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1990 | 41 | 1-3 |

Tytuł artykułu

Hypophysial portal blood flow during preganglionic stimulation of the superior cervical ganglion under condition of systemic arterial blood pressure stabilization in rat

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
Lipińska S., Szkudlarek U., Traczyk W. Z.: Hypophysial portal blood flow during preganglionic stimulation of the superior cervical ganglion under condition of systemic arterial blood pressure stabilization in rat. Acta Physiol. Pol. 1990, 41(1-3): 53-61. The presence of hypothalamic hormones in the pituitary portal blood is regarded as the principal factor by which the hypothalamus controls pituitary secretion. In contrast to numerous investigations on hypothalamic hormone release, the regulation of the hypophysial-portal blood flow (HPBF) has been scarcely studied. Hypophysial-portal vessels were exposed according to the Worthington’s method [1966]. The 10-min blood samples were collected before and during unilateral or alternative bilateral electrical stimulation of the preganglionic fibers of the superior cervical ganglia (SCG). During blood samples collection the stable systemic arterial blood pressure was maintained by a barostat. The HPBF was estimated according to the determination of the hemoglobin in samples of washed and collected blood from the cut pituitary portal vessels. The mean HPBF was 3.5 μ /min. Electrical stimulation of SCG. did not change HPBF. This indicates that sympathetic efferents do not participate in the regulation of HPBF under conditions of stabilization of the systemic arterial blood pressure.

Wydawca

-

Rocznik

Tom

41

Numer

1-3

Opis fizyczny

p.53-62,fig.,ref.

Twórcy

autor
  • Department of Physiology, Institute of Physiology and Biochemistry, Medical University, Lodz, Poland
  • Department of Physiology, Institute of Physiology and Biochemistry, Medical University, Lodz, Poland
autor
  • Department of Physiology, Institute of Physiology and Biochemistry, Medical University, Lodz, Poland

