Anatomy of the lower hypogastric plexus applied to endometriosis: a narrative review.

OBJECTIVE: The objective of the present study is to evaluate the anatomy of the inferior hypogastric plexus, correlating it with urological pathologies, imaging exams and surgeries of the female pelvis, especially for treatment of endometriosis. MATERIAL AND METHODS: We carried out a review about the anatomy of the inferior hypogastric plexus in the female pelvis. We analyzed papers published in the past 20 years in the databases of Pubmed, Embase and Scielo, and we included only papers in English and excluded case reports, editorials, and opinions of specialists. We also studied two human fixed female corpses and microsurgical dissection material with a stereoscopic magnifying glass with 2.5x magnification. RESULTS: Classical anatomical studies provide few details of the morphology of the inferior hypogastric plexus (IHP) or the location and nature of the associated nerves. The fusion of pelvic splanchnic nerves, sacral splanchnic nerves, and superior hypogastric plexus together with visceral afferent fibers form the IHP. The surgeon's precise knowledge of the anatomical relationship between the hypogastric nerve and the uterosacral ligament is essential to reduce the risk of complications and postoperative morbidity of patients surgically treated for deep infiltrative endometriosis involving the uterosacral ligament. CONCLUSION: Accurate knowledge of the innervation of the female pelvis is of fundamental importance for prevention of possible injuries and voiding dysfunctions as well as the evacuation mechanism in the postoperative period. Imaging exams such as nuclear magnetic resonance are interesting tools for more accurate visualization of the distribution of the hypogastric plexus in the female pelvis.

Nerve-sparing surgery for deep lateral parametrial endometriosis.

OBJECTIVE: Although dLPE is not overly rare, isolation of the autonomic nerves from dLPE cannot always be guaranteed. In patients with endometriosis lesions that are embedded in the deep parametrium, nerve-sparing techniques are no longer considered feasible, except for those with unilateral involvement. However, even one-sided radical parametrectomy may actually lead to bladder dysfunction, which seriously affects the quality of life. Therefore, the objective is to demonstrate the anatomical and technical highlights of nerve-sparing laparoscopic surgery for deep lateral parametrial endometriosis (dLPE). DESIGN: Stepwise demonstration of this method with a narrated video footage. SETTING: An urban general hospital. PATIENT(S): A 38-year-old woman, para 1, presented with a 5-year history of severe chronic pelvic and gluteal pain, all of which were resistant to pharmacotherapy. The patient showed no neurological disorders, such as bladder dysfunction. Magnetic resonance imaging revealed right ovarian endometrioma and hydrosalpinx with dLPE reaching the lateral pelvic wall. Based on the dermatome involved, we suspected that the main lesion causing gluteal pain was located around the second and third sacral roots. INTERVENTION(S): Laparoscopic excision of dLPE with a pelvic autonomic nerve-sparing technique, decompression of somatic nerves and preservation of all branches of the internal iliac vessels. Assessment of preserved tissue perfusion using indocyanine green. The procedure was performed using 8 steps, as follows: step 1, adhesiolysis and adnexal surgery; step 2, complete ureterolysis; step 3, identification and dissection of the hypogastric nerve and inferior hypogastric plexus with development of the pararectal space; step 4, dissection of the internal iliac vessels; step 5, identification and dissection of the sacral roots S2-S4 and the pelvic splanchnic nerves; step 6, complete removal of dLPE; step 7, hemostasis and assessment of tissue perfusion using indocyanine green; and step 8, application of barrier agents to prevent adhesion. Dissection of the pelvic nerves before dLPE excision revealed the relationship between the lesions and pelvic innervation, thereby reducing the risk of nerve injury, whether by minimizing the risk of neuropraxia or by allowing as many nerve fibers as possible to be spared in patients with some invasion of the pelvic nerve system. We considered even partial preservation of these nerves as beneficial to the resumption of pelvic organ functions. The step-by-step technique should help perform each stage of the surgery in a logical sequence, ensuring easy and safe completion of the procedure. MAIN OUTCOME MEASURE(S): Relief from severe pain, avoidance of postoperative morbidity (including intermittent self-catheterization). RESULT(S): The patient developed no perioperative complications, including postoperative bladder, rectal, or sexual dysfunctions. Pain was completely resolved. CONCLUSION(S): Nerve-sparing surgery is technically safe and feasible for selected patients with dLPE. Suitably tailored treatment should be provided for each individual based on both latest scientific evidence and life planning for the patient.

