Outcome of testicular sperm retrieval procedures in non-obstructive azoospermia: percutaneous aspiration versus open biopsy

The aim of this study was to evaluate whether the extraction of testicular spermatozoa with percutaneous versus open biopsy has an effect on the treatment outcome with intracytoplasmic sperm injection (ICSI) in men with non-obstructive azoospermia. Regardless of testicular size, follicle stimulating hormone concentration, and previous biopsy result, percutaneous testicular sperm aspiration (PTSA) using a 21-gauge butterfly needle was attempted first and if this failed testicular sperm extraction (TESE) was performed. In 63 men spermatozoa were found with PTSA whereas in 228 men TESE had to be undertaken. More men in the PTSA group had previously been diagnosed with hypospermatogenesis (82 versus 50%). Compared with the PTSA group, more men in the TESE group had germ cell aplasia (27 versus 10%) or maturation arrest (22 versus 8%). There was no difference between the groups regarding mean age of men and their partners, duration of stimulation, oestradiol concentration on the day of human chorionic gonadotrophin, number of oocytes retrieved, fertilization rate, and embryo quality between the two groups. The number of embryos transferred (4.38 versus 3.90) was significantly higher in the PTSA group (P < 0.05), reflecting the increased number of embryos available for transfer. Implantation rate per embryo was 20.7% in the PTSA and 13.3% in the TESE group (P < 0.05). Clinical pregnancy rates were 46 and 29% in the PTSA and TESE groups respectively (P < 0.05). Clinical abortion rates were similar (21.2 versus 24%). It is concluded that in men with non-obstructive azoospermia, easier sperm retrieval, which is most likely indicative of a more favourable histopathology, is associated with higher implantation rates per embryo.     

Pregnancies after intracytoplasmic sperm injection with cryopreserved testicular spermatozoa

In 25 patients (14 suffering from obstructive azoospermia, sixfrom non-obstructive azoospermia, three from astheno-azoospermiaand two from absence of ejaculation) spermatozoa were extractedfrom testicular biopsies. Intracytoplasmic sperm injection (ICSI)with fresh testicular spermatozoa was performed in 18 cases;spermatozoa in excess were cryopreserved in pills. No pregnancieswere achieved. In the remaining seven patients, testicular spermatozoawere retrieved and cryopreserved during a diagnostic testicularbiopsy. After thawing, sperm motility was assessed in 17 cases(68%), and 18 ICSI with cryopreserved testicular spermatozoawere performed. The mean two-pronuclear (2PN) fertilizationrate was 59%, the mean cleavage rate was 92%, and six clinicalpregnancies were achieved, all of them still ongoing (pregnancyrate 33%). A comparison of the results of ICSI carried out withfresh or cryopreserved testicular spermatozoa showed that themean 2PN fertilization rates per cycle (53 compared with 55%),mean cleavage rates per cycle (99 compared with 96%) and embryoquality were not significantly different In conclusion, cryopreservationof testicular spermatozoa is feasible, even in patients withnon-obstructive azoospermia, and the results of ICSI with frozen-thawedtesticular spermatozoa are similar to those obtained using freshtesticular spermatozoa. Cryopreservation of testicular spermatozoamay avoid repetition of testicular biopsies to retrieve spermatozoafor successive ICSI cycles in patients in whom the only sourceof motile spermatozoa is the testicle.     

Fertilization, pregnancy and embryo implantation rates after ICSI in cases of obstructive and non-obstructive azoospermia

