Summary
Rapid as well as sustained sperm transport from the cervical canal to the isthmical part of the fallopian tube is provided by cervico-fundal uterine peristaltic contractions that can be visualized by vaginal sonography. The peristaltic contractions increase in frequency and presumably also in intensity as the proliferative phase progresses. As shown by placement of labeled albumin macrospheres of sperm size at the external cervical os and serial hysterosalpingoscintigraphy (HSSG) sperm reach, following their vaginal deposition, the uterine cavity within minutes. In the early follicular phase a large proportion of the macrospheres remains at the site of application, while a smaller proportion enters the uterine cavity with even a smaller one reaching the isthmical part of the tubes. In the mid-follicular phase of the cycle with increased frequency and intensity of the uterine contractions the proportion of macrospheres entering the uterine cavity as well as the tubes has significantly increased. In the late follicular phase with maximum frequency and intensity of uterine peristalsis the proportion of macrospheres entering the tube increases further at the expense of those at the site of application as well as within the uterine cavity. The transport of the macrospheres into the tube is preferentially directed into the tube ipsilateral to the dominant follicle, which becomes apparent in the mid-follicular phase as soon as a dominant follicle can be identified by ultrasound. Since the macrosphere are inert particles the directed sperm transport into the tube ipsilateral to the dominant follicle is not functionally related to a mechanism such as chemotaxis but is rather provided by uterine contraction of which the direction may be controlled by a specific myometrial architecture in combination with an asymmetric distribution of myometrial oestradiol receptors.
Women with infertility and mostly mild endometriosis display on VSUP a uterine hyperperistalsis with nearly double the frequency of contractions during the early and mid- as well as midluteal phase in comparison to the fertile and healthy controls. During midcycle these women display a considerable uterine dysperistalsis in that the normally long and regular cervico-fundal contractions during this phase of the cycle have become more or less undirected and convulsive in character. Hyperperistalsis results in the transport of inert particles from the cervix into the tubes within minutes already during the early follicular phase, and may therefore constitute the mechanical cause for the development of endometriosis in that it transports detached endometrial cells and tissue fragments via the tubes into the peritoneal cavity. Moreover, dysperistalsis may contribute to the infertility in these patients since it results in a break down of sperm transport within the female genital tract.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
References
Abramovicz JS & Archer DF 1990 Uterine endometrial peristalsis–a transvaginal ultrasound study. Fertility and Sterility 54: 451–454
Adamson GD & Pasta DJ 1994 Surgical treatment of endometriosis-associated infertility: Meta analysis compared with survival analysis. American Journal of Obstetrics and Gynecology 171: 1488–1505
Amso NN, Crow J & Shaw RW 1994a Comparative immunohistochemical study of oestrogen and progesterone receptors in the fallopian tube and uterus at different stages of the menstrual cycle and the menopause. Human Reproduction 9: 1027–1037
Amso NN, Crow J, Lewin J & Shaw RW 1994b A comparative morphological and ultrastructural study of endometrial gland and fallopian tube epithelia at different stages of the menstrual cycle and the menopause. Human Reproduction 9: 2234–2241
Becker W, Steck T. Alber P & Borne W 1988 Hystero-salpingo-scinitraphy: A simple and accurate method of evulating fallopian tube patency. Nuklearmedizin 27: 252–257
Birnholz J. (1984) Ultrasonoc visualization of endometrial movements. Fertility and Sterility 41: 157–158
Cibils L.A. (1967) Contractility of the non-pregnant human uterus. Obstetrics and Gynecology. 30: 441–461
Crow J, Amso NN, Lewin J & Shaw RW 1994 Morphology and ultrastructure of fallopian tube epithelium at dif-ferent stages of the menstrual cycle and the menopause. Human Reproduction 9: 2224–2233
De Vries K, Lyons EA, Ballard G, Levi CS & Lindsay DJ 1990 Contractions of the inner third of the myometrium. Amercan Joumal of Obstetrics and Gynecology 162: 679–682
Drobnis EZ & Overstreet JW 1992 Natural history of mammalian spermatozoa in the female reproductive tract. Oxford Review of Reproductive Biology 14: 1–46
Einer-Jensen N 1988. Countercurrent transfer in the ovarian pedicle and it’s physiological implications. Oxford Reviews of Reproductive Biology 10: 348–381
Eliasson R & Posse N 1960 The effect of prostaglandins on the nonpregnant uterus in vivo. Acta Obstetrica et Gynecologica Scandinavica 39: 112–117
Fuchs A-R, Fuchs F & Soloff M.S 1985 Oxytocin receptors in nonpregnant human uterus. Journal of clinical Endocrinology and Metabolism 60: 37–41