Fertility- and Nerve-sparing Laparoscopic Eradication of Deep Endometriosis with Total Posterior Compartment Peritonectomy: The Kurashiki Method.

OBJECTIVE: To show technical highlights of a nerve-sparing laparoscopic eradication of deep endometriosis (DE) with posterior compartment peritonectomy. DESIGN: Demonstration of the technique with narrated video footage. SETTING: An urban general hospital. A systematic review and meta-analysis has suggested significant advantages of the nerve-sparing technique when considering the relative risk of persistent urinary retention in the treatment of DE [1]. In addition, a recent article has suggested that complete excision of DE with posterior compartment peritonectomy could be the surgical treatment of choice to decrease postoperative pain, improve fertility rate, and prevent future recurrence [2]. However, in DE, nerve-sparing procedures are even more challenging than oncologic radical procedures because the pathology resembles both ovarian/rectal cancer in terms of visceral involvement and advanced cervical cancer in terms of wide parametrial infiltration through the pelvic wall. INTERVENTIONS: The video highlights the anatomic and technical aspects of a fertility- and nerve-sparing surgery in DE with posterior compartment peritonectomy. After adhesiolysis and ovarian surgery, we developed retroperitoneal space at the level of promontory. The hypogastric nerve consists of the upper edge of the pelvic plexus, therefore the autonomic nerves were separated in a "nerve plane" by sharp interfascial dissection of the loose connective tissue layers both above (between the fascia propria of the rectum and the prehypogastric nerve fascia) and below (between the prehypogastric nerve fascia and the presacral fascia) the hypogastric nerve [3,4]. As a result of these dissections, the autonomic nerves in the pelvis were separated like a sheet with surrounding fascia. We then completely resected all DE lesions including peritoneal endometriosis while avoiding injury to the nerve plane. In a small number of our experiences, none of the patients (n = 51) required clean intermittent self-catheterization after this procedure. CONCLUSION: Fertility- and nerve-sparing laparoscopic eradication of DE with total posterior compartment peritonectomy is a feasible technique and may provide both curability of DE and functional preservation. Our nerve-sparing technique can reproducibly simplify this complex procedure.

Nerve-sparing in Gynecology.

OBJECTIVE: To demonstrate identification and dissection of the pelvic autonomic nerves in gynecologic surgery. DESIGN: Identification on the right and left pelvic pelvises, dissection and preservation of the inferior hypogastric plexus in deep endometriosis, and dissection and preservation of the pelvic autonomic nerves in radical hysterectomy. SETTING: Academic center. INTERVENTIONS: Robotic excision of the pelvic peritoneum, excision of deep endometriosis in the uterosacral ligaments, and radical hysterectomy. CONCLUSION: Pelvic autonomic nerves are easy to identify with the magnification provided with an endoscopic camera. They should be dissected and preserved whenever possible because of their important function.

Interstitial Cystitis/Bladder Pain Syndrome as Referred Pain From Injured T12/L1 Nerves: Symptomatic Improvement With Resection of Ilioinguinal and Iliohypogastric Nerves.

