Book contents
- How to Prepare the Endometrium to Maximize Implantation Rates and IVF Success
- How to Prepare the Endometrium to Maximize Implantation Rates and IVF Success
- Copyright page
- Contents
- Contributors
- Preface
- Chapter 1 Physiology of Endometrial Development through the Cycle and Implantation
- Chapter 2 Molecular and Cellular Basis of Human Embryo Implantation
- Chapter 3 Protein Biomarkers of Endometrial Receptivity
- Chapter 4 Genetic Markers of Endometrial Receptivity
- Chapter 5 Effects of Superovulation on the Endometrium
- Chapter 6 Screening the Uterine Microbiome Prior to Embryo Transfer
- Chapter 7 Estrogen and Progesterone Support in ART
- Chapter 8 The Role of Hysteroscopy and Endometrial Scratch in Improving Endometrial Receptivity
- Chapter 9 Fibroids and Polyps
- Chapter 10 Cleavage Stage or Blastocyst Transfer
- Chapter 11 Dummy Embryo Transfer
- Chapter 12 Does Catheter Type Influence Endometrial Implantation Success?
- Chapter 13 Should All Embryos Be Transferred in Unstimulated Cycles?
- Chapter 14 Rest after Embryo Transfer Is Unhelpful
- Chapter 15 Ectopic Pregnancies: Why Do They Happen?
- Chapter 16 The Role of NK Cells in Implantation after IVF and Treatment Strategies
- Chapter 17 Sex and Immune Receptivity for Embryo Transfer
- Chapter 18 Immunotherapy/IVIG, Prednisolone and Intralipid in IVF
- Chapter 19 The Role of Heparin and Aspirin to Aid Implantation
- Chapter 20 Early Pregnancy Loss
- Chapter 21 Is the Endometrium in Women with PCOS Compromised?
- Index
- References
Chapter 13 - Should All Embryos Be Transferred in Unstimulated Cycles?
Published online by Cambridge University Press: 07 January 2019
Book contents
- How to Prepare the Endometrium to Maximize Implantation Rates and IVF Success
- How to Prepare the Endometrium to Maximize Implantation Rates and IVF Success
- Copyright page
- Contents
- Contributors
- Preface
- Chapter 1 Physiology of Endometrial Development through the Cycle and Implantation
- Chapter 2 Molecular and Cellular Basis of Human Embryo Implantation
- Chapter 3 Protein Biomarkers of Endometrial Receptivity
- Chapter 4 Genetic Markers of Endometrial Receptivity
- Chapter 5 Effects of Superovulation on the Endometrium
- Chapter 6 Screening the Uterine Microbiome Prior to Embryo Transfer
- Chapter 7 Estrogen and Progesterone Support in ART
- Chapter 8 The Role of Hysteroscopy and Endometrial Scratch in Improving Endometrial Receptivity
- Chapter 9 Fibroids and Polyps
- Chapter 10 Cleavage Stage or Blastocyst Transfer
- Chapter 11 Dummy Embryo Transfer
- Chapter 12 Does Catheter Type Influence Endometrial Implantation Success?
- Chapter 13 Should All Embryos Be Transferred in Unstimulated Cycles?
- Chapter 14 Rest after Embryo Transfer Is Unhelpful
- Chapter 15 Ectopic Pregnancies: Why Do They Happen?
- Chapter 16 The Role of NK Cells in Implantation after IVF and Treatment Strategies
- Chapter 17 Sex and Immune Receptivity for Embryo Transfer
- Chapter 18 Immunotherapy/IVIG, Prednisolone and Intralipid in IVF
- Chapter 19 The Role of Heparin and Aspirin to Aid Implantation
- Chapter 20 Early Pregnancy Loss
- Chapter 21 Is the Endometrium in Women with PCOS Compromised?
- Index
- References
Summary
A summary is not available for this content so a preview has been provided. Please use the Get access link above for information on how to access this content.
