The Effect of VitC on IVF Outcome of DOR Patients

Peking University Third Hospital1,100 enrolled

Overview

In the context of the accelerating aging population and the continuous decline in birth rates nationwide, delaying reproductive aging in women and protecting the fertility of women of childbearing age have become urgent issues and key demands that need to be addressed in the field of maternal and child health in China. The ovaries have reproductive and hormone secretion functions and are crucial throughout the female reproductive lifecycle. Women of childbearing age in China face a serious problem of diminished ovarian reserve (DOR), which can lead to infertility, failed in vitro fertilization (IVF) treatments, miscarriage, and other adverse pregnancy outcomes, severely affecting the safety of women and their offspring. For DOR patients who desire to conceive, failure to intervene and treat promptly can result in irreversible losses and impose a significant psychological burden on them. However, there are currently no clear and reliable interventions that can improve ovarian function and enhance fertility in women with DOR. Therefore, exploring new, safe, and patient-acceptable intervention strategies is urgently needed, as it may bring hope and light to women with DOR. Nutrient supplementation, especially vitamin supplementation, has received increasing attention in disease treatment due to its safety, bioavailability, and effectiveness. Previous studies have shown that vitamin C may play an important role in treating diminished ovarian reserve. However, its effects on ovarian function need to be validated in the population. Based on the above research background, this project will conduct a randomized, placebo-controlled, double-blind, multicenter trial. The study subjects will be DOR infertility patients undergoing IVF/ICSI treatment. The intervention group will receive oral vitamin C supplementation at a dosage of 500 mg per dose, twice a day; the control group will receive a placebo with the same dosage and method for at least three months. Patients will be followed up until delivery outcomes, comparing the IVF/ICSI treatment results between the vitamin C supplementation group and the placebo group. The primary endpoint of this clinical trial is the live birth rate of the IVF/ICSI treatment cycle. Secondary endpoints include indicators of improved ovarian reserve function, ovarian aging molecular clocks, IVF-embryo culture indicators, pregnancy rates, pregnancy complications, and neonatal conditions, thereby providing new clues and theoretical basis for clinical treatment plans for DOR patients.

Study Type

INTERVENTIONAL

Allocation

Eligibility

Sex: FEMALEMin age: 20 YearsMax age: 45 Years

Medical Language ↔ Plain English

Definition of DOR: Currently, there is no internationally unified standard for DOR. According to the latest POSEIDON criteria for diminished ovarian reserve (DOR), serum AMH \<1.20 ng/mL or bilateral antral follicle count (AFC) \<5 is classified as DOR. In this study, the participants are primarily DOR patients, with the following inclusion criteria: * Infertile women undergoing their 1st or 2nd IVF treatment * Diagnosed with DOR: POSEIDON criteria (AMH \<1.2 ng/mL or bilateral AFC \<5) BMI between 18.5-28.0 kg/m² * Signed informed consent Exclusion Criteria：Participants meeting any of the following criteria will be excluded from the trial: * PGT (preimplantation genetic testing) candidates * DOR caused by ovarian surgery, cancer radiotherapy/chemotherapy * Other ovulation disorders (e.g., PCOS, Cushing's syndrome, non-classic congenital adrenal hyperplasia, hyperprolactinemia) or endometriosis (chocolate cysts) * Severe thyroid disorders: Hyperthyroidism, Graves' disease, Hashimoto's thyroiditis * Acute/chronic renal insufficiency, hemodialysis, or history of severe kidney impairment * Infectious diseases: HIV, active hepatitis, metabolic acidosis, tuberculosis, etc. * Severe autoimmune diseases (e.g., rheumatoid arthritis, lupus, Crohn's disease) * Cardiovascular events within the past 3 months: Coronary artery disease/myocardial infarction/clinically significant congestive heart failure；Stroke/transient ischemic attack (TIA)；Deep vein thrombosis/pulmonary embolism；Poorly controlled hypertension (SBP ≥160 mmHg or DBP ≥90 mmHg)；Diagnosed diabetes mellitus；Coronary intervention (PCI) or coronary artery bypass grafting (CABG)； * Neurological disorders (e.g., dementia,Alzheimer's, Parkinson's) or use of related medications * Psychiatric disorders or use of antiepileptic/antidepressant drugs * History of cancer or radiotherapy/chemotherapy * Allergy to vitamin C * Current high-dose vitamin C supplementation (\>500 mg/day) * Unwillingness to take the study-provided supplements * Alcohol abuse, smoking, or drug addiction * Participation in other clinical trials within the past month