OBJECTIVE: To evaluate the specific contribution of ilioinguinal (II) and iliohypogastric (IH) nerve injury and referred pain to interstitial cystitis/bladder pain syndrome and patient-reported chronic pelvic pain, and to enumerate the effects of II and IH nerve resection on the pain and voiding symptoms in patients with IC/BPS. MATERIALS AND METHODS: This was a prospective cohort study of 8 patients with ICS/BPS who had prior abdominal surgery. All patients received diagnostic image guided T12/L1 nerve blocks, followed by II and IH nerve resections. Validated O'Leary-Sant ICS symptom indices (OSPI) and pelvic pain and urgency/frequency patient symptoms scale (PUF) scores were collected at specified intervals pre- and post-operatively. RESULTS: Median scores at pre-operative (OSPI 13.9, PUF 20.4) and 1 week time points (OSPI 5.9, PUF 11), as well as differences between pre-operative and 10 month time points (OSPI 3.7, PUF 6) were all statistically significant (P = .008 and .009 at 1 week, and .007 and .008 at 10 months, for OSPI and PUF respectively). The mean difference in score from pre-operative to longest follow-up as measured by the OSPI was -14.4 (P < .001) and by PUF -10.3 (P < .001). All time points registered demonstrated improvement in pain scores. There were no surgical complications or adverse events. CONCLUSION: II and IH nerve resection may be an effective and durable treatment option for those with prior abdominal surgery who have referred interstitial cystitis/bladder pain syndrome pain from these injured nerves.

Identification and injury to the inferior hypogastric plexus in nerve-sparing radical hysterectomy.

Waterjet dissection of the inferior hypogastric plexus (IHP) resulted in a more rapid return of normal urodynamics than blunt dissection (control group) in patients who received laparoscopic nerve-sparing radical hysterectomy (NSRH) in a randomized controlled study. However, the definite reasons for these results were unknown. This subgroup analysis compared the neural areas and impairment in the IHP uterine branches harvested during NSRH as an alternative to the IHP vesical branches between the waterjet and control groups. This study included samples from 30 eligible patients in each group of the trial NCT03020238. At least one specimen from each side of the IHP uterine branches was resected. The tissues were scanned, images were captured, and the neural component areas were calculated using the image segmentation method. Immunohistochemical staining was used to evaluate neural impairment. The control and waterjet groups had similar areas of whole tissues sent for evaluation. However, the control group had significantly fewer areas (median 272158 versus 200439 µm2, p = 0.044) and a lower percentage (median 4.9% versus 3.0%, p = 0.011) of neural tissues. No significant changes in immunohistochemical staining were found between the two groups. For patients with residual urine ≤100 and >100 ml at 14 days after NSRH (42 and 18 patients, respectively), there were significantly different percentages of neural tissues in the resected samples (p < 0.001). Hence, Due to the accurate identification of IHP during NSRH, the waterjet dissection technique achieved better urodynamic results.

Anatomic Cartography of the Hypogastric Nerves and Surgical Insights for Autonomic Preservation during Radical Pelvic Procedures.

STUDY OBJECTIVE: To clarify the relationship of hypogastric nerves (HNs) with several pelvic anatomic landmarks and to assess any anatomic differences between the 2 sides of the pelvis, both in cadaveric and in vivo dissections. DESIGN: Prospective observational study. SETTING: An anatomic theater for cadaveric dissections and a university hospital for in vivo laparoscopy. PATIENTS: Five nulliparous female cadavers underwent laparotomic dissection; 10 nulliparous patients underwent laparoscopic surgery for rectosigmoid endometriosis without posterolateral parametrial infiltration. INTERVENTIONS: Measurements of the closest distance between HNs and ureters, the midsagittal plane, the midcervical plane, and uterosacral ligaments on both hemipelvises. A comparison of anatomic data of the 2 hemipelvises was conducted. MEASUREMENTS AND MAIN RESULTS: The right and left HNs were identified in all specimens, both on cadavers and in vivo dissections. A wide anatomic variability was reported. Regarding the differences between the 2 hemipelvises, we found that the right HN was significantly (p <.001) farther to the ureter (mean = 14.5 mm; range, 10-25 mm) than the left one (mean = 8.6 mm; range, 7-12 mm). The HN was closer to the midsagittal plane on the right side (mean = 14.6 mm; range, 12-17 mm) than on the left side (mean = 21.6 mm; range, 19-25 mm). The midcervical plane was found 2.7 mm (range, 2-4 mm) to the left of the midsagittal one. The right HN was found to be nonsignificantly closer to the midcervical plane and the uterosacral ligament on the right side than on the left side (p >.05). CONCLUSIONS: Despite a wide anatomic variability of position and appearance, the HNs are reproducibly identifiable using an "interfascial" technique and considering the ureters and uterosacral ligaments as anatomic landmarks.

