Spinal cord contusion impairs sperm motility in the rat without disrupting spermatogenesis

First emerging evidence of the relationship between Onuf's nucleus degeneration and reduced sperm number following spinal subarachnoid haemorrhage: Experimental study

Lumbosacral pathologies can lead to infertility. Onuf's nucleus changes in these pathologies may have a role in low sperm number. This study aims to investigate the relationship between Onuf's nucleus degeneration and sperm number following spinal subarachnoid haemorrhage. 22 rabbits were used. They were divided into three groups; five of them were used as the control (GI), five as the SHAM (GII) and twelve as the study groups (GIII). The study group received 0.7 ccs autologous blood into the spinal subarachnoid space at the T12-L1 level. After two weeks, all animals were decapitated, and S1-S3 laminectomy was done. Neurodegenerative changes of Onuf's nucleus, pudendal ganglia (S3) following two weeks after spinal SAH, were examined; sperm numbers were calculated. Degenerated neuron density of the Onuf's nucleus (n/mm³ ), the pudendal ganglia (S3) (n/mm³ ) and mean sperm numbers were calculated as 5 ± 2, 8 ± 3/mm³ and 98.345 ± 12.776/mm³ in the control (GI), 20 ± 5/mm³ , 243 ± 66/mm³ and 91.841 ± 9.654/mm³ in the SHAM (GII), 143 ± 39/mm³ , 2,350 ± 320/mm³ and 68.549 ± 5.540/mm³ in the study group (GIII). In conclusion, there were statistically significant differences between groups. Onuf's nucleus may be responsible for decreased sperm number following spinal SAH.

Effect of chronic spinal cord injury's severity on sperm parameters in rat: correlation with locomotion deficits

OBJECTIVES

Infertility is one of the major concerns for male patients following spinal cord injury (SCI). Although the severity of the injury has a large impact on extent of infertility, the effect of exact injury extent (with specific affected spinal tracts) on fertility is not studied yet.

MATERIALS AND METHODS

In the present study, sperm parameters, locomotion scores, and hormonal changes were evaluated following dorsal one third SCI (1/3 SCI), dorsal two third SCI (2/3 SCI), and complete spinal cord transection (TX) at T8 spinal level in male rats.

RESULTS

Sperm count decreased significantly following 1/3 SCI and Tx compered to normal (control and sham). In addition, sperm count decreased significantly in Tx compared to 1/3 SCI and 2/3 SCI. Concerning sperm motility, although, percentage of motile sperms decreased significantly in Tx group in comparison to all other groups, the percentage of rapid progressive motile sperms (RPM) decreased significantly in all SCI groups compared to normal. Meanwhile, locomotion score (BBB-score) showed a significant progressive decrease following SCI compared to normal or within SCI groups. However, there was no significant changes in the serum hormonal and seminal fructose concentrations following SCI compared to normal.

CONCLUSIONS

These results show that understanding the extent of SCI, the affected spinal tracts, and the resultant locomotion deficits may help to predict the deficits in sperm parameters and hence fertility potentials.

Severing the ventral funiculus in chronic spinal cord injury has the most deteriorating effect on spermatogenesis in rats

Sexual dysfunction, following spinal cord injury (SCI), is highly dependent on the extent of injury. SCI disrupts the supraspinal innervation of the reproductive organs; resulting in structural and functional deficits. Relating the extent of SCI to these changes could eventually improve diagnoses and treatment planning of sexual dysfunction following SCI. In the present study, following chronic SCI of different severities (1/3 dorsal SCI (1/3 SCI), 2/3 dorsal SCI (2/3 SCI), and complete transection (Tx)) at T8 spinal level, histological changes of seminiferous tubules parameters in testis were examined. The diameter of seminiferous tubules (DST) and epithelial height of seminiferous tubules (HST) were significantly decreased in all SCI groups compared to control and sham. In addition, DST in 2/3 SCI and Tx groups and HST in Tx group were significantly decreased in comparison with 1/3 SCI animals. Nonetheless, the diameter of seminiferous tubules' lumen decreased significantly in 2/3 SCI and Tx compared to control, sham, and 1/3 SCI groups. Concerning cellular component, the number of spermatocytes and spermatids layers significantly decreased in both 1/3 and 2/3 SCI in comparison to normal. However, Tx had the most prominent deteriorating effect on these layers; indicating impairment in the process of spermatogenesis. These results show that the spinal tracts are part of the neural circuitries innervating the testis and responsible for their structural support. These tracts are mainly distributed between the lateral and ventral funiculi at T8 spinal level. Consequently, sparing ventral funiculi in the SCI prevents the severe decline in spermatogenesis.

