Complete Periprostatic Anatomy Preservation During Robot
Transcription
Complete Periprostatic Anatomy Preservation During Robot
EUROPEAN UROLOGY 58 (2010) 407–417 available at www.sciencedirect.com journal homepage: www.europeanurology.com Surgery in Motion Complete Periprostatic Anatomy Preservation During Robot-Assisted Laparoscopic Radical Prostatectomy (RALP): The New Pubovesical Complex-Sparing Technique Anastasios D. Asimakopoulos a,*, Filippo Annino b, Alejandro D’Orazio c, Clovis Fraga T. Pereira d, Camille Mugnier c, Jean-Luc Hoepffner c, Thierry Piechaud c, Richard Gaston c a Division of Urology, Department of Surgery, Policlinico Tor Vergata, University of Tor Vergata, Rome, Italy b Department of Urology, University of Modena and Reggio Emilia, Modena, Italy c Department of Urology, Clinique Saint Augustin, Bordeaux, France d Serviço de Urologia do Instituto de Medicina Integral Prof. Fernando Figueira – IMIP, Recife/PE, Brazil Article info Abstract Article history: Accepted April 29, 2010 Published online ahead of print on May 18, 2010 Background: Puboprostatic ligament preservation has been proposed as a method to accelerate continence recovery after radical prostatectomy (RP). However, these ligaments present anatomic continuity with the bladder, and there must be interruption at some point to expose the prostatourethral junction. Objectives: To describe the surgical steps of pubovesical complex (PVC)–sparing robotassisted laparoscopic RP (RALP) and present the preliminary results of our technique. Design, setting, and participants: Thirty PVC-sparing RALP procedures were performed in patients <60 yr with clinically localised prostate cancer between 2007 and 2009 by the same surgeon. Surgical procedure: The principles of bladder neck preservation, tension and energy-free dissection of the bundles as well as seminal vesicle sparing are applied. Ventrally, a plane of dissection is developed between the detrusor apron and the prostate. The soft connective tissue between Santorini’s plexus and the prostate is blandly dissected, leaving the plexus intact and in place. Measurements: The rates and location of positive surgical margins (PSM) as well as functional outcomes are presented. Results and limitations: Three of 30 patients (10%) had a PSM (two apical margins and one on the left posterolateral side). At catheter removal, 24 of 30 patients (80%) were dry (0 pads), and 6 of 30 patients (20%) needed one security pad. After 3 mo, 22 of 30 patients (73%) presented an International Index of Erectile Function score >17 (with or without phosphodiesterase type 5 inhibitors). Thirteen of 22 potent patients had an Erection Hardness Score of 3, and 9 of 22 patients had a score of 4. Small sample size, low mean age of enrolled patients (52 yr), and the absence of diseases that could impair the continence and potency recovery are some of the limitations of the study. Moreover, it is difficult to quantify the effect of each applied continence-sparing technique. Conclusions: The holistic preservation of the PVC during RALP is technically feasible. It leads towards an absolute preservation of the periprostatic anatomy that may enhance early functional outcomes. Further studies are needed to confirm our results. Keywords: Pubovesical complex Robot-assisted prostatectomy Radical prostatectomy Early incontinence Prostate cancer Detrusor apron Dorsal vascular complex Please visit www.europeanurology.com and www.urosource.com to view the accompanying video. # 2010 European Association of Urology. Published by Elsevier B.V. All rights reserved. * Corresponding author. University of Rome Tor Vergata, Viale Oxford 81, 00133, Rome, Italy. Tel. +39 06 20902835/+39 340 6054387; Fax: +39 06 20902975. E-mail address: tasospao2003@yahoo.com (A.D. Asimakopoulos). 