Phthalates are commonly used as plasticizers and vehicles for cosmetic ingredients. Phthalate metabolites have documented biochemical activity including activating peroxisome proliferator-activated receptor and antiandrogenic effects, which may contribute to the development of obesity. In vitro and in vivo studies suggest that phthalates have significant effects on the development of obesity, especially after prenatal exposure at low doses. Although few studies have examined the effects of phthalate on obesity development in humans, some work has shown that phthalates affect humans and animals similarly. In this paper, we review the possible mechanisms of phthalate-induced obesity, and discuss evidence supporting the role of phthalates in the development of obesity in humans.
Animals ; Child ; Diethylhexyl Phthalate ; Endocrine Disruptors ; Humans ; Obesity ; Pediatric Obesity* ; Peroxisomes ; Plasticizers ; Plastics

OBJECTIVETo Investigate necessity of safety evaluation, research ideas, evaluation methods of DEHP in PVC medical devices.

METHODSThe ideas of The United States, Japan and the European Union on safety evaluation of DEHP in PVC medical devices was reviewed and sorted, regarding to currently requirements for PVC medical devices in our country, the research ideas and methods of DEHP in PVC medical devices was explored.

RESULTSDEHP released from High-risk PVC medical devices may exceed human tolerance intake values and thus potentially be harmful to human health. So it is necessary for production enterprise to assess safety of DEHP in PVC medical device. The assessment can be done by material control and detecting release of DEHP from PVC medical devices.

CONCLUSIONIn order to assess safety of DEHP in PVC medical device, production enterprise can firstly assess materials according to national standard. Secondly, production enterprise can detect release of DEHP from PVC medical devices simulating clinical application. By comparing release of DEHP from PVC medical devices and TI, safety of DEHP in PVC medical device can be evaluated.

Diethylhexyl Phthalate ; adverse effects ; Equipment Safety ; Plasticizers ; adverse effects ; Polyvinyl Chloride ; adverse effects

Trimellitic anhydride (TMA) is widely used industrially to make epoxy and alkyd resins, plasticizers and surfactants. The purpose of this study was to investigate whether contact dermatitis is induced by repeated TMA challenge and the role of interleukin (IL)-10 in the TMA-induced contact dermatitis. The repetition of the challenge enlarged the extent of an early and a late phase of contact dermatitis in IL-10(+/+) and IL-10(-/-) mice. In the late phase of TMA-induced contact dermatitis, the peak of ear swelling responses by single challenge showed at 12 h after challenge, but the peak was observed at 8 h after repeated challenge. In the IL-10(-/-) mice, the repetition of the TMA challenges enlarged the extent of the contact dermatitis, but less than those in IL-10(+/+) mice. These results indicate that mice sensitized by TMA could possibly offer a useful model to study the mechanism of contact dermatitis, and IL-10 may act as potential modulators in the TMA-induced contact dermatitis. IL-10 may provide therapeutic tools for the treatment of TMA-induced contact dermatitis.
Animals ; Dermatitis, Contact ; Ear ; Interleukin-10 ; Interleukins ; Mice ; Phthalic Anhydrides ; Plasticizers ; Plastics

Endocrine disrupting chemicals (EDCs) are exogenous chemicals contained in industrial substances and plasticizers commonly utilized worldwide. Human exposure to such chemicals, particularly at low-doses, is omnipresent, persistent, and occurs in complex mixtures. EDCs include bisphenol A, phthalates, pesticides, and persistent organic pollutants such as polychlorinated biphenyls. Burgeoning epidemiological, animal, and cellular data link environmental EDCs to metabolic dysfunction. In the last three decades, the number of diabetic patients has drastically increased worldwide, with current statistics suggesting that the number will double in the next two decades. There is epidemiological and experimental evidence linking background exposure to a selection of environmental EDCs with diabetes and impaired glucose metabolism. EDC may be related to increased risk of diabetes.
Animals ; Complex Mixtures ; Endocrine Disruptors ; Environmental Pollution* ; Glucose ; Humans ; Metabolism ; Pesticides ; Plasticizers ; Plastics ; Polychlorinated Biphenyls

