Distribution and Positive Predictive Value of Follicle Stimulating Hormone Among Nonazoospermic Men.

PURPOSE: Our goal was to characterize the distribution of follicle stimulating hormone (FSH) in fertile and subfertile nonazoospermic men, and to determine the ability of various FSH thresholds to predict fertility status. MATERIALS AND METHODS: We performed a retrospective cohort study of 1389 nonazoospermic men who presented for fertility evaluation. Men with at least 2 semen analyses and 1 FSH level were included. Men were dichotomized into fertile and subfertile groups based on total motile sperm count. FSH was evaluated within a multivariable model, and positive predictive values (PPVs) for subfertility were used to assess the clinical utility of various FSH thresholds. RESULTS: One thousand fifteen (80%) men were classified as fertile and 274 (20%) as subfertile. Age, presence of varicocele, and testosterone levels were not statistically different between the groups. Median FSH was 4.0 vs 6.0 (P < .001) among fertile vs subfertile men. Multiple FSH thresholds ranging from 2.9 to 9.3 performed similarly in predicting fertility status (PPV 0.49-0.59). Only FSH thresholds above the 95th percentile (12.1) had PPVs greater than 0.7. The highest PPV (0.84) was seen at an FSH of 20.8 (99th percentile). CONCLUSIONS: While there were significant differences in FSH levels among fertile and subfertile nonazoospermic men, multiple FSH cutoffs between 2.2 and 9.3 performed poorly for prediction of fertility status as determined by total motile sperm count. It was not until the 95th percentile FSH value that a clinically useful level of predictability for subfertility was reached, indicating that FSH should not be used as a standalone test of fertility status. Nonetheless, FSH testing remains clinically useful and may be most informative in the setting of extreme values or discordant FSH and semen analysis results.

Endocrine disruption and male reproductive disorders: unanswered questions.

Maternal exposure to endocrine-disrupting chemicals (EDCs) in human pregnancy is widely considered as an important cause of adverse changes in male reproductive health due to impaired foetal androgen production/action. However, the epidemiological evidence supporting this view is equivocal, except for certain phthalates, notably diethyl hexyl phthalate (DEHP). Maternal phthalate exposure levels associated with adverse reproductive changes in epidemiological studies are several thousand-fold lower than those needed to suppress foetal androgen production in rats, and direct studies using human foetal testis tissue show no effect of high phthalate exposure on androgen production. This conundrum is unexplained and raises fundamental questions. Human DEHP exposure is predominantly via food with highest exposure associated with consumption of a Western style (unhealthy) diet. This diet is also associated with increased exposure to the most common EDCs, whether persistent (chlorinated or fluorinated chemicals) or non-persistent (phthalates, bisphenols) compounds, which are found at highest levels in fatty and processed foods. Consequently, epidemiological studies associating EDC exposure and male reproductive health disorders are confounded by potential dietary effects, and vice versa. A Western diet/lifestyle in young adulthood is also associated with low sperm counts. Disentangling EDC and dietary effects in epidemiological studies is challenging. In pregnancy, a Western diet, EDC exposure, and maternal living in proximity to industrial sites are all associated with impaired foetal growth/development due to placental dysfunction, which predisposes to congenital male reproductive disorders (cryptorchidism, hypospadias). While the latter are considered to reflect impaired foetal androgen production, effects resulting from foetal growth impairment (FGI) are likely indirect. As FGI has numerous life-long health consequences, and is affected by maternal lifestyle, research into the origins of male reproductive disorders should take more account of this. Additionally, potential effects on foetal growth/foetal testis from the increasing use of medications in pregnancy deserves more research attention.

Long-term effect of exposure to triethylene glycol dimethacrylate (TEGDMA) on male mouse reproduction.

Our study investigated the impact on male mouse fertility and reproduction of long-term (14 weeks) exposure to triethylene glycol dimethacrylate (TEGDMA), a co-monomer of resin-based compounds, at doses of 0.01, 0.1, 1, and 10 ppm. Test and control mice were then paired with sexually mature untreated female mice and their fertility evaluated. Females paired with males exposed to all TEGDMA doses exhibited a significant decline in pregnancy rates, and significant increases in the total embryonic resorption-to-implantation ratio, except for males exposed to 0.01 ppm TEGDMA. Males in the highest dose group (10 ppm) showed significant increases in seminal vesicle and preputial gland weights. They also had significantly higher serum levels of luteinizing hormone (LH) and follicle stimulating hormone (FSH) than the controls, and the 0.01 ppm dosage group for FSH levels. TEGDMA exposure resulted in notable histopathological alterations in the testis, with detachment of germ cells and shedding of germinal epithelium into the tubule lumen. These results strongly indicate that TEGDMA exposure has detrimental consequences on the reproductive abilities and functions in male mice through disruption of the standard hormonal regulation of the reproductive system, leading to changes in spermatogenesis and ultimately leading to decreased fertility.

Impact of Cushing's syndrome on the gonadotrope axis and testicular functions in men.