0302-2838/$ – see back matter # 2010 European Association of Urology. Published by Elsevier B.V. All rights reserved. doi:10.1016/j.eururo.2010.04.032 408 1. EUROPEAN UROLOGY 58 (2010) 407–417 Table 2 – Inclusion and exclusion criteria Introduction Inclusion criteria Stress urinary incontinence represents one of the most feared complications of radical prostatectomy (RP) [1]. Patients expect not only to be continent but also to have a quick return to continence. Some robot-assisted laparoscopic RP (RALP) series report continence rates at catheter removal of about 70% [2]; however, the weighted mean continence rate immediately after catheter removal following RALP is 25.7% [3]. Evidently, early recovery of urinary continence remains a challenge to be overcome. Puboprostatic ligament preservation has been proposed to achieve accelerated return of continence after nervesparing procedures. Even with this technique, the rates of postoperative continence remain low [4]. A possible explanation could be that because there is demonstrable anatomic continuity with the bladder, there are no conceivable means of preserving the pubovesical ligaments during RALP, and there must be interruption at some point to expose the prostatourethral junction [5,6]. The management of the dorsal vascular complex (DVC) could also have important implications in continence recovery [7]. It has been demonstrated that the ‘‘cut and ligate’’ of the DVC technique offers quicker continence recovery than a ‘‘ligate and cut’’ technique [7]. However, both selective and standard ligation present inherent drawbacks (see Appendix A); thus, a ‘‘no touch’’ approach might be the ideal way to manage the DVC. The aim of our study was to propose and describe the steps of a new technique of surgical dissection that maximises the preservation of the periprostatic anatomy by keeping intact the pubovesical complex (PVC; ie, detrusor apron with pubovesical ligaments, DVC). To our knowledge, this is the first demonstration of the feasibility of this technique in the field of RALP. Our preliminary oncologic and functional results are also presented. Age <60 yr Clinically organ-confined disease (cT1–cT2a) Gleason score !6 Total serum PSA !10 ng/ml Normal preoperative continence, IIEF-6 >17 and normal IPSS Exclusion criteria Preoperative incontinence or erectile dysfunction Prostatic volume >60 ml Neoadjuvant therapy Any previous prostatic, urethral, or bladder neck surgery Positive anterior biopsy Positive MRI of the anterior prostate PSA = prostate-specific antigen; IIEF-6 = International Index of Erectile Function; IPSS = International Prostate Symptom Score; MRI = magnetic resonance imaging. All patients were staged according to the surgeon’s protocol for intrafascial dissection with a prostatic endorectal magnetic resonance imaging (MRI) scan (to evaluate the likelihood of extracapsular extension). Preoperative continence and erectile status were evaluated as documented by the International Continence Society (ICS) male short form (ICSmaleSF) questionnaire [8] and the International Index of Erectile Function (IIEF-6) erectile function domain score questionnaire (questions 1–5 and 15). Vascular (eg, diabetes mellitus, hypertension, dyslipidaemia, coronary artery disease) or neurologic comorbidities were prospectively registered in our database both in number and in severity. The presence of such conditions did not represent exclusion criteria, provided preoperative continence and potency were normal. (Inclusion and exclusion criteria are reported in Table 2. Prospectively collected data are shown in Table 3.) Biochemical recurrence (BCR) was defined as a serum prostatespecific antigen (PSA) level >0.2 ng/ml on two consecutive measurements. Acute toxicity of adjuvant radiation therapy (RT; onset <90 d after the start of the treatment) was scored using the Common Toxicity Criteria version 2.0 [9]. Late toxicity was scored according to the Radiation Therapy Oncology Group/European Organisation for Research and Treatment of Cancer morbidity scale version 9 [10]. All medical and surgical complications occurring both in inpatient and outpatient settings were recorded. They were classified as early (onset <30 d), intermediate (31–90 d), and late (>90 d) and graded 2. Methods and patients 2.1. Patient selection and eligibility criteria according to the modified Clavien classification [11]. 2.2. The PVC-sparing RALP was applied in 30 men with clinically localised prostate cancer (PCa) from October 2007 to March 2009. All the procedures were performed by one experienced surgeon (RG; previous experience shown in Table 1). The study was conducted in accordance with Good Clinical Practice rules and with the ethical principles contained in the Declaration of Helsinki as amended in Hong Kong. Each patient gave written informed consent, and the study protocol obtained institutional review board approval. Surgical technique The patient and trocar positions and the initial steps of the surgery, including the peritoneal incision, Retzius space preparation, and the tension and energy-free nerve-sparing dissection have been previously described [12]. We focus here on the refinements of our technique. 