Tytuł artykułuContractile effect of PGF2α and PGE2 on isolated branches of uterine and ovarian artery in different days of estrous cycle and early pregnancy in pigs
Tytuł czasopismaPolish Journal of Veterinary Sciences
Wydział PANNauki Biologiczne i Rolnicze
WydawcaUniversity of Warmia and Mazury in Olsztyn ; Polish Academy of Sciences Committee of Veterinary Sciences
ReferencjeBrenner R. (2004), Steroid receptors in blood vessels of the rhesus macaque endometrium: a review, Arch Histol Cytol, 67, 411. ; Cao J. (2002), In vitro pharmacological characterization of the prostanoid receptor population in the non-pregnant porcine myometrium, Eur J Pharmacol, 442, 115. ; Cao J. (2005), Uterine region-dependent differences in responsiveness to prostaglandins in the non-pregnant porcine myometrium, Prostaglandins Other Lipid Mediat, 75, 105. ; Celia G. (2002), Venoarterial communication as a mechanism for localized signaling in the rat uterine circulation, Am J Obstet Gynecol, 187, 1653. ; Chang K. (2008), Steroid hormones and uterine vascular adaptation to pregnancy, Reprod Sci, 15, 336. ; Chłopek J. (2008), Retrograde and local destination transfer of uterine prostaglandin E<sub>2</sub> during the porcine oestrous cycle, Med Weter, 64, 588. ; Christenson L. (1994), Luteal maintenance during early pregnancy in the pig: role for prostaglandin E<sub>2</sub>, Prostaglandins, 47, 61. ; Fischer H. (1985), Steroid metabolism by endometrial and conceptus tissues during early pregnancy and pseudopregnancy in gilts, J Reprod Fertil, 75, 69. ; Ford S. (1982), Blood flow to the uterine and ovarian vascular beds of gilts during the estrous cycle and early pregnancy, Biol Reprod, 27, 878. ; Guthrie H. (1986), Production of prostaglandin F<sub>2</sub> alpha and estrogen by embryonal membranes and endometrium and metabolism of prostaglandin F<sub>2</sub> alpha by embryonal membranes, endometrium and lung from gilts, Dom Anim Endocrinol, 3, 185. ; Heap R. (1985), Prostaglandin F<sub>2</sub>α is transferred from the uterus to the ovary in the sheep by lymphatic and blood vascular pathways, J Reprod Fertil, 74, 645. ; Heap R. (1989), Neurotransmitters and lymphatic-vascular transfer of prostaglandin F<sub>2</sub>α stimulate ovarian oxytocin output in sheep, J Endocrinol, 122, 147. ; Kotwica J. (1980), Mechanism of prostaglandin F<sub>2</sub>α penetration from the horn of the uterus to the ovaries in pigs, J Reprod Fertil, 59, 237. ; Kiriyama M. (1997), Ligand binding specificities of the eight types and subtypes of the mouse prostanoid receptors expressed in Chinese hamster ovary cells, Br J Pharmacol, 122, 217. ; Krzymowski T. (1986), Counter current transfer of 3H-PGF<sub>2</sub>α in the mesometrium: a possible mechanism for prevention of luteal regression, Anim Reprod Sci, 11, 259. ; Krzymowski T. (1987), Prostaglandin F<sub>2</sub>α back transfer from the mesometrium vasculature into the uterus of the gilt during early pregnancy and estrogen-induced pseudopregnancy, Anim Reprod Sci, 13, 199. ; Maigaard S. (1985), Differences in contractile activation between human myometrium and intramyometrial arteries, Acta Physiol Scand, 124, 371. ; Maigaard S. (1985a), Different responses to prostaglandin F<sub>2</sub> alpha and E<sub>2</sub> in human extra- and intramyometrial arteries, Prostaglandins, 30, 599. ; Pusateri A. (1990), Changes in morphology, cell number, cell size and cellular estrogen content of individual littermate pig conceptuses on days 9 to 13 of gestation, J Anim Sci, 68, 3727. ; Schmitz T. (2006), Localization and steroid regulation of prostaglandin E<sub>2</sub> receptor protein expression in ovine cervix, Reproduction, 131, 743. ; Skipor J. (2007), Luteinising hormone attenuates the vascular response to norepinephrine, Acta Vet Hung, 55, 251. ; Stefańczyk-Krzymowska S. (2005), Local transfer of prostaglandin E<sub>2</sub> into the ovary and its retrograde transfer into the uterus in early pregnant sows, Exp Physiol, 90, 807. ; Stefańczyk-Krzymowska S. (1997), Involvement of adrenoceptors in the ovarian vascular pedicle in the regulation of counter current transfer of steroid hormones to the arterial blood supplying the oviduct and uterus of pigs, Br J Pharmacol, 120, 763. ; Stefańczyk-Krzymowska S. (1990), Local transfer of prostaglandin F<sub>2</sub>α from the uterine lumen into the venous and arterial blood and into the uterine, mesometrial and ovarian tissue on day 18 of pregnancy in the pig, Anim Reprod Sci, 23, 223. ; Stefańczyk-Krzymowska S. (2002), Retrograde transfer of ovarian steroid hormones to the ovary in the porcine periovarian vascular complex, Exp Physiol, 87, 361. ; Stefańczyk-Krzymowska S. (1994), Local increase of steroid hormone concentrations in blood supplying the uterus and oviduct in anaesthetized and conscious gilts, Anim Reprod Sci, 37, 35. ; Stefańczyk-Krzymowska S. (1994a), Total content of prostaglandin F<sub>2</sub>α in the endometrium and myometrium from various sections of the porcine uterine horn during the estrous cycle, Prostaglandins, 48, 99. ; Stefańczyk-Krzymowska S. (2006), Retrograde and local destination transfer of uterine prostaglandin E<sub>2</sub> in early pregnant sow and its physiological consequences, Prostaglandins Other Lipid Mediat, 81, 71. ; Wąsowska B. (2006), Retrograde transfer of testosterone to the porcine ovary in follicular and luteal phase of the estrous cycle, Reprod Biol, 6, 149. ; White R. (2002), Estrogen and vascular function, Vascul Pharmacol, 38, 73.