Recognising the Sertoli-cell-only (SCO) syndrome: a case study.

Total Sertoli-cell-only (SCO) syndrome is often confused with a focal SCO picture, in which testicular illness caused damage to seminiferous tubules and compromised the Sertoli cell range of maturation and functions, but from which still some spermatozoa can be retrieved for assisted reproductive techniques. Here, a possibly new SCO syndrome phenotype is reported exhibiting complete lack of germ cells despite normal architecture of the seminiferous tubules with presence of mature Sertoli cells and normal Leydig cells in the intertubular tissue. Sertoli cells are immunonegative for the prepubertal differentiation markers cytokeratin-18, anti-Muellerian hormone and M2A antigen, but reveal a positive signal for the gap junctional protein connexin 43 known to be expressed in Sertoli cells with an adult type of differentiation. The complete lack of germ cells in combination with fully differentiated adult-type Sertoli cells in this case is in contradiction with known SCO subtypes and with the current hypothesis of reciprocal regulation of Sertoli and germ cell differentiation.

Cumulative pregnancy rates after transfer of fresh and thawed embryos.

Frozen-thawed embryo transfer is an effective procedure that allows further possibilities of pregnancy in addition to those obtained after the fresh in vitro fertilization (IVF). In our follow-up study we analysed all fresh embryo transfer procedures and every frozen-thawed embryo transfer performed from January 2000 to December 2001 evaluating the cumulative pregnancy rates. The study population was divided into two groups according to the female age: <38 years (group I) and >38 years (group II). All the best embryos were chosen for transfer and all the supernumerary good quality embryos were cryopreserved on the day of transfer. The embryos were then thawed and manipulated using a new technique. In group I, 527 patients (619 cycles) underwent fresh embryo transfer and in 232 of them (238 cycles) the embryos were frozen (44% per patients and 38.4% per cycle). In group II, 156 patients (193 cycles) underwent fresh embryo transfer and in 14 of them (15 cycles) the embryos were frozen (9% per patient and 7.8% per cycle). The pregnancy rate of group I patients that had their supernumerary embryos frozen (232 patients and 238 cycles) was 47.4% per cycle and 48.7% per patient whereas in the same population of group II patients (14 patients and 15 cycles) the clinical pregnancy rate was 35.7% per cycle and 38.5% per patients. The cumulative clinical pregnancy rate after transfer of fresh and thawed embryos was: group I, 74% per cycle and 76% per patients; group II, 42.8% per cycle and 46.1% per patient. Frozen-thawed embryo transfer is a cost-effective practice.

In-vitro differentiation of germ cells from frozen testicular biopsy specimens.

In some men with germ cell maturation arrest, spermatogenesis can be resumed during in-vitro culture of testicular biopsy samples. In this study, we examined whether similar differentiation events can be induced in cultured germ cells from cryopreserved testicular biopsy specimens. Fresh and cryopreserved aliquots of the same testicular biopsy samples were cultured in medium supplemented with FSH and testosterone. After 24 and 48 h of culture, the progression of spermatogenesis and the percentage of Sertoli cells with DNA damage, detected by terminal deoxynucleotidyl transferase-mediated dUTP nick-end labelling (TUNEL), were evaluated. Spermatogenesis progressed in a similar way in fresh and cryopreserved aliquots over the first 24 h of culture. However, in contrast to fresh aliquots, no additional progress of spermatogenesis was detected between the 24 and 48 h time points. The percentage of TUNEL-positive Sertoli cells in fresh aliquots showed only a moderate increase after 24 h of culture, whereas most Sertoli cells from cryopreserved aliquots became TUNEL-positive during the same culture period. These data show that limited progression of spermatogenesis can be achieved by culturing cryopreserved testicular biopsy specimens for 24 h, but no additional benefit can be expected from prolonging the culture beyond this time point.

Low dose prednisolone administration in routine ICSI patients does not improve pregnancy and implantation rates.

BACKGROUND: Glucocorticoids have been used in conjunction with zona dissection to improve pregnancy and implantation rates in IVF patients. The aim of this prospective randomized study was to evaluate the effect of low-dose prednisolone in addition to the standard protocol, on pregnancy and implantation rates in routine ICSI patients before and after embryo replacement. METHODS: A total of 313 patients in 360 consecutive cycles (patients <39 years old and with three or less than three ICSI attempts) performed at our centre were randomly assigned by computer-generated list to receive either prednisolone (10 mg/day in two divided doses), starting on the first day of ovarian stimulation and continuing for 4 weeks (group A), or no treatment (group B). RESULTS: The mean age, number of previously failed IVF attempts, basal FSH levels and the mean rank of trials were comparable between groups A and B. The mean (+/- SD) number of metaphase II oocytes retrieved (11.9 +/- 5.5 versus 12.0 +/- 5.1), 2-pronuclei fertilization rate (67.2 versus 65.8%), the pregnancy and the implantation rates were not different between the study and control groups (49.0 and 23.6% versus 50.0 and 23.3% respectively). CONCLUSION: Low-dose prednisolone treatment in addition to the standard protocol before and after embryo replacement does not appear to have a significant effect on pregnancy or implantation rates.

