Here, we present an elaborate and efficient protocol to treat isolated short bulbar or posterior urethral strictures with vessel-sparing excision and primary anastomosis.
Urethroplasty is considered to be the standard treatment for urethral strictures since it provides excellent long-term success rates. For isolated short bulbar or posterior urethral strictures, urethroplasty by excision and primary anastomosis (EPA) is recommended. As EPA only requires the excision of the narrowed segment and the surrounding spongiofibrosis, a full-thickness transection of the corpus spongiosum, as performed in the traditional transecting EPA (tEPA), is usually unnecessary. Jordan et al. introduced the idea of a vessel-sparing approach in 2007, aiming to reduce surgical trauma, especially to the dual arterial blood supply of the urethra, and, thus, potentially reducing the risk of postoperative erectile dysfunction or glans ischemia. This approach could also be beneficial for subsequent urethral interventions such as redo urethroplasty using a free graft, in which a well-vascularized graft bed is imperative. Nevertheless, these potential benefits are only assumptions as prospective studies comparing the functional outcome of both techniques with validated questionnaires are currently lacking. Moreover, vessel-sparing EPA (vsEPA) should at least be able to provide similar surgical outcomes as tEPA. The aim of this paper is to give an elaborate, step-by-step overview of how to manage patients with isolated short bulbar or posterior urethral strictures with vsEPA. The main objective of this manuscript is to outline the surgical technique and to report the representative surgical outcome. A total of 117 patients were managed according to the described protocol. The analysis was performed on the entire patient cohort and on the bulbar (n = 91) and posterior (n = 26) vsEPA group separately. Success rates were 93.4% and 88.5% for the bulbar and posterior vsEPA, respectively. To conclude, vsEPA, as outlined in the protocol, provides excellent success rates with low complication rates for isolated short bulbar and posterior urethral strictures.
Urethroplasty is considered the standard treatment for urethral strictures as it provides excellent long-term success rates1,2. A numerous amount of surgical techniques has been described, challenging the reconstructive urologist to choose the best approach, considering various stricture modalities such as the number of strictures, the stricture length, the stricture location, the etiology, comorbidities, and previous urethral interventions. For isolated short bulbar urethral strictures, the International Consultation on Urologic Diseases (ICUD) recommends urethroplasty by excision and primary anastomosis (EPA) associated with a composite success rate of 93.8%3,4.
Urethroplasty by EPA embodies an approach in which the entire diseased segment of the urethra is removed and replaced by healthy adjacent urethra without the need for grafts or flaps to bridge the gap. Traditionally, this approach included the full thickness transection of the corpus spongiosum at the level of the stricture5. However, as EPA only requires the excision of the narrowed segment and the surrounding spongiofibrosis, a full thickness transection of the corpus spongiosum, and the dual urethral blood supply within it, is usually unnecessary. Given this background, Jordan et al. introduced the idea of a vessel-sparing approach in 2007, offering a non-transecting alternative to the classic transecting EPA (tEPA)6,7. This vessel-sparing EPA (vsEPA) has been uprising ever since and several centers have—though slightly modified—implemented this technique in their surgical repertoire8,9,10,11,12.
The vessel-sparing technique aims to reduce surgical trauma, especially to the dual arterial blood supply of the urethra embedded in the corpus spongiosum. The preservation of the bulbar arteries potentially reduces the risk of postoperative erectile dysfunction or glans ischemia. Furthermore, it could be beneficial for subsequent urethral interventions such as redo urethroplasty using a free graft, in which a well-vascularized graft bed is imperative8,9. Nevertheless, these potential benefits are only assumptions as prospective studies comparing the functional outcome of both techniques with validated questionnaires are currently lacking.
As important as the functional outcome is, vsEPA should at least be able to provide similar surgical outcomes as tEPA. Promising short-term results have been published and are in line with the success rates reported by the ICUD, but a direct comparison between both techniques has, so far, not been performed3,4,8,9,10,11,12.
Pelvic fracture-related urethral injuries are associated with scar tissue formation and a subsequent urethral stricture or complete obliteration of the membranous urethra. Posterior strictures might also develop after surgery or irradiation to the prostate13. For these strictures, urethroplasty with the excision of the scar tissue and bulbo-prostatic anastomosis is recommended as well14. Traditionally, the bulbar arteries were ligated during this procedure if not already obliterated due to the pelvic fracture. To avoid this, a vessel-sparing variant has been introduced and reported as well15,16.
The aim of this paper is to give an elaborate, step-by-step overview of how to manage patients with isolated short bulbar or posterior urethral strictures with vsEPA. The main scope is to outline and visualize the surgical technique and to report the representative surgical outcome. An evaluation of the functional outcome parameters is beyond the scope of this paper.
