View clinical trials related to In Vitro Fertilization.
Filter by:Poor ovarian response (POR) remains one of the significant challenges of Assisted Reproductive Technology (ART). Facing difficulties related to clinical practice, optimizing the embryo culture process is necessary to improve the embryo number and quality in this group of patients. Potential techniques mentioned in the current literature include follicular size at trigger, dual trigger, artificial oocyte activation (AOA), blastocyst transfer, and the role of preimplantation genetic testing for aneuploidy (PGT-A). AOA is currently expected to improve treatment outcomes in poor ovarian responders with the potential for clinical efficacy. However, this issue has not been evaluated before.
observation of females condition will getting pregnant by undergoing assisted reproductive technologies, the most important of which is the in vitro fertilization (IVF), where blood and follicular fluid samples are collected from them at the same stage of in vitro fertilization, and then monitor the IVF outcomes until pregnancy occurs or not, based on blood tests. The levels of interested markers in blood and follicular fluid samples of the study individuals are assayed in order to compare these levels with the egg criteria such as egg number and maturation rate and finally compare the results with occurrence or absence of pregnancy.
The main embryotoxicity quality controls are the mouse embryo test (MEA = Mouse Embryo Assay) and the human sperm survival test (HSSA = Human Sperm Survival Assay). The HSSA test measures the survival (or mobility) of human sperm after exposure to the tested consumable for a predetermined period of time and compares it to that of unexposed sperm. It would appear that the HSSA is comparable in terms of sensitivity to the MEA test for the detection of toxicity.
Selection of developmentally competent oocytes enhances IVF efficiency. Usually, oocyte quality is determined based on its nuclear maturation and the presence of specific cytoplasmic and extracytoplasmic morphologic features. Gonadotropin-releasing hormone agonists (GnRH Agonists) and gonadotropin-releasing hormone antagonists (GnRH Antagonists) are used during controlled ovarian stimulation (COS) protocols in order to prevent premature luteinizing hormone (LH) surge and premature ovulation. However, GnRH receptors are also expressed in extra-pituitary tissues such as ovary, but it is still unknown whether the type of GnRH analogues used during COS could affect the oocyte morphology in polycystic ovary syndrome (PCOS) patients. The aim of this prospective, non-randomised, open-label, clinical trial is to compare the effects of two pituitary suppression regimens; GnRH Agonist-Long Protocol and GnRH Antagonist-Flexible Protocol on oocyte morphology in PCOS patients during IVF/ICSI.
This prospective, non-randomised, open-label, clinical trial is conducting on polycystic ovary syndrome (PCOS) subjects to compare the effects of two pituitary suppression regimens; GnRH Agonist-Long Protocol and GnRH Antagonist-Flexible Protocol on clinical and embryological IVF/ICSI outcomes, and on the follicular fluid levels of Placental Growth Factor (PlGF); which is known for his pivotal role in the regulation of ovulation, embryo development, and implantation
Selection of developmentally competent oocytes enhances IVF efficiency. Usually, oocyte quality is determined based on its nuclear maturation and the presence of specific cytoplasmic and extracytoplasmic morphologic features. Gonadotropin-releasing hormone agonists (GnRH Agonists) and gonadotropin-releasing hormone antagonists (GnRH Antagonists) are used during controlled ovarian stimulation (COS) protocols in order to prevent premature luteinizing hormone (LH) surge and premature ovulation. However, GnRH receptors are also expressed in extra-pituitary tissues such as ovary, but it is still unknown whether the type of GnRH analogues used during COS could affect the oocyte morphology, especially with the limited and conflicted currently available data. Thus, we are conducting this prospective, non-randomised, open-label, clinical trial to compare the effects of two pituitary suppression regimens; GnRH Agonist-Long Protocol and GnRH Antagonist-Flexible Protocol on oocyte morphology during IVF/ICSI.
The aim of this prospective, non-randomised, open-label, clinical trial is to compare the effects of two pituitary suppression regimens; GnRH Agonist-Long Protocol and GnRH Antagonist-Flexible Protocol on clinical and embryological IVF/ICSI outcomes, and on the follicular fluid levels of Placental Growth Factor (PlGF); which is known for his pivotal role in the regulation of ovulation, embryo development, and implantation.
The aim of this trial is to examine the possible effects of hCG administration for eight weeks prior to IVF/ICSI in women with low ovarian reserve. Primary outcome is the proportion of the antral follicle count that reach the pre-ovulatory stage.
Respectively for patients with repeated transplant failure and routine patients, Thawing frozen embryos in advance (18h) to extend the duration of embryonic development or thawing embryos on the day of transfer in the frozen embryo transfer cycle, to analyze which way can improve clinical pregnancy outcomes, is there a significant difference between the two ways or two types of patients?
The most successful treatment for infertility is in vitro fertilization (IVF), but less than 10% of infertile couples undergo IVF because of the high cost and relatively low success rate. Many patients have tried complementary and alternative medical treatments as an adjuvant therapy to improve their IVF success. Acupuncture given 2-4 times around the day of embryo transfer has not been shown to improve the IVF live birth rate. Chinese Herbal Medicine (CHM) may improve the IVF pregnancy rates, but the evidence so far is inconclusive because of high risks of bias in these studies. The objective of this multi-centre double blind randomized trial is to evaluate the efficacy of acupuncture with or without CHM on the live birth of IVF. The randomization process will be coordinated through a central mechanism. A total of 2,728 subjects will be randomized in 1:1:1:1 ratio in to one of the four treatment arms: 1) acupuncture and CHM, 2) acupuncture and placebo CHM, 3) control acupuncture and CHM or 4) control acupuncture and placebo CHM. Women will receive acupuncture or control acupuncture three times a week 4 weeks prior to IVF during ovarian stimulation, and before and after the embryo transfer. They will also take CHM or placebo CHM daily 4 weeks prior to IVF till a negative pregnancy test or till 8 weeks of gestation if pregnant.