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From the Department of Urology, University of São Paulo, São Paulo, Brazil; and the Department of Urology, Syrian Lebanese Hospital, São Paulo, Brazil.
| Correspondence to: Dr Marco A. Arap, Rua Adma Jafet, 50/3o andar, São Paulo, SP Brazil 01308-050 (e-mail: marcoarap{at}usp.br). |
| Received for publication November 2, 2006; accepted for publication January 29, 2007. |
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Abstract |
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Key words: Infertility, function, testis
Endocrine testicular function is expected to be normal in the event of a lost gonad. On the other hand, the exocrine testicular function (spermatogenesis) may be compromised (Cosentino et al, 1985; Lievano et al, 1999). Patients with testicular torsion seem to have bilateral abnormalities that result in decreased spermatogenesis (Krarup, 1978). It is unclear whether these abnormalities are due to an autoimmune process that occurs after the rupture of the hematotesticular barrier leading to formation of antisperm antibodies or as a result of reperfusion-induced injury to the testis (Becker et al, 1997; Lievano et al, 1999).
To date, there has been substantial difficulty in evaluating whether or not exocrine testicular function correlates with the formation of antisperm antibodies. We analyzed late hormonal levels, semen parameters, and the presence of antisperm antibodies in patients with surgical diagnoses of testicular torsion to 1) address the correlation of testicular fate and the autoimmune process, 2) evaluate late seminal parameters among patients treated with orchiopexy and orchiectomy, and 3) compare endocrine testicular function between the groups.
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Methods |
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The records of 64 patients who underwent surgical treatment for testicular torsion between 1989 and 2002 were analyzed. Of these, 48 were eligible to enter the study (age >16 years and no history of sexually transmitted or neurologic disease), and 24 agreed to participate in the protocol. They were thoroughly counseled about the study details and provided signed informed consent. Patients were further classified into two groups according to surgical procedure. Group 1 was composed of patients treated with orchiectomy and contralateral orchidopexy (n = 15), and group 2 was composed of patients treated with detorsion and bilateral orchidopexy (n = 9). All patients were submitted to the same evaluation, consisting of past and recent medical and urologic history and complete physical examination. Twenty voluntary men requesting vasectomy with no previous history of endocrinopathy, sexually transmitted disease, or neuropathy were included as controls. All patients and controls were evaluated according to the same protocol, including hormonal profile, routine seminal parameters, and the presence of seminal antisperm antibodies.
For the hormonal profile, blood was collected between 8 and 9 AM. Follicle-stimulating hormone (FSH), luteinizing hormone (LH), and testosterone concentrations were measured by standard radioimmunoassay in our in-house laboratory. The normal range established in our laboratory for each hormonal level is 200 to 950 ng/dL for testosterone, 2.6 to 7.8 UI/L for FSH, and 1.4 to 9.2 UI/L for LH. Semen was collected in the hospital by masturbation after 2 to 4 days of sexual abstinence, and seminal parameters were analyzed within 1 hour of ejaculation. All semen samples were evaluated by the same biologist for ejaculated volume, sperm concentration, morphology, motility, and forward progression. Motility and concentration were determined according to World Health Organization (WHO) criteria and morphology according to WHO and Kruger strict criteria (Kruger et al, 1988; WHO, 1992). antisperm antibodies were analyzed by an Immunobeads assay (Bio-Rad, Richmond, Calif).
All data were compared between the groups, and statistical significance of the differences was analyzed for all criteria with 2-tailed nonparametric tests (Student's t test). Correlations between variables were calculated using Spearman's nonparametric method. All analyses were calculated with MINITAB 14.2 (Six Sigma, Austin, Tex) and SPSS 14.0 (SPSS Inc, Chicago, Ill). P < .05 was considered statistically significant.
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Results |
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The left testis was affected in 73% of patients in group 1 and 55.5% in group 2. The median ischemia time (estimated from the beginning of pain to surgical treatment) was significantly higher in group 1 (48 hours [ICR, 48–120]) compared with group 2 (7 hours [ICR, 3–21]) (P = .0015)(Table 1).
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Hormonal Levels
The mean FSH concentration was statistically higher in group 1 compared
with group 2. Although statistically nonsignificant, the mean FSH level in
group 2 was higher than in the controls. LH levels in patients from group 1
were significantly higher than those in controls. No significant differences
were observed between groups 1 and 2 and between group 2 and the control. Mean
testosterone levels were significantly higher in both groups 1 and 2 compared
with the controls. No significant difference was observed between groups 1 and
2 concerning mean testosterone levels
(Table 2).
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Seminal Parameters
Mean sperm count was normal for all groups, and no statistical difference
was observed when groups 1 and 2 were compared with the controls or each
other. Three patients (21%) from group 1 and 3 patients (33%) from group 2
presented with oligospermia (Table
2). The average sperm motility was normal for groups 1 and 2.
However, patients subjected to orchiectomy showed better sperm motility than
those subjected to detorsion and orchiopexy. No significant difference was
found when groups 1 and 2 were compared with the controls. According to Kruger
criteria, mean sperm morphology was abnormal in all groups, including the
controls. Moreover, patients submitted to orchiopexy had the lowest mean
Kruger score (Kruger et al,
1988). Patients treated by orchiectomy had an mean Kruger score
between controls and those subjected to bilateral orchiopexy
(Kruger et al, 1988).
According to WHO criteria, mean sperm morphology was abnormal in all groups,
and again a significant difference was observed for groups 1 and 2 compared
with the controls and compared with each other
(Table 2).