Three-Dimensional Modelization of the Female Human Inferior Hypogastric Plexus: Implications for Nerve-Sparing Radical Hysterectomy.

BACKGROUND/AIMS: This study aims to describe the autonomic nervous network of the female pelvis with a 3D model and to provide a safe plane of dissection during radical hysterectomy for cervical cancer. METHODS: Pelvises of 3 human female fetuses were studied by using the computer-assisted anatomic dissection. RESULTS: The superior hypogastric plexus (SHP) was located at the level of the aortic bifurcation in front of the sacral promontory and divided inferiorly and laterally into 2 hypogastric nerves (HN). HN ran postero-medially to the ureter and in the lateral part of the uterosacral ligament until the superior angle of the inferior hypogastric plexus (IHP). IHP extended from the anterolateral face of the rectum, laterally to the cervix and attempted to the base of the bladder. Vesical efferences merged from the crossing point of the ureter and the uterine artery and ran through the posterior layer of the vesico-uterine ligament. CONCLUSIONS: The SHP could be injured during paraaortic lymphadenectomy. Following the ureter and resecting the medial fibrous part of the uterosacral ligament may spare the HN. No dissection should be performed under the crossing point of the ureter and the uterine artery.

Functional and molecular characterisation of the bilateral pelvic nerve crush injury rat model for neurogenic detrusor underactivity.

OBJECTIVES: To create a rat model for neurogenic detrusor underactivity (DU) by bilateral pelvic nerve crush injury (BPNI) and to study temporal changes in detrusor contractility and morphology. MATERIALS AND METHODS: Male Sprague-Dawley rats were subjected to BPNI or sham surgery and evaluated at 1, 3 and 9 weeks after surgery. Bladder function was determined in vivo by awake cystometry, micturition pattern analysis, and 24-h urine collection. Bladders were harvested for in vitro pharmacological investigation by isometric tension recording. Bladders and major pelvic ganglia were investigated by quantitative reverse transcription-polymerase chain reaction and histochemistry. RESULTS: Overflow incontinence was observed at 1 week after BPNI. At 3 and 9 weeks after BPNI, rats showed a bladder phenotype characteristic for DU with increased post-void residual urine volumes, reduced voiding efficiencies, and lower maximum pressures. In isolated bladder strips, contractile responses to KCl, carbachol, and α,ß-methylene adenosine 5'-triphosphate (α,ß-mATP) were preserved. On the other hand, neural-induced contractility was reduced after BPNI, in line with reduced expression of protein gene product 9.5 and choline acetyltransferase in the major pelvic ganglion at 1 week after BPNI. The bladder-to-body weight ratio and detrusor thickness increased after BPNI, indicating detrusor hypertrophy to compensate for the reduced neural input. CONCLUSIONS: BPNI induces a rat model for neurogenic DU. In this model, the detrusor maintains its contractility but denervation of the detrusor was observed.

Pelvic and hypogastric nerves are injured in a rat prostatectomy model, contributing to development of stress urinary incontinence.

