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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

Here, we present an optimized method for promptly removing a portion of cumulus-oocyte complexes following egg retrieval to expedite the IVF observation process, reducing the time required for granulosa cell removal, minimizing oocyte exposure to external elements, and does not hinder embryo development, ultimately improving the efficiency of IVF laboratory procedures.

Abstract

Despite the rapid advancements in clinical and laboratory technologies for in vitro fertilization (IVF), a significant proportion (10%-15%) of patients continue to experience fertilization disorders, leading to low fertilization rates and the production of nonviable embryos. Short-term fertilization involves the early removal of granulosa cells to observe the extrusion of the second polar body, enabling the assessment of fertilization and early remedial measures to address low fertilization rates and complete fertilization failure. However, the observation of short-term fertilization in IVF is impeded by challenges such as excessively large unprocessed clusters of cumulus-oocyte complexes and adhesion between eggs, necessitating complex external procedures for granulosa cell removal, and prolonged observation duration. To tackle this issue, this study proposes a method of immediate partial removal of granulosa cells post egg retrieval. This approach streamlines subsequent stages of short-term fertilization and traditional fertilization monitoring, reduces the time needed for oocyte extrusion, minimizes the likelihood of external environmental impacts on the oocytes, and decreases the risk of missing the critical fertilization observation window. Consequently, the study yields novel clinical evidence aimed at enhancing the operational efficiency of embryonic laboratories in IVF.

Introduction

In the field of in vitro fertilization-embryo transfer (IVF-ET), the typical fertilization rate falls within the range of 60% to 80%1. However, approximately 4% to 16% of cases encounter either complete fertilization failure or low fertilization rates, presenting challenges in prediction2,3. To improve clinical pregnancy outcomes and decrease the occurrences of complete non-fertilization and low fertilization, the utilization of short-term fertilization in IVF procedures is on the rise4. This approach entails the prompt removal of granulosa cells to monitor the extrusion of the second polar body, assess fertilization status, and potentially conduct remedial intracytoplasmic sperm injection (ICSI). The bond between the oocyte cumulus cell complex (OCCC) and the oocyte is stronger during short-term fertilization compared to traditional overnight fertilization, thereby increasing the challenge of OCCC removal5. Factors such as an excess of oocyte numbers, large OCCC complexes, or inter-oocyte adhesions can lead to prolonged granulosa cell removal times during short-term fertilization, thereby extending the period that eggs remain outside the incubator4. To optimize the fertilization observation period, a modified approach post-egg retrieval has been devised, involving partial excision of granulosa cells from oocytes with significant OCCC complexes. This technique aids in retaining the granulosa cells surrounding the oocytes, preserving the integrity of the early oocyte structure6, and allowing these cells to continue supplying vital factors for oocyte maturation and subsequent fertilization-embryo binding7.

Consequently, this study focuses on patients undergoing IVF-ET treatment at a reproductive medicine center as research participants, aiming to investigate the impact of an immediate partial granulosa cell mechanical excision method on the duration of procedures for both short-term fertilization and overnight fertilization monitoring while also evaluating outcomes of normal fertilization and late-stage development. This research intends to offer valuable insights for enhancing embryo laboratory procedures in IVF.

Protocol

All procedures were conducted in accordance with the standard operating procedures of the Department of Reproductive Medicine at Meizhou People's Hospital and were subject to review by the Ethics Committee of the same department. Written informed consent was obtained from each participating couple.The study included participants undergoing their first IVF cycle with cleavage or blastocyst stage embryo transfer, as well as females between 20 and 45 years of age. Exclusion criteria included the use of donor eggs/sperm and specific conditions such as congenital or secondary uterine abnormalities (e.g., septate uterus, unicornuate uterus, uterine didelphys), adenomyosis, uterine submucosal fibroids, or endometrial thickness below 7 mm on the day of embryo transfer. A total of 115 patients enrolled between December 2023 and February 2024 were stratified into two groups based on whether immediate partial removal of OCCC was performed.