Antisperm Antibodies
Mean seminal antisperm antibody levels were normal for the control group
and abnormal for both groups 1 and 2. However, no significant difference was
observed when groups 1 and 2 were compared with the control and when compared
with each other (Table 2). In
addition, no significant correlation was found between antisperm antibody
levels and age at torsion, ischemia time, seminal parameters, or treatment
applied (Table 3).
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Discussion |
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Average patient age in our study was comparable to that in other series (Krarup, 1978; Anderson et al, 1992; Kosar et al, 1999). Hormonal alterations following testicular torsion have been previously described in human as well as experimental studies (Bartsch et al, 1980; Fisch et al, 1988; Turner et al, 2005). The increase in gonadotropins, mainly FSH, may be due to tubular destruction related to testicular ischemia, ultimately leading to a diminished sperm concentration. Another possible explanation is a previously undetected deficient spermatogenesis (Anderson et al, 1986). Indeed, patients who underwent orchiectomy had higher levels of FSH when compared with those submitted to detorsion and orchiopexy. In addition, this difference was even higher when they were compared with the controls. Mean LH levels were also higher in patients submitted to orchiectomy than in controls, confirming previous studies (Bartsch et al, 1980; Fisch et al, 1988). Interestingly, although there was a difference in baseline hormone levels between the two groups, all values were within the normal range. In addition, mean testosterone levels were higher for both groups 1 and 2 compared with controls. These findings suggest that endocrine testicular function is preserved in patients treated for testicular torsion, probably due to an increase in LH levels.
Several groups have reported abnormal sperm concentration and motility after testicular torsion (Bartsch et al, 1980; Mastrogiacomo et al, 1982; Anderson and Williamson, 1990). In our series, the mean sperm concentration was normal for all groups and we did not identify significant differences among them. However, there was significantly better sperm motility in patients who underwent orchiectomy compared with patients whose gonad was preserved. This could be related to the release of abnormal sperm cells by the previously ischemic testis or to the rupture of the hematotesticular barrier and subsequent formation of antibodies against sperm cells (Mastrogiacomo et al, 1982).
To compare sperm morphology, we used Kruger strict criteria and WHO morphology (WHO, 1992). All patients, including the controls, had abnormal Kruger strict criteria (Kruger et al, 1988). When the WHO criteria was used, all but one patient from group 1 and 6 patients from the control group had abnormal morphology (WHO, 1992). We found a significant difference for groups 1 and 2 when compared with controls for both morphology criteria (Kruger et al, 1988; WHO, 1992). This was particularly evident for patients from group 2 (orchiopexy), who presented with the worst morphology. Again, this may result from abnormal sperm cells derived from the preserved testis. It is of note that our results may indicate a need to re-evaluate the established normal criteria, at least in our population, as the great majority of patients from the control group also presented with abnormal sperm morphology. According to other studies, the cut-off values for morphology normality are substantially lower than those proposed by the WHO manuals (Ombelet et al, 1997; Menkveld et al, 2001). There is a strong recommendation from WHO to individualize the references for normality of semen parameters in each laboratory. Decreased morphology has been reported by other investigators following testicular torsion (Bartsch et al, 1980; Schutte et al, 1986); however, Anderson et al (1992) did not observe significant differences among patients submitted to orchiectomy or orchiopexy in regard to sperm motility or morphology.
Mastrogiacomo et al (1982) identified antisperm antibodies in the semen of patients with testicular torsion and correlated antibody levels with sterility and particularly with motility alterations. On the other hand, Fraser et al (1985) followed 47 patients from 2 to 10 years after torsion and found gonadal dysfunction but no correlation to autoimmune response. More evidence against autoimmune reaction is found in the article of Anderson et al (1992), who verified pre-existing contralateral testis abnormalities in biopsies at the time of surgery and did not detect any cases of antisperm antibodies after testicular torsion. We believe that the qualitative sperm findings in our study were not related to autoimmune responses, as we did not find significant differences regarding antibodies between groups 1 and 2.
Animal models usually show histologic lesions occurring in the contralateral testis and abnormal levels of antisperm antibodies after experimental testicular torsion (Harrison et al, 1981; Cosentino et al, 1985; Kosar et al, 1997; Kosar et al, 1999). Given these results, it has been suggested that the best procedure is to remove the affected testis (Kosar et al, 1997). However, animal models for testicular torsion do not reproduce the conditions found in humans, such as the anatomy of the testis, known to be abnormally loose inside the vaginal layer (Anderson and Williamson, 1990). We did not verify significant differences in antisperm antibody levels among any of the groups. However, there was a tendency for both groups 1 and 2 to have higher antibody values compared with the controls (Table 2). Therefore, we believe that antibody formation is not related to the maintenance or removal of the affected testicle but possibly to an irreversible autoimmune response triggered at the moment of torsion.
The limited number of patients and cross-sectional design are the drawbacks of this study. However, the data were collected prospectively and all patients were treated with a careful follow-up and pre-established protocol; comprising the strengths of this study.
In conclusion, we presented evidence that patients treated for testicular torsion show mainly morphologic semen abnormalities and endocrine profiles within the normal range, despite the subclinical increases in FSH levels. Testicular fate did not have any correlation with the formation of antisperm antibodies. Patients subjected to orchiectomy presented with better motility and morphology compared with the detorsion group. Although these findings suggest that the maintenance of a severely ischemic testicle may impair seminal parameters, further studies may clarify whether maintenance of a severely ischemic testicle impacts testicular function.
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References |
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