DEHP is largely used in soft PVC products as the plasticizer, which is also widely applied in medical devices. Due to its potential and widespread toxicity and medical devices' specific use, the safety of DEHP's application in medical devices has received extensive attention. In this paper, a comprehensive review of the application and potential toxicity of DEHP in PVC medical devices is made on the basis of the research results all over the world. Besides, the safety evaluation in medical devices is discussed and some possible coping strategies are explored.
Diethylhexyl Phthalate ; adverse effects ; Equipment Safety ; Equipment and Supplies ; adverse effects ; Plasticizers ; adverse effects ; Polyvinyl Chloride

As we all know, DEHP is seriously harmful to human health and consequently has been acquired critical attention. DEHP is able to migrate from PVC medical devices for the non-chemically bound to PVC, thus contact with user and patient. The DEHP migration is influenced by various parameters. In order to assess the security of PVC-tubes medical devices scientifically of DEHP migration, we develop an experimental model by analyzing the parameters comprehensively and systematically, taking into account the clinical practices. For example, assessing the security of DEHP migration from infusion sets by utilizing this model.
Diethylhexyl Phthalate ; adverse effects ; Equipment and Supplies ; Humans ; Models, Theoretical ; Plasticizers ; adverse effects ; Polyvinyl Chloride

The work explored the DEHP migration parameters in PVC infusion in clinic,based on the previous research on the test model of DEHP migrated from PVC infusion,to assess the safety of PVC infusion.The leaching solution samples in different conditions were evaluated by analysis of the DEHP in leaching solution using GC-MS under simulated clinical transfusion way.The release behavior of DEHP was significantly affected by the storage time,storage temperature,surrounding temperature,dripping speed,sterilization process,volume of the leaching solution,and the property of the leaching solution.
Diethylhexyl Phthalate ; pharmacokinetics ; Gas Chromatography-Mass Spectrometry ; Plasticizers ; pharmacokinetics ; Polyvinyl Chloride ; pharmacokinetics ; Temperature

We used blood as leaching medium, simulating clinical operation under maximum condition, to develop Liquid-phase extraction- High Performance Liquid Chromatography (HPLC) method for determination of plasticizer Di-(2-ethylhexyl)phthalate (DEHP) released from Disposable Extracorporeal Circulation Tube in order to lay the foundation of risk analysis of this product. The characteristic wavelength of DEHP in methanol was detected. Acetonitrile was added to the leaching blood in proportion and extracted DEHP from blood. The methodology for HPLC to quantify DEHP was established and the DEHP amount released from this disposable extracorporeal circulation tube was measured. The experiments showed good results as follows. The characteristic wavelength of DEHP was 272nm. The concentration of DEHP (5-250 microg/mL) kept good linear relationship with peak area (r=0.9999). Method sensitivity was 1 microg/mL. Precisions showed RSD<5%. The adding standard extraction Recovery Rates of 25, 100 and 250 microg DEHP standard were 61.91 +/- 3.32)%, (69.38 +/- 0.55)% and (68.47 +/- 1.15)%. The DEHP maximum amounts released from 3 sets of this disposable extracorporeal circulation tube were 204.14, 106.30 and 165.34 mg/set. Our Liquid-phase Extraction-HPLC method showed high accuracy and precision, and relatively stable recovery rate. Its operation was also convenient.
Chromatography, High Pressure Liquid ; methods ; Computer Simulation ; Diethylhexyl Phthalate ; analysis ; blood ; Extracorporeal Circulation ; adverse effects ; instrumentation ; Humans ; Plasticizers ; analysis

OBJECTIVETo understand the dietary consumption of residents in Xiamen and the content of phthalic acid esters (PAEs) in food, and to assess the plasticizer exposure risk of diet in Xiamen.