1. Preparation before oocyte retrieval

  1. Place the oocyte pick-up dishes (Table of Materials) in the incubator at 37 Β°C overnight.
  2. Incubate 12 mL of follicle manipulating medium (Table of Materials) in 14 mL round bottom test tubes at 37 Β°C overnight. Transfer the tubes to the prewarmed test tube rack 30 min before oocyte retrieval.
  3. Prepare the follicle manipulating medium: Add 9 mL of follicle manipulating medium to a 14 mL round-bottom test tube (Table of Materials) and incubate at 37 Β°C overnight. On the day of oocyte retrieval, transfer 4.5 mL of the medium to a preincubated oocyte pick-up dish (Table of Materials) covered with 2 mL of 100% paraffin oil.
  4. Prepare the OCCC flushing solution: Add 4.5 mL of fertilization medium (Table of Materials) to an oocyte pick-up dish and incubate at 37 Β°C overnight.
  5. Prepare the fertilization medium: Add 1 mL of fertilization medium to a 6 cm dish covered with 100% paraffin oil (Table of Materials) and incubate at 37 Β°C overnight.
  6. Prepare the glass Pasteur pipettes (Table of Materials): Gently blunt and round the tips by burning them on an alcohol lamp for about 5 s (Figure 1).Attach a suction head to the tip of the Pasteur pipettes, ensuring it can touch the bottom of the dish without scratching. Rinse the glass Pasteur pipettes and 10 cm dishes with a follicle manipulation medium.

2. Oocyte retrieval and immediate partial removal of OCCC

NOTE: Use a stereomicroscope during oocyte isolation and OCCC removal procedures. For optimal results, all procedures should be performed on a heating table with temperature control (37 Β°C), and all equipment should be preheated 30 min before oocyte retrieval.

  1. Collect preovulatory follicular fluid during oocyte retrieval according to the ESHRE recommendations8.
    1. Briefly, use a 17 G needle to retrieve the oocytes under transvaginal ultrasound guidance. The appropriate negative pressure ranges from 120-140 mmHg.
    2. Pour the follicular fluid collected in the 14 mL round-bottom test tube into a 10 cm dish (Table of Materials), maintaining a fluid depth of less than 0.5 cm. Place the dish on a constant temperature platform (37 Β°C).
  2. Observe the OCCC under a stereomicroscope to confirm the presence of oocytes and assess their maturity.
    NOTE: The maturity of the OOOC is assessed based on the morphology of the cumulus cells and the visibility of certain oocyte structures9.
  3. Aspirate the OCCC using a blunt-ended Pasteur pipette. Tilt the 10 cm dish about 15 degrees and spread out all large OCCC. Avoid aspirating the oocyte and surrounding granulosa cells within a 2500 Β΅m radius. Cut excess granulosa cells with the Pasteur pipette along the longitudinal axis (Figure 2). The detailed steps are as follows:
    1. Observe with the naked eye to see if there is a grayish translucent mucoid mass in the follicular fluid. If not found, quickly search for the grayish translucent mucoid mass by rotating clockwise from the outside to the inside under a stereomicroscope, the OCCC.
    2. Confirm whether there are oocytes in the OCCC and make a preliminary assessment of oocyte maturity.
    3. Then, pre-prepare a silicone aspiration pipette with a round flame-polished Pasteur pipette, aspirate the OCCC, and at the same time, gently raise the culture dish at the 9-10 o'clock position with the left ring finger of the hand holding the 10 cm dish, tilting the culture dish slightly about 15Β° to the left (placing the ring finger under the dish is approximately the required angle).
    4. While spitting out the aspirated OCCC at the 11 o'clock position of the dish, gently elongate it horizontally to the right. Then, observe the size of the granulosa cells around the expanded OCCC. Subsequently, at the suitable position of the horizontally elongated OCCC, use the Pasteur pipette to make a quick and gentle descending cut on the excess granulosa cells from top to bottom.
  4. Transfer the cut OCCC into a collection dish containing OCCC flushing solution. Pour the remaining follicular fluid into a sterile sample container (Table of Materials). Repeat these steps until all complexes are collected.