The aetiology of azoospermia can be grossly divided into obstructive and non-obstructive causes. Although in both cases testicular spermatozoa can be used to treat male fertility, it is not well established whether success rates following intracytoplasmic sperm injection (ICSI) are comparable. Therefore, a retrospective analysis of fertilization, pregnancy and embryo implantation rates was performed following ICSI with testicular spermatozoa in obstructive or non-obstructive azoospermia. In total, 193 ICSI cycles were carried out with freshly retrieved testicular spermatozoa; in 139 cases of obstructive and 54 cases of non-obstructive azoospermia. The fertilization rate after ICSI with testicular spermatozoa in non-obstructive azoospermia was significantly lower than in obstructive azoospermia (67.8% versus 74.5%; P = 0.0167). Within the non-obstructive group, the fertilization rate in the group of maturation arrest (47.0%) was significantly lower than in case of Sertoli cell-only (SCO) syndrome (71.2%) or germ cell hypoplasia (79. 5%). Embryo quality on day 2 after ICSI was similar for all groups. Pregnancy rates per transfer between obstructive (36.8%) and non-obstructive groups (36.7%) were similar. In cases of maturation arrest the pregnancy rate per transfer was lowest (20.0%) although not significantly different from SCO syndrome or hypoplasia groups. Embryo implantation rates were not different between the obstructive (19.6%) and non-obstructive groups (25.8%), and were lowest in cases of germ cell hypoplasia (15.8%). This retrospective analysis shows that although fertilization rate after ICSI with testicular spermatozoa in non-obstructive azoospermia is significantly lower than in obstructive azoospermia, pregnancy and embryo implantation rates are similar.     

Testicular biopty gun needle biopsy in collecting spermatozoa for intracytoplasmic injection, cryopreservation and histology.

Using testicular spermatozoa from either open biopsy (29 cycles) or biopty gun needle biopsy (49 cycles), a total of 81 intracytoplasmic sperm injection (ICSI) cycles among 57 couples were carried out from January, 1994 to September, 1997. In six cycles, no spermatozoa were obtained, and in three cycles spermatozoa from both needle and open biopsies were used. The fertilization (37% after open and 41% after needle biopsy) and pregnancy rates (29% per embryo transfer compared with 16% per embryo transfer) were similar after both open and needle biopsies. Five pregnancies were achieved among the 14 couples with non-obstructive azoospermia of the male partner, four of these after needle biopsy. It was possible to use cryopreserved testicular spermatozoa after both needle and open biopsies, and one pregnancy started after using cryopreserved testicular spermatozoa in both groups. Histological needle biopsy was carried out in 62 cases, and they were all diagnostic, giving 15-20 cross-sections of seminiferous tubuli per biopsy. Testicular needle biopsy using a 14 gauge biopsy needle gave a sufficient amount of tissue and spermatozoa for ICSI, cryopreservation and histology, even in non-obstructive azoospermia. This technique is simpler and cheaper than open biopsy and, hence, it can be regarded as the optimal method for the retrieval of testicular spermatozoa.     

Fertility with testicular sperm extraction and intracytoplasmic sperm injection in non-obstructive azoospermic men

In non-obstructive azoospermia spermatozoa can usually onlybe isolated from the testicles, and thus the most promisingtreatment model is testicular sperm extraction (TESE). Hormoneconcentrations, testicular volume determinations and testicularbiopsy results are not uniform enough to select potential candidatesfor successful TESE and intracytoplasmic sperm injection (ICSI)approaches in advance. The aim of this study was to assess theefficacy of using ICSI with testicular spermatozoa in casesof non-obstructive azoospermia and to compare the inclusioncriteria and sperm existence in the testicles in sperm obtainableand non-obtainable groups. All men showed either complete orincomplete (n = 14) maturation arrest in spermatogenesis, severehypospermatogenesis (n = 10) or Sertoli cell-only syndrome (n= 5) in their testicular biopsies. Only 14 out of a total of29 men provided enough spermatozoa for the ICSI procedure, whileno spermatozoa were found in the testicular samples of the remaining15 men. Out of 123 oocytes obtained from 14 females, 101 wereinjected with the husbands' testicular sperm cells. Total fertilizationfailure was observed in three cases. Of 39 oocytes fertilized,38 cleaved. The fertilization and cleavage rates were 38.6 and97.4% respectively. The pregnancy rate was 20.7% per initiatedcycle. In the group from whom spermatozoa were obtainable, thepregnancy rate was 42.9% per initiated cycle and 54.5% per embryotransfer. A total of six pregnancies were achieved, of whichtwo Were twins and four were singletons. One singleton pregnancyresulted in abortion in the first trimester. There was no statisticaldifference concerning the serum follicle stimulating hormoneconcentration, testicular volume and biopsy results in groupsin which spermatozoa were obtainable or not. In conclusion,although the association of TESE with ICSI obtained pregnanciesfor some patients with non-obstructive azoospermia, furtherstudies are needed to determine the inclusion criteria for successfulTESE.     

