- Код статьи
- 10.31857/S0041377124030076-1
- DOI
- 10.31857/S0041377124030076
- Тип публикации
- Статья
- Статус публикации
- Опубликовано
- Авторы
- Том/ Выпуск
- Том 66 / Номер выпуска 3
- Страницы
- 268-273
- Аннотация
- Несмотря на то, что в программах экстракорпорального оплодотворения обычно используют зрелые ооциты, находящиеся на стадии метафазы II мейоза, возможно использование диплотенных ооцитов на стадии зародышевого пузырька (germinal vesicle, GV) после их созревания in vitro (in vitro maturation, IVM). Морфологическая характеристика нативных GV-ооцитов перспективна с точки зрения выявления предикторов для прогнозирования их способности к самопроизвольному созреванию в стимулированных циклах. Целью работы являлся анализ паттернов грануляции цитоплазмы GV-ооцитов, различающихся по способности к возобновлению и завершению мейотического созревания in vitro. Показано, что центральный паттерн грануляции негативно коррелирует со способностью GV-ооцитов к спонтанному созреванию in vitro.
- Ключевые слова
- ооциты человека ядро ооцита зародышевый пузырек цитоплазматическая грануляция созревание ооцитов
- Дата публикации
- 15.05.2024
- Год выхода
- 2024
- Всего подписок
- 0
- Всего просмотров
- 38
Библиография
- 1. Das M., Son W. Y., Buckett W., Tulandi T., Holzer H. 2014. In vitro maturation versus IVF with GnRH antagonist for women with polycystic ovary syndrome: treatment outcome and rates of ovarian hyperstimulation syndrome. Reprod. Biomed Online. V. 29. P. 545.
- 2. Escrich L., Galiana Y., Grau N., Insua F., Soler N., Pellicer A., Escribá M. 2018. Do immature and mature sibling oocytes recovered from stimulated cycles have the same reproductive potential? Reprod. Biomed. Online. V. 37. P. 667.
- 3. Escrich L., Grau N., Mercader A., Rubio C., Pellicer A., Escribá M. 2011. Spontaneous in vitro maturation and artificial activation of human germinal vesicle oocytes recovered from stimulated cycles. J. Assist. Reprod. Genet. V. 28. P. 111.
- 4. Gremeau A. S., Andreadis N., Fatum M., Craig J., Turner K., Mcveigh E., Child T. 2012. In vitro maturation or in vitro fertilization for women with polycystic ovaries? A case — control study of 194 treatment cycles. Fertil. Steril. V. 98. P. 355.
- 5. Kahraman S., Yakin K., Dönmez E., Samli H., Bahçe M., Cengiz G. 2000. Relationship between granular cytoplasm of oocytes and pregnancy outcome following intracytoplasmic sperm injection. Hum. Reprod. V. 15. P. 2390.
- 6. Martin-Palomino Olid N., García D., Rodríguez A., Vassena R. 2019. Could fertility clinics offer a sizable improvement of live birth rates by maturing post-GVBD oocytes in vitro? J. Assist. Reprod. Genet. V. 36. P. 1927.
- 7. Merviel P., Cabry R., Chardon K., Haraux E., Scheffler F., Mansouri N. B. 2017. Impact of oocytes with CLCG on ICSI outcomes and their potential relation to pesticide exposure. J. Ovarian Res. V. 10. P. 42.
- 8. Ortega-Hrepich C., Stoop D., Guzma ́n L., Van Landuyt L., Tournaye H., Smitz J., De Vos M. 2013. A ‘freeze-all’ embryo strategy after in vitro maturation: a novel approach in women with polycystic ovary syndrome? Fertil. Steril. V. 100. P. 1002.
- 9. Reader K. L., Stanton J. L., Juengel J. L. 2017. The role of oocyte organelles in determining developmental competence. Biology (Basel). V. 18: 35.
- 10. Rienzi L., Balaban B., Ebner T., Mandelbaum J. 2012. The oocyte. Hum. Reprod. V. 27. No. S1. P. i2.
- 11. Salimov D., Lisovskaya T., Otsuki J., Gzgzyan A., Bogolyubova I., Bogolyubov D. 2023. Chromatin morphology in human germinal vesicle oocytes and their competence to mature in stimulated cycles. Cells. V. 12: 1976.
- 12. Sánchez F., Romero S., De Vos M., Verheyen G., Smitz J. 2015. Human cumulus-enclosed germinal vesicle oocytes from early antral follicles reveal heterogeneous cellular and molecular features associated with in vitro maturation capacity. Hum. Reprod. V. 30. P. 1396.
- 13. Serhal P.F, Ranieri D. M., Kinis A., Marchant S., Davies M., Khadum I. M. 1997. Oocyte morphology predicts outcome of intracytoplasmic sperm injection. Hum. Reprod. V. 12. P. 1267.
- 14. Sun F., Cun J., Huang R., Chen Y., Verwoerd G., Yu Y. 2022. Different occurrence rates of centrally located cytoplasmic granulation in one cohort oocytes show distinctive embryo competence and clinical outcomes. Reprod. Biol. V. 22. P. 100649.
- 15. Takahashi Y., Hashimoto S., Yamochi T., Goto H., Yamanaka M., Amo A., Matsumoto H., Inoue M., Ito K., Nakaoka Y., Suzuki N., Morimoto Y. 2016. Dynamic changes in mitochondrial distribution in human oocytes during meiotic maturation. J. Assist. Reprod. Genet. V. 33. P. 929.
- 16. Van Blerkom J., Runner M. N. 1984. Mitochondrial reorganization during resumption of arrested meiosis in the mouse oocyte. Am. J. Anat. V. 171. P. 335.
- 17. Wang Y., Chen D., Cai B., Huang D., Xu Y., Ding C. 2023. Effects of different oocyte cytoplasmic granulation patterns on embryo development and euploidy: a sibling oocyte control study. Arch. Gynecol. Obstet. V. 308. P. 1593.
- 18. Wilding M., Dale B., Marino M., di Matteo L., Alviggi C., Pisaturo M. L., Lombardi L., de Placido G. 2001. Mitochondrial aggregation patterns and activity in human oocytes and preimplantation embryos. Hum. Reprod. V. 16. P. 909.
- 19. Yi X. F., Xi H. L., Zhang S. L., Yang J. 2019. Relationship between the positions of cytoplasmic granulation and the oocytes developmental potential in human. Sci. Rep. V. 9: 7215.
- 20. Yu Y. Dumollard R. Rossbach A. Lai F. A. Swann K. 2010. Redistribution of mitochondria leads to bursts of ATP production during spontaneous mouse oocyte maturation. J. Cell Physiol. V. 224. P. 672.
- 21. Zhang L., Zeng L., Liu H., Jia H., Wu Y., He C. 2022. Effects of oocyte cytoplasmic central granulation on embryonic development, blastocyst formation, and pregnancy outcome in assisted reproductive technology and its mechanism. Cell Mol. Biol. (Noisy-le-grand). V. 68. P. 161.