2.2.1. Bladder neck dissection: right side The catheter balloon previously filled to 5 ml is deflated, aiding in the identification of the bladder neck. The robotic atraumatic grasper is advanced in the operating field, and it gently retracts the bladder. We start the dissection on the right side, in the limit between the detrusor and the base of the prostate, lateral to the pubovesical Table 1 – Previous experience of the senior surgeon Type of prostatectomy Open RP (retropubic plus perineal) Laparoscopic RALP Years 1984–1997 1997–today 2001–today Total cases 1000 3500 1400 RP = radical prostatectomy; RALP = robot-assisted laparoscopic radical prostatectomy. ligaments. We develop this plane in depth, reaching the Denonvilliers’ fascia that covers the anterior surface of the seminal vesicle. (According to some authors [13], no Denonvilliers’ fascia is present anterior to the seminal vesicles—only a muscular structure with longitudinal disposition of the fibres tented between the outer layer of the bladder muscle and the prostate base. The incision exposes the vas deferens and the seminal vesicles.) Some big arterial branches for the base of the prostate located here are carefully clipped (Aesculap/B Braun, Melsungen, EUROPEAN UROLOGY 58 (2010) 407–417 409 Table 3 – Prospectively collected data Preoperative data: Age Vascular/neurologic comorbidities Preoperative PSA Clinical stage Prostate volume (by TRUS) Total biopsy cores Positive biopsy cores Biopsy Gleason score IIEF-6 IPSS ICSmaleSF MRI Intraoperative data: Surgical time Blood loss Transfusion rate Intraoperative complications Bilateral nerve-sparing procedures Postoperative data: Hospital stay Drainage blood secretion Catheterisation time Postoperative complications (also outpatient ones), graded according to the modified Clavien classification Pathologic stage and Gleason score Surgical margin status (positive or negative) Location of PSM Extension of PSM (focal vs extensive) Number of foci of PSM ICSmaleSF (baseline, 3, 6, and 12 mo) IIEF-6 (baseline, 3, 6, and 12 mo) EHS (baseline, 3, 6, and 12 mo) PSA every 3 mo Gastrointestinal/genitourinary toxicity of adjuvant RT PSA = prostate-specific antigen; TRUS = transrectal ultrasounds; IIEF-6 = International Index of Erectile Function-6; IPSS = International Prostate Symptom Score; ICSmaleSF = International Continence Society male short form; MRI = magnetic resonance imaging; PSM = positive surgical margins; EHS = Erection Hardness Score; RT = radiation therapy. Fig. 1 – Evidence of the triangular space formed by the base of the prostate, the bladder neck, and the right neurovascular bundle, closed inferiorly by the seminal vesicle. NVB = neurovascular bundle. Germany). At the end of this dissection, a triangular space is created and traction on them could cause disruption of the capsule. These small formed by the base of the prostate, the bladder neck, and the right arteries should be identified, clipped, and divided (Fig. 2). neurovascular bundle (NVB), closed inferiorly by the seminal vesicle Considering the low risk of cancer involvement in the distal part of (Fig. 1). In this way, not only is the lateral aspect of the bladder neck the seminal vesicles of the studied group, we performed a seminal exposed but also the dissection of the NVB begins. vesicle–sparing technique. The artery to the seminal vesicle is clipped and divided (not coagulated). No traction is applied. The same procedure 2.2.2. Nerve-sparing technique: the lateral dissection is applied for the vas deferens. A variable but consistent amount of nerves can be found along the ventral We repeat the same type of bladder neck dissection, NVB preservation, circumference of the prostatic capsule [14]. To preserve a maximum and seminal vesicle/vas deferens transection on the left side of the prostate. number of nerves, we perform a high incision for nerve sparing. With the NVB totally released, the posterior plane is developed by a lateral The endopelvic fascia followed by the prostatic fascia is opened at the approach anterior to the posterior layer of the Denonvilliers’ fascia, which 2 o’clock position. The intrafascial plane between the visceral prostatic remains in place, covering the perirectal fat. This hypovascular