Fertilization and pregnancy outcome with intracytoplasmic sperm injection for azoospermic men

The evident ability of the intracytoplasmic sperm injection (ICSI) procedure to achieve high fertilization and pregnancy rates regardless of semen characteristics has induced its application with spermatozoa surgically retrieved from azoospermic men. Here, ICSI outcome was analysed in 308 cases according to the cause of azoospermia; four additional cycles were with cases of necrozoospermia. All couples were genetically counselled and appropriately screened. Spermatozoa were retrieved by microsurgical epididymal aspiration or from testicular biopsies. Epididymal obstructions were considered congenital (n = 138) or acquired (n = 103), based on the aetiology. Testicular sperm cases were assessed according to the presence (n = 14) or absence (n = 53) of reproductive tract obstruction. The fertilization rate using fresh or cryopreserved epididymal spermatozoa was 72.4% of 911 eggs for acquired obstructions, and 73.1% of 1524 eggs for congenital cases; with clinical pregnancy rates of 48.5% (50/103) and 61.6% (85/138) respectively. Spermatozoa from testicular biopsies fertilized 57.0% of 533 eggs in non-obstructive cases compared to 80.5% of 118 eggs (P = 0.0001) in obstructive azoospermia. The clinical pregnancy rate was 49.1% (26/53) for non-obstructive cases and 57.1% (8/14) for testicular spermatozoa obtained in obstructive azoospermia, including three established with frozen-thawed testicular spermatozoa. In cases of obstructive azoospermia, fertilization and pregnancy rates with epididymal spermatozoa were higher than those achieved using spermatozoa obtained from the testes of men with non-obstructive azoospermia.     

Diagnostic epididymal and testicular sperm recovery and genetic aspects in azoospermic men.

Various procedures for sperm recovery in azoospermic men have been described, from open testicular biopsy to simple needle aspiration from the epididymis and the testis. Fifty-one obstructive and 86 non-obstructive azoospermic men were treated to compare the recovery of spermatozoa obtained by percutaneous aspiration from the epididymis (PESA) and aspiration/extraction from the testis (TESA, TESE) with histopathology. If TESA failed, the work up proceeded with TESE. All patients were karyotyped. Spermatozoa were recovered by PESA or TESA in all obstructive men (51/51 patients). In 22 out of 86 patients with non-obstructive azoospermia, testicular spermatozoa could be successfully recovered by TESA. In five additional patients TESE was successful in recovering spermatozoa where TESA had failed. In 43 patients, neither TESA nor TESE was successful. Sixteen patients chose not to proceed with TESE. Seven out of 86 patients had an abnormal karyotype in the non-obstructive group (8%), none in the obstructive group. In the non-obstructive patient group testicular histopathology showed hypospermatogenesis, incomplete maturation arrest and germ cell aplasia with focal spermatogenesis in cases where spermatozoa were recovered and complete germ cell aplasia, complete maturation arrest and fibrosis in cases where no spermatozoa were found. Spermatozoa were recovered by PESA or TESA from all patients with obstructive azoospermia and from approximately 40% of patients with non-obstructive azoospermia by TESA or TESE. Retrieval of viable spermatozoa in the infertility work-up was highly predictable for sperm recovery in subsequent ICSI cycles. TESA performed under local anaesthesia seems almost as effective as more invasive procedures in recovering testicular spermatozoa, both in obstructive and non-obstructive azoospermic men.     

Pregnancies achieved after frozen-thawed pronuclear oocytes obtained by intracytoplasmic sperm injection with spermatozoa extracted from frozen-thawed testicular tissues from non-obstructive azoospermic men.