All patients provided a signed written informed consent and the approval of the local Ethics Committee (EC/2014/0438) was obtained.
NOTE: The inclusion criteria for the presented protocol were: male; age ≥18 years; signed written informed consent; fit for operation; isolated urethral stricture; urethral stricture ≤3 cm; urethral stricture only at the bulbar or membranous site. The exclusion criteria were: female; transgender; age <18 years; absence of signed written informed consent; unfit for operation; >1 concomitant urethral strictures; urethral stricture >3 cm; urethral stricture outside of the bulbar or membranous site.
1. Preoperative Work-up
2. Initiation of Surgical Procedure
NOTE: The following steps take place after the surgical safety checklist and the administration of general anesthesia.
3. Surgical Procedure
4. Postoperative Care
5. Follow-up Visits
Between 2011 and 2017, a total of 117 patients with isolated short bulbar (n = 91) or posterior (n = 26) urethral strictures were treated with vsEPA at Ghent University Hospital. The baseline characteristics are displayed in Table 1. The median follow-up was 35 and 45 months for bulbar and posterior strictures, respectively. The strictures were longer in the patients who underwent posterior vsEPA and, accordingly, the number of patients with a calculated U-score of 5 was higher in this group17. In contrast to the bulbar vsEPA group, posterior strictures were predominantly traumatic (57.7%), whereas the bulbar vsEPA group mainly consisted of idiopathic urethral strictures (45.3%). Iatrogenic strictures at the bulbar site were largely caused by prior catheter use (6.6%) or a transurethral resection of the prostate (TURP) (18.7%), whereas posterior strictures occurred after irradiation, radical prostatectomy, or TURP in respectively 5 (19.2%), 3 (11.5%), and 4 (15.4%) patients. Traumatic posterior strictures were documented as 'complete obliteration' and 'incomplete obliteration' in, respectively, 5 (19.2%) and 10 (38.5%) patients. Seven of these patients were treated with a prior realignment procedure (2 open and 5 endoscopically) after the initial urethral disruption injury. A vast majority of the total patient cohort (82.1%) underwent prior urethral interventions, either open or endoscopically. The posterior vsEPA group, however, contained more patients without any former urethral intervention. Furthermore, the presence of a suprapubic catheter and a urinary infection was higher in the patients with posterior urethral strictures.
Per- and postoperative characteristics are displayed in Table 2. The median hospital stay and the catheter dwell time were 2 and 10 days, respectively. The operation time and the catheter stay were longer in the posterior vsEPA group. A total of 7 patients (6.6%) showed significant extravasation at the first VCUG and needed a catheter reinsertion for at least 1 week. The complication rate (23.9%) was comparable between the groups and mainly consisted of low-grade complications (Clavien-Dindo grade 1–2: 23.0%) such as wound dehiscence, wound infection, urinary infection, bladders spasms, and hematoma. One of the encountered hematomas required surgical drainage under general anesthesia and was categorized as a 3b complication according to the Clavien-Dindo classification18.
Nine patients (7.7%), consisting of 6 patients (6.6%) from the bulbar vsEPA group and 3 patients (11.5%) from the posterior vsEPA group, were considered a surgical failure. Two failures were observed between the second and the fifth postoperative year. The estimated failure-free survival was 95.3%, 95.3%, and 87.0% at, respectively, 1, 2, and 5 years for the bulbar vsEPA group, and 88.3% at 1, 2, and 5 years for the posterior vsEPA group. A Kaplan-Meier curve was constructed and illustrates the failure-free survival rate (Figure 3). The salvage treatment of recurrent urethral strictures consisted of redo urethroplasty, DVIU, dilation, and a combination of urethroplasty and DVIU in, respectively, 5, 2, 1, and 1 patients.
Figure 1: Exposure of the bulbar urethra with a self-retaining retractor. Please click here to view a larger version of this figure.
Figure 2: Mobilization of the bulbar urethra with a vessel loop. Please click here to view a larger version of this figure.
Figure 3: Kaplan-Meier curve for the failure-free survival. vsEPA = vessel-sparing excision and primary anastomosis. Please click here to view a larger version of this figure.
