Artículos de revistas
Time Of Day, Environment Luminosity And Physical Exercise Effects On Inflammatory And Performance Parameters Of Swimming Rats [efeitos Do Horário Do Dia, Luminosidade Ambiental E Exercício Físico Sobre Parâmetros Inflamatórios E De Performance Em Ratos Nadadores]
Registro en:
Revista Da Educacao Fisica. Universidade Estadual De Maringa, v. 26, n. 1, p. 97 - 106, 2015.
1033948
10.4025/reveducfis.v26i1.23186
2-s2.0-84939180967
Institución
Resumen
Animal models are quite used for inferences to Human beings regarding many physiological mechanisms, however, current experiments have been neglected adequate control on environment and chronobiological interferences. The aim of this study was to analyze inflammatory responses owing physical exercise kept until exhaustion at aerobic/anaerobic transition intensity in different times of day and environmental luminosities. Wistar Rats were submitted to a two environmental luminosities during night period: standard luminosity (SL; total darkness) or experimental luminosity (EL; >600nm; <15lux). Animals were submitted to the lactate minimum test and then submitted to an exhaustive exercise at such intensity (TE). Overall experimental procedures were performed at 12:00h or 20:00h. TE were not influenced by time of day or environmental luminosity, nevertheless, were found reduced scores to inflammatory markers to rats assessed under SL at 20:00hs, showing the importance of such control in experiments involving nocturnal animals. 26 1 97 106 Aguilera, G., Regulation of pituitary ACTH secretion during chronic stress (1994) Frontiers in Neuroendocrinology Philadelphia, 15 (4), pp. 321-350 Axelrod, J., Reisine, T.D., Stress hormones: Their interaction and regulation (1984) Science Washington D.C, 224 (4648), pp. 452-459 Beck, W.R., De Araujo, G.G., Gobatto, C.A., Methods of exercise intensity and lactataemia determination of lactate minimum test in rats (2012) Comparative Exercise Physiology Wageningen, 8 (2), pp. 113-116 Bjorvatn, B., The association between sleep duration, body mass index and metabolic measures in the Hordaland Health Study (2007) Journal of Sleep Research, Malden, 16 (1), pp. 66-76 Black, S., Kushner, I., Samols, D., C: Reactive protein (2004) Journal of Biological Chemistry, Rockville, 279 (47), pp. 48487-48490 Chaput, J.P., Sleep duration as a risk factor for the development of type 2 diabetes or impaired glucose tolerance: Analyses of the Quebec Family Study (2009) Sleep Medicine Philadelphia, 10 (8), pp. 919-924 Clough, G., Environmental effects on animals used in biomedical research (1982) Biological Reviews of the Cambridge Philosophical Society Cambridge, 57, pp. 487-523 Coop, S.W., Critical speed in the rat: Implications for hindlimb muscle blood flow distribution and fibre recruitment (2010) Journal of Physiology, Oxford, 588, pp. 5077-5087 Engel, P.C., Jones, J.B., Causes and elimination of erratic blanks in enzymatic metabolic assays involving the use of NAD in alkaline hydrazine buffers: Improved conditions for the assay of L-glutamate, L-lactate, and other metabolites (1978) Analytical Biochemistry, Philadelphia, 88 (2), pp. 475-484 Everson, C.A., Functional consequences of sustained sleep deprivation in the rat (1995) Behavioral Brain Research, Philadelphia, 69 (1-2), pp. 43-54 Everson, C., Bergmann, B.M., Rechtschaffen, A., Sleep deprivation in the rat: III. Total sleep deprivation (1989) Sleep Darien, 12 (1), pp. 13-21 Gabay, C., Kushner, I., Acute-phase proteins and other systemic responses to inflammation (1999) The New England Journal of Medicine, Waltham, 340 (6), pp. 448-454 Gabriel, H., Differential mobilization of leukocyte and lymphocyte subpopulations into the circulation during endurance exercise (1992) European Journal of Applied Physiology and Occupational Physiology, Berlin, 65 (6), pp. 529-534 Gleeson, M., The anti-inflammatory effects of exercise: Mechanisms and implications for the prevention and treatment of disease (2011) Nature Reviews Immunology London, 11, pp. 607-615 Gleeson, M., Short-term changes in the blood leukocyte and pletelet count following different durations of high-intensity treadmill running (1995) Journal of Sports Sciences, London, 13 (2), pp. 115-123 Ham, W.T., Jr., Mueller, H.A., Sliney, D.H., Retinal sensitivity to