- Type
- Chapter
- Information
- Publisher: Cambridge University PressPrint publication year: 2019
References
Kupka, MS, Ferraretti, AP, de Mouzon, J et al. Assisted reproductive technology in Europe, 2010: results generated from European registers by ESHREdagger. Human Reproduction. 2014;29:2099–113.Google Scholar
Evans, J, Hannan, NJ, Edgell, TA et al. Fresh versus frozen embryo transfer: backing clinical decisions with scientific and clinical evidence. Human Reproduction Update. 2014;20:808–21.Google Scholar
Calhaz-Jorge, C, de Geyter, C, Kupka, MS et al. Assisted reproductive technology in Europe, 2012: results generated from European registers by ESHRE. Human Reproduction. 2016;31:1638–52.Google ScholarPubMed
Noyes, RW, Hertig, AT, Rock, J. Dating the endometrial biopsy. American Journal of Obstetrics and Gynecology. 1975;122:262–3.Google Scholar
Devroey, P, Bourgain, C, Macklon, NS, Fauser, BC. Reproductive biology and IVF: ovarian stimulation and endometrial receptivity. Trends Endocrinol Metab. 2004;15:84–90.CrossRefGoogle ScholarPubMed
Kyrou, D, Kolibianakis, EM, Venetis, CA et al. How to improve the probability of pregnancy in poor responders undergoing in vitro fertilization: a systematic review and meta-analysis. Fertility and Sterility. 2009;91:749–66.Google Scholar
Venetis, CA, Kolibianakis, EM, Bosdou, JK, Tarlatzis, BC. Progesterone elevation and probability of pregnancy after IVF: a systematic review and meta-analysis of over 60 000 cycles. Human Reproduction Update. 2013;19:433–57.Google Scholar
Ubaldi, F, Bourgain, C, Tournaye, H et al. Endometrial evaluation by aspiration biopsy on the day of oocyte retrieval in the embryo transfer cycles in patients with serum progesterone rise during the follicular phase. Fertility and Sterility. 1997;67:521–6.CrossRefGoogle ScholarPubMed
Kolibianakis, EM, Devroey, P. The luteal phase after ovarian stimulation. Reproductive Biomedicine Online. 2002;5 Suppl 1:26–35.CrossRefGoogle ScholarPubMed
Van Vaerenbergh, I, Van Lommel, L, Ghislain, V et al. In GnRH antagonist/rec-FSH stimulated cycles, advanced endometrial maturation on the day of oocyte retrieval correlates with altered gene expression. Human Reproduction. 2009;24:1085–91.CrossRefGoogle ScholarPubMed
Evans, J, Hannan, NJ, Hincks, C, Rombauts, LJ, Salamonsen, LA. Defective soil for a fertile seed? Altered endometrial development is detrimental to pregnancy success. PloS one. 2012;7e53098.Google Scholar
Labarta, E, Martinez-Conejero, JA, Alama, P et al. Endometrial receptivity is affected in women with high circulating progesterone levels at the end of the follicular phase: a functional genomics analysis. Human Reproduction. 2011;26:1813–25.Google Scholar
Macklon, NS, van der Gaast, MH, Hamilton, A, Fauser, BC, Giudice, LC. The impact of ovarian stimulation with recombinant FSH in combination with GnRH antagonist on the endometrial transcriptome in the window of implantation. Reprod Sci. 2008;15:357–65.Google Scholar
Horcajadas, JA, Riesewijk, A, Polman, J et al. Effect of controlled ovarian hyperstimulation in IVF on endometrial gene expression profiles. Molecular Human Reproduction. 2005;11:195–205.Google Scholar
Luyet, BJ, Hodapp, EL. Revival of Frog’s Spermatozoa Vitrified in Liquid Air. Experimental Biology and Medicine. 1938;39:433–34.CrossRefGoogle Scholar
Rienzi, L, Gracia, C, Maggiulli, R et al. Oocyte, embryo and blastocyst cryopreservation in ART: systematic review and meta-analysis comparing slow-freezing versus vitrification to produce evidence for the development of global guidance. Human Reproduction Update. 2017;23:139–55.Google Scholar
Cobo, A, Garrido, N, Crespo, J, Jose, R, Pellicer, A. Accumulation of oocytes: a new strategy for managing low-responder patients. Reproductive Biomedicine Online. 2012;24:424–32.Google Scholar
Herrero, L, Pareja, S, Losada, C et al. Avoiding the use of human chorionic gonadotropin combined with oocyte vitrification and GnRH agonist triggering versus coasting: a new strategy to avoid ovarian hyperstimulation syndrome. Fertility and Sterility. 2011;95:1137–40.Google Scholar
Chamayou, S, Sicali, M, Alecci, C et al. The accumulation of vitrified oocytes is a strategy to increase the number of euploid available blastocysts for transfer after preimplantation genetic testing. Journal of Assisted Reproduction and Genetics. 2017. Epub 2017 January 9.Google Scholar
Chatzimeletiou, K, Morrison, EE, Panagiotidis, Y et al. Cytoskeletal analysis of human blastocysts by confocal laser scanning microscopy following vitrification. Human Reproduction. 2012;27:106–13.Google Scholar
Tachataki, M, Winston, RM, Taylor, DM. Quantitative RT-PCR reveals tuberous sclerosis gene, TSC2, mRNA degradation following cryopreservation in the human preimplantation embryo. Molecular Human Reproduction. 2003;9:593–601.Google Scholar
Van den Abbeel, E, Camus, M, Van Waesberghe, L et al. Viability of partially damaged human embryos after cryopreservation. Human Reproduction. 1997;12:2006–10.Google ScholarPubMed