STUDY QUESTION: Does Cushing's syndrome (CS) differently affect the gonadotrope axis and testicular functions (GA/TF) according to the hypercortisolism intensity and underlying etiology? SUMMARY ANSWER: Endogenous cortisol excess caused by CS leads to varying degrees of hypogonadotropic hypogonadism (HH) with more severe GA/TF impairment and altered spermatogenesis in men with intense hypercortisolism associated with paraneoplastic/ectopic adrenocorticotrophic hormone (ACTH) secretion (EAS). WHAT IS KNOWN ALREADY: CS is very rarely studied in men due to its lower prevalence in men than in women. In a few old reports focusing exclusively on a limited number of men with Cushing's disease (CD), the occurrence of hypogonadism was reported. However, a detailed assessment of the impact of CS on the GA/TF in a significant series of patients has not been performed. Yet, hypogonadism could worsen CS-associated comorbidities such as osteoporosis and myopathy. To date, the full spectrum of GA/TF impairment in men with CS of different etiologies and intensity remains unknown. STUDY DESIGN, SIZE, DURATION: In this monocentric study, 89 men with CS diagnosed at a tertiary endocrine university center (Bicêtre, Paris Saclay) between January 1990 and July 2021 were evaluated and compared to 40 normal men of similar age. PARTICIPANTS/MATERIALS, SETTING, METHODS: The CS patient cohort of 89 men included 51 with CD, 29 with EAS and 9 with CS of adrenal origin i.e. (ACTH-independent CS (AI-CS)). They all had frank hypercortisolism, with increased 24 h-urinary-free cortisol (24 h-UFC) in two separate samples. A case-control study was performed focusing on pituitary gonadotrope function and testicular sex steroids and peptides. An additional set of six CS men had an evaluation including semen analysis. In a subgroup of 20 men with available data after CS remission, a longitudinal analysis was conducted to assess the reversibility of GA/TF defects. MAIN RESULTS AND THE ROLE OF CHANCE: Compared to controls, men with CS had significantly lower total testosterone (TT), bioavailable TT, and free TT (P < 0.0001). Hypogonadism, defined as serum TT levels <3.0 ng/ml, was present in 83% of men with EAS, in 61% of men with CD, and in 33% of men with AI-CS. Low-normal LH concentrations in the included men with hypercortisolism indicated HH. Serum sex hormone-binding globulin levels were moderately decreased in men with CD (P = 0.01 vs controls). Among the CS men, those with EAS had significantly lower TT, LH, and FSH levels than those with CD or AI-CS. When compared to controls, patients with EAS were the only group exhibiting a significant decrease in both serum FSH (P = 0.002) and the testicular peptides inhibin B (P < 0.0001) and anti-Müllerian hormone (P = 0.003). Serum INSL3 levels were significantly lower in men with CD than in the controls (P = 0.03). Of note, 24 h-UFC and ACTH were inversely and significantly associated with the majority of reproductive hormones including LH, FSH, TT, and inhibin B. Following successful curative therapy, reproductive assessment at a mean of 6.0 ± 4.3 years showed a significant increase in serum TT (P < 0.0001) and plasma LH (P = 0.02) levels, indicating a reversal of HH in 75% of the affected males. Among the six patients with available semen analysis, the two EAS cases exhibited a decrease in Sertoli cell peptides associated with a severe oligozoospermia, which completely normalized following removal of the source of hypercortisolism. LIMITATIONS, REASONS FOR CAUTION: The potential bias due to the retrospective design is counteracted by the analysis of the largest male CS cohort to date as well as the use of stringent inclusion and exclusion criteria. Due to the low number of patients with semen analysis in this study, further research is needed to unravel the full spectrum of spermatogenesis defects in men with CS. WIDER IMPLICATIONS OF THE FINDINGS: This work reveals the variable spectrum of reproductive impact in men with CS. We demonstrate that GA/TF impairment depends on the intensity of hypercortisolism which in turn is related to the underlying etiology. The causal link between hypercortisolism and GA/TF impairment was attested by its reversibility in most patients after CS remission. The wider implications of our findings lie in the potential generalization to a much commoner entity, iatrogenic CS due to chronic exposure to exogenous glucocorticoids. STUDY FUNDING/COMPETING INTEREST(S): Several research grants were attributed to J.Y.: (i) a grant from Programme Hospitalier de Recherche Clinique (PHRC # P081212 HYPOPROTEO); (ii) a grant from the French Association of Patients with Adrenal Diseases ('Association surrénales'); and (iii) independent Investigator Research Grants from HRA Pharma, Novartis and Recordati Pharma. A SICPA Foundation grant (Lausanne, Switzerland) allowed protected research time for G.E.P. The above sponsors were not involved in any part of the study. The authors have no competing or other conflicts of interest to declare. TRIAL REGISTRATION NUMBER: N/A.

Staining-free, Automated Sperm Analysis for In Vitro Fertilization Lab Use.