plane can be fascia and the capsule, which is deep to the venous sinuses of Santorini’s created easily using blunt dissection. The bladder neck is left intact and plexus, is developed with blunt dissection using articulated scissors; preserved: We transect it only at the end of the prostatectomy. At this point, bipolar coagulation is used only as necessary. The right NVB is carefully we focus on the ventral surface of the prostate. rolled off the lateral surface of the midprostate. This ‘‘lateral approach’’ permits global vision of the bundle and takes into consideration the 2.2.3. curve it makes on the posterolateral surface of the midgland as well as The tissue that obscures the prostate in part constitutes an extension of Detrusor apron and pubovesical complex preservation the variations in its course, which depends on prostate volume [15]. the anterior wall of the bladder beyond the bladder neck (the detrusor After the initial dissection of the middle part of the bundle, we apron [DA]) [5,6]. This tissue can be grasped with the robotic atraumatic continue its dissection in two parts—first a cranial part (retrograde, grasper (Figs. 3 and 4). Along the anterior commissure from the point at towards the base of the prostate in order to reach the base of the seminal which the DA leaves the prostate (to attach to the pubis) to the anterior vesicle), and then the caudal part (antegrade, towards the apex). Major prostate-urethral junction, an avascular plane is present (Fig. 5). The attention should be given in the dissection of the NVB towards the apex, fibromuscular tissue between the DVC and the prostate is dissected at because one or two small arteries leave the bundle to enter the prostate, the midline, between the pubic symphysis and the anterior commissure of 410 EUROPEAN UROLOGY 58 (2010) 407–417 Fig. 4 – Detrusor apron (DA) grasped by the robotic atraumatic grasper. The asterisk represents the attachment of the DA to the pubis. The dashed line indicates the anterior commissure of the prostate and corresponds to the dissection plane that should be followed to separate the DA by the ventral surface of the gland. P = prostate; B = bladder. Fig. 2 – The asterisk represents a clipped distal artery that leaves the neurovascular bundle (NVB; between the dashed lines) to penetrate into the prostate. P = prostate; A = apex of the gland. the prostate, usually without severing any veins, as this is a relatively avascular plane (Figs. 6 and 7) [5]. Following the same plane of dissection, we separate the DA with the pubovesical ligaments from the anterior surface of the prostate (Figs. 8 and 9). The urethra is then divided. The bladder neck is preserved and divided by a lateral approach at the end of the procedure. Fig. 10 shows the final aspect of the surgical field. 2.2.4. A Urethrovesical anastomosis running urethrovesical anastomosis (3-0, Poliglecaprone 25; DemeTECH, Miami, FL, USA) is achieved by a lateral view starting at the 5 o’clock position. Because the PVC is spared, it is necessary to perform the anastomosis in two halves, passing the needle under the complex on two occasions. Fig. 5 – The curved arrow indicates the avascular plane present between the point at which the detrusor apron (DA) leaves the prostate (to attach to the pubis) to the anterior prostate-urethral junction. From this level, it starts the anterior dissection of the pubovesical complex (ie, the DA and the dorsal vascular complex, sparing both the structures). P = prostate; A = apex; NVB = neurovascular bundle. * Dorsal vascular complex. The quality of the anastomosis is tested for any leaks. A pelvic drain is placed via one of the robotic ports; the prostate is then removed in an endobag (Vygon Lapbag [75 " 150], Unimax Medical Systems, Tapei Hsien, Taiwan) via an umbilical incision. 2.2.5. Postoperative care The drain is removed when the volume is <100 ml/d or in the absence of any suspicious signs of a urinary fistula. Patients are regularly discharged with the Foley catheter still in place; the catheter is then electively removed on an outpatient basis. Fig. 3 – Focus on the anterior prostate. P = prostate; DA = detrusor apron, PVF = prostatic visceral fascia. All the patients received therapy with phosphodiesterase type 5 inhibitors (PDE5-Is) (initially, tadalafil 20 mg, one capsule twice per EUROPEAN UROLOGY 58 (2010) 407–417 Fig. 6 – The fibromuscular tissue between the DVC and the prostate is dissected at the midline. A = prostate apex; DVC = dorsal vascular complex. * Membranous urethra. ** Fibromuscular tissue between the DVC and the prostate. 