Hostname: page-component-cd9895bd7-fscjk Total loading time: 0 Render date: 2024-12-28T18:49:10.521Z Has data issue: false hasContentIssue false

Effects of short-term whole body vibration on animals with particular reference to poultry

Published online by Cambridge University Press:  18 September 2007

Graham B. Scott
Affiliation:
Poultry Science Department, Scottish Agricultural College, Auchincruive, Ayr KA6 5HW, UK
Get access

Abstract

Animals are exposed to various vibration and movement stimuli during transport. The vibrations are a potential source of stress in birds because the resonances they set up in the internal organs are likely to be major aversive stimuli. This paper considers the possible effects of vibration on broilers in transport by reference to the known effects of vibration on other species. The fundamental frequency of poultry transporters is between 1 and 2 Hz, with a secondary peak of 10 Hz and a chassis vibration in the lateral axis of 12–18 Hz. Suggested resonance frequencies for the viscera of broiler chickens exposed to vertical vibration are around 10 Hz, and so coincide with the secondary peak. Skeletal muscle responds to movement and vibration in order to maintain postural stability and reduce the effects of resonance. Standing birds maintain stability by wing extension and by flapping or squatting. Involuntary muscle and cardiac muscle are also affected by vibration with blood circulation, heart beat and possibly gut control changing as a result. Vibration-induced vasodilatation may occur, as may blood pooling in the organs, pulmonary damage and impaired thermoregulation. Biochemical changes resulting from vibration could have adverse effects on meat quality in birds unable to recover before slaughter.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1994

