Effect of Exposure to Follicular Fluid in Endometrioma Patients on the Presence of Polar Body I, Distribution Pattern and Intensity of Mitochondria Oocyte Fluorescence

Tjokorda Gede Ngurah Chandragiram; Made Suyasa Jaya; Jacqueline Sudiman; Ida Bagus Putra Adnyana; Alit Darma Asmara; Putu Pradnya Paramitha Dewi; Agustinus Darmawan

doi:10.24018/ejmed.2022.4.6.1569

Research Article

Tjokorda Gede Ngurah Chandragiram

Sanjiwani Hospital, Indonesia

* Corresponding author

Made Suyasa Jaya

Prof dr IGNG Ngoerah Hospital, Indonesia

Jacqueline Sudiman

Prof dr IGNG Ngoerah Hospital, Indonesia

Ida Bagus Putra Adnyana

Prof dr IGNG Ngoerah Hospital, Indonesia

Alit Darma Asmara

Prof dr IGNG Ngoerah Hospital, Indonesia

Putu Pradnya Paramitha Dewi

Prof dr IGNG Ngoerah Hospital, Indonesia

Agustinus Darmawan

Prof dr IGNG Ngoerah Hospital, Indonesia

10.24018/ejmed.2022.4.6.1569

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Submitted 2022-10-26
Published 2022-12-24

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Abstract

Introduction: Mitochondria are small organelles that are directly involved in many essential cellular functions. Mitochondria are very sensitive to the surrounding environmental conditions and are easily affected by various free radicals or ROS. Endometriosis is a disease associated with increased ROS. The effect of endometriosis on oocyte mitochondrial abnormalities or dysfunction has received limited attention. This study aims to determine the effect of exposure to follicular fluid in endometrioma patients on the presence of polar body I, distribution pattern, and intensity of mitochondrial fluorescence in mice oocytes.

Methods: The study design was a randomized post-test only control group design using oocytes of immature Swiss mice exposed to follicular fluid from endometrioma patients. Follicular fluid was taken at the time of picking oocytes from infertility patients who participated in the FIV-ISIS program. Immature oocytes were matured in vitro (IVM) in culture media with follicular fluid added from endometrioma and non-endometriotic patients as a control. The presence of polar body I (oocyte maturation), fluorescence intensity (amount/metabolic activity) and mitochondrial distribution pattern were compared in the two groups. Data analysis with SPSS 16.0 program. Variable analysis was done by chi square test and independent t test.

Results: Polar body I was significantly lower (30% vs 75%) in the treatment group compared to the control group (p=0,01). The pattern of diffuse distribution (30% vs 70%) was significantly lower in the treatment group compared to the control group (p=0,027). The mean fluorescence intensity (556,54

268.96 vs 818,07228.17) was significantly lower in the treatment group compared to the control group (p<0,001).

Conclusion: The effect of exposure to follicular fluid in endometrioma patients significantly reduced the presence of polar body I, caused a change in distribution pattern and decreased the intensity of mitochondrial fluorescence in mice oocytes.

Keywords: Endometriosis, mitochondria, polar body I, ROS

References

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DOI | Google Scholar

Gabor M, Lori R, Attila L. Endometriosis is a cause of infertility. Does reactive oxygen damage to gametes and embryos play a key role in the pathogenesis of infertility caused by endometriosis? Front Endocrinol. 2018; 9: 725.
DOI | Google Scholar

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DOI | Google Scholar

Marcus W, Jurema D. In vitro maturation of human oocytes for assisted reproduction. Fertil Steril. 2006; 86(5): 20-5.
DOI | Google Scholar

Isil K, Göktan K, Seda S, Pinar T. Detrimental effects of endometriosis on oocyte morphology in intracytoplasmic sperm injection cycles: A retrospective cohort study. Gynecol Endocrinol. 2008; 34(3): 206-11.
DOI | Google Scholar

Cohen J, Ziyyat A, Naoura I, Chabbert-Buffet N, Aractingi S, Darai E, et al. Effect of induced peritoneal endometriosis on oocyte and embryo quality in a mouse model. J Assist Reprod Genet. 2015; 32(2): 263-70.
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Dalton CM, Szabadkai G, Carroll J. Measurement of ATP in single oocytes: Impact of maturation and cumulus cells on levels and consumption. J Cell Physiol. 2014; 229: 353-61.
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Lee YX, Lin P-H, Rahmawati E, Ma Y-Y, Chan C, Tzeng C-R. Mitochondria Research in Human Reproduction. The Ovary. 2019; 327-335.
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Hamdan M. The sensitivity of the DNA damage checkpoint prevents oocyte maturation in endometriosis. Sci Rep. 2016; 6: 36994.
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Effect of Exposure to Follicular Fluid in Endometrioma Patients on the Presence of Polar Body I, Distribution Pattern and Intensity of Mitochondria Oocyte Fluorescence. (2022). European Journal of Medical and Health Sciences, 4(6), 98-101. https://doi.org/10.24018/ejmed.2022.4.6.1569