PURPOSE: Computer-aided sperm analysis is typically used in andrology labs, not in in vitro fertilization labs, which requires staining for sperm morphology measurement. In in vitro fertilization labs, sperm analysis still relies on manual observation and suffers from subjectivity and inconsistency. We developed a system for automated measurement of sperm concentration, motility, and morphology without the need for sperm staining. The reproducibility and reliability of the system were evaluated. MATERIALS AND METHODS: Thirty-five fresh semen and 25 washed samples were obtained from male partners attending for fertility investigations. Sperm concentration, motility, and morphology were automatically measured simultaneously, leveraging robust sperm tracking for concentration and motility measurement and low contrast image segmentation for morphology measurement of live sperm. Reproducibility of sperm measurements was evaluated by intraclass correlation coefficients. Reliability of sperm measurement was evaluated by Passing and Bablok regression analysis and Bland-Altman analysis. RESULTS: Automated measurement of concentration, motility, and morphology had intraclass correlation coefficients higher than 0.97. The regression and Bland-Altman analysis indicated that automated measurement and off-line manual benchmarking with zoomed-in images were interchangeable. Further analysis on semen and washed samples and the measurement on progressive and nonprogressive motility also showed high reproducibility and reliability. CONCLUSIONS: Automated sperm analysis revealed high reproducibility and reliability. The system is designed for routine use in in vitro fertilization labs to perform quantitative sperm analysis on live samples.

The relationship of total progressive motile sperm count with the outcome of IUI? An analysis of 5171 cycles.

Background: The role of motile sperm count in intrauterine insemination (IUI) success rate is controversial. This retrospective cohort study performed among unselected infertile couples undergoing IUI was to explore the association between the total progressive motile sperm count (TPMSC) and the live birth rate (LBR) following IUI.Methods: The total cohort of 5363 cycles, 2666 infertile couples between January 2015 and December 2018 and finally 5171 cycles, 2647 couples were included for analysis in Sun Yat-sen memorial hospital of Sun Yat-sen University. The primary outcome was LBR per cycle. And the secondary outcome measure was clinical pregnancy rate (CPR) per cycle.Results: From the receiver operating characteristic (ROC) analysis of female age predicting live birth, female age cutoff was defined as 28 years. With a female age of ≤28 years, the CPRs were 11.5%, 14.9%, 16.1%, and 15.8% in quartile groups of pre-wash TPMSC, respectively. For the LBRs the values were 9.4%, 12.9%, 14.4%, and 11.3%, and there were also no significant differences in quartile groups of pre-wash TPMSC with ≤24 million (M), [24M-50M], [50M-97M], >97M. No statistically significant differences in the CPRs (p = .051) and LBRs (p = .088) were also observed in the quartiles groups of post-wash TPMSC. With a female age of >28 years, the CPR in couples with post-wash TPMSC ≤22.32 M was significantly lower than with post-wash TPMSC >81.0 M (p = .007). There was an obvious trend in which CPRs and LBRs increased with the post-wash TPMSC during the <81 M interval in women >28 years.Conclusions: The optimal female age cutoff for live birth was 28 years in IUI cycles. Pre-wash and post-wash TPMSC were not significantly associated with CPR and LBR per cycle. When female age >28 years, there was a better outcome with post-wash TPMSC >22.32 million.

Iron oxide nanoparticles reversibly affect sperm quality in Wistar rats.

Iron oxide nanoparticles (IONP) are being utilised for various biomedical applications due to their unique properties like superparamagnetism and greater colloidal stability. Interaction of IONP with male reproductive system is underrepresented in the literature. Current study strives to demonstrate the effects of IONP on sperm quality, reproductive hormones and fertility of adult Wistar rats. Spherical IONP with 15-20 nm size were injected for a maximum of 60 days in three different exposure schemes. Three increasing doses (20, 40 and 80 mg/kg) along with a control group were tested. Sperm count, sperm viability, motility and morphology were scored after the experimental periods. A group of rats was used to examine male fertility. Concentrations of male reproductive hormones in serum were also measured in all groups. Total sperm count and motility was significantly decreased in treated groups in comparison to control after 60 days of exposure. Changes in sperm viability and sperm morphology mostly proved to be statistically insignificant. Serum concentrations reproductive hormones like testosterone, luteinizing hormone and follicular stimulating hormone varied insignificantly between control and treatment groups. Male fertility was also not affected due to the exposure. Further, it is also reported that a 45-day recovery period restores the sperm quality up to a considerable extent. Overall, the study demonstrates that long term exposure of IONP has adverse effects on male sperm production and function that can be reversed if exposure is withdrawn.

A mixture of pyrethroids induces reduced fecundity and increased testicular genotoxicity in rats.

To achieve crop protection and higher agricultural yield, pesticides are used; and among them pyrethroid based ones are the most preferred choice because of their specificity on the pests. Uncontrolled use of pesticides resulted in contamination of food products. Presence of residual amounts of pyrethroids was reported in agricultural products sold in Indian market, indicating that humans are constantly exposed to these chemicals through food on a routine basis. Studies that determine the toxic effects of pyrethroids at doses equivalent to human exposure are rare. We orally administered a mixture of pyrethroids (detected in the rice and vegetables of Indian market) to male rats for 15 months to mimic the long-term exposure in humans. We observed reduced fecundity, sperm count and 13ß-hydroxysteroid dehydrogenase enzyme activity. The serum concentrations of hormones involved in male reproductive function were altered. Further, testicular genotoxicity as reflected by perturbations in the expression pattern of genes involved in the molecular processes of gametogenesis was evident. Such toxic effects may also be occurring in humans who consume agricultural products that contain residual amounts of pyrethroids on a regular basis throughout their lifetime.