3. Semen preparation and in vitro insemination

  1. Collect the semen samples via ejaculation on the morning of oocyte retrieval. Evaluate sperm concentration, motility, and morphology under a light microscope following World Health Organization (WHO, 2010) criteria10. Then, transfer the sperm pellet to a new centrifuge tube and wash it twice in fertilization medium11. Incubate them at 6% CO2 and 37 Β°C until needed.
  2. Inseminate OCCCs with 1 x 105 to 3 x 105 motile spermatozoa per milliliter in a single droplet approximately 2-3 h after retrieval in the fertilization dish (Table of Materials). Add 6-8 OCCC and 1 mL of the fertilization medium to the fertilization dish.
    NOTE: After washing the sticky OCCC, they are transferred to the fertilization dish using a Pasteur pipette. Release one OCCC at a time, lifting the pipette gently off the liquid surface before releasing the next, ensuring that each OCCC is placed individually in the dish to prevent clustering.

4. Cumulus cells removal

  1. For short-term fertilization, follow the steps described below.
    1. Co-incubate OCCCs with spermatozoa for4-6 h. After incubation, mechanically remove the cumulus cells surrounding the oocytes.
    2. Aspirate the oocytes using a pipette with an inner diameter slightly smaller than the oocytes to ensure complete removal of cumulus cells.
    3. Confirm fertilization by observing the presence of two polar bodies. Oocytes showing a second polar body are considered fertilized.
    4. Identify those cases that do not show the second polar body as fertilization failures, necessitating rescue ICSI.
  2. For regular fertilization, after 18-20 h of co-incubation, remove cumulus cells using the pipettes for fertilization assessment.

5. Embryo culture

  1. Culture and monitor the fertilized oocytes for 3-5 days following oocyte retrieval. Assess fertilization at 20 h post-insemination to determine the number of pronuclei. Subsequently, culture each zygote individually in a medium droplet and transfer the embryos post-fertilization to a cleavage medium.
    NOTE: An ideal embryo by the third day should consist of six or more equally-sized blastomeres and exhibit a fragmentation rate of less than or equal to 10%12.
  2. The decision to proceed with blastocyst culture depends on the patient's preferences and the specific circumstances, such as the quantity and quality of embryos obtained on day 3. Transfer the day 3 embryos to the blastocyst medium and assess on day 5. Use Gardner's scoring system to evaluate blastocysts, with high-quality blastocysts having scores of β‰₯ 4 BB13.

6. Outcome measurements and statistical analysis

  1. Report continuous data as the mean Β± standard deviation and express ordinal data as proportions. Perform statistical analysis using the Student's t-test or the chi-squared test in an appropriate data analysis software (here, IBM SPSS Statistics). Deem a significance level of P < 0.05 as statistically significant.

Results

In the group undergoing short co-incubation procedures, patients who received rescue were excluded. Out of 47 patients receiving short-term insemination, no significant differences were observed in terms of patients' age and the number of retrieved oocytes (Table 1). The immediate partial removal of OCCC resulted in a loosening of the remaining OCCC around the oocytes (Figure 3), facilitating the detection of a second polar body. The average procedure time was significan...

Discussion

The immediate partial removal of granulosa cells can accelerate the early disintegration process of short-term fertilization, reduce the observation time for the second polar body in both short-term fertilization and conventional IVF and do not compromise subsequent embryo development. Currently, laboratories globally employ various strategies to mitigate fertilization disorders and low success rates. The preferred method involves removing granulosa cells for observing the second polar body 4-6 h post short-term fertiliz...

Disclosures

The authors declare no competing interests.

Acknowledgements

The authors express their gratitude to the Department of Reproductive Medicine staff at Meizhou People's Hospital in Guangdong, China, for their active participation in this study.

