Abstract
The present investigation was performed to assess the concentrations of four heavy metals—lead (Pb), cadmium (Cd), copper (Cu), and cobalt (Co)—in goats reared in the vicinity of an industrial area of West Bengal, India, including soil, water, and feedstuffs; tissues of liver, kidney, lung, spleen, and muscle; and milk and faeces. In addition, histopathological changes in liver, lung, kidney, spleen, and muscle samples were examined. Mejia block as an industrial polluted site and Vatar block as a reference site (without any industrial activities and 120 km away from the polluted site) were selected for this study. The results showed that concentrations of these heavy metals in soil, water feedstuffs, all tissues, milk, and faeces were greater (P < 0.05) in the polluted site than the reference site. The largest concentrations of Cd and Pb were found in kidney followed by liver, lung, spleen, and muscle. However, Co and Cu accumulations in the tissues were in following order: liver > kidney > lung > spleen > muscle. Concentrations of heavy metals were greater in older animals than in young ones. Haemoglobin, total protein, packed cell volume, total erythrocyte counts, and total leucocytes counts were significantly (P < 0.01) decreased in blood of goats in the polluted site compared with the reference site. Serum glucose, creatinine, aspartate amino transferase, alanine amino transferase, and alkanline phosphatase were significantly (P < 0.05 to P < 0.01) increased. Histological examination showed several pathological alterations including degeneration, vacuolation, and tubulitis in kidney; congestion, degeneration, periportal necrosis, and focal haemorrhages in liver; and congestion and diffuse haemorrhage in lungs. It was concluded that natural exposure to these environmental heavy metals significantly increases toxic heavy-metal concentrations in several visceral organs resulting in pathological changes in these tissues. Thus, consumption of the meat of goats reared in the polluted site may pose human health hazards.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abraham RJJ, Chandran M, Shanmugam M (1999) Levels of toxic metals in goat muscle and organs. Cerion 28:62–65
Agency for Toxic Substances and Disease Registry (2013) Minimum risk levels (MRLs). Available at: http://www.atsdr.cdc.gov/mrls/pdfs/atsdr_mrls_july_2013.pdf. Accessed 24 August 2013
Al-Masri MS, Al-Kharfan K, Al-Shamali K (2006) Speciation of Pb, Cu and Zn determined by sequential extraction for identification of air pollution sources in Syria. Atmos Environ 40:753–761
Aneta S, Tadeusz W, Elzbieta Z (2012) Effect of dietary cadmium and or lead on histopathological changes in the kidneys and liver of bank voles (Myodes glareolus) in different group densities. Ecotoxicology 21:2235–2243
Antoniou V, Zantopoulos N (1992) Cadmium concentrations in plants and goat tissues from various areas of Chalikidiki, Greece. Bull Environ Contam Toxicol 48:515–519
Bancroft JD, Stevens A (1980) Theory and practice of histology technique. Churchill Livingstone, New York
Chabukdhara M, Nema AK (2013) Heavy metals assessment in urban soil around industrial clusters in Ghaziabad, India: Probabilistic health risk approach. Ecotoxicol Environ Saf 87:57–64
Chatterjee S (2011) Source, disposal and impacts of airborne pollutants: a case study of Mangalpur industrial complex, Ranigunj. J Human Ecol 35:195–201
Chen YW, Yang CY, Chun FH, Dong ZH, Yuk ML, Shing HL (2009) Heavy metals, islet function and diabetes development. Ilets 1:169–176
Cornelius CE (1989) Liver function. In: Kaneko JJ (ed) Clinical biochemistry of domestic animals. Academic Press, San Diego, CA, pp 185–234
Dorian C, Gattone VH (1992) Renal cadmium deposition and injury as a result of accumulation of cadmium metallothionein (CdMT) by proximal convoluted tubules—a light microscope autoradiographic study with CdMT. Toxicol Appl Pharmacol 114:173–181
Dutta BK, Misra A, Singh A, Sar TK, Sarkar S, Bhatacharya A et al (2010) Chronic arsenicosis in cattle with special reference to its metabolism in arsenic endemic village of Nadia district West Bengal India. Sci Total Environ 409:284–288
Dwivedi SK, Dey S, Swarup D (1995) Lead in blood and milk from urban Indian cattle and buffalo. Vet Hum Toxicol 37:471–472
