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Infrared thermography as a non-invasive tool to study animal welfare

Published online by Cambridge University Press:  11 January 2023

M Stewart*
Affiliation:
Animal Behaviour and Welfare, AgResearch Ltd, Ruakura Research Centre, Private Bag 3123, Hamilton, New Zealand
JR Webster
Affiliation:
Animal Behaviour and Welfare, AgResearch Ltd, Ruakura Research Centre, Private Bag 3123, Hamilton, New Zealand
AL Schaefer
Affiliation:
Agriculture and Agri-Food Canada, Lacombe Research Centre, 6000 C & E Trail Lacombe, Alberta, Canada T4L 1W1
NJ Cook
Affiliation:
Alberta Agriculture Food and Rural Development, Lacombe, Alberta, Canada T4L 1W1
SL Scott
Affiliation:
Agriculture and Agri-Food Canada, P.O. Box–1000A, Brandon, Manitoba, Canada R7A 5Y3
*
* Contact for correspondence and requests for reprints: [email protected]
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Abstract

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Growing public concern regarding animal welfare and consumer demand for humanely produced products have placed pressure on the meat, wool and dairy industries to improve and confirm the welfare status of their animals. This has increased the need for reliable methods of assessing animal welfare during commercial farm practices. The measurement of the stress caused by commercial farm practices is a major component of animal welfare assessment. However, a major issue for animal welfare science is that many of the techniques used to measure stress involve invasive procedures, such as blood sampling, which may themselves cause a stress response and therefore affect the measurement of interest. To reduce this problem, a number of non-invasive or minimally invasive methods and devices have been developed to measure stress. These include the measurement of cortisol concentrations in saliva and faeces, and remote devices for recording body temperature, heart rate and the collection of blood samples. This review describes the benefits and limitations of some of these methods for measuring stress. In particular, the review focuses on recent advances and current research in the use of infrared thermography (IRT) for measuring stress. Specific applications for IRT in the dairy and beef industries are also described including an automated, non-invasive system for early diagnosis of infection in cattle. It is essential that non-invasive measures of acute and chronic stress are developed for reliable assessment of animal welfare during standard farm management practices and IRT may be a useful tool for this purpose. IRT may offer advantages over many other non-invasive systems as it appears to be capable of measuring different components of the stress axis, including acute sympathetic and hypothalamic-pituitary-adrenocortical responses.

Type
Research Article
Copyright
© 2005 Universities Federation for Animal Welfare