damage from short wavelength light (1976) Nature, London, 260 (5547), pp. 153-155 Hopkins, W.G., Measures of reliability in sports medicine and science (2000) Sports Medicine New York, 30 (1), pp. 1-15 Ikeda, M., Sagara, M., Inoué, S., Continuous exposure to dim illumination uncouples temporal patterns of sleep, body temperature, locomotion and drinking behavior in the rat (2000) Neuroscience Letters, Philadelphia, 279 (3), pp. 185-189 Ilnerová, H., Effect of one minute exposure to light at night on rat pineal serotonin N-acetyltransferase and melatonin (1979) Journal of Neurochemistry, Malden, 32 (2), pp. 673-675 Jacobs, G.H., Fenwick, J.A., Williams, G.A., Cone-based vision of rats for ultraviolet and visible lights (2001) Journal of Experimental Biology, Cambridge, 204, pp. 2439-2446 Kendall, A., Exercise and blood lymphocyte subset resposes: Intensity, duration and subject fitness effects (1990) Journal of Applied Physiology, Bethesda, 69 (1), pp. 251-260 Kolataj, A., Rysinska, J., Flak, P., The influence of selection on reaction to stress in mice (1992) Journal of Animal Breeding and Genetics, Malden, 109 (2), pp. 144-148 Könczöl, K., Nesfatin-1 exerts long-term effect on food intake and body Temperature (2012) International Journal of Obesity, London, 36 (12), pp. 1514-1521 Madjid, M., Leukocyte count and coronary heart disease (2004) Journal of the American College of Cardiology, Washington, D.C, 44 (10), pp. 1945-1956 McARDLE, W.D., Montoye, H.J., Reliability of exhaustive swimming in the laboratory rat (1966) Journal of Applied Physiology, Bethesda, 21 (4), pp. 1431-1434 Nieman, D.C., Nehlsen-Cannarella, S.L., The immune response to exercise (1994) Seminars in Hematology New York, 31 (2), pp. 166-179 Nieman, D.C., Pedersen, B.K., Exercise and immune function. Recent developments (1999) Sports Medicine, New York, 27 (2), pp. 73-80 Oliveira, A.C., Sleep deprivation reduces total plasma homocysteine levels in rats (2002) Canadian Journal of Physiology and Pharmacology, Ottawa, 80 (3), pp. 193-197 Pedersen, B.K., Bruunsgaard, H., Klokker, M., Exercise-induced immunomodulation: Possible roles of neuroendocrine factors and metabolic factors (1997) International Journal of Sports Medicine, Kempten, 18 (1), pp. S2-7 Petersen, A.M., Pedersen, B.K., The anti-inflammatory effect of exercise (2005) Journal of Applied Physiology, Bethesda, 98 (4), pp. 1154-1162 Pittendrigh, C.S., Daan, S.A.A., Functional analysis of circadian pacemakers in nocturnal rodents. IV. Entrainment: Pacemaker as clock (1976) Journal of Comparative Physiology, New York, 106 (3), pp. 291-331 Seelaender, M.C., Kazantzis, M., Costa Rosa, L.F.B.P., The effect of adrenaline and Walker-256 tumour-induced cachexia upon Kupffer cell metabolism (1999) Cell Biochemistry and Function, Malden, 17 (3), pp. 151-156 Semple-Rowland, S.L., Dawson, W.W., Retinal cyclic light damage threshold for albino rats (1987) Laboratory Animal Science Illinois, 37 (3), pp. 289-298 Strasner, A., Effects of exercise intensity on natural killer cell activity in women (1997) International Journal of Sports Medicine, Kempten, 18 (1), pp. 56-61 Sun, J.H., Reduction in pineal N-acetyltransferase activity and pineal and serum melatonin levels in rats after their exposure to red light at night (1993) Neuroscience Letters Philadelphia, 149 (1), pp. 56-58 Tanaka, H., Circadian variation of thermoregulatory responses during exercise in rats (1990) American Journal of Physiology: Regulatory, Integrative, and Comparative Physiology, Bethesda, 258 (4), pp. 836-841 Tegtbur, U., Busse, M.W., Braumann, K.M., Estimation of an individual equilibrium between lactate production and catabolism during exercise (1993) Medicine and Science in Sports and Exercise,Hagerstown, 25 (5), pp. 620-627 Voltarelli, F., Gobatto, C.A., Mello, M.A.R., Determination of metabolic transition by lactate minimum test in malnourished rats during swimming exercise (2007) Revista da Educação Física Maringá, 18 (1), pp. 33-39 Voltarelli, F., Mello, M.A.R., Gobatto, C.A., Muscle glycogen and anaerobic threshold for swimmin rats (2004) Motriz, Rio Claro, 10 (1), pp. 25-30 Wielgus, A.R.E., Blue light induced A2E oxidation in rat eyes-experimental animal model of dry AMD (2010) Photochemical and Photobiology Sciences Cambridge, 9 (11), pp. 1505-1512