European Union (2006) Commission regulation (EC) No. 1881/2006 of 19 December 2006 setting maximum levels for certain contaminants in foodstuffs. Off J Eur Union 2006; L364/5
Faulkner WR, Meites S (1982) Selected methods for the small clinical chemistry laboratory. American Association for Clinical Chemistry, Washington, DC
Han JC, Park SY, Hah BG (2003) Cadmium induces impaired glucose tolerance in rat by down regulating GLUT4 expression in adipocytes. Arch Biochem Biophys 413:213–220
Hogstrand C, Haux C (1991) Mini-review. Binding and detoxification of heavy metal in lower vertebrates with reference to metallothionein. Comp Biochem Physiol C 100:249–252
Jadhav SH, Sarkar SN, Patil RD, Tripathi HC (2007) Effects of subchronic exposure via drinking water to a mixture of eight water-contaminating metals: a biochemical and histopathological study in male rats. Arch Environ Contam Toxicol 53:667–677
Jain NC (1986) Schalm’s veterinary haematology, 4th edn. Lea and Febiger, Philadelphia
Jarup L (2003) Hazards of heavy metal contamination. Br Med Bull 68:167–182
Jayakumar P, Paul VI (2006) Patterns of cadmium accumulation of the catfish Clarias batrachus (Linn.) exposed to sublethal concentration of cadmium chloride. Veterinarski Arhiv 76:167–177
Kaneko JJ (1980) Clinical biochemistry of domestic animals, 3rd edn. Academic Press, New York
Khillare PS, Balachandaran S, Meena BR (2004) Spatial and temporal variation of heavy metal in atmospheric aerosol of Delhi. Environ Monit Assess 90:1–21
Kind PRN, King EJ (1954) Estimation of plasma phosphatase by determination of hydrolysed phenol with aminoantipyrin. J Clin Pathol 7:332–336
Krishna AK, Govil PK (2007) Soil contamination due to heavy metals from an industrial area of Surat, Gujarat, Western India. Environ Monit Assess 124:263–275
Kumar S (2005) Studies on experimental lead toxicity in chicken and the effect of cadmium supplementation in modulating the toxicity. Indian J Vet Pathol 29:150
Kumar P, Prasad Y, Patra AK, Swarup D (2007) Levels of cadmium and lead in tissues of freshwater fish (Clarias batrachus L.) and chicken in Western UP (India). Bull Environ Contam Toxicol 79:396–400
Kumar P, Prasad Y, Patra AK, Ranjan R, Swarup D, Patra RC et al (2009) Ascorbic acid, garlic extract and taurine alleviate cadmium-induced oxidative stress in freshwater catfish (Clarias batrachus). Sci Total Environ 407:5024–5030
Lokeshwari H, Chandrappa GT (2006) Impact of heavy metal contamination of Bellandur Lake on soil and cultivated vegetation. Curr Sci 91:622–627
Lucas AM, Jamroz C (1961) Atlas of avian haematology. Government Printer, Washington
Luo XG, Lin JF, Steward YX, Lu FA, Liu LB, Yu SX (2005) Effect of dietary supplementation with copper sulfate for tribasic copper chloride on broiler performance, relative copper bioavailablity and oxidation stability of vit-E in feed. Poult Sci 84:888–893
Madejón P, Dominguez MT, Murillo JM (2009) Evaluation of pastures for horses grazing on soils polluted by trace elements. Ecotoxicology 18:417–428
Maiti SK, Swarup D (1990) Some haematobiochemical finding in experimental chronic lead poisoning in goat. Indian J Anim Sci 60:761–765
Miles RD, O’Keefe SF, Henry PR, Ammersman CB, Luo XG (1998) The effect of dietary supplementation with copper sulfate for tribasic copper chloride on broiler performance, relative copper bioavailablity and dietary pro-oxidant activity. Poult Sci 77:416–425
Mohajeri G, Norouzian MA, Mohseni M, Afzalzadeh A (2014) Changes in blood metals, hematology and hepatic enzyme activities in lactating cows reared in the vicinity of a lead-zinc smelter. Bull Environ Contam Toxicol 92:693–697
Nakazato K, Nagamine T, Suzuki K, Kusakabe T, Moon HD, Oikawa M et al (2008) Subcellular changes of essential metal shown by in-air micro-PIXE in oral cadmium-exposed mice. Biometals 21:83–91
Natt MP, Herrick CA (1952) A new blood diluent for counting the erythrocytes and the leucocytes of the chicken. Poult Sci 31:735–778
Nawrot T, Plusquin M, Hogervorst J, Roels H, Celis H, Thijs L et al (2006) Environmental exposure to cadmium and risk of cancer: a prospective population-based study. Lancet Oncol 7:119–126
Nordberg M, Nordberg GF (2009) Metallothioneins: Historical development and overview. In: Sigel A, Sigel H, Sigel RKO (eds) Metal ions in life sciences, vol 5. Royal Society of Chemistry, London, UK, pp 1–29