References

Alam, MGS and Dobson, H 1986 Effect of various veterinary procedures on plasma concentrations of cortisol, luteinising hormone and prostaglandin F2 alpha metabolite in the cow. Veterinary Record 118: 710CrossRefGoogle ScholarPubMed
Barham, AR, Barham, BL, Johnson, AK, Allen, DM, Blanton, JR and Miller, MF 2002 Effects of the transportation of beef cattle from the feedyard to the packing plant on prevalence levels of Escherichia coli O157 and Salmonella spp. Journal of Food Protection 65: 280283CrossRefGoogle Scholar
Beausoleil, NJ, Stafford, KJ and Mellor, DJ 2004 Can we use change in core body temperature to evaluate stress in sheep? Proceedings of the New Zealand Society of Animal Production 64: 7276Google Scholar
Bell, ME, Wood, CE and Keller-Wood, M 1991 Influence of reproductive state on pituitary-adrenal activity in the ewe. Domestic Animal Endocrinology 8: 245254CrossRefGoogle ScholarPubMed
Berry, RJ, Kennedy, AD, Scott, SL, Kyle, BL and Schaefer, AL 2003 Daily variation in the udder surface temperature of dairy cows measured by infrared thermography: potential for mastitis detection. Canadian Journal of Animal Science 83: 687693CrossRefGoogle Scholar
Bluett, SJ, Fisher, AD and Waugh, CD 2000 Heat challenge of dairy cows in the waikato: a comparison of spring and summer. Proceedings of New Zealand Society of Animal Production 60: 226229Google Scholar
Broom, DM and Johnson, KG 1993 Stress and Animal Welfare. Chapman & Hall: London, UKCrossRefGoogle Scholar
Champion, RA, Rutter, SM and Penning, PD 1997 An automatic system to monitor lying, standing and walking behaviour of grazing animals. Applied Animal Behaviour Science 54: 291305CrossRefGoogle Scholar
Clark, JD, Rager, DR and Calpin, JP 1997 Animal well-being. IV. Specific assessment criteria. Laboratory Animal Science 47: 586597Google ScholarPubMed
Cook, NJ and Schaefer, AL 2002 Stress responses of wapiti (Cervus elaphus canadensis) to removal of velvet antler. Canadian Journal of Animal Science 82: 1117CrossRefGoogle Scholar
Cook, NJ, Church, JS, Schaefer, AL, Webster, JR, Matthews, LR and Suttie, JM 2005 Stress and pain assessment of velvet antler removal from Elk (Cervus elaphus canadensis) and Reindeer (Rangifer tarandus). Online Journal of Veterinary Research 9: 2436Google Scholar
Cook, NJ, Schaefer, AL, Lepage, P and Morgan Jones, S 1996 Salivary vs serum cortisol for the assessment of adrenal activity in swine. Canadian Journal of Animal Science 76: 329335CrossRefGoogle Scholar
Cook, NJ, Schaefer, AL, Warren, L, Burwash, L, Anderson, M and Baron, V 2001 Adrenocortical and metabolic responses to ACTH injection in horses: an assessment by salivary cortisol and infrared thermography of the eye. Canadian Society of Animal Science 81: 621 (Abstracts of Technical Papers)Google Scholar
Cusack, PMV, McMeniman, N and Lean, IJ 2003 The medicine and epidemiology of bovine respiratory disease in feedlots. Australian Veterinary Journal 81: 480487CrossRefGoogle ScholarPubMed
De Silva, M, Kiehm, DJ, Kaltenbach, CC and Dunn, TG 1986 Comparison of serum cortisol and prolactin in sheep blood sampled by two methods. Domestic Animal Endocrinology 3: 1116CrossRefGoogle Scholar
Eigenberg, RA, Hahn, GL, Nienaber, JA, Brown-Brandl, TM and Spiers, DE 2000 Development of a new respiration rate monitor for cattle. Transactions of the American Society of Agricultural Engineers 43: 723728CrossRefGoogle Scholar
Fisher, AD, Verkerk, GA, Morrow, CJ and Matthews, LR 2002 The effects of feed restriction and lying deprivation on pituitary-adrenal axis regulation in lactating cows. Livestock Production Science 73: 255263CrossRefGoogle Scholar
Fraser, D, Ritchie, JS and Fraser, AF 1975 The term ‘stress’ in a veterinary context. British Veterinary Journal 131: 653662CrossRefGoogle Scholar
Gill, R, Howard, WH, Leslie, KE and Lissemore, K 1990 Economics of mastitis control. Journal of Dairy Science 73: 33403348CrossRefGoogle ScholarPubMed
Hopster, H, van der Werf, JTN, Erkens, JHF, Blokhuis, HJ and Hopster, H 1999 Effects of repeated jugular puncture on plasma cortisol concentrations in loose-housed dairy cows. Journal of Animal Science 77: 708714CrossRefGoogle ScholarPubMed
Houe, H 1999 Epidemiological features and economical importance of bovine virus diarrhoea virus (BVDV) infections. Veterinary Microbiology 64: 89107CrossRefGoogle ScholarPubMed
Hurnik, JF, Webster, AB and DeBoer, S 1985 An investigation of skin temperature differentials in relation to estrus in dairy cattle using a thermal infrared scanning technique. Journal of Animal Science 61: 10951102CrossRefGoogle ScholarPubMed
Ingram, J, Cook, C and Harris, P 2002 The effect of transport on core and peripheral body temperature and heart rate of sheep. Animal Welfare 11: 103112Google Scholar
Ingram, JR, Matthews, LR, Carragher, JF and Schaare, PR 1997 Plasma cortisol responses to remote adrenocorticotropic hormone (ACTH) infusion in free-ranging red deer (Cervus elaphus). Domestic Animal Endocrinology 14: 6371CrossRefGoogle Scholar
Jensen, P and Toates, FM 1997 Stress as a state of motivational systems. Applied Animal Behaviour Science 53: 145156CrossRefGoogle Scholar
Kastelic, JP, Cook, RB, Coulter, GH, Wallins, GL and Entz, T 1996 Environmental factors affecting measurement of bovine scrotal surface temperature with infrared thermography. Animal Reproduction Science 41: 153159CrossRefGoogle Scholar
Kelley, KW 1985 Immunological consequences of changing environmental stimuli. In: Moberg, GP (ed) Animal Stress pp 193224. American Physiological Society: Bethesda, Maryland, USACrossRefGoogle Scholar