Urinary incontinence affects 40% of elderly men, is common in diabetic patients and in men treated for prostate cancer, with a prevalence of up to 44%. Seventy-two percent of prostatectomy patients develop stress urinary incontinence (SUI) in the first week after surgery and individuals who do not recover within 6 months generally do no regain function without intervention. Incontinence has a profound impact on patient quality of life and a critical unmet need exists to develop novel and less invasive SUI treatments. During prostatectomy, the cavernous nerve (CN), which provides innervation to the penis, undergoes crush, tension, and resection injury, resulting in downstream penile remodeling and erectile dysfunction in up to 85% of patients. There are other nerves that form part of the major pelvic ganglion (MPG), including the hypogastric (HYG, sympathetic) and pelvic (PN, parasympathetic) nerves, which provide innervation to the bladder and urethra. We examine if HYG and PNs are injured during prostatectomy contributing to SUI, and if Sonic hedgehog (SHH) regulatory mechanisms are active in the PN and HYG nerves. CN, PN, HYG and ancillary (ANC) of uninjured, sham and CN crush/MPG tension injured (prostatectomy model) adult Sprague Dawley rats (n = 37) were examined for apoptosis, sonic hedgehog (SHH) pathway, and intrinsic and extrinsic apoptotic mechanisms. Fluorogold tracing from the urethra/bladder was performed. PN and HYG response to SHH protein was examined in organ culture. TUNEL, immunohistochemical analysis for caspase-3 cleaved, -8, -9, SHH, Patched and Smoothened (SHH receptors), and neurite formation, were examined. Florogold positive neurons in the MPG were reduced with CN crush. Apoptosis increased in glial cells of the PN and HYG after CN crush. Caspase 9 was abundant in glial cells (intrinsic), while caspase-8 was not observed. SHH and its receptors were abundant in neurons and glia of the PN and HYG. SHH treatment increased neurite formation. PN and HYG injury occur concomitant with CN injury during prostatectomy, likely contributing to SUI. PN and HYG response to SHH treatment indicates an avenue for intervention to promote regeneration and prevent SUI.

Superior Hypogastric Plexus and Its Surgical Implications During Spine Surgery: A Review.

The superior hypogastric plexus (SHP) is a complex nervous collection located at the lumbosacral region below the level of the aortic bifurcation. As a part of the autonomic nervous system, it is an extension of the preaortic plexuses and continues bilaterally as the hypogastric nerves that ultimately contribute to the inferior hypogastric plexus. Although commonly described as a plexiform structure, several morphologic variations exist. Damage to the SHP can occur during anterior and anterolateral approaches to the lumbosacral spine leading to dysfunction of the abdominopelvic viscera. Visceral afferents travel in the SHP and are responsible for transmitting pain. Management therapies such as SHP blockade or presacral neurectomy can reduce pelvic pain caused by cancer and nonmalignant etiologies. This review highlights some of the recent findings regarding the nature of the SHP.

Effect of TRPV4 activation in a rat model of detrusor underactivity induced by bilateral pelvic nerve crush injury.

AIMS: To produce an animal model of peripheral neurogenic detrusor underactivity (DU) and to evaluate the effect of TRPV4 receptor activation in this DU model. METHODS: In female Sprague-Dawley rats, bilateral pelvic nerve crush (PNC) was performed by using sharp forceps. After 10 days, awake cystometrograms (CMG) were recorded in sham and PNC rats. A TRPV4 agonist (GSK 1016790A) with or without a TRPV4 antagonist (RN1734) were administered intravesically and CMG parameters were compared before and after drug administration in each group. The TRPV4 transcript level in the bladder mucosa and histological changes were also evaluated. RESULTS: In CMG, PNC rats showed significant increases in intercontraction intervals (ICI), number of non-voiding contractions (NVCs), baseline pressure, threshold pressure, bladder capacity, voided volumes, and post-void residual (PVR) compared to sham rats. Contraction amplitude and voiding efficiency were significantly decreased in PNC rats. In PNC rats, intravesical application of GSK1016790A (1.5 µM) significantly decreased ICI, bladder capacity, voided volume, and PVR without increasing NVCs, and these effects were blocked by RN1734 (5.0 µM). In contrast, 1.5 µM GSK1016790A had no significant effects on CMG parameters in normal rats. TRPV4 expression within the bladder mucosa of PNC rats was increased in association with urothelial thickening. CONCLUSIONS: Rats with bilateral PNC showed characteristics of DU, and this model seems appropriate for further evaluation of peripheral neurogenic mechanisms of DU. Also, TRPV4 receptors, the activation of which reduced bladder capacity and PVR, could be a target for DU treatment.