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Anon (1964) A study of the effects of anaesthesia, high oxygen and feeding upon the resonant frequencies of visceral organs. Technical Report AMRL-TDR-64−14. Aerospace Medical Research Laboratories, Wright-Patterson, Air Force Base, OhioGoogle Scholar
Ariizumi, M., Yamaguchi, Y. and Okada, A. (1986) Effect of local vibration on the brain monoamines in rats. Scandinavian Journal of Work, Environment and Health 12:435437Google Scholar
Bailey, K.J., Stephens, D.B. and Delaney, C.E. (1986) Observations on the effects of vibration and noise on plasma ACTH and zinc levels, pregnancy and respiration rate in the guinea pig. Laboratory Animals 20: 101108CrossRefGoogle Scholar
Black, A.H. (1965) Cardiac conditioning in curarized dogs: the relationship between heart rate and skeletal behaviour. In: Classical Conditioning (Ed. Prokasy, W.F.) Appleton-Century Crofts, New York, pp. 112Google Scholar
Blivaiss, B.B., Litta-Modignani, R., Galansino, G. and Foa, P.P. (1965) Endocrine and metabolic response of dogs to whole-body vibration. Aerospace Medicine 36:11381144Google Scholar
Broderson, A.B. (1972) Biothermal response of the rhesus monkey to mechanical vibration. Annual Scientific Meeting of Aerospace Medical Association, Florida 8–11 May, pp 4142Google Scholar
Brooks, G.A., Hittelman, K.J., Faulkner, J.A. and Beyer, R.E. (1971) Tissue temperature and whole animal oxygen consumption after exercise. American Journal of Physiology 221:427431CrossRefGoogle ScholarPubMed
Burke, D. (1980) Muscle spindle function during motion. Trends in Neuroscience 11:251253CrossRefGoogle Scholar
Catterson, A.D., Hoover, G.H. and Ashe, W.F. (1962) Human psychomotor performance during prolonged vertical vibration. Aerospace Medicine 33:598602Google Scholar
Clark, J.G., Williams, J.D., Hood, W.B. Jr and Murray, R.H. (1967) Initial cardiovascular response to low frequency whole-body vibration in humans and animals. Aerospace Medicine 38:464467Google ScholarPubMed
Diener, H.C., Dichgans, J., Bruzek, W. and Selinka, H. (1982) Stabilization of human posture during induced oscillations of the body. Experimental Brain Research 45:126_132Google ScholarPubMed
Dines, J.H., Sutphen, J.H., Roberts, L.B. and Ashe, W.F. (1965) Intravascular pressure measurements during vibration. Archives of Environmental Health 11:323326CrossRefGoogle Scholar
Dupuis, H. and Zerleet, G. (1986) The Effect of Whole-Body Vibration. Springer-Verlag, New YorkCrossRefGoogle Scholar
Edwards, R.G., McCutcheon, E.P. and Knapp, C.F. (1972) Cardiovascular changes produced by brief whole-body vibration of animals. Journal of Applied Physiology 32:386390CrossRefGoogle ScholarPubMed
Floyd, W.N., Broderson, A.B. and Goodno, J.F. (1973) Effect of whole-body vibration on peripheral nerve conduction time in the rhesus monkey. Aerospace Medicine 44:281285Google ScholarPubMed
Fox, R.A., Keil, L.C., Daunton, N.G., Crampton, G.H. and Lucot, J. (1987) Vasopressin and motion sickness in cats. Aviation Space and Environmental Medicine 58 (Suppl):A143–147Google ScholarPubMed
Fraser, T.M. (1961) Tracking performance during low frequency vibration. Aerospace Medicine 32:829835Google ScholarPubMed
Gillies, J.D., Lance, J.W., Neilson, P.D. and Tassinari, C.A. (1969) Presynaptic inhibitions of the monosynaptic reflex by vibration. Journal of Physiology 205:329339CrossRefGoogle ScholarPubMed
Gottschaldt, K.M. (1985) Structure and function of avian somatosensory receptors. In: Form and Function in Birds: Volume 3 (Eds King, A.S. and McLelland, J.). Academic Press, London, pp. 375461Google Scholar
Guignard, J.C. (1960) Physiological effects of mechanical vibration. Proceedings of the Royal Society of Medicine 53:9296Google ScholarPubMed
Guignard, J.C. and Coles, R.R.A. (1965) Effects of infrasonic vibration on the hearing. 5e Congr: Int.d' AcoustLiegeGoogle Scholar
Hood, W.B. Jr. and Higgins, L.S. (1965). Circulatory and respiratory effects of whole body vibration in anaesthetized dogs. Journal of Applied Physiology 20:11571162CrossRefGoogle Scholar
Hood, W.B. Jr, Murray, R.H., Urschel, C.W., Bowers, J.A. and Clark, J.G. (1966) Cardiopulmonary effects of whole-body vibration in man. Journal of Applied Physiology 21:17251731CrossRefGoogle ScholarPubMed
Hoover, G.N. and Ashe, W.F. (1962) Respiratory responses to whole-body vertical vibration. Aerospace Medicine 33:980984Google ScholarPubMed
Hoover, G.N., Ashe, W.F., Dines, J.H. and Fraser, T.M. (1961) Vibration studies, III. Blood pressure responses to whole-body vibration in anaesthetized dogs. Archives of Environmental Health 3:426432CrossRefGoogle Scholar
International Organisation for Standardization (ISO) (1989) Evaluation of human exposure to whole-body vibration. ISO 2623. International Organisation for Standardization, Geneva.Google Scholar
Jauhiainen, T., Kohonen, A., Tarkkanen, J. and Kaimio, M. (1969) The effect of whole-body vibration on the cochlea. Laryngoscope 79:19501955CrossRefGoogle ScholarPubMed
Kazanskaya, Y.P. and Luk'yanova, L.D. (1966) Respiratory changes during vibration. In: The Effect of Space Flight on Functions of the Central Nervous System. NASA document TTF-413, pp.118121Google Scholar
Kettlewell, P.J. and Turner, M.J.B. (1985) A review of broiler chicken catching and transport systems. Journal of Agricultural Engineering Research 31:93114CrossRefGoogle Scholar