Total vsEPA (n = 117) | Bulbar vsEPA (n = 91) | Posterior vsEPA (n = 26) | |
Median age (years) (IQR) | 47 (30 – 66) | 44 (29 – 63) | 59 (29 – 73) |
Median follow-up (months) (IQR) | 38 (17 – 64) | 35 (15 – 59) | 45 (32 – 77) |
Median stricture length (cm) (IQR) | 1.5 (1.0 – 2.0) | 1.5 (1.0 – 2.0) | 2.0 (1.5 – 3.3) |
Etiology n (%) | |||
Idiopathic | 53 (45.3) | 52 (57.1) | 1 (3.8) |
Iatrogenic | 37 (31.6) | 27 (29.7) | 10 (38.5) |
Catheter | 7 (6.0) | 6 (6.6) | 1 (3.8) |
TURP | 19 (16.2) | 17 (18.7) | 2 (7.7) |
Radical prostatectomy | 4 (3.4) | 2 (2.2) | 2 (7.7) |
Irradiation | 2 (1.7) | 0 | 2 (7.7) |
TURP + irradiation | 3 (2.6) | 1 (1.1) | 2 (7.7) |
Radical prostatectomy + irradiation | 1 (0.9) | 0 | 1 (3.8) |
Failed hypospadias repair | 1 (0.9) | 1 (1.1) | 0 |
External trauma | 23 (19.7) | 8 (8.8) | 15 (57.7) |
Inflammatory | 4 (3.4) | 4 (4.4) | 0 |
U-score n (%) | |||
4 | 96 (82.1) | 82 (90.1) | 14 (53.8) |
5 | 20 (17.1) | 9 (9.9) | 11 (42.3) |
6 | 1 (0.9) | 0 | 1 (3.8) |
Prior interventions n (%) | |||
None | 21 (17.9) | 11 (12.1) | 10 (38.5) |
1 DVIU or dilation | 33 (28.2) | 27 (29.7) | 6 (23.1) |
> 1 DVIU or dilation | 41 (35.0) | 33 (36.3) | 8 (30.8) |
Urethroplasty | 4 (3.4) | 4 (4.4) | 0 |
Urethroplasty + DVIU or dilation | 18 (15.4) | 16 (17.6) | 2 (7.7) |
Comorbidity n (%) | |||
Smoking | 13 (11.6) | 9 (10.3) | 4 (16.0) |
Diabetes | 8 (7.2) | 4 (4.6) | 4 (15.4) |
Cardial comorbidity | 20 (17.9) | 12 (13.8) | 8 (32.0) |
Vascular comorbidity | 16 (14.3) | 11 (12.6) | 5 (20.0) |
Presence of suprapubic catheter n (%) | 27 (23.1) | 16 (17.6) | 11 (42.3) |
Preoperative urinary infection n (%) | 27 (23.1) | 12 (13.2) | 15 (57.7) |
Table 1: Baseline characteristics. vsEPA = vessel-sparing excision and primary anastomosis; IQR = interquartile range; cm = centimeters; TURP = transurethral resection of the prostate; DVIU = direct vision internal urethrotomy
Total vsEPA (n = 117) | Bulbar vsEPA (n = 91) | Posterior vsEPA (n = 26) | |
Median operation time (min) (IQR) | 94 (80 – 108) | 87 (73 – 100) | 109 (100 – 135) |
Median hospital stay (days) (IQR) | 2 (1 – 2) | 2 (1 – 2) | 2 (2 – 3) |
Median catheter stay (days) (IQR) | 10 (8 – 15) | 9 (8 – 14) | 14 (11 – 16) |
Significant extravasation at first VCUG n (%) | 7 (6.6) | 6 (7.4) | 1 (3.8) |
Complications (Clavien-Dindo) n (%) | |||
None | 89 (76.1) | 68 (74.7) | 21 (80.8) |
Grade 1 | 17 (14.5) | 14 (15.4) | 3 (11.5) |
Grade 2 | 10 (8.5) | 8 (8.8) | 2 (7.7) |
Grade 3 | 1 (0.9) | 1 (1.1) | 0 |
Failure n (%) | 9 (7.7) | 6 (6.6) | 3 (11.5) |
Estimated failure-free survival % (SD) | |||
1y-FFS | 95.3 (2.3) | 88.3 (6.4) | |
2y-FFS | 95.3 (2.3) | 88.3 (6.4) | |
5y-FFS | 88.3 (5.2) | 88.3 (6.4) |
Table 2: Per- and postoperative characteristics. vsEPA = vessel-sparing excision and primary anastomosis; min = minutes; IQR = interquartile range; VCUG = voiding cystourethrography; SD = standard deviation; FFS = failure-free survival
Urethral stricture repair by vessel-sparing excision and primary anastomosis was initially performed at Ghent University Hospital in 2010. Thereafter, it became a standard of practice in the hospital's management of patients with isolated short bulbar or posterior urethral strictures. As the bulb remains attached to the perineal body, access to the posterior urethra and the resection of the fibrotic tissue at that site can be compromised. A distortion of the pubic rami due to a pelvic fracture might further impede accessibility. If this is the case and a full resection cannot be accomplished because of poor access, a peroperative decision is made to perform a transecting procedure with the ligation of the bulbar arteries and the detachment of the bulb away from the perineal body. The described protocol gives an elaborate, step-by-step overview of the experience at Ghent University Hospital, a tertiary referral center for urethral stricture disease.