Determining integrity of bladder innervation and smooth muscle function 1 year after lower spinal root transection in canines.

AIMS: To assess bladder smooth muscle function and innervation after long-term lower spinal root transection in canines. METHODS: Thirteen female mixed-breed hound dogs underwent bladder decentralization, which included transection of all sacral dorsal and ventral roots caudal to L7 and hypogastric nerves, bilaterally (n = 3); all sacral roots and hypogastric nerves plus transection of L7 dorsal roots, bilaterally (n = 4); or a sham operation (n = 6). At a year after initial surgery, bladder function was assessed in vivo by stimulation of the pelvic plexus. The bladder tissue was harvested for ex vivo smooth muscle contractility studies. Remaining bladder was evaluated for nerve morphology immunohistochemically using neuronal marker PGP9.5, apoptotic activity using terminal deoxynucleotidyl transferase dUTP nick end labeling, and histopathology using a hematoxylin and eosin stain. RESULTS: Sacral root decentralization did not reduce maximum strength of pelvic plexus stimulation-induced bladder contraction, although long-term sacral dorsal and ventral root plus L7 dorsal root transection significantly decreased contraction strength. Electric field stimulation-induced contractions of the detrusor from all decentralized animals were preserved, compared to controls. Viable nerves and intramural ganglia were visualized in the bladder wall, regardless of group. There was no difference in amount of apoptosis in bladder smooth muscle between groups. CONCLUSION: Bladder smooth muscle cells maintain their function after long-term bladder decentralization. While pelvic plexus-induced bladder contractions were less robust at 1 year after lower spinal root transection, the absence of atrophy and preservation of at least some nerve activity may allow for successful surgical reinnervation after long-term injury.

Nerve-Sparing Technique during Laparoscopic Radical Hysterectomy: Critical Steps.

STUDY OBJECTIVE: To show the feasibility and safety of nerve-preserving laparoscopic radical hysterectomy (type C1 Querleu-Morrow Classification [1]) for the treatment of early cervical cancer. DESIGN: A surgical video article (Canadian Task Force classification III). SETTING: A university hospital (University Hospital of Barcelona, Barcelona, Spain). PATIENTS: Nerve-preserving radical hysterectomy is performed in a patient with Fédération Internationale de Gynécologie et d'Obstétrique stage 1B1 cervical cancer with deep stromal invasion. INTERVENTIONS: Three steps are fundamental for the removal of the cérvix with a safe oncologic margin and preservation of the pelvic autonomic nerves [2]. 1. Step 1: for the correct preservation of the pelvic splanchnic nerves (ventral roots from spinal nerves S2-S4) and the inferior hypogastric plexus during the section of the paracervix, it is essential to identify the deep uterine vein. This vein will correspond with the inferior limit of the dissection. 2. Step 2: during the dissection of the uterosacral ligament and after dissecting the Okabayashi space, the inferior hypogastric nerve is isolated. This nerve runs 2 cm parallel below the uterosacral ligament in the peritoneal leaf of the broad ligament. 3. Step 3: during the section of the vesicouterine ligament, the lateral side must be preserved because it includes the medial and inferior vesical veins that drain to the deep uterine vein. CONCLUSION: Nerve-sparing laparoscopic radical hysterectomy is an attractive surgical approach for early-stage cervical cancer. Direct visualization of the pelvic autonomic nervous system (sympathetic and parasympathetic branches) innervating the bladder and rectum makes the nerve-sparing approach a safe and feasible procedure.