Genistein lowers fertility with pronounced effect in males: Meta-analyses on pre-clinical studies.

Genistein, an isoflavonoid, is found in a plethora of plant-based foods, and has been approved for use in various therapies. A couple of studies in adult men observed a negative correlation between genistein exposure and reproductive parameters. To assess the effects of genistein exposure on reproduction and fertility in males and females, we performed quantitative meta-analyses by pooling data from published studies on animals that assessed various reproductive parameters. Pooled analysis showed significant decreases in sperm count in males exposed to genistein during adulthood (Hedges's g = -2.51, p = 0.013) and in utero (Hedges's g = -0.861, p = 0.016) compared with controls. In males exposed to genistein in utero, serum testosterone levels decreased (Hedges's g = -6.301, p = 0.000) and luteinizing hormone (LH) (Hedges's g = 7.127, p = 0.000) and FSH (Hedges's g = 6.19, p = 0.000) levels increased in comparison with controls. In females, the number of corpora lutea (Hedges's g = -2.103, p = 0.019) and the litter size (Hedges's g = -1.773, p-value = 0.000) decreased; however, female reproductive hormones remained unaffected. These meta-analyses show that genistein has detrimental effects on male reproductive system and on the progression and sustenance of pregnancy, with more pronounced adverse impact in males, particularly when exposed in utero.

Optimizing pregnancy outcomes in intrauterine insemination cycles by stratifying pre-wash total motile count and patient-specific factors: a patient counseling tool.

PURPOSE: The purpose of this study is to clarify which pre-wash total motile count are associated with improved clinical pregnancy rate (CPR) and live birth rate (LBR) based on maternal age, AMH level, stimulation regimen, and infertility diagnosis. METHODS: This was a retrospective cohort study of first completed IUI cycles at two academic fertility centers from 5/2015 to 9/2019. Cycles were stratified by pre-wash TMC, maternal age, AMH level, stimulation regimen, and infertility diagnosis. The primary outcome was CPR and secondary outcomes were live birth and miscarriage. RESULTS: One thousand one hundred fifty-four cycles were analyzed. Of the 162 cycles that resulted in a CPR (14.0%), most had an insemination TMC > 20 million. Compared to TMC > 20 million, there was no difference in CPR or LBR for lower TMC categories, excluding the TMC < 2 million group, in which there were no pregnancies. When TMC was stratified by deciles, there was also no difference in CPR and LBR, including within the lowest decile (TMC 0.09-8.6 million). Younger age and higher ovarian reserve parameters were associated with higher pregnancy and LBR when stratified by TMC. There was no difference in pregnancy and LBR when considering different stimulation protocols. CONCLUSIONS: Our data suggest that pregnancy and LBR are equivalent above a TMC of 2 million. Data stratified by TMC and patient parameters can be used to counsel patients pursuing ART.

Is controlled ovarian stimulation and insemination an effective treatment in older women with male partners with decreased total motile sperm counts?

OBJECTIVE: To assess the effect of the total motile sperm counts (TMSC) on the success of controlled ovarian stimulation (COH) and intra-uterine insemination (IUI) in women 38-42 years of age. STUDY DESIGN: A database of all women aged 38-42 years who underwent IUI with stimulation at a University Reproductive Centre between 2009 and 2018 inclusive was developed. Including stimulation with clomiphene citrate, letrozole or gonadotropins and divided into TMSC 5.00-10.0 mil and < 5.00 mil. Statistics were compared with multivariate logistic regression, t tests or Chi-squared tests. RESULTS: A total of 397 cycles of IUI in 397 patients were included, of which, 190 cycles with TMSC 5.00-10.0 and 207 cycles with TMSC < 5.00. There were no statistical differences in the baseline characteristics between the two groups including: age (P = 0.2), gravidity (P = 0.7), parity (P = 0.6), basal FSH (P = 0.2), basal E2 (P = 0.4), antral follicular count (P = 0.5) and the number of mature follicles stimulated (P = 0.2). As expected, TMSC was 7.6 ± 1.5 mil in the first group and 2.4 ± 1.6 mil in the second group (P < 0.0001). The clinical pregnancy rate per cycle in the 5.01-10.00 TMSC group was 9.5 vs. 3.4% when TMSC < 5.00 (P = 0.01). When evaluating only women 40-42 years of age (99 women in the 5.00-10.00 TMSC group and 95 in the group of TMSC < 5.00); the pregnancy rates were not statistically different between the two groups (7 vs. 7.3%, P = 1), nor was the clinical pregnancy rate (5 vs. 6.3%, P = 0.7). CONCLUSIONS: Women 38-39 years of age have poorer outcomes at COH/IUI when TMSC < 5 million than if it is 5-10 million. Once a woman is 40 years of age, this effect is lost. With TMSC 5-10 million, women 38-39 years of age have respectable outcomes at COH/IUI. Clinical pregnancy rates are very low in women 40 years of age with TMSC ≤ 10 million or 38-39 years old with TMSC < 5 million and other treatments should be offered.