The use of frozen-thawed testicular tissue as a source of spermatozoa for intracytoplasmic sperm injection (ICSI) in non-obstructive azoospermia yields favourable fertilization and pregnancy rates while avoiding both repetitive biopsies and unexpected cycle cancellations. Spermatozoa were obtained from frozen-thawed testicular biopsy specimens from 67 non-obstructive azoospermic men. Following fertilization, supernumerary two pronuclear (2PN) oocytes were frozen. After thawing, 17 cycles of embryo transfer were carried out with a mean number of 2.7 embryos and a mean cumulative embryo score (CES) of 18.3 per transfer. The clinical pregnancy and implantation rates per transfer in these cycles (23.5 and 8.3% respectively) were comparable to those of fresh embryo transfers (35.7 and 12.7% respectively) with a mean number of 2.7 embryos and a mean CES of 28.7 per transfer. Abortion rates, although higher with cryopreserved 2PN oocytes were not significantly different. With this approach, cryopreservation of supernumerary 2PN oocytes can be used to improve the cumulative pregnancy rates in a severely defective spermatogenetic population. To our knowledge, these are the first pregnancies reported which have been obtained by the transfer of cryopreserved pronuclear oocytes obtained from ICSI using cryopreserved testicular spermatozoa.     

Outcome of first and repeated testicular sperm extraction and ICSI in patients with non-obstructive azoospermia

BACKGROUND: It is unclear whether or not testicular sperm extraction (TESE) should be repeated for patients in whom no sperm were found during their first TESE attempt. METHODS AND RESULTS: The outcome of repeated TESE was evaluated in patients with non-obstructive azoospermia (NOA) after failing to obtain sperm in their first extraction attempt, or having used all available cryopreserved testicular tissue. Out of 83 patients with NOA, patients repeated TESE two (n = 22), three (n = 8), four (n = 6) and five (n = 3) times. Distribution of main testicular histology included germ cell aplasia (55%), maturation arrest (29%) and germ cell hypoplasia (16%). The first TESE yielded mature sperm for ICSI in 39% of patients (sp+), and failed in the remaining 61% (sp-). A second TESE yielded mature sperm in 1/4 from the sp- group and in 16/18 from the sp+ group. At the third, fourth and fifth trials, 8/8, 5/6 and 3/3 of the original sp+ patients were sp+ again respectively. Compared with the outcome of the first trial, all further trials did not differ statistically in the rate of fertilization (54 versus 49%), implantation (9.5 versus 5.4%), or clinical pregnancy/cycle (19 versus 15%). No pregnancies were achieved among the three patients after their fifth TESE. Pregnancies occurred in all histological groups, except maturation arrest. CONCLUSIONS: The outcome of repeated TESE cycles, up to the fourth trial, justifies the procedure.     

Testicular needle biopsy, open biopsy, epididymal aspiration and intracytoplasmic sperm injection in obstructive azoospermia

Testicular or epididymal spermatozoa were obtained for in-vitrofertilization and intracytoplasmic sperm injection ICSI) in27 cycles out of 33 (in six men the azoospermia proved to havetesticular causes). Testicular needle biopsy carried out inaddition to surgical open biopsy proved to be an effective methodto obtain spermatozoa for ICSI from patients with obstructiveazoospermia. Thus it might be possible to replace scrotal operationsby simple needle biopsies. Embryos resulting from ICSI withtesticular spermatozoa were used in 19 transfers that resultedin six pregnancies. One pregnancy resulted from six embryo transfersfrom ICSI after microsurgical-epididymal sperm aspiration (MESA).The normal fertilization rates with testicular (37.3%) and MESAspermatozoa (53.7%) did not differ significantly from each other,but with testicular spermatozoa the rate was significantly lowerthan that obtained with ejaculated spermatozoa and ICSI (59.7%)in the matched couples. The abnormal fertilization of oocyteswith one pronucleus was significantly higher with testicularspermatozoa than with ejaculated spermatozoa in the controlcouples.     