Materials

NameCompanyCatalog NumberComments
G-IVFT PLUSVitrolife10136
OVOILVitrolife10029
G-MOPS PLUSVitrolife10130
Falcon 3003 dishCorning353003
Falcon 3001 dishCorning353001
Falcon 2001 tubeCorning352001
Falcon 4013 cupCorning354013
Falcon 3037 dishCorning351058
Pasteur pipetteDarwinD1150-5P

References

  1. Chen, C., Kattera, S. Rescue ICSI of oocytes that failed to extrude the second polar body 6 h post-insemination in conventional IVF. Hum Reprod. 18 (10), 2118-2121 (2003).
  2. Barlow, P., et al. Fertilization failure in IVF: why and what next. Hum Reprod. 5 (4), 451-456 (1990).
  3. KuczyΕ„ski, W., et al. Rescue ICSI of unfertilized oocytes after IVF. Hum Reprod. 17 (9), 2423-2427 (2002).
  4. He, Y., et al. Effect of early cumulus cells removal and early rescue ICSI on pregnancy outcomes in high-risk patients of fertilization failure. Gynecol Endocrinol. 34 (8), 689-693 (2018).
  5. Turathum, B., Gao, E. M., Chian, R. C. The function of cumulus cells in oocyte growth and maturation and in subsequent ovulation and fertilization. Cells. 10 (9), 2292 (2021).
  6. BΓ‘rcena, P., RodrΓ­guez, M., Obradors, A., Vernaeve, V., Vassena, R. Should we worry about the clock? Relationship between time to ICSI and reproductive outcomes in cycles with fresh and vitrified oocytes. Hum Reprod. 31 (6), 1182-1191 (2016).
  7. Telfer, E. E., Grosbois, J., Odey, Y. L., Rosario, R., Anderson, R. A. Making a good egg: human oocyte health, aging, and in vitro development. Physiol Rev. 103 (4), 2623-2677 (2023).
  8. D'Angelo, A., et al. Recommendations for good practice in ultrasound: oocyte pick up. Hum Reprod Open. 2019 (4), hoz025 (2019).
  9. Hu, Y., et al. Transcriptomic profiles reveal the characteristics of oocytes and cumulus cells at GV, MI, and MII in follicles before ovulation. J Ovarian Res. 16 (1), 225 (2023).
  10. Lu, W. H., Gu, Y. Q. Insights into semen analysis: a Chinese perspective on the fifth edition of the WHO laboratory manual for the examination and processing of human semen. Asian J Androl. 12 (4), 605-606 (2010).
  11. De los Santos, M. J., et al. Revised guidelines for good practice in IVF laboratories (2015). Hum Reprod. 31 (2015), 685-686 (2016).
  12. Nagy, Z. P., et al. Pronuclear morphology evaluation with subsequent evaluation of embryo morphology significantly increases implantation rates. Fertil Steril. 80 (1), 67-74 (2003).
  13. Gardner, D. K., Lane, M., Stevens, J., Schlenker, T., Schoolcraft, W. B. Reprint of: Blastocyst score affects implantation and pregnancy outcome: towards a single blastocyst transfer. Fertil Steril. 112 (4 Suppl1), e81-e84 (2019).
  14. Esfandiari, N., Claessens, E. A., Burjaq, H., Gotlieb, L., Casper, R. F. Ongoing twin pregnancy after rescue intracytoplasmic sperm injection of unfertilized abnormal oocytes. Fertil Steril. 90 (1), 199.e5-199.e7 (2008).
  15. Wetzels, A. M., et al. The effects of co-culture with human fibroblasts on human embryo development in vitro and implantation. Hum Reprod. 13 (5), 1325-1330 (1998).
  16. Kattera, S., Chen, C. Short coincubation of gametes in in vitro fertilization improves implantation and pregnancy rates: a prospective, randomized, controlled study. Fertil Steril. 80 (4), 1017-1021 (2003).

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