Association of linear type pelvic traits with testicular characteristics and reproductive capability of breeding dairy bulls.

Associations of pelvic linear type traits (PLT) on production and reproduction of cows were widely documented; in contrast, importance of PLT on bulls' reproductive ability, semen quality, semen cryo-preservability, frozen semen doses (FSD) production etc. was inadequately reported. The present study was conducted on Frieswal bulls (N = 378, age: 6-91 months, m) to assess age-wise growth dynamics of pelvic dimensions, classifying age into 6 groups (6 m, 7-12 m, 13-24 m, 25-36 m, 37-48 m, >48 m). Iso-age group bulls' (N = 100; 25-36 m) records were analysed after classifying seasons (summer/rainy/winter) of semen collection, if pelvic morphometric traits had any practical associations with testicular traits, semen quality and FSD production or not. A discriminant function was developed based on PLT, which showed poor predictive ability to distinguish FSD/non-FSD category bulls. Age significantly influenced growth and dimensions of gonadal and external pelvic morphometry traits. The dimensions of PLT increased at higher rate up to 36 m age and thereafter enhancement became insignificant. Pelvic linear type traits were positively (p < .01) associated with testicular/scrotal traits. Among PLT studied, pelvic triangle area (PTA) was the strongest discriminating variable to distinguish between good and poor breeding bulls. Bulls of larger PTA (≥1000 cm2 ), at average 30 m age, produced relatively inferior-quality semen, viz. lower volume (-3%), sperm concentration (-48 × 106 /mL), motility, semen quality index, total sperm counts/ejaculate (-601 × 106 ), motile sperm counts/ejaculate (-474 × 106 ) and total post-thaw motile sperm counts (-226 106 ), than bulls of lesser PTA (<1000 cm2 ). It was concluded that external PTA could be a useful addition to the bulls' breeding soundness evaluation.

Beneficial Effect of Methanolic Extract of Frankincense (Boswellia Sacra) on Testis Mediated through Suppression of Oxidative Stress and Apoptosis.

Boswellia sacra oleo gum resin (Burseraceae) commonly known as frankincense is traditionally used in many countries for its beneficial effect on male fertility. This study explores its effect on the male reproductive system after a 60-day repeated administration at two different doses to rats (in vivo) and on human Leydig cells (in vitro). The methanolic extract of B. sacra was analyzed for the presence of various constituents by preliminary phytochemical analysis and gas chromatography-mass spectrometry (GC-MS) while quantitative analysis of boswellic acids was done by high-performance liquid chromatography (HPLC). Administration of B. sacra extract to rats elevated the serum testosterone levels with an associated reduction in serum levels of FSH and LH. An increase in the activity of antioxidant enzymes, superoxide dismutase and catalase, was seen. A dose-dependent increase in the sperm count and sperm motility was also observed. The in vivo results were supported by changes in the expression of the Bcl-2 gene and caspase-3 gene in human Leydig cells in vitro. The results of this study support the traditional use of B. sacra to increase male fertility.

[Seasonal variations influenced the semen quality of the sperm donor in Beijing area].

OBJECTIVE: To investigate the change trends of sperm quality with seasonal variations among the volunteers of sperm donors in Beijing area, as well as the relationship between two parameters. METHODS: Semen data from the volunteers of sperm donors in Human Sperm Bank of Peking University Third Hospital were collected using a retrospective study method. The subjects were divided into 4 seasonal groups based on the lunar solar terms and the time of sperm donation. The data were assessed to find whether there were differences in semen parameters among different seasonal groups, and to analyze the change trends and the influence of seasonal factors on semen parameters. RESULTS: A total of 21 174 semen parameter data were analyzed. Firstly, to analyze all data as a whole, in spring, summer, autumn and winter groups, sperm concentration was (106.04±59.67)×106/mL, (97.61±47.41)×106/mL, (100.18±47.17)×106/mL, (100.59±38.68)×106/mL, respectively, and the spring group was significantly higher than the other 3 seasonal groups (P < 0.001); proportion of progressive motility sperm (PR) was 56.49%±12.76%, 58.02%±13.65%, 58.05%±12.36%, and 57.66%±12.61%, respectively, spring group was lower than the other three seasonal groups, and summer group was better among the latter (P < 0.001). There was no difference in normal rate of sperm morphology among the four seasonal groups. The qualified rate of sperm donors in the winter group was higher than that in the other three seasons groups (P < 0.01), while the qualified rate in the summer group was lower than that in the other three seasons groups. In addition, the semen parameters of the volunteers during the screening period and the official sperm donation period were analyzed respectively, which revealed that sperm concentration of spring group was higher than that of summer and winter groups, and PR was lower than that of summer and autumn groups. On account of the semen parameters of official sperm donation period, multiple linear regression analysis found that season was the main factor affecting sperm concentration, the average sperm concentration in spring group was about 6×106/mL higher than in winter group, but PR was 2.9% lower in spring group compared with autumn group (all P < 0.05). CONCLUSION: Season was the influencing factor of semen quality of sperm donors in Beijing area. We recommend spring and winter may be the preferred seasons for sperm donation.