Preincubation of human oocytes may improve fertilization and embryo quality after intracytoplasmic sperm injection.

The aim of this study was to examine the relationship between different preincubation periods of oocytes and the outcome of intracytoplasmic sperm injection (ICSI). We analysed retrospectively 95 ICSI treatment cycles performed to alleviate severe male-factor infertility. Oocyte collection was performed approximately 36 h after human chorionic gonadotrophin administration. The cumulus-corona-oocyte complexes obtained were incubated until the moment of ICSI. Fertilization, embryo development and implantation rates were analysed in four groups, which were divided according to the time lapse between oocyte retrieval and ICSI: group I, < or =3 h (18 cycles); group II, >3-< or =6 h (52 cycles); group III, >6-< or =9 h (14 cycles); and group IV, >9-< or =12 h (11 cycles). Immediately before ICSI the cumulus and corona cells were removed from the oocytes. A total of 723 metaphase II oocytes were injected: 126 from group I, 380 from group II, 126 from group III and 91 from group IV. The fertilization rates obtained were 52.3, 66.8, 65.1 and 69.2% respectively [P < 0.05 (using the chi2 test) between group I and groups II, III and IV]. Cleavage rates were similar in all groups (68.1, 69.7, 79.2 and 79.3% respectively), but the proportion of good quality embryos (< or =20% fragmentation) was significantly lower (P < 0.05) in group I (24.2%) compared with groups II (39.8%) and IV (39.6%). However, no statistically significant differences were observed between the four groups with regard to implantation rates (11.7, 13.2, 10.4 and 20.4% respectively). The results suggest that a preincubation period between oocyte retrieval and ICSI can improve the fertilization rate and embryo quality. This period might be necessary for some oocytes to reach full cytoplasmic maturity, leading to a higher activation rate upon microinjection.

Criteria predicting the absence of spermatozoa in the Sertoli cell-only syndrome can be used to improve success rates of sperm retrieval.

In patients with non-obstructive azoospermia, testicular sperm extraction (TESE) is a method of choice to recover spermatozoa as a male therapeutic approach in intracytoplasmic sperm injection (ICSI) programmes. However, the efficacy of TESE in this indication is burdened by a frequent failure of sperm recovery, which renders useless both the invasive testicular intervention and ovarian stimulation of the patient's spouse. One of the most frequent pathological pictures characterizing complete absence of spermatozoa is germinal aplasia (Sertoli cell- only syndrome or SCOS). Two different histological patterns of SCOS have been already described during the past five decades. These two patterns can be characterized as the congenital (pure) and the secondary (mixed) forms. Both patterns, with different prognosis to retrieve spermatozoa by therapeutic testicular biopsy, are frequently confused when TESE is performed during ICSI programmes. Useful criteria to predict the absence of spermatozoa can be obtained by a definite recognition of the two typical histological patterns during the diagnostic testicular biopsy. The diagnosis of congenital or acquired SCOS can be refined by endocrine, chemical, immunohistochemical and molecular biology aids. Reduction of both sperm retrieval failure and unnecessary ovarian stimulation can be achieved by combination of these methods.

Reproductive capacity of spermatozoa from men with testicular failure.

Controversial reports have been published about the influence of sperm source and of the underlying testicular pathology on success rates of intracytoplasmic sperm injection (ICSI). In this controlled study, ICSI treatment cycles with testicular spermatozoa from men with obstructive and non-obstructive azoospermia were compared with ICSI ejaculated sperm cycles with semen parameters < or = 5 x 10(6)/ml and < or = 10% progressive motility. The control cases were matched for female age, rank of trial, female basal follicle-stimulating hormone serum concentrations and close proximity to the study group's procedure. The fertilization, cleavage, pregnancy and abortion rates were similar in matched groups irrespective of the type of azoospermia. However, the implantation rate in the non-obstructive azoospermic patient group was significantly lower than that in the matched ejaculated sperm group (13.4% versus 26%, P = 0.05). On the other hand, no impairment of the implantation rate was observed in the obstructive azoospermic patient group. These data show that testicular pathology has a negative impact on reproductive performance of testicular spermatozoa, resulting in a decreased implantation potential without any apparent effect on fertilization and early preimplantation development.