Testicular sperm extraction (TESE) and ICSI in patients with permanent azoospermia after chemotherapy

BACKGROUND: Patients persistently azoospermic after chemotherapy have been considered traditionally as sterile unless sperm was frozen before therapy. Recent advances during the last decade combining testicular sperm extraction (TESE) and ICSI in patients with non-obstructive azoospermia allow these males to father their own genetic offspring. METHODS: A retrospective study was conducted of 12 patients with non-obstructive azoospermia after chemotherapy undergoing TESE between 1995 and 2002. Cancer type and anti-neoplastic treatments were recorded, together with maximum testicular volume, serum FSH levels and testicular histopathology. When TESE was successful, spermatozoa were cryopreserved for performing ICSI later. RESULTS: In five patients (41.6%) motile spermatozoa for cryopreservation and ICSI were retrieved. Four of them had received chemotherapy for testicular cancer, and one had been treated by chemotherapy/radiotherapy for Hodgkin's disease. Clinical and histological parameters were unable to predict with certainty TESE outcome in an individual patient. Eight ICSI cycles were performed on five couples and one pregnancy was obtained which resulted in the delivery of a healthy girl. CONCLUSION: Some patients with permanent azoospermia after chemotherapy can be successfully treated by TESE-ICSI. This procedure, however, may have potential genetic risks. Therefore, freezing semen before starting gonadotoxic therapy is the strategy of choice, and patients should be counselled accordingly.     

In-vitro culture of spermatozoa induces motility and increases implantation and pregnancy rates after testicular sperm extraction and intracytoplasmic sperm injection.

The aim of this study was to determine the effect of 24-h in-vitro culture of testicular spermatozoa in recombinant follicle stimulating hormone (recFSH) supplemented medium versus simple medium on sperm motility, and to analyse the outcome of intracytoplasmic sperm injection (ICSI) of such spermatozoa. A total of 143 positive testicular sperm extraction procedures in men with non-obstructive azoospermia was evaluated prospectively. Extracted testicular tissue samples were randomized to be cultured in vitro for 24 h in simple medium or recFSH supplemented media. ICSI was performed with spermatozoa cultured in recFSH (n = 73) or in simple medium (n = 70). Sperm motility following in-vitro culture, embryo quality after ICSI, and implantation and pregnancy rates were assessed. Of the 898 MII oocytes available in the recFSH group, 646 (71.9%) were injected with spermatozoa showing either twitching or progressive motility. However, only 29.1% of the oocytes in the simple medium group (245/841) were injected with motile spermatozoa (P < 0.05). Fertilization rate (68.8 versus 42.1%), implantation rate per embryo (20.1 versus 13.2%), and clinical pregnancy rate (47. 9 versus 30%) were significantly increased in the recFSH group compared with the simple medium group respectively (P < 0.05). In conclusion, in-vitro culture with recFSH appears to increase the motility of testicular spermatozoa, thus increasing the success of ICSI.     

Correlation between testicular histology and outcome after intracytoplasmic sperm injection using testicular spermatozoa

A comprehensive study is presented of a series of 124 infertilemen undergoing testicular sperm retrieval for intracytoplasmicsperm injection (ICSI). In this study we correlated the histologicalchanges observed in the testicular tissue with the results ofthe wet preparation and the outcome after ICSI using testicularspermatozoa. In all patients with normal spermatogenesis andhypospermatogenesis spermatozoa were recovered from the wetpreparation. The sperm recovery rate was 84% in patients withincomplete germ-cell aplasia and maturation arrest, while inpatients with complete germ-cell aplasia or maturation arrestthis figure was 76%. In these patients more specimens were sampledand fewer spermatozoa were recovered. Since no spermatozoa wererecovered in only 10 patients, ICSI with testicular sperm wasperformed in the remaining 114 couples (91.9%). The normal fertilizationrate was 57.8%. The fertilization rate was significantly lowerin couples among whom the husband showed germ-cell aplasia andmaturation arrest. Overall, 55.2% of normally fertilized oocytesdeveloped into embryos showing 50% of anucleate fragments. Therewere no major differences between the different histologicalcategories in terms of embryonic development in vitro. The overallpregnancy rates per testicular sperm extraction (TESE) procedure,per ICSI procedure and per transfer were respectively 36.3,39.5 and 43.7%. The overall implantation rate per embryo (sacs/embryosreplaced) was 20.3%. A lower implantation rate was observedin couples among whom the husband had maturation arrest (notstatistically significant). The above data show that testicularbiopsies may have an important therapeutic role in the managementof infertility in azoospermic patients.     