Kleiber, M 1975 The Fire of Life. RE Krieger Publishing Company: Huntington, New York, USAGoogle Scholar
Lefcourt, AM and Adams, WR 1998 Radiotelemetric measurement of body temperature in feedlot steers during winter. Journal of Animal Science 76: 18301837CrossRefGoogle ScholarPubMed
Lefcourt, AM, Bitman, J, Kahl, S and Wood, DL 1993 Circadian and ultradian rhythms of peripheral cortisol concentrations in lactating dairy cows. Journal of Dairy Science 76: 26072612CrossRefGoogle ScholarPubMed
Lefcourt, AM, Erez, B, Varner, MA, Barfield, R and Tasch, U 1999 A noninvasive radiotelemetry system to monitor heart rate for assessing stress responses of bovines. Journal of Dairy Science 82: 11791187CrossRefGoogle ScholarPubMed
Lowe, TE, Cook, CJ, Ingram, JR and Harris, PJ 2005 Changes in ear-pinna temperature as a useful measure of stress in sheep (Ovis aries). Animal Welfare 14: 3542Google Scholar
Marchant-Forde, RM, Marlin, DJ and Marchant-Forde, JN 2004 Validation of a cardiac monitor for measuring heart rate variability in adult female pigs: accuracy, artefacts and editing. Physiology & Behavior 80: 449458CrossRefGoogle ScholarPubMed
Marieb, EN 1989 Human Anatomy and Physiology pp 676677. Benjamin Cummings: California, USAGoogle Scholar
Mohr, E, Langbein, J and Nurnberg, G 2002 Heart rate variability: a noninvasive approach to measure stress in calves and cows. Physiology & Behavior 75: 251259CrossRefGoogle ScholarPubMed
Morrow, CJ, Kolver, ES, Verkerk, GA and Matthews, LR 2002 Fecal glucocorticoid metabolites as a measure of adrenal activity in dairy cattle. General and Comparative Endocrinology 126: 229241CrossRefGoogle ScholarPubMed
Mulleder, C, Palme, R, Menke, C and Waiblinger, S 2003 Individual differences in behaviour and in adrenocortical activity in beef-suckler cows. Applied Animal Behaviour Science 84: 167183CrossRefGoogle Scholar
Negrao, JA, Porcionato, MA, de Passille, AM and Rushen, J 2003 Cortisol in saliva and plasma of cattle after ACTH administration and milking. Journal of Dairy Science 87: 17131718CrossRefGoogle Scholar
Nikkhah, A, Plaizier, JC, Einarson, MS, Berry, RJ, Scott, SL and Kennedy, AD 2005 Short communication. Infrared thermography and visual examination of hooves of dairy cows in two stages of lactation. Journal of Dairy Science 88: 27492753CrossRefGoogle ScholarPubMed
Palme, R, Robia, C, Baumgartner, W and Mostl, E 2000 Transport stress in cattle as reflected by an increase in faecal cortisol metabolite concentrations. Veterinary Record 146: 108109CrossRefGoogle ScholarPubMed
Palmer, SE 1981 Use of the portable infrared thermometer as a means of measuring limb surface temperature in the horse. American Journal of Veterinary Research 42: 105108Google ScholarPubMed
Pol, F, Courboulay, V, Cotte, JP, Martrenchar, A, Hay, M and Mormede, P 2002 Urinary cortisol as an additional tool to assess the welfare of pregnant sows kept in two types of housing. Veterinary Research 33: 1322CrossRefGoogle ScholarPubMed
Purohit, RC and McCoy, MD 1980 Thermography in the diagnosis of inflammatory processes in the horse. American Journal of Veterinary Research 41: 11671174Google ScholarPubMed
Rutter, SM, Champion, RA and Penning, PD 1997 An automatic system to record foraging behaviour in free-ranging ruminants. Applied Animal Behaviour Science 54: 185195Google Scholar
Schaefer, AL, Cook, NJ, Tessaro, SV, Deregt, D, Desroches, G, Dubeski, PL, Tong, AKW and Godson, DL 2003 Early detection and prediction of infection using infrared thermography. Canadian Journal of Animal Science 84: 7380CrossRefGoogle Scholar
Schaefer, AL, Jones, SDM, Murray, AC, Sather, AP and Tong, AKW 1989 Infrared thermography of pigs with known genotypes for stress susceptibility in relation to pork quality. Canadian Journal of Animal Science 69: 491495CrossRefGoogle Scholar
Schaefer, AL, Jones, SDM, Tong, AKW and Vincent, BC 1988 The effects of fasting and transportation on beef cattle. 1. Acid-base-electrolyte balance and infrared heat loss of beef cattle. Livestock Production Science 20: 1524Google Scholar
Schaefer, AL, Matthews, LR, Cook, NJ, Webster, J and Scott, SL 2002 Novel non-invasive measures of animal welfare. Animal Welfare and Behaviour: From Science to Solution, Joint NAWAC/ISAE Conference. 27–28 June 2002. Hamilton, New ZealandGoogle Scholar
Schwartzkopf, GKS and Stookey, JM 1997 The use of infrared thermography to assess inflammation associated with hot-iron and freeze branding in cattle. Canadian Journal of Animal Science 77: 577583Google Scholar
Scott, SL, Schaefer, AL, Tong, AKW and Lacasse, P 2000 Use of infrared thermography for early detection of mastitis in dairy cows. Canadian Journal of Animal Science 80: 764765 (Abstracts of Technical Papers)Google Scholar
Stewart, M, Webster, JR, Verkerk, GA, Colyn, JJ and Schaefer, AL 2005 Infrared thermography as a non-invasive measure of stress in dairy cows. Journal of Animal Science 83, Suppl 1: Abstract 633Google Scholar
Tong, AKW, Schaefer, AL and Jones, SDM 1995 Detection of poor quality beef using infrared thermography. Meat Focus International 4: 443445Google Scholar
Verkerk, GA, Phipps, AM and Matthews, LR 1996 Milk cortisol concentrations as an indicator of stress in lactating dairy cows. Proceedings of the New Zealand Society of Animal Production 56: 7779Google Scholar
Weiss, JM 1972 Psychological factors in stress an disease. Scientific American 226: 104113CrossRefGoogle ScholarPubMed
Yang, W and Yang, PPT 1992 Literature survey on biomedical applications of thermography. Bio-Medical Materials and Engineering 2: 718CrossRefGoogle ScholarPubMed