Effects of antioxidant co-supplementation therapy on spermatogenesis dysfunction in relation to the basal oxidation-reduction potential levels in spermatozoa: A pilot study.

Purpose: In this pilot study, the authors compared the effects of antioxidant co-supplementation therapy and methylcobalamin therapy in patients with impaired semen quality. Methods: Eighty-four subjects who visited male infertility clinics and showed abnormal semen test results were randomly subjected to one of the two therapies: antioxidant co-supplementation therapy with vitamin C, vitamin E, coenzyme Q10, and flaxseed oil or methylcobalamin therapy. The oxidation-reduction potential (ORP) and 8-hydroxy-2'-deoxyguanosine levels were used as indicators of oxidative stress levels in semen. Semen analysis was also performed. Results: The authors obtained results from 67 patients who had completed 3 months of treatment. Neither antioxidant co-supplementation therapy nor methylcobalamin therapy changed the semen parameters significantly (except for the sperm concentration, which was increased by the latter therapy). When the pre-treatment ORP value in semen was higher than the cutoff value, both therapies significantly increased the sperm concentration. The 8-hydroxy-2'-deoxyguanosine level did not yield any meaningful predictive value with regard to increased sperm concentrations. Conclusions: Both antioxidant co-supplementation therapy and methylcobalamin therapy increased the sperm concentration in patients with impaired semen quality when the basal ORP levels in their semen were elevated.

Do the Covid-19 vaccines affect the reproductive parameters of men?-A Northern Saudi experience.

Background: The COVID-19 vaccine acceptance is a psychological behavior influenced by many factors, including fear of an adverse effect on the reproductive system. Aims: The aim of this study is to assess the COVID-19 vaccines effect on reproductive parameters among the male population of northern Saudi Arabia. Patients and Methods: We conducted a prospective cohort study among 100 volunteers who received two doses of COVID-19 vaccines. A pre- and post-vaccination blood sample was collected and analyzed for testosterone, prolactin, and follicle-stimulating hormone (FSH). Semen samples were also collected and analyzed. The Wilcoxon signed-rank test was used to compare the values between pre- and post-vaccination. Results: Of the 100 samples analyzed, there was a significant increase in progressive sperm motility after the second dose of vaccination, but the increase was within the physiological limits (pre-55.03 [42.00-61.75] vs. post-57.50 [42.25-63.00], P = 0.008). Similarly, a significant increase in serum testosterone level after the second vaccination dose was observed (pre-380.65 [301.60-485.73] vs. post-410 [318.18-505.35], P = 0.016). Conclusion: These preliminary results show that the COVID-19 vaccines do not have any adverse effect on the reproductive parameters of men. A prospective long-term follow-up study will be necessary on all WHO -approved COVID vaccines to determine their long-term effect on men's reproductive health. The future follow-up study could strengthen our findings and encourage the men who have vaccine hesitancy to take due to fear of its effect on reproductive parameters.

Total Motile Sperm Count in Adolescent Boys with Varicocele is Associated with Hormone Levels and Total Testicular Volume.

PURPOSE: The risk factors for future infertility in adolescents with varicocele are controversial, and little is known about the association between hormone levels and semen parameters. Semen analysis is likely the closest marker of fertility but may be difficult to obtain in some boys secondary to personal, familial or religious reasons. Identifying other clinical surrogates for abnormal semen parameters may offer an alternative for assessing varicocele severity in these boys. We hypothesized that hormone levels and total testicular volume are predictive of abnormal total motile sperm count. MATERIALS AND METHODS: We retrospectively reviewed Tanner 5 boys with palpable left varicoceles who underwent a semen analysis and had serum hormone levels tested (luteinizing hormone, follicle-stimulating hormone, inhibin B, anti-müllerian hormone and/or total testosterone) within a 6-month period. Total testicular volume was also calculated. Abnormal total motile sperm count was defined as <9 million sperm per ejaculate. RESULTS: A total of 78 boys (median age 17.2 years, IQR 16.5-18.0) were included. Luteinizing hormone, anti-müllerian hormone and total testosterone were not correlated with any semen analysis parameter. There was a negative correlation between follicle-stimulating hormone and total motile sperm count (ρ -0.35, p=0.004) and positive correlation between inhibin B and total motile sperm count (ρ 0.50, p <0.001). Total testicular volume was significantly positively correlated with total motile sperm count (ρ 0.35, p=0.01). ROC analyses revealed an optimal follicle-stimulating hormone cutoff of 2.9, an optimal inhibin B cutoff of 204 and an optimal total testicular volume cutoff of 34.4 cc to predict abnormal total motile sperm count. CONCLUSIONS: Total motile sperm count is inversely associated with follicle-stimulating hormone levels, and directly associated with inhibin B levels and total testicular volume. Optimized cutoffs for serum follicle-stimulating hormone, inhibin B and total testicular volume may prove to be reasonable surrogates for total motile sperm count in boys who defer semen analysis for personal or religious/cultural reasons.

