Elemental composition of the hair and milk of black-spotted cows and its relationship with intestinal microbiome reorganization

Background and Aim: The cattle breeding system is facing severe problems associated with the increased negative impact of various human activity areas on the environment and the bodies of farm animals. The use of heavy metals in different production areas leads to their accumulation in the environment due to the ingestion of animals and humans through animal products. This study aimed to assess the elemental composition of the hair and milk of black-spotted cows and to identify the relationship between the content of toxic and essential elements and the state of the intestinal microbiome. Materials and Methods: The element status was estimated by studying the chemical composition of the biosubstrates using inductively coupled plasma-mass spectroscopy. Based on the analysis of hair, the elemental composition, and the use of the coefficient of toxic load, two groups of animals were formed: Group I, which included cows with a lower load factor, and Group II, which included cows with a higher load factor. Results: An increase in the heavy metal concentrations in the hair and milk of animals in Group II was observed. The As, Fe, Pb, Al, Co, Ni, and V concentrations in the hair of cows from Group II increased relative to Group I by 19%, 29%, 24.5%, 32.3%, 35.6%, 21.5%, and 18.2%, respectively. There was a significant increase in the level of Fe by 11.5%, Cr by 8.25%, Mn by 17.6%, Pb by 46.1%, and Cd by 25% in Group II compared with Group I in the assessment of elemental milk composition. There were no apparent changes in the intestinal microbiome of Group II. Conclusion: Some heavy metals were accumulated in the bodies and milk of animals. This shows a high probability of heavy metals causing harm to the health of animals and humans.

[1]  S. Notova,et al.  The total accumulation of heavy metals in body in connection with the dairy productivity of cows , 2021, Environmental Science and Pollution Research.

[2]  N. Ahmad,et al.  Heavy Metals in Acrylic Color Paints Intended for the School Children Use: A Potential Threat to the Children of Early Age , 2021, Molecules.

[3]  Calderón-Sánchez Francisco,et al.  Heavy metals in blood, milk and cow's urine reared in irrigated areas with wastewater , 2021, Heliyon.

[4]  M. Aschner,et al.  The Effect of Lead Exposure on Autism Development , 2021, International journal of molecular sciences.

[5]  J. Ni,et al.  A critical review of advancement in scientific research on food animal welfare-related air pollution. , 2020, Journal of hazardous materials.

[6]  B. Kuczyńska,et al.  The Effect of Selected Factors on the Content of Fat-Soluble Vitamins and Macro-Elements in Raw Milk from Holstein-Friesian and Simmental Cows and Acid Curd Cheese (Tvarog) , 2020, Animals : an open access journal from MDPI.

[7]  G. Genchi,et al.  The Effects of Cadmium Toxicity , 2020, International journal of environmental research and public health.

[8]  U. Nkwunonwo,et al.  A Review of the Health Implications of Heavy Metals in Food Chain in Nigeria , 2020, TheScientificWorldJournal.

[9]  Jorge Castro-Bedriñana,et al.  Lead and cadmium blood levels and transfer to milk in cattle reared in a mining area , 2020, Heliyon.

[10]  A. Patterson,et al.  The gut microbiome: an orchestrator of xenobiotic metabolism , 2019, Acta pharmaceutica Sinica. B.

[11]  E. Wall,et al.  Phenotypic and genetic analysis of milk and serum element concentrations in dairy cows. , 2019, Journal of dairy science.

[12]  Jiaqi Wang,et al.  Relationships between Pb, As, Cr, and Cd in individual cows' milk and milk composition and heavy metal contents in water, silage, and soil. , 2019, Environmental pollution.

[13]  Bung-Nyun Kim,et al.  The Effect of Prenatal Cadmium Exposure on Attention-deficit/Hyperactivity Disorder in 6-Year-old Children in Korea , 2019, Journal of preventive medicine and public health = Yebang Uihakhoe chi.

[14]  E. Levei,et al.  Metal (Pb, Cu, Cd, and Zn) Transfer along Food Chain and Health Risk Assessment through Raw Milk Consumption from Free-Range Cows , 2019, International journal of environmental research and public health.

[15]  B. Ametaj,et al.  Mineral Elements in the Raw Milk of Several Dairy Farms in the Province of Alberta , 2019, Foods.

[16]  I. Lean,et al.  Effects of in-feed enzymes on milk production and components, reproduction, and health in dairy cows. , 2019, Journal of dairy science.

[17]  S. Miroshnikov,et al.  The total content of toxic elements in horsehair given the level of essential elements , 2019, Environmental Science and Pollution Research.