411 Fig. 8 – Development of the plane of dissection (curved arrow) between the detrusor apron and the anterior prostatic surface. The assistant pulls the gland to the right side. The preserved bladder neck is clearly evident (through a lateral view). week; then, tadalafil 5 mg, one capsule per day) for the first 2 mo after surgery and thereafter as subjectively needed. 2.3. Histopathology Details about specimen processing are reported in Table 4. Fig. 11 shows the histologic differences between a standard and a pubovesical-sparing technique. 2.4. Functional outcome assessment Validated questionnaires were mailed to the patients, and their answers were received via mail. The mailed questionnaires included ICSmaleSF, Fig. 9 – The anterior surface of the prostate has been totally freed from both the detrusor apron and the dorsal vascular complex. P = prostate; DA = detrusor apron; DVC = dorsal vascular complex; NVB = neurovascular bundle. * Bladder neck. ** Membranous urethra. IIEF-6, and Erection Hardness Score (EHS) at baseline, 3, 6, and 12 mo after surgery. Nonresponders were sent a follow-up questionnaire. A third party not involved in direct patient care collected the data. The number of pads the patient used at catheter removal and at 3, 6, and 12 mo after surgery was assessed. Potency was defined as an IIEF-6 score #17 (with or without PDE5-Is). 3. Fig. 7 – Dissection of the fibromuscular tissue (**) between the dorsal vascular complex (DVC) and the prostate in the midline. Combined movements of sharp and mainly bland dissection, with an upward direction, are necessary to detach the DVC from the anterior prostatic surface. A = apex. * Membranous urethra. Results Thirty patients were prospectively evaluated. Their preoperative characteristics are summarised in Table 5. The perioperative, postoperative, and pathologic results are reported in Tables 4, 6 and 7. The PSA nadir was <0.01 ng/ml in all cases. After a median follow-up of 21 mo (range: 12–30), no patient had 412 EUROPEAN UROLOGY 58 (2010) 407–417 Table 4 – Pathologic data specimen processing Fixation Coating (to delineate surgical margins) Specimen processing Apex Bladder neck section TNM classification PSM definition Mean specimen weight, g Pathologic Gleason score 5 (2 + 3 or 3 + 2) 6 (3 + 3) 7 (3 + 4) Mean pathologic Gleason score Site of PSM Single vs multiple PSM sites Focal** versus nonfocal PSM En bloc, 10% neutral buffered formalin India ink Whole mount technique [16]; specimens were step-sectioned transversely at 2–4-mm intervals An apical shaved section, 2–4-mm thick, was truncated perpendicular to the prostatic urethra and subsequently sectioned as slices parallel to the prostatic urethra Either by sampling portions of tissue at the junction of the prostatic capsule and bladder neck or by sampling the most proximal portion of the submitted specimen corresponding to the anatomical bladder neck 2002 Tumour cells in contact with ink 39 (range: 32–54) 0 16 14 6.5 2 apical (1 right, 1 left)* 1 left posterolateral 3 vs 0 2 vs 1 PSM = positive surgical margin. In both cases, the preoperative biopsy was positive in the apex. ** Focal was defined a PSM <1 mm. * experienced BCR. Three patients with PSMs received adjuvant RT. Mean time between surgery and irradiation was 52 d (range: 45–60). No acute or late gastrointestinal toxicity was observed. Data on genitourinary toxicity (GUT) are reported in Table 8. Only a late grade 3b complication (anastomotic stricture) was observed and endoscopically resolved (Table 6). 3.1. Continence At catheter removal, 80% (24 patients) were completely dry (0 pads), while 20% (6 patients) used a single liner for security Table 5 – Preoperative patient characteristics Mean age, yr (range) Mean PSA, ng/ml (range) Mean prostate volume as evaluated by TRUS, ml (range) Gleason score of the biopsy 5 (2 + 3 or 3 + 2) 6 (3 + 3) Mean biopsy Gleason score Clinical stage cT1c cT2a Median total biopsy cores, no. (range) Median positive biopsy cores, no. (range) Comorbidities 52 (43–60) 7.15 (3.8–10) 35.5 (27–42) 4 26 5.9 21 9 16 (12–19) 3 (1–5) One case of hypertension; one case of dyslipidaemia PSA = prostate-specific antigen; TRUS = transrectal ultrasound. Table 6 – Perioperative and postoperative data