Testicular sperm extraction: impact of testicular histology on outcome, number of biopsies to be performed and optimal time for repetition

Testicular sperm extraction (TESE) may not always be successful in patients with non-obstructive azoospermia, as they only have minute foci of active spermatogenesis from which a tiny number of spermatozoa can be extracted. The aim of this study was to find the percentile incidence of successful TESE in non-obstructive azoospermia patients in relation to various histopathological patterns and the number of performed biopsies, and to determine the optimal time needed for repetition. A total of 216 patients underwent bilateral testicular biopsy taking a single piece from each testis for sperm retrieval and pathological evaluation. In another 100 patients, the same procedure was done but taking multiple samples (maximum four samples/testis). Spermatozoa were successfully retrieved from 37.5 and 49% of patients who supplied single and multiple samples respectively. TESE was significantly higher when multiple samples were taken in all histopathological groups except for Sertoli cell-only syndrome, tubular sclerosis and Klinefelter's pattern. Twenty-seven patients underwent repeated TESE for ICSI between 1 and 24 months from the first procedure; all of them had easy sperm retrieval during the first procedure. Although sperm retrieval was successful in 75 and 94.7% of patients who underwent the second attempt, before and after 3 months respectively, a second TESE was usually more difficult and necessitated multiple sampling.     

Genetics: The use of epididymal and testicular spermatozoa for intracytoplasmic sperm injection: the genetic implications for male infertility

The results and rationale of using testicular and epididymalspermatozoa with intracytoplasmic sperm injection (ICSI) forsevere cases of male infertility are reviewed. A total of 72consecutive microsurgical epididymal sperm aspiration (MESA)cases were performed for congenital absence of the vas (CAV)and for irreparable obstructive azoospermia. ICSI was used toobtain normal embryos for transfer and fertilization in 90%of the cases. The overall fertilization rate was 46% with anormal cleavage rate of 68%. The pregnancy and delivery ratesper transfer were 58 and 37% respectively. The delivery rateper cycle was 33%. In many cases, no epididymal spermatozoawere available and so testicular sperm extraction (TESE) wasused for sperm retrieval. The transfer rate was lower with TESE(84 versus 96%) and the spermatozoa could not be frozen andsaved for use in future cycles. However, there was little differencein pregnancy rates using epidiymal or testicular spermatozoa.The results were not affected by whether the obstruction wascaused by CAV or failed vasoepididymostomy. Both fresh and frozenspermatozoa gave similar results; the only significant factorappeared to be the age of the female. Because of the consistentlygood results obtained using epididymal sperm with ICSI whencompared with conventional IVF, and the similarly good resultswith testicular tissue spermatozoa, ICSI is mandatory for allfuture MESA patients. All CAV patients and their partners shouldbe offered genetic screening for cystic fibrosis; hence pre-implantationembryo diagnosis should be available in any full service MESAprogramme. It is now clear that even with non-obstructive azoospermia,e.g. Sertoli-cell only, or maturation arrest, there are usuallysome small foci of spermatogenesis which allow TESE with ICSIto be carried out. This means that even in men with azoospermiadue to absence of spermatogenesis or to a block in meiosis,there are usually a few spermatozoa available in the testesthat are adequate for successful ICSI. Finally, it is likelythat some forms of severe male factor infertility are geneticallytransmitted and although ICSI offspring have been shown to becompletely normal, it is possible that the sons of these infertilecouples will also require ICSI when they grow up and wish tohave a family.     