Fukuda M & Fukuda K 1994 Uterine endometrial cavity movement and cervical mucus. Human Reproduction 9: 1013–1016
Goerttler K 1930 Die Architektur der Muskelwand des menschlichen Uterus und ihre funktionelle Bedeutung. Gegenbaurs Morphologisches Jahrbuch 65: 45–52
Harper MJK 1994 Gamete and zygote transport. p123–187 In The physiology of reproduction. Eds Knobil E. & Neill, JD Raven Press, New York
Hartman CG 1962 Science and the safe period. A compendium of human reproduction. Williams and Wilkins, Baltimore
Hein PR, Eskes TKAB, Stolte LAM, Braaksma JF, Jansens J & Hoek JM 1973 The influence of steroids on uterine motility in the nonpregnant human uterus. p107–140 In Uterine contractions - side effects of steroidal contraceptives. Ed Josimovich, J.B. New York: Wiley and Sons
Hendricks CН 1966 Inherent motility patterns and response characteristics in the nonpregnant uterus. Amercan Journal of Obstetrics and Gynecology 96: 824–841
Hull ME, Moghissi KS, Magyar DF, & Hayes MF 1986 Comparison of different treatment modalities of endometriosis in infertile women. Fertility and Sterility 47: 40–44
Hunter RHF 1987 Human fertilization in vivo with special reference to progression, storage and release of competent spermatozoa. Human Reproduction 2: 329–332
Iturralde M & Venter PP 1981 Hysterosalpingo-radionuclide scintigraphy. Seminars in Nuclear Medicine 11: 301–314
Jansen RPS 1980 Cyclic changes in the human fallopian tube isthmus and their functional importance. American Journal of Obstetrics and Gynecology 136: 292–308
Karim SMM & Hillier K 1973 The role of prostaglandins in myometrial contraction. p141–169 In Uterine contrac-tion - side effects of steroidal contraceptives. Ed Josimovich JB New York: Wiley and Sons
Kunz G & Leyendecker G 1996 Uterine peristalsis throughout the menstrual cycle. Physiological and pathophysi-ological aspects. Human Reproduction update (in press)
Kunz G, Beil D, Deininger H, Wildt L & Leyendecker G 1996a The dynamics of rapid sperm transport through the female genital tract. Evidence from vaginal sonography of uterine peristalsis and hysterosalpingoscintigraphy Human Reproduction 11: 627–632
Kunz G. Mall G & Leyendecker G 1996b Asymmetry of oestrogen receptor expression in the myometrium relative to the site of the dominant follicle and corpus luteum during the menstrual cycle in healthy women. Human Reproduction II: Abstract book 1, p 158
Leyendecker G, Kunz G, Wildt L, Beil D & Deiniger H 1996 Uterine hyperperistalsis and dysperistalsis as dysfunctions of the mechanism of rapid sperm transport in patients with endometriosis and infertility. Human Reproduction, 11: 1542–1551
Lefebvre DL, Farookhi R, Larcher A, Neculcea J & Zingg HH 1994a Uterine oxytocin gene expression. I. Induction during pseudopregnancy and the estrous cycle. Endocrinology 134: 2556–2561
Lefebvre DL, Farookhi R, Giaid A, Neculcea J & Zingg HH 1994b Uterine oxytocin gene expression. II. Induction by exogenous steroid administration. Endocrinology 134: 2562–2566
Lyons EA, Taylor PJ, Zheng, XH, Ballard G, Levi CS & Kredentser JV 1991 Characterization of subendometrial myometrial contractions throughout the menstrual cycle in normal fertile women. Fertility and Sterility 55: 771–775
Martinez-Gaudio M. Yoshida T & Bentsson LP 1973 Propagated and non propgated myometrial contractions in normal menstrual cycles. American Journal of Obstetrics and Gynecology 115: 107–111
Moghissi KS 1977 Sperm migration through the human cervix. In The uterine cervix in reproduction p146–165. Eds Insler V & Bettendorf G. Georg Thieme Publishers Stuttgart
Mortimer D 1983 Sperm transport in the human female reproductive tract. Oxford Reviews of Reproductive Biology 5: 40–61
Oike K, Obata S, Tagaki K, Matsuo K, Ishihara K & Kikuchi S 1988 Observation of endometrial movement with transvaginal sonography. Journal of Ultrasound in Medicine 7: 99
Romanini C 1994 Measurement of uterine contractions. P337–355 In The uterus. Eds Chard.J & Grudzinskas JG Cambridge Reviews in Reproduction, Cambridge University Press
Williams M, Hill C.J, Scudamore I, Dunphy B, Cooke ID & Barratt CLR 1993 Sperm numbers and distribution within the human fallopian tube around ovulation. Human Reproduction 8: 2019–2026
Wilcox AJ, Weinberg CR & Baird DD 1995 Timing of sexual intercourse in relation to ovulation–effects on the probability of conception, survival of the pregnancy, and sex of the baby. New England Journal of Medicine 333: 1517–1521
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 1997 Springer Science+Business Media New York
About this chapter
Cite this chapter
Kunz, G., Beil, D., Deiniger, Н., Einspanier, A., Mall, G., Leyendecker, G. (1997). The Uterine Peristaltic Pump. In: Ivell, R., Holstein, AF. (eds) The Fate of the Male Germ Cell. Advances in Experimental Medicine and Biology, vol 424. Springer, Boston, MA. https://doi.org/10.1007/978-1-4615-5913-9_49
Download citation
DOI: https://doi.org/10.1007/978-1-4615-5913-9_49
Publisher Name: Springer, Boston, MA
Print ISBN: 978-1-4613-7711-5
Online ISBN: 978-1-4615-5913-9
eBook Packages: Springer Book Archive