Fig. 10 – The final aspect of the surgical field. The prostate has already been shelled out from underneath the spared pubovesical complex; the urethrovesical anastomosis has been performed under the spared complex by a running suture with lateral approach. DA = detrusor apron. * Accessory pudendal artery. Mean operative time, min (range) Bilateral nerve-sparing procedures Transfusion rate Mean blood loss, ml (range) Mean bladder catheterisation time, d (range) Urinary retention Stenosis of the anastomosis Urine leak Prolonged drain secretion of blood Mean hospital stay, d 132 (70–180) 30/30 0/30 (0%) 96 (70–230) 8.53 (7–9) 0/30 (0%) 1/30 (3%) 0/30 (0%) 0/30 (0%) 3.8 Pathologic stage pT2a pT2b pT2c pT2 overall pT3a 4 (13.3%) 5 (16.6%) 18 (60%) 27 (90%) 3 (10%) 413 EUROPEAN UROLOGY 58 (2010) 407–417 Fig. 11 – Final pathology: (A) standard dissection and (B) pubovesical complex preservation. In the lower part of the figure, the microscopic view of the inserts is provided. In (A), the order of the tissues (from anterior to posterior) is ink, striated muscle (detrusor apron), fat tissue, striated muscle fibres mingled with some smooth muscle fibres, and prostatic parenchyma with glands. When the detrusor apron (DA) is preserved (B), the striated muscular layer (DA) and the majority of fat tissue (that represents our marker during the anterior dissection) are no longer visible. A mixed smooth and striated muscle layer covers the glandular parenchyma. Even if no prostatic capsule is present at this level, the limit of the prostate can be still well identified by the presence of these muscular fibres (which assume a more circular orientation at this level). In all cases, in the microscopic evaluation, this muscular layer was respected; thus, no benign prostatic glandular tissue was left in place during the anterior dissection. Table 7 – Overall rate of positive surgical margins and distribution per pathologic stage Pathologic stage pT2a pT2b pT2c pT3a Overall pT2 PSM rate PSM = positive surgical margin. PSM cases (%) 0/4 (0) 0/5 (0) 2/18 (11) 1/3 (33) 3/30 (10) 2/27 (7) Table 8 – Genitourinary toxicity in patients who received adjuvant radiation therapy Acute One case of grade 1 urgency One case of grade 1 urinary incontinence Late One case of grade 2 pollakisuria/nocturia (resulting from an anastomotic stricture and resolved endoscopically 12 mo after RALP) – RALP = robot-assisted laparoscopic radical prostatectomy. 414 EUROPEAN UROLOGY 58 (2010) 407–417 Table 9 – Potency evaluation according to Mulhall criteria [17] Surgeon volume Patient comorbidity profile Collection of erectile function outcome data Validated questionnaires used Baseline erectile function data Definition of adequate erectile function Proportion of men returning to normal erectile function (12 mo) Proportion of men returning to preoperative IIEF-6 score (12 mo) Extent of use of erectogenic medications (3 mo) Extent to which a rehabilitation strategy was used See Table 1 One case of hypertension, one case of dyslipidaemia Third party IIEF-6, EHS Mean IIEF-6 score: 23.2 IIEF-6 score >17 100% 86.7% See Fig. 13 Tadalafil 20 mg twice per week/tadalafil 5 mg once per day for 2 mo, then as subjectively needed IIEF-6 = International Index of Erectile Function-6; EHS = Erection Hardness Score. Fig. 12 – Potency evaluation at 3 months. IIEF = International Index of Erectile Function. Fig. 14 – Erection Hardness Score. reasons. One month after surgery, all the patients were completely dry. According to the ICSmaleSF questionnaire (0 max, 24 min), 28 patients presented a score of 0, while two patients scored 1 (loss of urine when coughing or sneezing) at catheter removal. Both patients with acute GUT recovered within 3 mo; thus, the global continence rates (at catheter removal, 1 mo, and 12 mo after surgery) were not influenced. 3.2. Potency/penile rigidity The first potency evaluation was performed after 3 mo of follow-up (time to nadir in erectile function after RP [17]). Results are reported in Table 9 and Figs. 12–15. Fig. 15 – International Index of Erectile Function (IIEF-6) score. * Significance at p < 0.05. 