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Spermatogenic Activity (spermatogenic + activity)

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Medical Sciences75%

Selected Abstracts

Testosterone-immunopositive primordial germ cells in the testis of the bullfrog, Rana catesbeiana

JOURNAL OF ANATOMY, Issue 6 2005
E. Sasso-Cerri
Abstract In amphibia, steroidogenesis remains quiescent in distinct seasonal periods, but the mechanism by which spermatogenesis is maintained under low steroidogenic conditions is not clear. In the present study, testosterone location in the testes of Rana catesbeiana was investigated immunohistochemically during breeding (summer) and nonbreeding (winter) periods. In winter, the scarce interstitial tissue exhibited occasional testosterone immunopositivity in the interstitial cells but the cytoplasm of primordial germ cells (PG cells) was clearly immunopositive. By contrast, in summer, PG cells contained little or no immunoreactivity whereas strong immunolabelling was present in the well-developed interstitial tissue. These results suggest that PG cells could retain testosterone during winter. This androgen reservoir could be involved in the control of early spermatogenesis in winter and/or to guarantee spermiogenesis and spermiation in the next spring/summer. The weak or negative immunoreaction in the summer PG cells might reflect consumption of androgen reservoir by the intense spermatogenic activity from spring to summer. Thus, besides acting as stem cells, PG cells of R. catesbeiana could exert an androgen regulatory role during seasonal spermatogenesis. [source]

Clinical evaluation of spermatogenic activity of processed Shilajit in oligospermia

ANDROLOGIA, Issue 1 2010
T. K. Biswas
Summary The safety and spermatogenic activity of processed Shilajit (PS) were evaluated in oligospermic patients. Initially, 60 infertile male patients were assessed and those having total sperm counts below 20 million ml,1 semen were considered oligospermic and enrolled in the study (n = 35). PS capsule (100 mg) was administered twice daily after major meals for 90 days. Total semenogram and serum testosterone, luteinising hormone and follicle-stimulating hormone were estimated before and at the end of the treatment. Malondialdehyde (MDA), a marker for oxidative stress, content of semen and biochemical parameters for safety were also evaluated. Twenty-eight patients who completed the treatment showed significant (P < 0.001) improvement in spermia (+37.6%), total sperm count (+61.4%), motility (12.4,17.4% after different time intervals), normal sperm count (+18.9%) with concomitant decrease in pus and epithelial cell count compared with baseline value. Significant decrease of semen MDA content (,18.7%) was observed. Moreover, serum testosterone (+23.5%; P < 0.001) and FSH (+9.4%; P < 0.05) levels significantly increased. HPLC chromatogram revealed inclusion of PS constituents in semen. Unaltered hepatic and renal profiles of patients indicated that PS was safe at the given dose. The present findings provide further evidence of the spermatogenic nature of Shilajit, as attributed in Ayurvedic medicine, particularly when administered as PS. [source]

The presence of germ cells in the semen of azoospermic, cryptozoospermic and severe oligozoospermic patients: stringent flow cytometric analysis and correlations with hormonal status

CLINICAL ENDOCRINOLOGY, Issue 5 2007
C. H. Yeung
Summary Objective, To understand the clinical significance of immature germ cells commonly found in ejaculates with low sperm counts by a novel and stringent flow cytometric quantitative method. Patients/measurements, A total of 65 azoospermic, 38 cryptozoospermic and 42 severe oligozoospermic patients underwent routine hormone and semen analysis. Cells from each ejaculate were stained for DNA and mitochondria and analysed as spermatozoa (HC), round spermatids (1N), primary spermatocytes (4N) or diploid cells (2N). Results, About 90% of HC particles were eliminated as contaminants of the spermatozoa population by the analysis of their laser light scatter pattern and mitochondria staining intensity. Ploidy identification accuracy was improved by selection of singlets and elimination of cell aggregates for analysis. Distribution peaks for HC, 1N and 4N cells were displayed in 53%, 56% and 25% ejaculates, respectively, with prevalence in severe oligozoospermia > cryptozoospermia > azoospermia. 1N cell numbers were correlated with 4N and HC cells. For HC and 1N cells, the number/ejaculate and the incidence of distribution peaks were correlated with serum testosterone levels, and inversely with FSH for HC, 1N and 4N cells, suggesting that the abnormal shedding of 1N and 4N germ cells is the consequence rather than the cause of spermatogenic failure in these patients. Ploidy data bear no association with clinical diagnosis except for Klinefelter patients. Conclusion, Whereas incidence of HC cells in azoospermic ejaculates may suggest minimal spermatogenic activity which evades detection by routine semen analysis, the presence of 1N and 4N cells in semen of patients provides noninvasive information about their spermatogenic status. [source]