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Vol. 4 No. 6 (2022)

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[1] Babayev E, Seli E. Oocyte mitochondrial function and reproduction. Curr Opin Obstet Gynecol. 2015; 27(3): 175-81.
DOI | Google Scholar

[2] Gabor M, Lori R, Attila L. Endometriosis is a cause of infertility. Does reactive oxygen damage to gametes and embryos play a key role in the pathogenesis of infertility caused by endometriosis? Front Endocrinol. 2018; 9: 725.
DOI | Google Scholar

[3] Gustavo N, Emre S, Eduardo L, Juan A. The role of mithocondrial activity in female fertility and assisted reproductive technologies: Overview and current insights. Reprod Biomed Online. 2018; 36: 686-97.
DOI | Google Scholar

[4] Sanchez M, Valeria S, Ludovica B. Is the oocyte quality affected by endometriosis? A review of the literature. J Ovarian Res. 2017; 10: 43.
DOI | Google Scholar

[5] Marcus W, Jurema D. In vitro maturation of human oocytes for assisted reproduction. Fertil Steril. 2006; 86(5): 20-5.
DOI | Google Scholar

[6] Isil K, Göktan K, Seda S, Pinar T. Detrimental effects of endometriosis on oocyte morphology in intracytoplasmic sperm injection cycles: A retrospective cohort study. Gynecol Endocrinol. 2008; 34(3): 206-11.
DOI | Google Scholar

[7] Cohen J, Ziyyat A, Naoura I, Chabbert-Buffet N, Aractingi S, Darai E, et al. Effect of induced peritoneal endometriosis on oocyte and embryo quality in a mouse model. J Assist Reprod Genet. 2015; 32(2): 263-70.
DOI | Google Scholar

[8] Karen L, Jo A, Jennifer LJ. Review the role of oocyte organelles in determining developmental competence. Biology. 2017; 6: 35.
DOI | Google Scholar

[9] El-Raey M, Somfai T, Abdel-Ghaffar AE, Abou EL-Roos ME, Nagai T. Facts around Mitochondrial Shape, Reorganization and Oocyte Maturation. Theriogenology Insight. 2013; 3(2): 53.
DOI | Google Scholar

[10] Dumollard R, Duchen M, Carroll J. The role of mitochondrial function in the oocyte and embryo. Curr Top Dev Biol. 2007; 77: 21-49.
DOI | Google Scholar

[11] Buravkov SV, Pogodina MV, Buravkova LB. Comparison of mitochondrial fluorescent dyes in stromal cells. Bull Exp Biol Med. 2014; 157(5): 654-8.
DOI | Google Scholar

[12] Cottet‐Rousselle C, Ronot X, Leverve X, Mayol J. Cytometric assessment of mitochondria using fluorescent probes. Cytometry. 2011; 79A: 405-25.
DOI | Google Scholar

[13] Dalton CM, Szabadkai G, Carroll J. Measurement of ATP in single oocytes: Impact of maturation and cumulus cells on levels and consumption. J Cell Physiol. 2014; 229: 353-61.
DOI | Google Scholar

[14] Lee YX, Lin P-H, Rahmawati E, Ma Y-Y, Chan C, Tzeng C-R. Mitochondria Research in Human Reproduction. The Ovary. 2019; 327-335.
DOI | Google Scholar

[15] Hamdan M. The sensitivity of the DNA damage checkpoint prevents oocyte maturation in endometriosis. Sci Rep. 2016; 6: 36994.
DOI | Google Scholar

[16] Van Berklom, J. Mitochondria in human oogenesis and preimplantation embryogenesis, engines of metabolism, ionic regulation and developmental competence. Reproduction. 2004; 128: 269-80.
DOI | Google Scholar

[17] Hai-Yan H. Evidence that growth hormone can improve mitochondrial function in oocytes from aged mice. Reproduction. 2019; 157: 345-358.
DOI | Google Scholar

Effect of Exposure to Follicular Fluid in Endometrioma Patients on the Presence of Polar Body I, Distribution Pattern and Intensity of Mitochondria Oocyte Fluorescence

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