4. Fig. 13 – Extent of utilisation of erectogenic medications. PDE5-Is = phosphodiesterase type 5 inhibitors. Discussion The traditional descriptions of puboprostatic ligament– sparing surgery do not take into consideration the ligaments’ demonstrable anatomic continuity with the bladder [5,6,18]. As a consequence, in all the described techniques, there is an interruption of these ligaments at some point to expose the prostatourethral junction. When surgeons declare that they do not take down EUROPEAN UROLOGY 58 (2010) 407–417 these ligaments, they mean that they do not interrupt their continuity by disarticulation at their junction with the pubis [5,6]. In the perineal operation, these structures are spared, because the prostate is shelled out from underneath the overlying DA and DVC [5,19]. With our study, we demonstrate for first time that the PVC can be also preserved during RALP. Our anterior dissection aims to spare the anatomical structure that physiologically supports the external urethral sphincter and preserves the urethra in its normal place in the pelvic floor. With this technique, no additional manoeuvres (suspension stitches of the periurethral complex [20,21], puboperineoplasty [22]) are necessary for anterior stabilisation of the urethral sphincter. Moreover, by keeping the DVC intact, we avoid the drawbacks of both the selective and the standard ligation techniques (see Appendix A). Careful patient selection with low-risk PCa maximises the oncologic outcome. The overall rate of PSM in our study was low and conforms to the literature [23]. In our practice, all the candidates for intrafascial dissection are submitted to endorectal MRI, aiming to improve the staging even for T1c disease [24]. In a small cohort of patients like ours, performing this technique may not have hindered the final oncologic outcome in terms of anterior PSMs, but if the technique is routinely performed, the risk of anterior PSM could become clinically significant. In this direction, endorectal MRI could also aid in reducing the risk of misdiagnosed anterior PCa, because it provides excellent imaging of the whole gland, including the challenging anterior part [25]. In addition, at least two biopsies per side of the anterior prostate were obtained in the candidates of this technique, because they could increase detection rate in patients with negative digital rectal examination and elevated PSA [26] levels (ie, the majority of our patient cohort). 415 The described technique, although feasible, is not easy to perform. The lateral approach to the bladder neck requires experience to be performed safely. Even if preservation of the bladder neck is thought to compromise cancer control by increasing the likelihood of PSM at the prostate base [27] and therefore adversely affecting cancer control [28], we did not observe PSMs at the prostate base with bladder neck preservation. Finding and developing the avascular plane between the DA and the anterior prostate-urethral junction under the DVC is demanding. Attention should be given to small prostates, where the length of the avascular plane is shorter and consequently the DVC, the urethral sphincter, and the NVBs could easily be damaged. In contrast, in very large glands, the DA appears thinner and more spread out, and consequently its dissection from the anterior prostate is more difficult. Performing the urethrovesical anastomosis under the preserved PVC is another demanding step. The use of the fourth robotic arm to pull the DA, exposing the prostatourethral junction, is of paramount importance. It is important to underline that in our experience, the single steps of the described technique were progressively matured; now, they are described in their totality as a set of surgical manoeuvres. Table 10 reassumes the surgical principles of our technique. To our knowledge, the rate of urinary continence at catheter removal is the highest reported in the literature. The majority of our patients were dry at catheter removal, and the remainder only required the use of one security liner. All patients but one (97%) did not complain of any interference of their urinary symptoms with their quality of life. The published weighted mean potency rate 3 mo after RALP is 38.4% [3]. In our study, 73% of patients presented with an IIEF-6 score #17 (with or without PDE5-Is) associated with an EHS #3 for the same follow-up period. Our highly Table 10 – Surgical tips and suggestions 1 2 3 4 5 6 7 8 9 Even if bladder neck preservation does not seem to hinder the oncologic outcome in terms of PSM, extra attention should be paid if preoperative biopsies of the prostate basis are positive for high-grade PCa. Proper patient selection is