Locations (6)

Beijing Obstetrics and Gynecology Hospital,Capital Medical University

Beijing, Beijing Municipality, China

RECRUITING

Peking university third hospital

Beijing, Beijing Municipality, China

RECRUITING

The second hospital of Hebei Medical University

Shijiazhuang, Hebei, China

RECRUITING

General Hospital of Ningxia Medical University

Yinchuan, Ningxia, China

RECRUITING

Tang Du Hospital

Xi’an, Shanxi, China

RECRUITING

Peking University Shenzhen Hospital

Shenzhen, Shenzhen, China

RECRUITING

Outcomes

Primary Outcomes

Live birth rate

The main outcome of this trial is the live birth resulting from a sustained pregnancy after the first embryo transfer within 6 months for patients undergoing fresh transfer cycles or frozen embryo cycles. Live birth rate (%) = Number of subjects with live births in each group / Total number of subjects in each group × 100%.

Time frame: 1 year after oocyte retrieval following embryo transfer

Secondary Outcomes

Cumulative live birth rate

Live births within 1 year after oocyte retrieval following embryo transfer; calculated as: (Final number of live births / Number of randomized participants) × 100%

Time frame: 1 year after oocyte retrieval following embryo transfer

Singleton live birth rate

(Number of singleton live births / Number of randomized participants) × 100%

Time frame: 1year after oocyte retrieval following embryo transfer

Twin live birth rate

(Number of women with twin live births / Number of randomized participants) × 100%

Time frame: 1 year after oocyte retrieval following embryo transfer

Clinical pregnancy rate

Presence of at least one gestational sac (including intrauterine and ectopic) confirmed by transvaginal ultrasound 28-30 days after embryo transfer; includes singleton pregnancy rate and twin pregnancy rate (twin and multiple pregnancy rates should be reported along with pregnancy loss rate)

Time frame: 28-30 days after embryo transfer

Ongoing pregnancy

Presence of at least one gestational sac with fetal heartbeat confirmed by transvaginal ultrasound at 12 weeks after embryo transfer.

Time frame: 12 weeks after embryo transfer.

Time to pregnancy leading to live birth

or participants who achieved live birth, the time from intervention initiation to clinically confirmed pregnancy (confirmed by ultrasound 30 days after transfer). Survival analysis will be used to compare between intervention and control groups.

Time frame: 1 year after oocyte retrieval following embryo transfer

Number of oocytes retrieved

Time frame: 3 to 12 months from enrollment

Number of normally fertilized oocytes

On Day 1 post-retrieval, oocytes with two pronuclei (2PN) are counted as normally fertilized.

Time frame: Day 1 post-retrieval

Total fertilization failure

No oocytes in the current treatment cycle show 2PN after fertilization or injection.

Time frame: Day 1 post-retrieval

Number of usable embryos

On Day 3 post-retrieval, embryos with ≥4 cells and ≤30% fragmentation are considered usable.

Time frame: On Day 3 post-retrieval

Number of high-quality embryos

On Day 3 post-retrieval, 2PN-derived embryos with ≥6 cells and ≤10% fragmentation are classified as high-quality.

Time frame: On Day 3 post-retrieval

Number of implanted embryos

The number of gestational sacs (including intrauterine and ectopic) detected by transvaginal ultrasound 28-30 days after embryo transfer.

Time frame: 28-30 days after embryo transfer.

Ectopic pregnancy

A pregnancy occurring outside the uterine cavity, diagnosed by ultrasound, surgical visualization, or histopathology.

Time frame: 1 year after oocyte retrieval following embryo transfer

Miscarriage

Spontaneous loss of an intrauterine pregnancy before 20 weeks of gestation. This should occur after ultrasound confirmation of a viable pregnancy.

Time frame: 1 year after oocyte retrieval following embryo transfer

Stillbirth

Fetal death occurring after 20 weeks of gestation, before complete expulsion or extraction. Death is determined by the absence of breathing or other signs of life (e.g., heartbeat, umbilical cord pulsation, or definite voluntary movement) after delivery.

