A PBPK model to study the transfer of α-hexabromocyclododecane (α-HBCDD) to tissues of fast- and slow-growing broilers

Food Additives & Contaminants: Part A Pub Date : 2019-11-07 DOI:10.1080/19440049.2019.1681596

B. Méda, A. Travel, Y. Guyot, J. Henri, E. Royer, E. Baéza-Campone, C. Jondreville

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引用次数: 3

Abstract

ABSTRACT A physiologically based pharmacokinetic (PBPK) model was developed to investigate the production-specific factors involved in the transfer of α-hexabromocyclododecane (α-HBCDD) to broiler meat. The model describes growth and lipid deposition in tissues of fast- (FG) and slow- (SG) growing broilers from hatching to slaughter and simulates the exposure through the ingestion of contaminated feed or expanded polystyrene insulation material. Growth parameters were obtained from the literature while parameters relative to uptake, distribution, and elimination of α-HBCDD were adjusted using results of a previous experiment involving broilers exposed through feed throughout the rearing period or allowed to depurate before slaughter. The model was used to compare the two main edible tissues, breast and leg meat, as well as skin, and to investigate the variability within strain. Between strains and within strain, α-HBCDD assimilation efficiency (AE) is higher when the animals are slaughtered young or heavy. However, increasing slaughter age will lower α-HBCDD concentration in tissues, due to dilution. Based on fresh weight, the concentration of α-HBCDD in breast muscles and skin tends to be lower in SG than in FG broilers (−30 to +10%), while it is 10% to 80% higher in leg muscles. Compared to breast muscles, consuming leg muscles would elicit an exposure 9 and 16 times higher in FG and SG broilers, respectively. The consumption of skin together with muscles would multiply the exposure by up to 36 times compared to breast muscle alone. In case of acute exposure, the α-HBCDD concentration in tissues increased sharply, all the more since the animals are lighter in weight, and then decreased rapidly. In FG broilers, dilution through growth contributed for up to 37%, 28% and 97% to the decontamination of breast muscles, leg muscles and skin, respectively, depending on the duration of depuration before slaughter.

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采用PBPK模型研究α-六溴环十二烷(α-HBCDD)在快、慢生长肉鸡组织中的转移

摘要建立了一种基于生理的药代动力学(PBPK)模型，研究α-六溴环十二烷(α-HBCDD)向肉鸡肉转移的生产特异性因子。该模型描述了快速(FG)和慢速(SG)肉鸡从孵化到屠宰的生长和组织中的脂质沉积，并模拟了通过摄入受污染的饲料或膨胀聚苯乙烯绝缘材料的暴露。生长参数从文献中获得，α-HBCDD的摄取、分布和消除相关参数根据先前的试验结果进行调整，该试验涉及整个饲养期通过饲料暴露的肉鸡或屠宰前允许净化的肉鸡。该模型用于比较两种主要的可食用组织，胸肉和腿肉以及皮肤，并研究菌株内的变异性。品种间和品种内α-HBCDD同化效率(AE)在幼屠宰和重屠宰时较高。然而，随着屠宰年龄的增加，α-HBCDD在组织中的浓度会因稀释而降低。按鲜重计算，SG肉鸡胸肌和皮肤α-HBCDD浓度低于FG肉鸡(- 30 ~ +10%)，而腿部肌肉α-HBCDD浓度高出10% ~ 80%。与胸肌相比，食用腿部肌肉对肉鸡的暴露量分别高出9倍和16倍。与单独消耗乳房肌肉相比，皮肤和肌肉的暴露量最多可增加36倍。急性暴露时，组织中α-HBCDD浓度急剧升高，且由于动物体重较轻，α-HBCDD浓度急剧升高，随后迅速下降。在FG肉鸡中，生长稀释对胸肌、腿肌和皮肤去污的贡献率分别高达37%、28%和97%，具体取决于屠宰前去污的持续时间。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Food Additives & Contaminants: Part A

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