Can a Low Sperm Concentration without Assessing Motility Confirm Vasectomy Success? A Retrospective Descriptive Study.

PURPOSE: A fresh post-vasectomy semen analysis showing 100,000 nonmotile sperm/mL or less confirms sterility. Mailed sample or self-testing at home with SpermCheck® Vasectomy decreases the inconvenience of producing a fresh sample, but without assessing motility. We evaluated if there is a sperm concentration under which no motile sperm are observed that could fortify the use of these alternatives. MATERIALS AND METHODS: We conducted a study of post-vasectomy semen analyses performed at the andrology laboratory of the Quebec City university hospital, Canada. Sperm concentration and motility were assessed on fresh noncentrifuged 10 µL samples at 400× magnification. We calculated the proportion of post-vasectomy semen analysis showing motile sperm according to sperm concentration for all and first prescribed post-vasectomy semen analysis by the 5 physicians who performed the most vasectomies. RESULTS: We identified 6,492 post-vasectomy semen analyses prescribed by 169 physicians. The 5 vasectomists prescribed 95.6% (6,204) of the post-vasectomy semen analyses; 96.1% (5,965) were first tests. We observed motility in all sperm concentration strata but it decreased with lower concentrations. At the first post-vasectomy semen analysis, among patients with less than 1 million, 250,000 and 100,000 sperm/mL, 0.5% (27/5,842) and 0.3% (19/5,760 and 17/5,725) had motility, respectively. CONCLUSIONS: If the first post-vasectomy semen analysis on a mailed sample shows less than 1 million sperm/mL, we recommend requesting an additional mailed sample instead of a fresh sample. SpermCheck Vasectomy could falsely indicate a successful vasectomy in a very small proportion of cases. The optimal post-vasectomy semen analysis strategy must involve shared decision making, balancing the inconvenience of providing a fresh sample with the risk of a false-negative result.

Semen parameter thresholds and time-to-conception in subfertile couples: how high is high enough?

STUDY QUESTION: What thresholds for total sperm count, sperm concentration, progressive motility, and total progressive motile sperm count (TPMC) are associated with earlier time-to-conception in couples undergoing fertility evaluation? SUMMARY ANSWER: Values well above the World Health Organization (WHO) references for total sperm count, concentration, and progressive motility, and values up to 100 million for TPMC were consistently associated with earlier time-to-conception and higher conception rates. WHAT IS KNOWN ALREADY: Although individual semen parameters are generally not able to distinguish between fertile and infertile men, they can provide clinically useful information on time-to-pregnancy for counseling patients seeking fertility treatment. Compared to the conventional semen parameters, TPMC might be a better index for evaluating the severity of male infertility. STUDY DESIGN, SIZE, DURATION: We used data from a longitudinal cohort study on subfertile men from 2002 to 2017 and included 6061 men with initial semen analysis (SA) in the study. PARTICIPANTS/MATERIALS, SETTING, METHODS: Men from subfertile couples who underwent a SA within the study period were included, and 5-year follow-up data were collected to capture conception data. Couples were further categorized into two subgroups: natural conception (n = 5126), after separating those who achieved conception using ART or IUI; natural conception without major female factor (n = 3753), after separating those with severe female factor infertility diagnoses. TPMC was calculated by multiplying the semen volume (ml) by sperm concentration (million/ml) and the percentage of progressively motile sperm (%). Cox proportional hazard models were used to report hazard ratios (HRs) with 95% CIs before and after adjusting for male age, the number of previous children before the first SA, and income. Using the regression tree method, we calculated thresholds for total sperm count, sperm concentration, progressive motility, and TPMC to best differentiate those who were more likely to conceive within 5 years after first SA from those less likely to conceive. We also plotted continuous values of semen parameters in predicting 5-year conception rates and time-to-conception. MAIN RESULTS AND THE ROLE OF CHANCE: Overall, the median time to conception was 22 months (95% CI: 21-23). A total of 3957 (65%) couples were known to have achieved conception within 5 years of the first SA. These patients were younger and had higher values of sperm concentration, progressive motility, and TPMC. In the overall cohort, a TPMC of 50 million best differentiated men who were more likely to father a child within 5 years. Partners of men with TPMC ≥50 million had a 45% greater chance of conception within 5 years in the adjusted model (HR: 1.45; 95% CI: 1.34-1.58) and achieved pregnancy earlier compared to those men with TPMC < 50 million (median 19 months (95% CI: 18-20) versus 36 months (95% CI: 32-41)). Similar results were observed in the natural conception cohort. For the natural conception cohort without major female factor, the TPMC cut-off was 20 million. In the visual assessment of the graphs for the continuous semen parameter values, 5-year conception rates and time-to-conception consistently plateaued at higher values of sperm concentration, total sperm count, progressive motility, and TPMC compared to the WHO reference levels and our calculated thresholds. For TPMC, values up to 100-150 million were still associated with a better conception rate and time-to-conception in the visual assessment of the curves. LIMITATIONS, REASONS FOR CAUTION: There was limited information on female partners and potential for inaccuracies in capturing less severe female infertility diagnoses. Also we lacked details on assisted pregnancies achieved outside of our healthcare network (with possible miscoding as 'natural conception' in our cohort). We only used the initial SA and sperm morphology, another potentially important parameter, was not included in the analyses. We had no information on continuity of pregnancy attempts/intention, which could affect the time-to-conception data. Finally, most couples had been attempting conception for >12 months prior to initiating fertility treatment, so it is likely that we are underestimating time to conception. Importantly, our data might lack the generalizability to other populations. WIDER IMPLICATIONS OF THE FINDINGS: Our results suggest that a TPMC threshold of 50 million sperm provided the best predictive power to estimate earlier time-to-conception in couples evaluated for male factor infertility. Higher values of sperm count, concentration and progressive motility beyond the WHO references were still associated with better conception rates and time-to-conception. This provides an opportunity to optimize semen parameters in those with semen values that are low but not abnormal according to the WHO reference values. These data can be used to better inform patients regarding their chances of conception per year when SA results are used for patient counseling. STUDY FUNDING/COMPETING INTEREST(S): None. TRIAL REGISTRATION NUMBER: N/A.