crucial. Before all the traction manoeuvres of the prostate, free the NVBs, preferably with a high anterior release technique, to maximise the preservation of the periprostatic neuronal network and obtain a tension-free dissection. Use clips to control small vessels, and avoid use of energy near the NVBs (energy-free dissection). Minimise the risk of treating patients with anterior (thus nonpalpable) tumours. Endorectal MRI and additional biopsy cores of the anterior prostate could be helpful. Preserve any accessory pudendal artery to maintain oxygenation of the erectile tissue. Choose adequate prostate volumes. In very small prostates, the avascular plane between the PVC and the prostate-urethral junction is short (risk of damaging of urethral sphincter, NVBs, DVC), while in very large prostates, the DA is thin and thus difficult to dissect from the anterior surface of the prostate. Use the fourth robotic arm with the atraumatic grasper to pull the DA and expose adequately the prostate-urethral junction. In low-risk PCa, there is a very low risk of PCa involvement of the distal part of the seminal vesicles (<0.3%); thus, the tips of the seminal vesicles could be left in place, probably without hindering the final oncology. This manoeuvre reduces the risk of injury of the cavernous nerves and consequently could improve continence and potency rates. Remember that there is no single ‘‘trick’’ for obtaining perfect functional outcomes. Bladder neck preservation, maximised preservation of the periprostatic nerves through the high anterior release technique, tension and energy-free dissection of the NVBs, sparing the reflection of the endopelvic fascia (associated with an intrafascial dissection), seminal vesicle sparing, preservation of any accessory pudendal artery, and the PVC-sparing techniques as a set of surgical manoeuvres, lead to maximised preservation of the periprostatic anatomy, which is probably the key to success for a modern prostatectomy. PSM = positive surgical margin; PSA = prostate-specific antigen; NVB = neurovascular bundle; MRI = magnetic resonance imaging; DVC = dorsal vascular complex; PVC = pubovesical complex; DA = detrusor apron. 416 EUROPEAN UROLOGY 58 (2010) 407–417 selected cohort (preoperatively young, potent patients) could partially explain this difference in the potency rates. Moreover, the patients were not affected by comorbidities that could impair the continence/potency recovery. In addition to the highly selected cohort, the study population was small to allow any definitive conclusions. Moreover, several techniques with a possible synergistic effect on continence recovery (preservation of the bladder neck, endopelvic fascia reflection, tip of seminal vesicles; incremental nerve-sparing technique) were performed, and it is difficult to quantify the effect of each one. 5. Conclusions The holistic preservation of the PVC during RALP is technically feasible. Combined with other surgical manoeuvres, it leads towards the absolute preservation of the periprostatic anatomy. Adequately designed studies should evaluate whether it enhances early functional outcomes. Author contributions: Anastasios D. Asimakopoulos had full access to all the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis. Study concept and design: Asimakopoulos, Gaston. Acquisition of data: Asimakopoulos, Annino, D’Orazio, Fraga, Gaston. Analysis and interpretation of data: Asimakopoulos, Gaston. Drafting of the manuscript: Asimakopoulos. Critical revision of the manuscript for important intellectual content: Asimakopoulos, Gaston. Statistical analysis: Annino. Obtaining funding: None. Administrative, technical, or material support: Asimakopoulos, Annino. Supervision: Asimakopoulos, Mugnier, Hoepffner, Piechaud, Gaston. Other (specify): None. Financial disclosures: I certify that all conflicts of interest, including Diagram 1 – (a) Selective ligation and (b) standard ligation. specific financial interests and relationships and affiliations relevant to the subject matter or materials discussed in the manuscript (eg, employment/ affiliation, grants or funding, consultancies, honoraria, stock ownership or options, expert testimony, royalties, or patents filed, received, or pending), are the following: None. Funding/Support and role of the sponsor: None. Acknowledgment statement: The authors acknowledge D. M. 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