Roland Weber1, Christine Herold1, Henner Hollert2, Josef Kamphues3, Markus Blepp4, Karlheinz Ballschmiter5. 1. POPs Environmental Consulting, Lindenfirststraße 23, 73527 Schwäbisch Gmünd, Germany. 2. 2Department of Ecosystem Analysis, Institute for Environmental Research, RWTH Aachen University, 52074 Aachen, Germany. 3. 3Institute of Animal Nutrition, University of Veterinary Medicine Hannover, Foundation, 30559 Hannover, Germany. 4. 4Öko-Institut e.V, 79100 Freiburg, Germany. 5. 5Ulm University, 89081 Ulm, Germany.
Abstract
BACKGROUND: In the past, cases of PCDD/F and PCB contamination exceeding limits in food from animal origin (eggs, meat or milk) were mainly caused by industrially produced feed. But in the last decade, exceedances of EU limit values were discovered more frequently for PCDD/Fs or dioxin-like(dl)-PCBs from free range chicken, sheep, and beef, often in the absence of any known contamination source. RESULTS: The German Environment Agency initiated a project to elucidate the entry of PCBs and PCDD/Fs in food related to environmental contamination. This paper summarizes the most important findings. Food products from farm animals sensitive to dioxin/PCB exposure-suckling calves and laying hens housed outdoor-can exceed EU maximum levels at soil concentrations that have previously been considered as safe. Maximum permitted levels can already be exceeded in beef/veal when soil is contaminated around 5 ng PCB-TEQ/kg dry matter (dm). For eggs/broiler, this can occur at a concentration of PCDD/Fs in soil below 5 ng PCDD/F-PCB-TEQ/kg dm. Egg consumers-especially young children-can easily exceed health-based guidance values (TDI). The soil-chicken egg exposure pathway is probably the most sensitive route for human exposure to both dl-PCBs and PCDD/Fs from soil and needs to be considered for soil guidelines. The study also found that calves from suckler cow herds are most prone to the impacts of dl-PCB contamination due to the excretion/accumulation via milk. PCB (and PCDD/F) intake for free-range cattle stems from feed and soil. Daily dl-PCB intake for suckler cow herds must in average be less than 2 ng PCB-TEQ/day. This translates to a maximum concentration in grass of 0.2 ng PCB-TEQ/kg dm which is less than 1/6 of the current EU maximum permitted level. This review compiles sources for PCDD/Fs and PCBs relevant to environmental contamination in respect to food safety. It also includes considerations on assessment of emerging POPs. CONCLUSIONS: The major sources of PCDD/F and dl-PCB contamination of food of animal origin in Germany are (1) soils contaminated from past PCB and PCDD/F releases; (2) PCBs emitted from buildings and constructions; (3) PCBs present at farms. Impacted areas need to be assessed with respect to potential contamination of food-producing animals. Livestock management techniques can reduce exposure to PCDD/Fs and PCBs. Further research and regulatory action are needed to overcome gaps. Control and reduction measures are recommended for emission sources and new listed and emerging POPs to ensure food safety.
BACKGROUND: In the past, cases of PCDD/F and PCB contamination exceeding limits in food from animal origin (eggs, meat or milk) were mainly caused by industrially produced feed. But in the last decade, exceedances of EU limit values were discovered more frequently for PCDD/Fs or dioxin-like(dl)-PCBs from free range chicken, sheep, and beef, often in the absence of any known contamination source. RESULTS: The German Environment Agency initiated a project to elucidate the entry of PCBs and PCDD/Fs in food related to environmental contamination. This paper summarizes the most important findings. Food products from farm animals sensitive to dioxin/PCB exposure-suckling calves and laying hens housed outdoor-can exceed EU maximum levels at soil concentrations that have previously been considered as safe. Maximum permitted levels can already be exceeded in beef/veal when soil is contaminated around 5 ng PCB-TEQ/kg dry matter (dm). For eggs/broiler, this can occur at a concentration of PCDD/Fs in soil below 5 ng PCDD/F-PCB-TEQ/kg dm. Egg consumers-especially young children-can easily exceed health-based guidance values (TDI). The soil-chicken egg exposure pathway is probably the most sensitive route for human exposure to both dl-PCBs and PCDD/Fs from soil and needs to be considered for soil guidelines. The study also found that calves from suckler cow herds are most prone to the impacts of dl-PCB contamination due to the excretion/accumulation via milk. PCB (and PCDD/F) intake for free-range cattle stems from feed and soil. Daily dl-PCB intake for suckler cow herds must in average be less than 2 ng PCB-TEQ/day. This translates to a maximum concentration in grass of 0.2 ng PCB-TEQ/kg dm which is less than 1/6 of the current EU maximum permitted level. This review compiles sources for PCDD/Fs and PCBs relevant to environmental contamination in respect to food safety. It also includes considerations on assessment of emerging POPs. CONCLUSIONS: The major sources of PCDD/F and dl-PCB contamination of food of animal origin in Germany are (1) soils contaminated from past PCB and PCDD/F releases; (2) PCBs emitted from buildings and constructions; (3) PCBs present at farms. Impacted areas need to be assessed with respect to potential contamination of food-producing animals. Livestock management techniques can reduce exposure to PCDD/Fs and PCBs. Further research and regulatory action are needed to overcome gaps. Control and reduction measures are recommended for emission sources and new listed and emerging POPs to ensure food safety.
Authors: Ron L A P Hoogenboom; Guillaume Ten Dam; Mark van Bruggen; Suzanne M F Jeurissen; Stefan P J van Leeuwen; Rob M C Theelen; Marco J Zeilmaker Journal: Chemosphere Date: 2016-02-24 Impact factor: 7.086
Authors: João Paulo Machado Torres; Claudio Leite; Thomas Krauss; Roland Weber Journal: Environ Sci Pollut Res Int Date: 2012-07-25 Impact factor: 4.223
Authors: Martin van den Berg; Michael S Denison; Linda S Birnbaum; Michael J Devito; Heidelore Fiedler; Jerzy Falandysz; Martin Rose; Dieter Schrenk; Stephen Safe; Chiharu Tohyama; Angelika Tritscher; Mats Tysklind; Richard E Peterson Journal: Toxicol Sci Date: 2013-03-14 Impact factor: 4.849
Authors: Alfredo Mazza; Prisco Piscitelli; Andrea Falco; Maria Lucia Santoro; Manuela Colangelo; Giovanni Imbriani; Adele Idolo; Antonella De Donno; Leopoldo Iannuzzi; Annamaria Colao Journal: Int J Environ Res Public Health Date: 2018-01-10 Impact factor: 3.390
Authors: Geniece M Lehmann; Krista Christensen; Mark Maddaloni; Linda J Phillips Journal: Environ Health Perspect Date: 2014-10-10 Impact factor: 9.031
Authors: Alexander Sotnichenko; Elena Tsis; Magomed Chabaev; Vasily Duborezov; Alexander Kochetkov; Roman Nekrasov; Victor Okhanov Journal: Toxics Date: 2021-04-08
Authors: Wenjing Guo; Bohu Pan; Sugunadevi Sakkiah; Gokhan Yavas; Weigong Ge; Wen Zou; Weida Tong; Huixiao Hong Journal: Int J Environ Res Public Health Date: 2019-11-08 Impact factor: 3.390