Neulen, J, Yan, Z, Raczek, S et al. Human chorionic gonadotropin-dependent expression of vascular endothelial growth factor/vascular permeability factor in human granulosa cells: importance in ovarian hyperstimulation syndrome. The Journal of Clinical Endocrinology and Metabolism. 1995;80:1967–71.Google Scholar
Al-Inany, HG, Youssef, MA, Ayeleke, RO et al. Gonadotrophin-releasing hormone antagonists for assisted reproductive technology. The Cochrane Database of Systematic Reviews. 2016;4:CD001750.Google ScholarPubMed
Shapiro, BS, Andersen, CY. Major drawbacks and additional benefits of agonist trigger–not ovarian hyperstimulation syndrome related. Fertility and Sterility. 2015;103:874–78.CrossRefGoogle ScholarPubMed
Munne, S, Dailey, T, Sultan, KM, Grifo, J, Cohen, J. The use of first polar bodies for preimplantation diagnosis of aneuploidy. Human Reproduction. 1995;10:1014–20.Google Scholar
Hardy, K, Handyside, AH. Biopsy of cleavage stage human embryos and diagnosis of single gene defects by DNA amplification. Arch Pathol Lab Med. 1992;116:388–92.Google Scholar
McArthur, SJ, Leigh, D, Marshall, JT, de Boer, KA, Jansen, RP. Pregnancies and live births after trophectoderm biopsy and preimplantation genetic testing of human blastocysts. Fertility and Sterility. 2005;84:1628–36.Google Scholar
Helmerhorst, FM, Perquin, DA, Donker, D, Keirse, MJ. Perinatal outcome of singletons and twins after assisted conception: a systematic review of controlled studies. BMJ. 2004;328:261.Google Scholar
Henningsen, AK, Pinborg, A, Lidegaard, O et al. Perinatal outcome of singleton siblings born after assisted reproductive technology and spontaneous conception: Danish national sibling-cohort study. Fertility and Sterility. 2011;95:959–63.Google Scholar
Pandey, S, Shetty, A, Hamilton, M, Bhattacharya, S, Maheshwari, A. Obstetric and perinatal outcomes in singleton pregnancies resulting from IVF/ICSI: a systematic review and meta-analysis. Human Reproduction Update. 2012;18:485–503.CrossRefGoogle ScholarPubMed
Maheshwari, A, Pandey, S, Shetty, A, Hamilton, M, Bhattacharya, S. Obstetric and perinatal outcomes in singleton pregnancies resulting from the transfer of frozen thawed versus fresh embryos generated through in vitro fertilization treatment: a systematic review and meta-analysis. Fertility and Sterility. 2012;98:368–77 e1–9.Google Scholar
Wennerholm, UB, Henningsen, AK, Romundstad, LB et al. Perinatal outcomes of children born after frozen-thawed embryo transfer: a Nordic cohort study from the CoNARTaS group. Human Reproduction. 2013;28:2545–53.Google Scholar
Sazonova, A, Kallen, K, Thurin-Kjellberg, A, Wennerholm, UB, Bergh, C. Obstetric outcome in singletons after in vitro fertilization with cryopreserved/thawed embryos. Human Reproduction. 2012;27:1343–50.Google Scholar
Roy, TK, Bradley, CK, Bowman, MC, McArthur, SJ. Single-embryo transfer of vitrified-warmed blastocysts yields equivalent live-birth rates and improved neonatal outcomes compared with fresh transfers. Fertility and Sterility. 2014;101:1294–301.Google Scholar
Belva, F, Bonduelle, M, Roelants, M, Verheyen, G, Van Landuyt, L. Neonatal health including congenital malformation risk of 1072 children born after vitrified embryo transfer. Human Reproduction. 2016;31:1610–20.Google Scholar
Maheshwari, A, Raja, EA, Bhattacharya, S. Obstetric and perinatal outcomes after either fresh or thawed frozen embryo transfer: an analysis of 112,432 singleton pregnancies recorded in the Human Fertilisation and Embryology Authority anonymized dataset. Fertility and Sterility. 2016;106:1703–8.Google Scholar
Chen, ZJ, Shi, Y, Sun, Y et al. Fresh versus Frozen Embryos for Infertility in the Polycystic Ovary Syndrome. The New England journal of Medicine. 2016;375:523–33.Google Scholar
Shapiro, BS, Daneshmand, ST, Garner, FC et al. Evidence of impaired endometrial receptivity after ovarian stimulation for in vitro fertilization: a prospective randomized trial comparing fresh and frozen-thawed embryo transfer in normal responders. Fertility and Sterility. 2011;96:344–8.Google Scholar
Shapiro, BS, Daneshmand, ST, Garner, FC et al. Evidence of impaired endometrial receptivity after ovarian stimulation for in vitro fertilization: a prospective randomized trial comparing fresh and frozen-thawed embryo transfers in high responders. Fertility and Sterility. 2011;96:516–18.Google ScholarPubMed
Groenewoud, ER, Cantineau, AE, Kollen, BJ, Macklon, NS, Cohlen, BJ. What is the optimal means of preparing the endometrium in frozen-thawed embryo transfer cycles? A systematic review and meta-analysis. Human Reproduction Update. 2017;23:255–61Google Scholar
Peeraer, K, Couck, I, Debrock, S et al. Frozen-thawed embryo transfer in a natural or mildly hormonally stimulated cycle in women with regular ovulatory cycles: a RCT. Human Reproduction. 2015;30:2552–62.Google Scholar
Groenewoud, ER, Cohlen, BJ, Al-Oraiby, A et al. A randomized controlled, non-inferiority trial of modified natural versus artificial cycle for cryo-thawed embryo transfer. Human Reproduction. 2016;31:1483–92.Google Scholar