Bibliografia

  • 1. Alper R. H., Demarest K. T, Moore K. E. (1980). Effect of surgical sympathectomy on catecholamine concentration in the posterior pituitary of the rat. Experientia, 36, 134-135.
  • 2. Ariano M. A., Kenny S. L. (1985). Peptide coincidence in rat superior cervical ganglion. Brain Res., 340, 181-185.
  • 3. Blask D. E., Reiter R. J., Johanson L. Y. (1977). Pineal-induced alternations in reproductive function and pituitary prolactin in the female rat: The effect of bilateral superior cervical ganglionectomy and nervi conarii transection. J. of Neuroscience Res., 127-133.
  • 4. Björklund A., Moore R. Y., Nobin A., Stenevi A. (1973). The organization of tubero-hypophysial and reticulo-infundibular catecholamine neuron systems in the rat brain. Brain Res., 51, 171-191.
  • 5. Cardinali D. P., Faigon M. R., Scacchi P., Moguilevsky J. (1979). Failure of melatonin to increase plasma prolactin levels in ovariectomized rats subjected to superior cervical ganglionectomy or pinealectomy. J. Endocrinol., 82, 315-319.
  • 6. Cardinali D. P., Vacas M. I., Gejman P. V., Pisarev M. A., Barontini M., Boado R. J., Juvenal G. J. (1983). The sympathetic superior cervical ganglia as “Little neuroendocrine brains”. Acta Physiol. Latinoam., 33, 205-221.
  • 7. Cardinali D. P., Ladizesky M. G. (1985). Changes in parathyroid hormone and calcium levels after superior cervical ganglionectomy of rats. Neuroendocrinology, 40, 291-296.
  • 8. Edwinson L., Owman C., West K. A. (1971). Changes in cerebral blood volume of mice at various time-periods after superior cervical sympathectomy. Acta Physiol. Scand., 82, 521-526.
  • 9. Edwinson L., Jansen I., McCulloch J., Uddman R. (1987). Tachykinins and the cerebrovascular bed. In: Peptidergic Mechanisms in the Cerebral Circulation. Eds. Edwinson L., McCulloch J., VCH, p. 117-131.
  • 10. Fendler K., Endroczi E., Lissak K. (1965). The effect of cervical sympathectomy on posterior pituitary oxytocic activity in rats under chronic stress. Acta Physiol. Hung., 27, 275-278.
  • 11. Fendler K., Vermes I., Stark A., Lissak K. (1972). Effect of cervical sympathectomy on water balance in pituitary stalk-sectioned rats. Acta Physiol. Hung., 42, 61-65.
  • 12. Findell P. R., Mulchahey J. J., Shepard J. M., Gropper M. A., Battacharya J., Weiner R. I. (1987). Direct Measurement of blood pressure within the long hypophysial portal blood vessels. Neuroendocrinology, 45, 263-266.
  • 13. Gejman P. V., Cardinali D. P., Finkielman S., Nahmod V. E. (1981). Changes in drinking behavior caused by superior cervical ganglionectomy and pinealectomy in rats. J. Auton. Nerv. System, 4, 249-259.
  • 14. Goldman H. (1963). Effect of acute stress on the pituitary gland. Endocrine gland blood flow. Endocrinology, 72, 588-591.
  • 15. Green H. D., Gregg D. E. (1940). The Relationship Between Differential Pressure and Blood Flow in a Coronary Artery. Am. J. Physiol., 130, 97-107.
  • 16. Haefely W., Hürliman A., Thoenen H. (1965). Relation between the rate of stimulation and the quantity of noradrenaline liberated from sympathetic nerve endings in isolated perfused spleen of the cat. J. Physiol., 181, 48-54.
  • 17. Harris G. W. (1947). The blood vessels of the rabbits pituitary gland and the significance of the pars and zona tuberalis. J. Anat. (London), 81, 343-351.
  • 18. Karasek M., Lipińska S., Pawlikowski M. (1980a). Quantitative changes of the Golgi Profilles and densecore vesicles in the rat superior cervical ganglion cells after preganglionic stimulation. Acta Med. Pol., 21, 4-5.
  • 19. Karasek M., Traczyk W. Z., Orłowska-Majdak M., Rubacha G. (1980b). Quantitative changes of the neurosecretory granules in the rat neurohypophysis after preganglionic stimulation of the superior cervical ganglion. Acta Med. Pol., 21, 4. 351- 352.
  • 20. Kelly P. A. T. (1987). Vasoactive intestinal polypeptide: functional significance in cerebral organization and in the control of cerebral blood flow. In: Peptidergic Mechanisms in the Cerebral Circulation. Eds. Edwinson L., McCulloch J.. VCH, p. 100-116.
  • 21. Lee T. J. F. (1987). Evidence for against VIP as a transmitter for vasodilation in cerebral blood vessels. In: Peptidergic Mechanisms in the Cerebral Circulation. Eds. Edwinson L., McCulloch J., VCH, p. 64-73.
  • 22. Lederis K. (1967). Acetylocholine in the mammalian neurohypophysis. J. Endocrinol., 37, XXIV-XXV.
  • 23. Lederis K. (1974). Neurosecretion and the functional structure of the neurohypophysis. In: Handbook of Physiology. Endocrinology. The Pituitary Gland and Its Neuroendocrine Control. Washington. DC: Am. Physiol., Soc., sect. 7, vol. IV, p. 81-102.
  • 24. Lipińska S., Rubacha G., Traczyk W. Z. (1979). Influence of sympathetic efferents on vasopressin and oxytocin release from neurohypophysis. Proceedings of the Symposium “Peptides and brain function”. Łódź, Ann. Acad. Med. Lodz., 22, supl. 21, 93 - 99.
  • 25. Lipińska S., Orłowska-Majdak M., Rubacha G., Traczyk W. 2. (1982). Oxytocin release from neurophysis, evoked by preganglionic stimulation of rat superior cervical ganglion. Endocrinology, 79, 385-392.
  • 26. McLachlan E. M. (1975). An analysis of the release of acetylocholinę from preganglionic nerve terminals. J. Physiol., 245, 447-466.
  • 27. Nikitovich-Winer M. B., Goldman H. (1986). Effect of hypothalamic deafferentiation on hypophysial and other endocrine gland blood flows. Endocrinology, 118, 1166-1170.
  • 28. Page В. B. (1982). Pituitary blood flow. Am. J. Physiol., 243, E427-E442.
  • 29. Popa G., Fielding U. (1930). A portal circulation from the pituitary to the hypothalamic region. J. Anat., 65, 88-91.
  • 30. Popa G., Fielding U. (1933). Hypophysial portal vessels and their colloid accompaniment. J. Anat., 67, 227-232.
  • 31. Porter J. C., Hines M. F. M., Smith K. R., Smith A. J. K. (1967). Quantitive evaluation of local blood flow of the adenohypophysis in rats. Endocrinology, 80, 583-598.
  • 32. Reiter R. J. (1980). The pineal and its hormones in the control of reproduction. Endocrine Rev., 1, 109-131.
  • 33. Saavedra J. M. (1985). Central and peripheral catecholamine inervation of the rat intermediate and posterior pituitary lobes. Neuroendocrinology, 40, 281-284.
  • 34. Szentagothai J., Flerko B., Mess B., Halasz B. (1968). Hypothalamic control of the anterior pituitary. Akademiai Kiado, Budapest.
  • 35. Szkudlarek U. (1986). Mechanism of hypoxia-induced increase of pituitary blood flow in rats. Proceedings of the XXX International Union of Physiological Sciences, Vancouver, Canada. July, 13-18, P 118.01.
  • 36. Szkudlarek U., Lipińska S., Traczyk W. Z. (1990). Tachykinins and control of hypophysial portal blood flow. Acta Physiol. Pol. 41, supplement 34 (1), 231—232.
  • 37. Tour U. I., Kelly P. A. T., Edwinson L., McCulloch J. (1987). Neuropeptide Y: importance in the cerebral circulation. In: Mechanisms in the Cerebral Circulation. Eds. Edwinson L., McCulloch J., VCH, p. 75-99.
  • 38. Traczyk W. Z., Szkudlarek U. (1986). Effects of prostaglandins on pituitary portal blood flow. 1st International Congress of Neuroendocrinology, San Francisco, California, Program and Abstracts, July 9-11, P 262.
  • 39. Uddman R. (1987). Peptidergic innervation of the cerebrovascular bed. In: Mechanisms in the Cerebral Circulation. Eds. Edwinson J., McCulloch J., VCH, p. 15-33.
  • 40. Wislocki G. B., King L. S. (1936). The permeability of the hypophysis and hypothalamus to vital dyes, with a study of the hypophyseal vascular supply. Am. J. Anat., 58, 421-472.
  • 41. Wiggers C. J., Cotton F. S. (1933a). Studies on the Coronary Circulation. I. The Coronary Pressure Pulses and Their Interpretation. Am. J. Physiol., 106, 9-15.
  • 42. Wiggers C. J., Cotton F. S. (1933b) Studies on the Coronary Circulation. II. The Systolic and Diastolic Flow Through the Coronary Vessels. Am. J. Physiol., 106, 597-610.
  • 43. Worthington W. C. jun. (1966). Blood samples from the pituitary stalk of the rat: method of collection and factors determining volume. Nature, 210, 710-712.

Typ dokumentu

Bibliografia

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