Ogheneovo AS (2010) Biochemical changes in urine and plasma of rats in food chain-mediated cadmium toxicity. Toxicol Ind Health 26:459–467
Öhrvik H, Oskarsson H, Lundh T, Staffan Skerfving S, Tallkvist J (2007) Impact of iron status on cadmium uptake in suckling piglets. Toxicology 240:15–24
Olawoyin R, Oyewole SA, Grayson RL (2012) Potential risk effect from increased levels of soil heavy metals on human health in the Niger delta. Ecotoxicol Environ Saf 85:120–130
Patra RC, Swarup D, Dwivedi D, Sahoo A (2001) Trace mineral in blood of young calves during exposure to lead. Indian J Anim Sci 71:507–510
Patra RC, Swarup D, Naresh R, Kumar P, Shekhar P (2005) Cadmium level in blood and milk from animals reared around different polluting sources in India. Bull Environ Contam Toxicol 74:1092–1097
Patra RC, Swarup D, Kumar P, Nandi D, Naresh R, Ali SL (2008) Milk trace elements in lactating cows environmentally exposed to greater levels of lead and cadmium around different industrial unit. Sci Total Environ 404:36–43
Reglero MM, Monsalve-González L, Taggart MA, Mateo R (2008) Transfer of metals to plants and red deer in an old lead mining area in Spain. Sci Total Environ 406:287–297
Reitman S, Frankel S (1957) A Colorimetric method for determination of serum glutamic oxaloacetic and glutamic pyruvic transaminases. Am J Clin Pathol 28:56–63
Roggeman S, de Boeck G, De Cock H, Blust R, Bervoets (2014) Accumulation and detoxification of metals and arsenic in tissues of cattle (Bos taurus), and the risks for human consumption. Sci Total Environ 466–467:175–184
Rubio R, Tineo P, Torreblance A, Del-Romo J, Mayans JD (1991) Histological and electron microscopical observations on the effects of lead on gills and midget gland of Procamarus clarkii. Toxicol Environ Chem 31:347–352
Sandel EB (1950) Colorimetric determination of traces of metal. Inter Science Publishers, New York
Satarug S, Baker JR, Urbenjapol S, Haswell-Elkins M, Reilly PEB, Williams DJ et al (2003) A global perspective on cadmium pollution and toxicity in non-occupationally exposed population. Toxicol Lett 137:65–83
Sola-Larrañaga C, Navarro-Blasco I (2009) Chemometric analysis of minerals and trace elements in raw cow milk from the community of Navarra, Spain. Food Chem 112:189–196
Somasundaram J, Krishnasamy R, Savithri P (2005) Biotransfer of heavy metals in Jersey cows. Indian J Anim Sci 75:1257–1260
Srinivasa Gowd S, Govil PK (2008) Distribution of heavy metals in surface water of Ranipet industrial area in Tamil Nadu, India. Environ Monit Assess 136:263–275
Srinivasa Gowd Swarup D, Patra RC, Naresh R, Kumar P, Shekhar P (2005) Blood lead levels in lactating cows reared around polluted localities: transfer of lead in to milk. Sci Total Environ 347:106–110
Srinivasa Gowd Włostowski T, Dmowski K, Bonda-Ostaszewska E (2010) Cadmium accumulation, metallothionein and glutathione levels, and histopathological changes in the kidneys and liver of magpie (Pica pica) from a zinc smelter area. Ecotoxicology 19:1066–1073
Tennant BC (1997) Hepatic function. In: Kaneko JJ, Harvey JW, Bruss ML (eds) Clinical biochemistry of domestic animals. Academic Press, San Dieogo, CA, pp 327–349
Tietz NW (1976) Fundamental of clinical chemistry. W. B. Saunders, Philadelphia
Wooton IDP (1974) Estimation of protein by biuret method. In: Microanalysis in medical biochemistry, 5th edn. Churchill Livingstone, Edinburgh, pp 156–158
Yuan G, Dai S, Yin Z, Lu H, Jia R, Xu J et al (2014) Toxicological assessment of combined lead and cadmium: acute and sub-chronic toxicity study in rats. Food Chem Toxicol 65:260–268
Zheng J, Chen KH, Yan X, Chen SJ, Hu GC, Peng XW et al (2013) Heavy metals in food, house dust, and water from an e-waste recycling area in South China and the potential risk to human health. Ecotoxicol Environ Saf 96:205–212
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Kar, I., Mukhopadhayay, S.K., Patra, A.K. et al. Metal Concentrations and Histopathological Changes in Goats (Capra hircus) Reared Near an Industrial Area of West Bengal, India. Arch Environ Contam Toxicol 69, 32–43 (2015). https://doi.org/10.1007/s00244-015-0130-2
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00244-015-0130-2