Fertilization and pregnancy using intentionally cryopreserved testicular tissue as the sperm source for intracytoplasmic sperm injection in 10 men with non-obstructive azoospermia

Testicular tissue extraction (TESE) to obtain spermatozoa for use with intracytoplasmic sperm injection (ICSI) has recently been employed in patients with non-obstructive azoospermia. Standard protocol is to retrieve a new sample of testis tissue on the day of oocyte recovery. Unfortunately, approximately 30% of men will possess no spermatozoa in their tissue, making ICSI an impossibility. We investigated whether testicular tissue that was intentionally obtained well before any planned ICSI cycle and cryopreserved could then serve as an efficacious sperm source in a subsequent ICSI cycle. This study reports on 10 men with non-obstructive azoospermia who did have spermatozoa found within their testis tissue at the time of TESE and who chose to use their frozen samples as the source of spermatozoa for a later cycle of ICSI. In 19 cycles the overall fertilization rate was 48%. Embryo transfer occurred in 89% of cycles. Two couples have achieved pregnancy (one ongoing, one delivered). All patients except one had multiple vials of frozen tissue remaining following their first cycle. This approach is offered as an alternative to repeated testicular tissue sampling, as the availability of spermatozoa is assured prior to the initiation of ovulation induction. This tissue can be harvested at the same time as diagnostic biopsy, thereby minimizing the number of surgical procedures.      

High implantation and pregnancy rates with testicular sperm extraction and intracytoplasmic sperm injection in obstructive and non-obstructive azoospermia

Thirty-two infertile couples with obstructive and non-obstructiveazoospermia were included in this study. Testicular sperm extraction(TESE) was performed in 16 obstructive azoospermic cases wheremicrosurgical sperm aspiration (MESA) or percutaneous spermaspiration (PESA) were impossible because of totally destroyedepididymis and 16 non-obstructive azoospermia cases with severespermatogenetic defect where the testicles were the only sourceof sperm cells. A total of 288 oocytes was obtained from 32females and 84% were injected. The fertilization rates (FR)with 2 pronuclei (PN) and cleavage rate were 50.8 and 68.2%respectively. A total of 15 pregnancies was achieved (53% perembryo transfer), nine from the obstructive and six from thenon-obstructive group. Four pregnancies resulted in clinicalabortion (26.6%). The ongoing pregnancy rate was 39.2% per embryotransfer (ET) and 343% per started cycle. A high implantationrate was also achieved (26.6% in non-obstructive and 30% inobstructive azoospermia group). Using testicular spermatozoain combination with ICSI in both obstructive and non-obstructiveazoospermic groups, high implantation and pregnancy rates canbe achieved.     

Outcome of ICSI using fresh and cryopreserved-thawed testicular spermatozoa in patients with non-mosaic Klinefelter's syndrome.

BACKGROUND: Recently, intracytoplasmic sperm injection (ICSI) of testicular spermatozoa retrieved surgically from patients with non-mosaic Klinefelter's syndrome resulted in several deliveries. The aim of this study was to evaluate the outcome of ICSI using fresh and cryopreserved-thawed testicular spermatozoa in these patients. METHODS AND RESULTS: Following informed consent regarding the genetic risks of their potential offspring, mature testicular spermatozoa were found in five out of 12 (42%) patients who underwent testicular sperm extraction, and ICSI was performed while excess tissue was cryopreserved. The mean age of the patients was 28.7 +/- 3.6 (range 23-36 years). Their baseline FSH was elevated (mean 38.3 +/- 11.4; range 22-58 mIU/ml). All patients had small testicles of 2-4 ml in volume. The outcome of ICSI using fresh or cryopreserved-thawed testicular spermatozoa during five cycles in each group, was compared. No statistical significant difference was found in the two pronuclear fertilization rate (66 versus 58%), embryo cleavage rate (98 versus 90%) and embryo implantation rate (33.3 versus 21.4%) for fresh or cryopreserved sperm accordingly. The clinical outcome after using fresh testicular sperm included two singleton pregnancies (one delivered and one ongoing) and a triplet pregnancy resulting in a twin delivery (after reduction of an 47,XXY embryo). After using cryopreserved-thawed testicular spermatozoa, two pregnancies were obtained resulting in one delivery of twins and one early spontaneous abortion. CONCLUSIONS: Outcome of ICSI using cryopreserved-thawed testicular spermatozoa of patients with non-mosaic Klinefelter's syndrome is comparable with that following the use of fresh spermatozoa. The genetic implications for the future offspring should be explained to the patients.     