Time frame: 1 year after oocyte retrieval following embryo transfer

Termination of pregnancy

Medical, surgical, or other artificial termination of an intrauterine pregnancy (including fetal reduction procedures).

Time frame: 1 year after oocyte retrieval following embryo transfer

Moderate or severe ovarian hyperstimulation syndrome (OHSS)

OHSS is primarily characterized by cystic enlargement of the ovaries, increased vascular permeability, third-space fluid accumulation (resulting in ascites and pleural effusion), and localized or generalized edema.)

Time frame: 1 year after oocyte retrieval following embryo transfer

Pregnancy complications

Including gestational diabetes mellitus, hypertensive disorders of pregnancy, antepartum hemorrhage, etc.

Time frame: 1 year after oocyte retrieval following embryo transfer

Gestational age

The number of weeks from fertilization to delivery, plus 14 days.

Time frame: 1 year after oocyte retrieval following embryo transfer

Preterm birth

Birth occurring before 37 weeks of gestation (i.e., fewer than 259 days of pregnancy).

Time frame: 1 year after oocyte retrieval following embryo transfer

Birth weight

The weight of the newborn at birth. Abnormal birth weight includes: Low birth weight (LBW): \<2,500 g Very low birth weight (VLBW): \<1,500 g High birth weight (macrosomia): \>4,000 g Very high birth weight: \>4,500 g

Time frame: 1 year after oocyte retrieval following embryo transfer

Large for gestational age (LGA)

Newborns with birth weight above the 90th percentile for their gestational age and sex.

Time frame: 1 year after oocyte retrieval following embryo transfer

Small for gestational age (SGA)

Newborns with birth weight below the 10th percentile for their gestational age and sex.

Time frame: 1 year after oocyte retrieval following embryo transfer

Neonatal death

Death of a live-born infant within 28 days after birth. This can be further categorized as: Early neonatal death: Death occurring within the first 7 days of life. Late neonatal death: Death occurring between 8 and 28 days of life.

Time frame: 1 year after oocyte retrieval following embryo transfer

Birth defect

Structural, functional, or genetic abnormalities occurring during pregnancy, which may be identified prenatally, at birth, or postnatally, and may be life-threatening or fatal. Major congenital anomalies should be reported as infants with at least one major congenital anomaly detected. If a major birth defect is identified in a multiple pregnancy, it should be explicitly reported.

Time frame: 1 year after oocyte retrieval following embryo transfer

Possible Vitamin C Side Effects-Abdominal Pain and Diarrhea:

A single high dose (5-10 g) of vitamin C may cause transient osmotic diarrhea and/or abdominal bloating. However, the human body has a high tolerance, and even such high doses are generally safe. Typically, these symptoms gradually improve or disappear after continued use.

Time frame: 1 year

Possible Vitamin C side effect--Hyperuricemia

Hyperuricemia: Vitamin C can be partially metabolized into oxalate and dose-dependently increase oxalate levels in urine. High doses of vitamin C may temporarily increase uric acid excretion, while high-dose intravenous administration may stimulate polyuria. Therefore, the daily recommended dose of vitamin C should not exceed 1 gram. Urine routine tests will be conducted during follow-up.

Time frame: 1 year

Possible Vitamin C side effect--Kidney stones

Some studies have found that high-dose oral vitamin C significantly increases the risk of kidney stone formation in men by 41%. Additionally, long-term high concentrations of oxalate in urine may contribute to stone formation. Thus, high-dose vitamin C supplementation in at-risk populations may lead to urinary tract stones, as self-reported by participants.

Time frame: 1 year

Possible Vitamin C side effect--Hemolysis

Intravenous or high-dose oral vitamin C may induce hemolysis in patients with glucose-6-phosphate dehydrogenase (G6PD) deficiency and worsen hemolysis in those with paroxysmal nocturnal hemoglobinuria. If such symptoms occur, vitamin C should be discontinued immediately, medical attention sought, and researchers contacted.

Time frame: 1 year

Vitamin C level after supplementation

Time frame: 3 months to 1 year

The Effect of VitC on IVF Outcome of DOR Patients

Overview

Conditions

Interventions

Eligibility

Locations (6)

Outcomes

Primary Outcomes

Secondary Outcomes

Central Contacts