Clinical Research Directory

The Impact of Assisted Hatching on Pregnancy Outcomes After Vitrified-Warmed Embryo Transfer in Advanced-age Patients

The goal of this clinical trial is to evaluate the effect of laser assisted hatching (LAH) on pregnancy outcomes, with live birth rate as the primary outcome, in advanced age infertile women aged ≥35 years who are undergoing non-donor IVF/ICSI cycles and planning vitrified-warmed embryo transfer. It also aims to monitor the safety of LAH and assess various secondary pregnancy and neonatal outcomes. The main questions it aims to answer are: Does laser assisted hatching improve the live birth rate in advanced age women undergoing vitrified-warmed embryo transfer? Does laser assisted hatching affect secondary outcomes including implantation rate, biochemical pregnancy rate, clinical pregnancy rate, ectopic pregnancy rate, ongoing pregnancy rate, miscarriage rate, multiple pregnancy rate, preterm birth rate, and rates of obstetric and neonatal complications as well as congenital anomalies? Researchers will compare the Laser Assisted Hatching (LAH) Group to the Control Group (without LAH) to see if LAH can improve pregnancy outcomes in the study population. Participants will: * Be randomly assigned to either the LAH Group or the Control Group at a 1:1 ratio, stratified by age (\<40 years/≥40 years) and embryo stage (cleavage stage/blastocyst) using stratified block randomization. * Undergo the first or second frozen-thawed embryo transfer cycle, with transferred embryos meeting the quality criteria (cleavage-stage embryos: Grade I, Grade II, or CP and above; blastocysts: 4BC/CB and above). * Receive embryo vitrification and warming after routine fertilization and culture; LAH Group will undergo LAH (thinning zona pellucida for cleavage-stage embryos, removing 1/4-1/3 of zona pellucida circumference for blastocysts) in G2 medium after embryo thawing, while Control Group will not receive assisted hatching. * Have endometrial preparation by natural, ovulatory, or hormone replacement cycles as appropriate, and 1-2 viable embryos will be transferred under ultrasound guidance within 3 hours after thawing, followed by routine luteal support after transfer. * Complete follow-up at multiple time points: 12-15 days after embryo transfer (serum β-hCG test), 28 days after embryo transfer (transvaginal ultrasound), 12 weeks of gestation (ultrasound), 28 weeks of gestation (ultrasound), and 1 month after delivery (collection of delivery and neonatal information). * Provide demographic, clinical, and embryological baseline data, as well as various outcome data during the study period. * Undergo regular monitoring of vital signs, laboratory test results, and adverse events, with key prevention and control of specific risks related to LAH such as embryo damage and multiple pregnancy.

Noninvasive Implantation Potential vs Morphology-Based Selection in IVF Single Blastocyst Transfer

Background: Morphology-based embryo selection cannot detect aneuploidy, which is common in advanced maternal age and recurrent pregnancy loss. NICS-AI combines non-invasive chromosome screening (NICS) of cell-free DNA from spent blastocyst culture medium with AI integration of developmental day and morphology to improve embryo ranking. Methods: This multicenter, single-blind, parallel randomized controlled trial will include 520 participants. Participants undergoing conventional IVF will be eligible if they meet either (i) female age 35-43 years or (ii) recurrent miscarriage (≥2 losses \<28 gestational weeks, including biochemical pregnancy with serum hCG \>25 IU/L). They must consent to blastocyst culture/vitrification and frozen-thawed single blastocyst transfer (SBT), and have ≥2 Day-5/Day-6, 2PN-derived blastocysts with morphology grade ≥4BC/4CB at randomization. Key exclusions include any ICSI-based fertilization or PGT-related procedures, known genetic disease meeting PGT indications, donor oocytes, untreated uterine anomalies/hydrosalpinx, or contraindications to pregnancy/ART. Randomization/interventions: Participants will be randomized 1:1 to NICS-AI-guided selection or morphology-based selection. In the NICS-AI arm, culture-medium DNA is tested and an AI-derived composite implantation score ranks embryos; controls use morphology alone (tie-break by cryopreservation order). Outcomes/analysis: The primary endpoint is live birth after the first SBT (delivery with ≥1 live-born infant per transfer cycle, per randomized participant). Secondary endpoints include first clinical pregnancy, early miscarriage (\<12 weeks, excluding biochemical pregnancy), ongoing pregnancy to 12 weeks, and cumulative pregnancy/live birth outcomes within 1 year (≤3 SBTs from one retrieval). Safety includes fetal malformations and neonatal outcomes through 1 year postpartum.

Adipose Stem Cell Mitochondria Supplementation to Oocytes (ASCENT)

The purpose of this study is to investigate the potential of autologous adipose stem cell (ASC) mitochondrial transfer (ASCENT) to oocytes along with intracytoplasmic sperm injection (ICSI)as a means of enhancing embryo development and improving the success rate of in patients with a history of multiple IVF failures. Embryo quality plays a crucial role in determining the success of assisted reproductive technologies and directly contributes to repeated pregnancy failures. Several factors, including age, physiological conditions, genetics, and environmental influences, can significantly impact embryo quality. Oocytes, the largest cells in the human body, are heavily reliant on mitochondria. Mitochondria's role in providing energy for oocytes is crucial, and insufficient energy production has been linked to poor oocyte and embryo quality. Some human studies have shown that increasing oocyte mitochondrial mass can improve embryo quality in patients who have experienced repeated IVF failures.