Nerve Sparing and Surgery for Deep Infiltrating Endometriosis: Pessimism of the Intellect or Optimism of the Will.

Nerve-sparing surgery is an emerging technique for surgery-related dysfunction. Within the past 15 years, an essential progress in recognition and understanding of the anatomy of the pelvic autonomous nervous system has been made. Surgical preservation of vegetative nerves has become well known in many cancer centers. The technique has led to improvement of the quality of life following oncologic radical procedures. Positive results have led to the adoption of such techniques in the surgical treatment of deep infiltrating endometriosis in an aim to prevent urinary, rectal, and sexual dysfunction. Even though nerve-sparing excision of endometriosis is feasible and offers good outcomes in terms of bladder morbidity; digestive and sexual functions seem to be more complex to assess. Moreover, functional impairment in deep infiltrating endometriosis may preexist prior to surgery and function may not be restored despite nerve preservation. In cases where endometriosis lesions are deeply embedded in the parametrium, nerve-sparing techniques may only be feasible in those with a unilateral involvement. The nerve-sparing surgical approach is therefore a safer radical surgery in the hands of experienced surgeons that has to be tailored to the unique nature of deep infiltrating endometriosis and balanced between the natural aggressiveness of such a debilitating disease and postoperative morbidity. Good knowledge of pelvic nerve anatomy and function allows understanding of related symptoms to reduce morbidity, whenever this goal is still achievable.

Impotence Following Radical Prostatectomy: Insight into Etiology and Prevention.

This study was undertaken to identify the cause of impotence in men undergoing radical prostatectomy, with the hope that this information may provide insight into the possible prevention of this complication. The autonomic innervation of the corpora cavernosa in the male fetus and newborn was traced to determine the topographical relationship between the pelvic nerve plexus, and the prostate, urethra and urogenital diaphragm. We have demonstrated that the branches of the pelvic plexus that innervate the corpora cavernosa are situated between the rectum and urethra, and penetrate the urogenital diaphragm near or in the muscular wall of the urethra. Injuries to the pelvic plexus can occur in 2 ways: 1) during division of the lateral pedicle and 2) at the time of apical dissection with transection of the urethra. Thirty-one men who underwent radical retropubic prostatectomy were evaluated to determine risk factors that correlated with postoperative impotence: 5 (16 per cent) were fully potent, 7 (23 per cent) had partial erections that were inadequate for sexual intercourse and 19 (61 per cent) had total erectile impotence. The 2 factors that had a favorable influence on postoperative potency were age and pathologic stage of the lesion: 31 per cent of the patients less than 60 years old were potent versus only 6 per cent of the patients more than 60 years, while 33 per cent of the patients with tumor microscopically confined to the prostatic capsule were potent versus only 5 per cent of those with capsular penetration. When the factors of age and capsular penetration were combined 60 per cent of the men less than 60 years old who had an intact prostatic capsule were potent. Arterial insufficiency and psychogenic factors were excluded as major contributing factors by the finding of normal penile blood flow and absence of nocturnal penile tumescence in the impotent patients. We conclude that impotence after radical prostatectomy results from injury to the pelvic nerve plexus that provides autonomic innervation to the corpora cavernosa. Further studies will be necessary to determine whether refinements in surgical technique, especially during ligation of the lateral pedicle and apical dissection, can prevent this complication.

Current concepts and practical techniques of nerve-sparing laparoscopic radical hysterectomy.