Temporal trends in semen concentration and count among 327 373 Chinese healthy men from 1981 to 2019: a systematic review.

STUDY QUESTION: Are there temporal trends of sperm concentration (SC) and total sperm count (TSC) in Chinese healthy males from 1981 to 2019? SUMMARY ANSWER: Our result indicated a temporal decrease in SC and TSC among 327 373 healthy Chinese men in the recent four decades. WHAT IS KNOWN ALREADY: A review of 61 papers reported a temporal decline in SC and TSC from 1938 to 1990. This trend was later confirmed by a systematic review of 185 published papers from 1981 to 2013. However, the majority of the included individuals were from western countries. In China, whether SC and TSC have declined remains controversial. STUDY DESIGN, SIZE, DURATION: This systematic review of published articles used data extracted from Pubmed, Science Direct, Embase, China-National-Knowledge-Infrastructure (CNKI) and Wanfang Data to assess changes in SC and TSC in China from 1981 to 2019. PARTICIPANTS/MATERIALS, SETTING, METHODS: A total of 111 studies including 327 373 individuals who provided semen samples from 1981 to 2019 were extracted for the present analysis. Study selection and data extraction were performed by two independent researchers. The trends in SC and TSC were analysed using liner-regression and meta-regression before and after adjusting for potential covariates. Moreover, subgroups, categorised based on geographic region, fertility status or recruitment source, were also analysed. MAIN RESULTS AND THE ROLE OF CHANCE: SC declined significantly (slope liner-regression = -0.748 million/ml/year; P = 0.005; slope meta-regression = -0.824 million/ml/year; P < 0.001) between 1981 and 2019 in China. Trends for TSC was similar to that for SC (slope liner-regression = -2.073 million/year; P = 0.032; slope meta-regression = -2.188 million/year; P = 0.003). In subgroup meta-regression analyses, males with definite fertility had continuous declines in SC (slope northern group=-2.268, P = 0.009; slope southern group=-1.014, P = 0.009) and TSC (slope northern group=-9.675, P = 0.010; slope southern group=-3.215, P = 0.042). However, in the unselected group, where fertility status was unknown, the obvious downward trend in SC was only seen in males from Northern regions (slope = -0.836, P = 0.003). Another subgroup analysis demonstrated that obvious decreases in SC (slope = -1.432, P < 0.001) and TSC (slope=-4.315, P = 0.001) were only seen in volunteer groups but not in pre-pregnancy examination groups and other recruitment groups. The results changed minimally in multiple sensitivity analyses. LIMITATIONS, REASONS FOR CAUTION: The validity of the meta-analysis results was limited mainly by the quality of the included studies. Additionally, our study spanned many decades and the recommended criteria for some semen parameter assessments have significantly changed, which may bring about some unavoidable bias. Moreover, the data remain insufficient especially in some provinces of China. WIDER IMPLICATIONS OF THE FINDINGS: The present study is the first study to report significant decreases in SC and TSC in 327 373 healthy Chinese men between 1981 and 2019, indicating a serious reproductive health warning. Further studies on the causes of the declines are urgently needed. STUDY FUNDING/COMPETING INTEREST(S): D.Z. is supported by the National Natural Science Funding of China, Natural Science Funding of Shaanxi Province, Science Funding of Health Department, Shaanxi Province, Fundamental Research Funds for the Central University and the Project of Independent Innovative Experiment for Postgraduates in Medicine in Xi'an Jiaotong University. The authors have no conflicts of interests to declare. TRIAL REGISTRATION NUMBER: N/A.