Outcome of testicular sperm recovery and ICSI in patients with non-obstructive azoospermia with a history of orchidopexy

BACKGROUND: Little is known about sperm recovery and ICSI using testicular sperm from men with non-obstructive azoospermia who had a previous orchidopexy. We therefore studied the sperm recovery in this subgroup and evaluated clinical parameters predicting successful sperm retrieval and the outcome of ICSI. METHODS: A total of 79 non-obstructive azoospermic men with a history of orchidopexy underwent a sperm recovery procedure. The predictive value of clinical parameters such as age at sperm retrieval, age at orchidopexy, testicular volume, FSH, FSH/LH ratio, testosterone and androgen sensitivity index (LH x testosterone) for successful testicular sperm retrieval was evaluated using receiver operating characteristics (ROC) curve analysis. A comparison between 64 ICSI cycles performed in these couples and 92 cycles performed in couples in which the men had an unexplained non-obstructive azoospermia was carried out. RESULTS: Testicular spermatozoa were recovered in 41 patients (52%). The mean age at orchidopexy of the patients with a positive sperm recovery was 10.6 years [95% confidence interval (CI) 7.3-13.8] versus 15.5 years (95% CI 11.3-19.8) for those where no spermatozoa were found. The mean testicular volume of the largest testis of patients with spermatozoa found was 10 ml (95% CI 8.3-11.9) versus 8.5 ml (95% CI 5.8-11.1) in patients with no spermatozoa found. The mean FSH and testosterone value for patients with successful and unsuccessful sperm recovery, respectively, was 24.1 IU/l (95% CI 17.9-30.3) and 4.4 ng/ml (95% CI 3.7-5.1) versus 28.8 IU/l (95% CI 19.4-38.2) and 3.4 ng/ml (95% CI 2.2-4.5). All clinical and biological parameters examined failed to predict the outcome of the testicular sperm extraction. No differences were observed between the orchidopexy and unexplained group for the number of oocytes retrieved, fertilization rate, embryo quality, pregnancy rate and implantation rate. CONCLUSIONS: As in the population of men with non-obstructive azoospermia, the sperm recovery rate for patients with a history of orchidopexy is approximately 50% and there are currently no clinical parameters predicting successful sperm retrieval in this subpopulation of patients. The outcome of the ICSI cycles is comparable with that in the population of men with non-obstructive azoospermia.     

Should diagnostic testicular sperm retrieval followed by cryopreservation for later ICSI be the procedure of choice for all patients with non-obstructive azoospermia?

BACKGROUND: This was a retrospective study to determine if diagnostic testicular biopsy followed by cryopreservation should be the procedure of choice for all patients with testicular failure. METHODS: The first part of the study analysed 97 ICSI cycles scheduled with frozen-thawed testicular sperm for 69 non-obstructive azoospermia (NOA) patients. The second part focused on a subgroup of 32 patients who underwent 42 ICSI cycles with frozen and 44 cycles with fresh testicular sperm. Sperm characteristics, fertilization, embryo quality, pregnancy and implantation rates were evaluated. RESULTS: Part I: The average time needed to find sperm was 113 min per cycle and 17 min per individual sperm. Fertilization rate, embryo transfer rate, ongoing pregnancy and implantation rates were 58.4%, 83%, 20.8% and 11.3%, respectively. Part II: The search time per sperm was higher (P=0.016) in frozen (18 min) than in fresh suspensions (13 min). A higher embryo transfer rate was observed in fresh cycles than in frozen cycles (93.2% vs 76.2%, P=0.028). Fertilization, ongoing pregnancy and implantation rates were comparable for the two groups. CONCLUSIONS: Even in a programme with low-restrictive criteria for patient allocation and for sperm cryopreservation, diagnostic testicular biopsy followed by cryopreservation can be the procedure of choice for patients with testicular failure.