Laparoscopic radical hysterectomy has been widely performed for patients with early-stage cervical cancer. The operative techniques for nerve-sparing to avoid bladder dysfunction have been established during the past three decades in abdominal radical hysterectomy, but how these techniques can be applied to laparoscopic surgery has not been fully discussed. Prolonged operation time or decreased radicality due to less accessibility via a limited number of trocars may be a disadvantage of the laparoscopic approach, but the magnified visual field in laparoscopy may enable fine manipulation, especially for preserving autonomic nerve tracts. The present review article introduces the practical techniques for sparing bladder branches of pelvic nerves in laparoscopic radical hysterectomy based on understanding of the pelvic anatomy, clearly focusing on the differences from the techniques in abdominal hysterectomy.

[Anatomical consideration for the technique of nerve-sparing during radical hysterectomy for cervical cancer]. / Bases anatomiques et principe du nerve-sparing au cours de l'hystérectomie radicale pour cancer du col utérin.

Radical hysterectomy (RH) is an effective treatment for early-stage cervical cancer IA2 to IIA1 but RH is often associated with several significant complications such as urinary, anorectal and sexual dysfunction due to pelvic nerve injuries. Pelvic autonomic nerves including the superior hypogastric plexus (SHP), hypogastric nerves (HN), pelvic splanchnic nerves (PSN), sacral splanchnic nerves (SSN), inferior hypogastric plexus (IHP) and efferent branches of the IHP. We aimed to precise the neuroanatomy of the female pelvis in order to provide key-points of surgical anatomy to improve NSRH for cervical cancer. The SHP could be injured during periaortic lymph node dissection and its preservation necessitates an approach on the right side of the aorta and a blunt dissection of the promontory before lomboaortic lymphadenectomy. Injuries to HN can occur during the resection of USL at the posterior pelvic wall and of rectovaginal ligaments and to preserve HN only the medial fibrous part of the uterosacral ligament should be resected. The middle rectal artery, the deep uterine vein and the ureter should be identified to preserve PSN and IHP during resection of paracervix. Vesical branches can be preserved by blunt dissection of the posterior layer of the vesicouterine ligament after identifying the inferior vesical vein. In most of cases, NSRH for cervical cancer can be performed. Anatomical landmarks as middle rectal artery, deep uterine vein, inferior vesical vein and ureter and the respect of nervous part of uterine ligament and of parametrium provide to surgeon a safe preservation of pelvic innervation without compromising oncological outcomes.

[Deep infiltrating endometriosis surgical management and pelvic nerves injury]. / Identification des sites anatomiques à risque de lésion nerveuse lors de chirurgie pour endométriose pelvienne profonde.

OBJECTIVES: Deep pelvic endometriosis surgery may need substantial excisions, which in turn expose to risks of injury to the pelvic nerves. To limit functional complications, nerve-sparing surgical techniques have been developed but should be adapted to the specific multifocal character of endometriotic lesions. The objective was to identify the anatomical areas where the pelvic nerves are most at risk of injury during endometriotic excisions. METHODS: The Medline and Embase databases have been searched for available literature using the keywords "hypogastric nerve or hypogastric plexus [Mesh] or autonomic pathway [Mesh], anatomy, endometriosis, surgery [Mesh]". All relevant French and English publications, selected based on their available abstracts, have been reviewed. Five female adult fresh cadavers have been dissected to localize the key anatomical areas where the pelvic nerves are most at risk of injury. RESULTS: Six anatomical areas of high risk for pelvic nerves have been identified, analysed and described. Pelvic nerves can be damaged during the dissection of retrorectal space and the anterolateral rectal excision. Furthermore, before an uterosacral ligament excision, a parametrial excision, a colpectomy or a dissection of the vesico-uterine ligament, the hypogastric nerves, splanchnic nerves, inferior hypogastric plexus and its efferent pathways must be mapped out to avoid injury. The distance between the deep uterin vein and the pelvic splanchnic nerves were measured on four cadavers and varied from 2.5cm to 4cm. CONCLUSION: Six key anatomical pitfalls must be known in order to limit the functional complications of the endometriotic surgical excision. Applying nerve-sparing surgical techniques for endometriosis would lead to less urinary functional complications and a better short-term postoperative satisfaction.

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.