Expression and distribution of key proteins of the endocannabinoid system in the human seminal vesicles.

The endocannabinoid system (ECS), comprising the cannabinoid receptors (CBR), their ligands, and enzymes controlling the turnover of endocannabinoids, has been suggested to be involved in male reproductive function. As information is scarce on the expression of the ECS in human male reproductive tissues, this study aimed to investigate by means of molecular biology (RT-PCR) and immunohistochemistry/immunofluorescence the expression and distribution of CB1 and CB2, GPR55 (an orphan G protein-coupled receptor that recognises cannabinoid ligands) and FAAH (isoforms 1 and 2) in the human seminal vesicles (SV). The specimens expressed PCR products corresponding to CB1 (66 bp), CB2 (141 bp), GPR55 (112 bp), FAAH1 (260 bp) and FAAH2 (387 bp). Immumohistochemistry revealed dense expression of CB1, CB2 and GPR55 located to the pseudo-stratified columnar epithelium and varicose nerves (also characterised by the expression of vasoactive intestinal polypeptide and calcitonin gene-related peptide). Cytosolic staining for FAAH1 and FAAH2 was seen in cuboidal cells of all layers of the epithelium. No immunoreactivity was detected in the smooth musculature or nerve fibres. CB1, CB2, GPR55, FAAH1 and FAAH2 are highly expressed in the human SV. Considering their localisation, the ECS may be involved in epithelial homeostasis, secretory function or autonomic mechano-afferent signalling.

Pelvic nerve injury negatively impacts female genital blood flow and induces vaginal fibrosis-implications for human nerve-sparing radical hysterectomy.

OBJECTIVE: This study sought to develop a novel animal model to study the impact of nerve-sparing radical hysterectomy (NSRH) on female genital blood flow. DESIGN: In vivo animal study. POPULATION: Thirty Sprague-Dawley female rats. MATERIALS AND METHODS: Female rats underwent either unilateral pelvic nerve (PN) crush (PNC; n = 9), or crush of both the PNs and all efferent nerves in the pelvic plexus ('clock-nerve crush', CNC; n = 9). Under anaesthesia, we electrically stimulated the crushed PN at 3 and 10 days after crush while monitoring blood pressure and recording clitoral and vaginal blood flows by laser Doppler. Uninjured PNs were stimulated as an internal control. Twelve additional rats were assigned either to bilateral PNC or sham surgery, and genital tissues were processed 10 days after injury for in vitro analysis. MAIN OUTCOME MEASURES: Genital blood flow, nNOS, eNOS, collagen I-III. RESULTS: Stimulation of the crushed PN in both groups subjected to PNC and CNC induced significantly lower peak genital blood flow at 3 and 10 days (P < 0.05) compared to stimulation of the non-crushed control PN. The immunofluorescence and Western blot analyses revealed that all injured rats exhibited more vaginal collagen III and collagen I than rats did that ad undergone sham surgeries (P < 0.05). PCN reduced nNOS expression in both clitoral and vaginal tissue. CONCLUSIONS: Based on our study it may be hypothesised that NSRH might cause reductions of genital blood flow and vaginal fibrosis due to neurapraxia of the pelvic nerve and reductions of nNOS nerve fibres in clitoral and distal vaginal tissue. TWEETABLE ABSTRACT: Pelvic nerve neurapraxia during nerve-sparing radical hysterectomy could lead to sexual arousal dysfunction.

The analgesic tramadol has minimal effect on gastrointestinal motor function.

AIMS: The analgesic tramadol, an opioid agonist and monoaminergic reuptake blocker, has been assumed to interfere less with gastrointestinal motor function than other opioid analgesics, but this has not been specifically investigated. In this study we examined the effect of tramadol on variables of gastrointestinal motor function. METHODS: Ten healthy volunteers participated in a two-arm, placebo-controlled, double-blind, randomized, cross-over study comparing tramadol 50 mg and placebo solutions given four times a day for 10 days. Oro-caecal (lactulose H2-breath test) and colonic (solid markers) transit times and anal sphincter pressures were measured after 10 days dosing. RESULTS: Median oro-caecal transit time was 90 min (interquartile range: 75-105) with placebo and 90 min (60-105) with tramadol (not significant). The median total colonic transit time increased from 45.6 h (25.2-64.8) with placebo to 58.8 h (50.4-78.0) with tramadol (not significant), which is still within the normal range (< 60 h). Anal sphincter resting pressures were not significantly changed by tramadol compared with placebo. CONCLUSIONS: Tramadol has a minor delaying effect on colonic transit, but no effect on upper gastrointestinal transit or gut smooth muscle tone. Tramadol may be a useful analgesic where interference with gut motor function is undesirable.