthalate) esters are among the most important industrial chemicals and perhaps the most studied esters of carboxylic acids. They are used as plasticizers for a variety of plastics; those of C8 and above are used to add flexibility to PVC. They are also used with vinyl and cellulose resins to lend toughness and flexibility. They are commonly used in wire and cable coverings, moldings, vinyl consumer products, and medical devices. Some low‐molecular‐weight phthalate esters (e.g., methyl, ethyl, and butyl) are used as industrial solvents rather than as plasticizers. Occasionally, these low‐molecular‐weight phthalates have applications for consumer products such as ink and lacquer. Physically, phthalates occur mainly in liquid form with high boiling ranges and very low vapor pressures, both of which contribute to the high stability of these materials. The biological responses to phthalate esters vary based on the alcohol side chain and the animal species tested. Generally, biological responses are greatest for butyl (C4) to hexyl (C6) alcohol esters, including branched hexyl alcohol esters. In general, all phthalate esters have low potential for acute toxicity following oral, dermal, or inhalation exposure. They are nonirritating or slightly irritating to the skin and eyes, and they are not sensitizers. Developmental and reproductive toxicity is most associated with the C4–C6 alcohol esters, and carcinogenesis in two species has been demonstrated for two esters. Rodents are most sensitive for these endpoints; primates appear to be insensitive.

Abstract  Alternative plasticizers have become more popular due to health concerns about phthalate esters. We demonstrated that phthalate esters enhanced skin sensitization to fluorescein isothiocyanate (FITC) in mouse contact hypersensitivity models. Alternative plasticizers have not been well studied as to their effect on the immune system. We previously found that diisopropyl adipate (DIPA), an aliphatic dicarboxylic acid ester, enhanced skin sensitization to FITC. Sebacate esters are also widely used as alternative plasticizers. Here we tested diisopropyl sebacate (DIPS), which has the same alcohol with an aliphatic dicarboxylic acid of longer chain, using BALB/c mice. The results showed that DIPS facilitated skin sensitization to FITC and increased FITC-presenting dendritic cell trafficking from the skin to draining lymph nodes. Furthermore, DIPS activated transient receptor potential ankyrin 1 (TRPA1). The latter feature has been commonly observed for phthalate esters and DIPA, which have adjuvant effects. In summary, the adjuvant effect of a sebacate ester was demonstrated in a mouse model.

Abstract  Acetyl tributyl citrate (ATBC) and dibutyl sebacate (DBS) plasticizers are components of polyvinylidene chloride. These compounds can pass from the polyvinylidene chloride packing films to the enclosed food (Baba et al. 1988). Therefore, there may be a potential hazard to health. Toxicity of these compounds in laboratory animals is well known. As the in vitro toxicity of these compounds to various mammalian cells, determined using the same cell culture systems has apparently not been documented, we examined the toxicity of ATBC and DBS on human, monkey and dog cells grown in culture systems.

Abstract  The toxicity of 92 commercially used chemicals was determined in rabbits and rats. Minimum and maximum dose concentrations for oral toxicity, skin penetration, vapor inhalation, and skin and eye irritation were found. Single oral dose toxicity for rats after 14 days ranged from 0.089 milligrams per kilograms (mg/kg) for 1,4-dichloro-2-butene (31423924) to 22.8mg/kg for 1,3-butanediol (25265752). Penetration of rabbit skin was not measurable in some chemicals, but as high as 17.3 milliliters per kilogram for tetrahydronaphthalene (119642). Lowest daily subacute dose ranged from trace amounts of acrolein (107028) to 10.3 grams per kilogram (gm/kg) tetrabutyl-thiodisuccinate (10042894). Trace amounts of aldol (107891) reduced growth; 5.33gm/kg dichloral-urea reduced appetite. Trace amounts of aldol allyl-alcohol and 2.92gm/kg di(2)-ethylhexyl)-adipate (103231) altered liver or kidney weight; trace amounts of 15 chemicals and 10.3gm/kg tetrabutyl-thiodisuccinate produced microscopic lesions; trace amounts of monoisopropanolamine (78966) and 10.3gm/kg tetrabutyl-thiodisuccinate caused death. The authors recommend changing the rabbit eye injury test as it exaggerates the hazard from certain materials, adding some expression for the rate of healing, and dropping the microscopic study of tissues from the subacute dosesseries since the technique is not sufficiently sensitive to justify its cost.