Summary
As has been previously shown young newborn guinea pigs do not shiver on cold exposure although oxygen consumption is considerably increased, i.e. chemical thermogenesis (non-shivering thermogenesis) is the prevailing mechanism of heat production. In the course of the first weeks of life non-shivering thermogenesis is gradually replaced by shivering thermogenesis. In the present study it has been shown that the cold-induced oxygen uptake can be reduced in guinea pigs, 0 to 2 days of age, from 69 to 38 ml/kg min by Alderlin, an adrenergic β-receptor blocking agent. This effect was accompanied by an onset of shivering demonstrating that the shivering mechanism is already developed at the time of birth but is not set in function under normal conditions. Similar results have been obtained using Hexamethonium-Bromide and Dichloroisoproterenol. The elicitation of shivering following the administration of the drugs prevents the oxygen uptake from being reduced to the basal level (ca. 20 ml/kg min). When shivering was already present as in older animals (2 to 3 weeks of age) it remained uninfluenced by Alderlin (as veryfied by electromyography); the agent was thus considered suitable to block selectively chemical thermogenesis. On this basis, it was estimated from further data that the contribution of nonshivering thermogenesis to the total heat production is reduced from 91 to 26% within the first three weeks of life. Moreover, it could be shown that the shivering mechanism is less effective than chemical thermogenesis.
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Literatur
Baum, H., H. A. El-Khanagry, and R. E. Moore: Catecholaminestimulated thermogenesis: Some factors influencing the pattern of respiration of isolated kitten diaphragms. J. Physiol. (Lond.) 169, 237 (1963)
Black, J. W., and J. S. Stephenson: Pharmacology of a new adrenergic betareceptor blocking compound (Nethalide). Lancet 1962 II, 311.
Brück, K.: Temperature regulation in the newborn infant. Biol. Neonat. (Basel) 3, 65 (1961
——, u. B. Wünnenberg: Untersuchungen über die Modi der Thermogenese beim neugeborenen Meerschweinchen. Pflügers Arch. ges. Physiol. 282, 362 (1965).
Davis, T. R. A.: Nonshivering thermogenesis. Fed. Proc. 22, 777 (1963).
Dawes, G. S., and G. Mestyan: Changes in the oxygen consumption of newborn guinea-pigs and rabbits on exposure to cold. J. Physiol. (Lond.) 168, 22 (1963).
Dole, V. P.: A relation between non-esterified fatty acids in plasma and the metabolism of glucose. J. clin. Invest. 35, 150 (1956).
Dornhorst, A. C., and B. F. Robinson: Clinical Pharmacology of a β-adrenergicblocking agent (Nethalide). Lancet 1962 II, 314.
Freund, H., u. S. Jansen: Über den Sauerstoffverbrauch der Skeletmuskulatur und seine Abhängigkeit von der Wärmeregulation. Pflügers Arch. ges. Physiol. 200, 96 (1923)
Hallwachs, O., H. Hupfer u. R. Thauer: Die Bedeutung der tiefen Körpertemperatur für die Auslösung der chemischen Temperaturregulation. I. Kältezittern durch Senkung der tiefen Körpertemperatur bei konstanter, erhöhter Hauttemperatur. Pflügers Arch. ges. Physiol. 274, 97 (1961).
Hannon, J. P., and A. M. Larson: Fatty acid metabolism during norepinephrine thermogenesis in the cold-acclimatized rat. Amer. J. Physiol. 203, 1055 (1962).
Hsieh, A. C. L., L. D. Carlson, and G. Gray: Role of the sympathetic nervous system in the control of chemical regulation of heat production. Amer. J. Physiol. 190, 247 (1957).
Jansky, L., and J. S. Hart: Participation of sceletal muscle and kidney during non-shivering thermogenesis in cold-acclimated rats. Canad. J. Biochem. 41, 953 (1963)
Karlberg, P., R. E. Moore, and T. K. Oliver jr.: The thermogenic response of the newborn infant to Noradrenaline. Acta paediat. (Uppsala) 51, 284 (1962).
Moore, R. E., and M. C. Underwood: Hexamethonium, hypoxia and heat production in newborn and infant kittens and puppies. J. Physiol. (Lond.) 161, 30 (1962)
—— —— The thermogenic effects of noradrenaline in newborn and infant kittens and other small mammals. A possible hormonal mechanism in the control of heat production. J. Physiol. (Lond.) 168, 290 (1963).
Pilkington, T. R. E., R. D. Lowe, B. F. Robinson, and E. Titterington: Effect of adrenergic blockade on glucose and fatty acid mobilisation in man. Lancet 1962 II, 316.
Rautenberg, W., E. Simon u. R. Thauer: Die Bedeutung der Kerntemperatur für die chemische Temperaturregulation beim Hund in leichter Narkose. I. Isolierte Senkung der Rumpfkerntemperatur. Pflügers Arch. ges. Physiol. 278, 337 (1963).
Schotz, M. C., and I. H. Page: Effect of norepinephrine and epinephrine on nonesterified fatty acid concentration in plasma. Proc. Soc. exp. Biol. (N. Y.) 101, 624 (1959).
Scopes, J. W., and J. P. M. Tizard: The effect of intravenous noradrenaline on the oxygen consumption of newborn mammals. J. Physiol. (Lond.) 165, 305 (1963).
Smith, R. F., and D. J. Hoijer: Metabolism and cellular function in cold acclimation. Physiol. Rev. 42, 60 (1962)
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Brück, K., Wünnenberg, B. Blockade der chemischen Thermogenese und Auslösung von Muskelzittern durch Adrenolytica und Ganglienblockade beim neugeborenen Meerschweinchen. Pflügers Arch. 282, 376–389 (1965). https://doi.org/10.1007/BF00412511
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DOI: https://doi.org/10.1007/BF00412511