King, A.I., Aston, R. and Van Kirk, D.J. (1969) Quantitation of pulmonary fluid changes due to whole-body vibration in the mouse. Proceedings of the Society of Experimental Biology and Medicine 131:531533CrossRefGoogle ScholarPubMed
Kosmakos, F.C., Keller, E.C. and Collins, W.E. (1975) Effects of mechanical vibration on rat plasma calcium, magnesium, phosphate and xanthine oxidase. Aviation Space and Environmental Medicine 46:13631367Google ScholarPubMed
Kuznetsova, M.A. (1966) Effect of multiple exposure to vibration on the functional state of the spinal reflex arc (translation). In: The Effect of Space Flight on Functions of the Central Nervous System, NASA document TTF-413, pp. 4060Google Scholar
Lawther, A. and Griffin, M.J. (1988) A survey of the occurrence of motion sickness amongst passengers at sea. Aviation Space and Environmental Medicine 59:399406Google ScholarPubMed
Leibowitz, H.W., Johnson, C.A. and Isabella, E. (1972) Peripheral motion detection and refractive error. Science 177:12071208CrossRefGoogle ScholarPubMed
Liedtke, A.J. and Schmid, P.G. (1969) Effect of vibration on total vascular resistance in the forelimb of the dog. Journal of Applied Physiology 26:95100CrossRefGoogle ScholarPubMed
Ljung, B. and Sivertsson, R. (1975) Vibration-induced inhibition of smooth muscle contraction. Blood Vessels 12:3852Google ScholarPubMed
Luk'yanova, L.D. (1965) Effect of general repeated vibration on oxygen tension in the brain of rats. In: Effects of Ionizing Radiation and of Dynamic Factors on the Functions of the Central Nervous system – Problems of Space Physiology (Ed. Livshits, N.), National Aeronautics and Space Administration, Washington DC NASA Document TTF-354, pp. 111125Google Scholar
Luscot, J.B., Crampton, G.H., Matson, W.R and Gamache, P.H. (1989) Cerebrospinal fluid constitents of cat vary with susceptibility to motion sickness. Life Sciences 44:12391245CrossRefGoogle Scholar
Madig, E.B. and Coerman, R. (1960) The reaction of the human body to extreme vibrations. Proceedings of the Institute of Environmental Science 37:135Google Scholar
MAFF (1991) Agricultural Statistics, United Kingdom, 1989. HMSO, Edinburgh PressGoogle Scholar
McCutcheon, E.P., Edwards, R.G., Evan, J.M., Lafferty, J.F. and McCoy, D.F. (1974) A standard psychophysiological preparation for evaluating the effects of environmental vibration stress. Phase II: Implementation. Aerospace Medical Research Laboratories, Wright-Patterson Air Force Base, OhioGoogle Scholar
Mitchell, M.A., Kettlewell, P.J. and Maxwell, M.H. (1992) Indicators of physiological stress in broiler chickens during road transportation. Animal Welfare 1:91103CrossRefGoogle Scholar
Mountcastle, V.B., Talbot, W.H., Sakata, H. and Hyvarinen, J. (1969) Corticol neuronal mechanisms in flutter-vibration studied in unanaesthetized monkeys. Neuronal periodically and frequency discrimination. Journal of Neurophysiology 32:452484CrossRefGoogle Scholar
Nickerson, J.L. (1966) Internal body movement along three axes resulting from externally applied sinusoidal forces. Aerospace Medical Research Laboratories, Wright-Patterson Air Force Base, OhioCrossRefGoogle ScholarPubMed
Nicol, C.J., Blakeborough, A. and Scott, G.B. (1990) Aversiveness of motion and noise to broiler chickens. British Poultry Science 32:249260CrossRefGoogle Scholar
Randall, J.M. (1992) Human subjective response to lorry vibration: implications for farm animal transport. Journal of Agricultural Engineering Research 52:295307CrossRefGoogle Scholar
Randall, J.M., Streader, W.V. and Meehan, A.M. (1993) Vibration on poultry transporters. British Poultry Science 34:635642CrossRefGoogle ScholarPubMed
Riopelle, A.J., Hines, M. and Lawrence, M. (1958) US Army Medical Research Laboratory Report No. 358, Fort Knox, KentuckyGoogle Scholar
Rutter, S.M. and Randall, J.M. (1993) The aversion of domestic fowl to whole-body vibratory motion. Applied Animal Behaviour Science 37:6973CrossRefGoogle Scholar
Rutter, S.M., Scott, G.B. and Moran, P. (1993) The aversiveness of mechanical conveying to laying hens. British Poultry Science 34:279285CrossRefGoogle Scholar
Sass, D.J., Corrao, P. and Ommaya, A.K. (1971) Brain motion during vibration of water immersed rhesus monkeys. Journal of Biomechanics 4:331334CrossRefGoogle ScholarPubMed
Schmitz, M.A. and Boettcher, C.A. (1960) Some physical effects of low frequency, high amplitude vibration. American Society of Mechanical Engineering 5:15Google Scholar
Scott, G.B. (1993) Poultry handling - a review of mechanical devices and their effect on bird welfare. World's Poultry Science Journal 49:4457CrossRefGoogle Scholar
Starck, J., Pekkarinen, J., Pykko, I., Aalto, H. and Toppila, E. (1991) Transmission of vibration from support surface to human body in the evaluation of postural stability. Journal of Low Frequency Noise and Vibration 10:17CrossRefGoogle Scholar
Stephens, D.B., Bailey, K.J., Sharman, D.F. and Ingram, D.L. (1985) An analysis of some behavioural effects of the vibration and noise components of transport in pigs. Quarterly Journal of Experimental Physiology 70:211217CrossRefGoogle ScholarPubMed
Takano, K. and Homma, S. (1968) Muscle spindle responses to vibratory stimuli at certain frequencies. Japanese Journal of Physiology 18:145156Google ScholarPubMed
Walgenbach, S.C., Burger, R.E. and Smith, A.H. (1979) Effects of high-G on ventilation/perfusion in the domestic fowl. The Physiologist 22:S59S60Google ScholarPubMed