METHODSThe survey was conducted by stratified cluster random sampling method in Xiamen from September to October in 2010. According to the Xiamen administrative division, six neighborhood communities were selected as sampling units, then 25 families were randomly chosen from each sampling units.From the above 150 families, the permanent residents over the age of six were permitted to our study. The survey included 495 residents totally. These participants' information, such as basic personal information, physical activity levels, meal frequency and the average consumption of 33 kinds of food in 13 categories were collected using questionnaires. Thirteen categories included cereal and tubers, beans, vegetables, fungi and algae, fruits, dairy products, meat, seafood, eggs, snacks, beverages, cooking oil and spices. The height and weight of residents were measured and the average daily dietary intake was calculated. Thirty-three kinds of food in 13 categories were collected in supermarkets in Xiamen. According to the annual sales ranking, the top three-five brands of each kinds of food were selected and numbered, then two or three brands were chosen by random number table method from them; three completely individual packed samples in the same batch of each brand were detected; 243 samples were included in our study.100-500 g solid samples or 100-500 ml liquid samples were collected. The content of diethyl phthalate (DEP), dibutyl phthalate (DBP), di (2-ethylhexyl) phthalate (DEHP) in food were detected by liquid chromatography mass spectrometry, which expressed by median (minimum-maximum). The exposure dose, contribution rate and risk index of PAEs were calculated by point estimation method.

RESULTSAccording to the average daily dietary intake of residents in Xiamen, the top three ones in 13 categories of food were cereal and tubers (337.16 g/d, 18.21%), vegetables (309.12 g/d, 16.69%) and fruits (213.20 g/d, 11.51%). The content of DEP, DBP or DEHP among different categories of food was significantly different (χ² values were 58.05, 50.19 and 102.10, P < 0.01). Among 13 categories of food, seafood contained the most DEP (0.090 (0.000-0.324)mg/kg); cooking oil had the most DBP (0.700(0.000-2.980) mg/kg) and DEHP (5.115(0.000-24.160) mg/kg). DEP, DBP and DEHP exposure(0.19, 4.20, 18.10 µg × kg⁻¹ ×d ⁻¹)in dietary food in Xiamen were less than the reference dose(RfD) (800, 100, 20 µg × kg⁻¹ × d⁻¹) proposed by the United States Environmental Protection Agency (EPA), and the risk indexes were 0.02%, 4.20% and 90.50%, respectively. Among 13 categories of foods, seafood was the main source of DEP dietary exposure. The exposure dose and contribution rate of DEP in seafood were 0.18 µg × kg⁻¹ × d⁻¹ and 94.74%, respectively.Vegetables were the main source of DBP and DEHP dietary exposure. The exposure dose and contribution rate of DBP and DEHP were 1.48 µg × kg⁻¹ × d⁻¹, 35.24% and 6.07 µg × kg⁻¹ × d⁻¹, 33.54%, respectively.

CONCLUSIONThe food consumed by residents in Xiamen was overall in a safe state, but to some extent, there still exists DEHP exposure risk in foods.

China ; Dibutyl Phthalate ; Diet ; Diethylhexyl Phthalate ; Food Contamination ; Humans ; Phthalic Acids ; Plasticizers ; Risk Assessment ; Seafood ; United States ; Vegetables

Endocrine disrupting chemicals (EDCs) are natural or man-made agents that interfere in some way with human or animal normal endocrine function, and even influence the endocrine function of their offspring. There are many kinds of EDCs, which are widely present in soil, water, and even food. This review elaborates the impact of EDCs on human and animal semen quality from the viewpoint of epidemiology and biology by focusing on pesticides, plasticizers and detergents.
Detergents ; adverse effects ; Endocrine Disruptors ; adverse effects ; Humans ; Male ; Pesticides ; adverse effects ; Plasticizers ; adverse effects ; Semen ; drug effects ; Semen Analysis