View clinical trials related to Oligozoospermia.
Filter by:The goal of this clinical trial is to compare in Oligozoospermia Patient. The main questions it aims to answer are: 1. Electroacupuncture therapy and standard therapy can affect oligozoospermia. 2. Electroacupuncture therapy and standard therapy can affect semen and spermatozoa plasma SOD levels. Researchers will compare patient with standard therapy with patient with standard therapy with electroacupuncture.
This is a multicenter, case-control study that aims to investigate the relationship between microbiota and sperm quality via stool, blood, and urine microbiome, metabolomics, and collected clinical metadata. The results of the spermatogenic dysfunction, including aspermia, oligozoospermia, asthenozoospermia, and teratozoospermia, will be compared to normal basic semen analysis utilizing the World Health Organization (WHO) semen analysis procedure 5th edition.
Severe Oligospermia (oligozoospermia) refer to semen with a low concentration of sperm and is a common finding in male infertility. Often semen with a decreased sperm concentration may also show significant abnormalities in sperm morphology and motility that affect Male fertility. The purpose of this study is to assess the ability of Autologous Adipose-Derived Adult Stromal Vascular Fraction (SVF) cells to stimulate Sertoli and spermatogonia cells and affect male fertility.
A male factor is responsible for almost half the cases of subfertility. Varicocele is a major cause of impaired spermatogenesis and potentially a correctable cause. It affects up to 40% of men with primary subfertility and 80% of men with secondary subfertility. Varicocelectomy is now accepted as a cost effective treatment in subfertile men with clinically palpable varicocele and impaired semen parameters. Recently, Varicocelectomy is reported to improve fertility potential in patients with severe oligozoospermia. In one such study, Varicocelectomy was associated with a statistically significant increase in sperm density and motility. Spontaneous pregnancy was achieved in16.7% of cases. In a recent meta-analysis, Varicocelectomy in men with severe oligozoospermia showed a strong trend toward improvement in pregnancy rate (PR) [OR= 1.69, 95% CI (0.951, 3.020), p= 0.073] and statistically significant increase in live birth rate (LBR)[OR=1.699, 95%CI (1.020, 2.831), p= 0.04]. The impact of ligation of internal spermatic artery (ISA) during Varicocelectomy is a matter of debate. Conventional view is arterial ligation can negatively affect testicular function and decrease the likelihood of post-operative paternity. Other investigators reported that ligation of ISA was not associated with significant changes in postoperative semen parameters, testicular size or PR in comparison to artery preservation. Moreover, laparoscopic artery-ligating Varicocelectomy was proved to be superior in the form of shorter operative time and lower recurrence rates with no difference in semen parameters or PR in comparison to laparoscopic artery-preservation varicocelectomy. Also, isolation of ISA is not an easy task during subinguinal Varicocelectomy due to compression by external oblique aponeurosis and its inherent anatomical variation. In 29 % and 57% of the cases, the ISA is surrounded by the varicose vessels and adherent to the veins respectively. Thus, the ISA is liable to a substantial risk of accidental ligation during subinguinal Varicocelectomy. Whether or not ligation of the ISA has a deleterious effect on the fertility outcomes in patients with severe oligozoospermia; this is not clear in the literature. This prospective randomized study was conducted to assess the impact of ISA ligation during subinguinal Varicocelectomy on fertility outcome in patients with severe oligozoospermia.
The investigators hope to learn if Letrozole is effective and safe in improving severe male infertility by increasing testosterone, decreasing oestradiol and stimulating sperm production thereby improving sperm motility (movement) and concentration. The study is being conducted because Letrozole is not yet proven to be a standard treatment in subjects with absent or very low sperm counts. The investigators are hoping to determine whether Letrozole is equal or superior to no treatment.
Oligozoospermia, refers to a low concentration of sperm. A low sperm count or poor sperm quality is the cause of infertility in about 20% of couples with fertility problems, and a contributory factor in a further 25% of couples. In the majority of cases, no cause can be found. For mild male infertility, intra uterine insemination (IUI) is the procedure of choice with a pregnancy rate of 6.5%. In IUI, sperm is inserted using a thin, flexible catheter directly into a woman's uterus. Azoospermia affects 1% of the male population and 20% of male infertility situations. Over 50% of azoospermic cases are due to testicular failure, including absence or failed production as well as low production and maturation arrest during the process of spermatogenesis. ICSI allows successful fertilization even with immature sperm obtained directly from testicular tissue. This is done through TESA (Testicular sperm aspiration) or TESE (Testicular sperm extraction). In cases of TESE small strips of testicular tissue are extracted with the intention of finding few viable sperm cells to be used for IVF or ICSI. Men with non-obstructive azoospermia have 0 to 3 mature spermatids per seminiferous tubule in contrast to 17-35 mature spermatids in men with normal spermatogenesis. TESE success rates are approximately 50% but differ according to etiology. Unfortunately, there is no method of pointing out where sperm may be found. TESE is accompanied with pain, tissue loss, reduced success in future TESE due to tissue scaring and testosterone deficiency. The complex process of spermatogenesis includes maturation of young spermatids into spermatozoas, a process which takes approximately 74 days. During spermatogenesis, spermatogonial stem cells are transformed into spermatids and released from the seminiferous tubule epithelium into its lumen. Non-motile spermatozoa are transported through the seminifreous tubules to the epididymis by testicular fluid secreted from the Sertoli cells with the aid of peristaltic contraction. During transport through the epididymis, sperm cells develop the ability to progress forward, undergo capacitation and attach and penetrate the egg. The electric charge of the spermatic cell has been termed zeta potential (electrokinetic potential) and is defined as the electric potential in the slip plane between the sperm membrane and its surroundings. Mature sperm possess an electric charge of −16 to −20 mV. In the animal study conducted, positive electrical current with a low amplitude bellow sensation level was situated around the scrotum of four normospermic and one oligospermic male pigs. At the end of the research the concentration of spermatocytes in the epididymis obtained in surgery was found to be 200 to 1600 percent above the baseline. Our intention is to evaluate if positive electrical current with a low amplitude bellow sensation level situated on the scrotum will increase the concentration of spermatocytes in the ejaculate. If our hypothesis is confirmed this may become a method for treating male infertility. The period of improvement is still unclear.
The investigators are testing the hypothesis that two ounces of whole-shelled walnuts/day added to the diet of men seeking care for infertility will beneficially affect sperm parameters and fertility. The investigators will compare the walnut intervention to the commonly suggested recommendation of adding an OTC multivitamin supplement to the diet.