[18]  A. Frolov,et al.  The Reference Values of Hair Content of Trace Elements in Dairy Cows of Holstein Breed , 2019, Biological Trace Element Research.

[19]  P. Myer Bovine Genome-Microbiome Interactions: Metagenomic Frontier for the Selection of Efficient Productivity in Cattle Systems , 2019, mSystems.

[20]  S. Miroshnikov,et al.  The content of toxic elements in hair of dairy cows as an indicator of productivity and elemental status of animals , 2019, Environmental Science and Pollution Research.

[21]  Ki‐Hyun Kim,et al.  Heavy metals in food crops: Health risks, fate, mechanisms, and management. , 2019, Environment international.

[22]  J. Gross,et al.  Invited review: Metabolic challenges and adaptation during different functional stages of the mammary gland in dairy cows: Perspectives for sustainable milk production. , 2019, Journal of dairy science.

[23]  Fatimah M. Alqahtani,et al.  Contamination level and risk assessment of heavy metal deposited in street dusts in Khamees-Mushait city, Saudi Arabia , 2018, Human and Ecological Risk Assessment: An International Journal.

[24]  M. Niku,et al.  Publisher Correction: The composition of the perinatal intestinal microbiota in cattle , 2018, Scientific reports.

[25]  S. Sobhanardakani Human Health Risk Assessment of Cd, Cu, Pb and Zn through Consumption of Raw and Pasteurized Cow’s Milk , 2018, Iranian journal of public health.

[26]  M. Niku,et al.  The composition of the perinatal intestinal microbiota in cattle , 2018, Scientific Reports.

[27]  S. Opiyo,et al.  Fecal microbiome of periparturient dairy cattle and associations with the onset of Salmonella shedding , 2018, PloS one.

[28]  L. Iannotti The benefits of animal products for child nutrition in developing countries. , 2018, Revue scientifique et technique.

[29]  Kamila Puppel,et al.  Relationship between the degree of antioxidant protection and the level of malondialdehyde in high-performance Polish Holstein-Friesian cows in peak of lactation , 2018, PloS one.

[30]  Ľ. Grešáková,et al.  The effects of high dose of two manganese supplements (organic and inorganic) on the rumen microbial ecosystem , 2018, PloS one.

[31]  C. Ríos,et al.  Metallothionein in Brain Disorders , 2017, Oxidative medicine and cellular longevity.

[32]  M. Siegrist,et al.  The importance of food naturalness for consumers: Results of a systematic review , 2017 .

[33]  Zhongtang Yu,et al.  Metagenomic investigation of gastrointestinal microbiome in cattle , 2017, Asian-Australasian journal of animal sciences.

[34]  T. Kimura,et al.  International Journal of Molecular Sciences the Functions of Metallothionein and Zip and Znt Transporters: an Overview and Perspective , 2022 .

[35]  L. Pieper,et al.  [Evaluation of sulfur status in dairy cows in Germany]. , 2016, Tierarztliche Praxis. Ausgabe G, Grosstiere/Nutztiere.

[36]  T. Murati,et al.  Lead Concentrations in Raw Cow and Goat Milk Collected in Rural Areas of Croatia from 2010 to 2014 , 2016, Bulletin of Environmental Contamination and Toxicology.

[37]  Jun-Hong Wang,et al.  Effects of chelated Zn/Cu/Mn on redox status, immune responses and hoof health in lactating Holstein cows , 2015, Journal of veterinary science.

[38]  I. Bolodurina,et al.  Method of Sampling Beef Cattle Hair for Assessment of Elemental Profile , 2015 .

[39]  C. Neethu,et al.  Heavy-metal resistance in Gram-negative bacteria isolated from Kongsfjord, Arctic. , 2015, Canadian journal of microbiology.

[40]  T. Gressley,et al.  Immune responses in lactating Holstein cows supplemented with Cu, Mn, and Zn as sulfates or methionine hydroxy analogue chelates. , 2012, Journal of dairy science.

[41]  M. Cristani,et al.  Levels of "toxic" and "essential" metals in samples of bovine milk from various dairy farms in Calabria, Italy. , 2004, Environment international.

[42]  C. Jie,et al.  Soil degradation: a global problem endangering sustainable development , 2002 .

[43]  J. C. Street,et al.  Accumulation and depletion of cadmium and lead in tissues and milk of lactating cows fed small amounts of these metals. , 1982, Journal of dairy science.

[44]  A. Frolov,et al.  Effect of lead concentration in hair on elemental interrelation and milk production of the Holstein cows , 2019, Animal Husbandry and Fodder Production.