Preservation of Spermatogenesis in Spinal Cord Injured Rats With Exogenous Testosterone. Relationship With Serum Testosterone Levels and Cellular Localization of cAMP Responsive Element Modulator

The current experiment examined the effects of exogenous testosterone (T) on spermatogenesis in rats with spinal cord injury (SCI) and their relationship with the cellular distribution of a cyclic AMP-responsive element modulator (CREM) in testicular cells. Implantation of T-filled Silastic capsules (TCs, 1-20 cm) resulted in dose-dependent, biphasic changes in testicular T levels and spermatogenesis in SCI rats. However, dose responsiveness of spermatogenesis to exogenous T in SCI rats differed from that in sham control rats. Specifically, implantation of 2-cm TCs enhanced the effects of SCI on spermatogenesis, resulting in total regression of the seminiferous epithelium. Although 3-cm TCs maintained complete spermatogenesis in sham control rats, this regimen failed to support complete spermatogenesis in SCI rats. Although complete spermatogenesis was maintained in SCI rats given 5-20-cm TC implants, various abnormalities persisted. Cellular distribution of CREM remained normal in SCI rats but was altered in those SCI rats that received 3- or 5-cm TC implants. Such effects were associated with reduced CREM proteins in testicular tissues. These results were consistent with altered cAMP signaling and its regulation in testicular cells after SCI and provided possible mechanistic explanations for the effects of SCI on spermatogenesis.

CONCLUSION

SCI resulted in changes in the responsiveness of spermatogenesis to exogenous T. These effects were associated with altered cAMP/CREM signaling in testicular cells. Further studies, including a study of the relationship between serum T levels and normalcy of sperm functions and the role of neural-endocrine interactions in mediating the effects of SCI on spermatogenesis and sperm function, are needed so that therapeutic regimens can be designed for clinical use.

Link between low-dose environmentally relevant cadmium exposures and asthenozoospermia in a rat model

OBJECTIVE

To define the mechanism(s) underlying an association between asthenozoospermia and elevated blood, seminal plasma, and testicular cadmium levels in infertile human males using a rat model of environmentally relevant cadmium exposures.

SETTING

University medical center andrology research laboratory.

ANIMAL(S)

Male Wistar rats (n = 60), documented to be sensitive to the testicular effects of cadmium.

INTERVENTION(S)

Rats were given ad libitum access to water supplemented with 14% sucrose and 0 mg/L, 5 mg/L, 50 mg/L, or 100 mg/L cadmium for 1, 4, or 8 weeks beginning at puberty.

MAIN OUTCOME MEASURE(S)

Testicular cadmium levels were determined by atomic absorption, cauda epididymal sperm motility by visual inspection, and testicular gene expression by DNA microarray hybridization.

RESULT(S)

Chronic, low-dose cadmium exposures produced a time- and dose-dependent reduction in sperm motility. Transcription of genes regulated by calcium and expression of L-type voltage-dependent calcium channel mRNA splicing variants were altered by cadmium exposure. Expression of calcium binding proteins involved in modulation of sperm motility was unaffected.

CONCLUSION(S)

A causal relationship between elevated testicular cadmium and asthenozoospermia was identified. Aberrrant sperm motility was correlated with altered expression of L-type voltage-dependent calcium channel isoforms found on the sperm tail, which regulate calcium and cadmium influx.

Assessment of nuclear DNA integrity of epididymal spermatozoa following experimental chronic spinal cord injury in the rat

Infertility is considered as one of the major problems associated with spinal cord injury (SCI). However, the exact underlying mechanism is still unknown. Therefore, the main objective of this experimental study was to evaluate the effect of chronic SCI on sperm parameters as well as chromatin integrity and DNA of spermatozoa aspirated from cauda epididymis of rats. Forty-five adult Wistar rats were divided into three groups - SCI, sham, and control. Following laminectomy, SCI was induced onto exposed dura matter (T10). The sham group underwent laminectomy of T10 only, while the control rats were not exposed to any type of injury or medication. The cauda epididymal sperms were aspirated after 8 weeks for analysis of sperm parameters and sperm chromatin integrity with aniline blue (AB), chromomycin A3 (CMA3), sodium dodecyl sulphate (SDS), and acridine orange (AO) tests. The sperm progressive motility and normal morphology of SCI rats were significantly changed when compared with other groups (p < 0.05). In addition, AB as well as CMA3 tests were insignificantly increased in the SCI group when compared with the sham and control groups. However, SDS and AO tests were significantly changed in SCI samples when compared with the sham and control groups (p < 0.001). The results showed that chronic SCI in rat disturbs sperm parameters as well as nuclear maturity and DNA integrity of sperms. Therefore, sperm chromatin structure is compromised in SCI animals as revealed by chromatin structural probes. These alterations may reduce the fertility potential of the male gamete following SCI.

Rodent models for treatment of spinal cord injury: research trends and progress toward useful repair

PURPOSE OF REVIEW

In this review, we have documented some current research trends in rodent models of spinal cord injury. We have also catalogued the treatments used in studies published between October 2002 and November 2003, with special attention given to studies in which treatments were delayed for at least 4 days after injury.

RECENT FINDINGS

Most spinal cord injury studies are performed with one of three general injury models: transection, compression, or contusion. Although most treatments are begun immediately after injury, a growing number of studies have used delayed interventions. Mice and the genetic tools they offer are gaining in popularity. Some researchers are setting their sights beyond locomotion, to issues more pressing for people with spinal cord injury (especially bladder function and pain).

SUMMARY

Delayed treatment protocols may extend the window of opportunity for treatment of spinal cord injury, whereas continued progress in the prevention of secondary cell death will reduce the severity of new cases. The use of mice will hopefully accelerate progress towards useful regeneration in humans. Researchers must improve cross-study comparability to allow balanced decisions about potentially useful treatments.