Although the protocol offers an extensive description, some crucial steps call for extra attention. A successful procedure starts with a correct indication. Patients with isolated short bulbar or posterior urethral strictures are ideal candidates for this approach3,4,14,15,16.
In order to successfully perform an anastomotic repair urethroplasty, both urethral ends need to be well-vascularized and the anastomosis must be completed in a tension-free way. Therefore, as the bulbar urethra has a limited elasticity, traditionally, only strictures up to 3 cm were treated with EPA. In 2006, however, Morey et al. reported equivalent success rates in strictures of up to 5 cm treated with anastomotic repair urethroplasty3,4,19. By splitting the corpora cavernosa, strictures up to 5 cm might indeed be treated successfully with EPA.
Nevertheless, the patient series investigated by Morey et al. consisted of 11 patients in each group and the mean follow-up was only 22 months. Furthermore, the estimation of the stricture length based upon preoperative investigations should be interpreted carefully, as conventional urethrography might underestimate the actual stricture length at the bulbar site. Nash et al. reported a correlation of only 0.69 between conventional urethrography and peroperative length measurements of bulbar urethral strictures20. The telescopic effect in a two-dimensional urethrogram and the different stricture appearances according to the patient's positioning and penile traction might explain this result20.
An underestimation of the stricture length might lead to a peroperative conversion from an anastomotic repair to an augmented repair using a free graft or a pedicled flap. Since the procedure involves a dorsal stricturotomy, a conversion towards a dorsal onlay graft urethroplasty ('Barbagli procedure') is most likely21,22. For this reason, it is of the greatest importance that the surgeon performing the operation masters a variety of urethroplasty techniques in order to address this issue.
Another point of attention is timing, as the introduction of even a small caliber instrument in the urethra may rupture the stricture, causing a significant problem in determining the distal extent of the urethral stricture as discussed in step 3.3.1. This, in turn, could lead to an insufficient urethroplasty procedure leaving fibrotic tissue, and, thus, stricture disease, behind. Therefore, any urethral manipulation must be avoided at least 3 months before surgery23.
Regarding surgical technique, the described procedure differs from the original vessel-sparing variant of Jordan et al. in which the bulbar arteries are dissected free at the bulb of the corpus spongiosum in order to retract them6. In fact, this is unnecessary, time-consuming, and causes more surgical trauma8. Furthermore, the duration of the catheter stay forms another important issue but is still a matter of debate. However, Poelaert et al. concluded that in uncomplicated cases, the catheter can be removed safely after 8–10 days postoperatively24.
Regarding the reported results, the bulbar and posterior vsEPA were also considered separately. Comparing these groups is not the focus of this paper, as it is clinically irrelevant, given the fundamentally different nature of the stricture etiology, pathogenesis, and management. Nevertheless, some noteworthy differences were encountered and are worth putting in perspective. The differences in follow-up are most likely coincidental, but the longer strictures in the posterior vsEPA group can be explained by the fact that the posterior strictures were predominantly caused by pelvic trauma resulting in urethral disruption injuries and the subsequent obliteration or extensive stricture formation at the membranous urethra25. This can also explain the higher U-score of the posterior vsEPA group, as this score is partly based on the stricture length17. Posterior urethral strictures caused by external trauma are—in acute setting—managed with the placement of a suprapubic catheter to ensure urinary derivation and to reduce the risk of urinary extravasation14. This, in turn, explains the differences in the presence of suprapubic catheters and, as suprapubic catheters involve a substantial risk of infection, the differences in preoperatively established urinary infections. Due to the more complex character of the strictures in the posterior vsEPA group, their operation time and catheter stay were longer. Posterior strictures require further proximal dissection and a cystoscope can be introduced in the suprapubic tract to facilitate the identification of the prostatic apex which further contributes to a longer operation time in these patients. The complication rate was low and mainly consisted of low-grade complications, which is in line with the experience at other centers10.
Nine patients, consisting of 6 patients from the bulbar vsEPA group and 3 patients from the posterior vsEPA group, were considered a surgical failure. This corresponds to a success rate of 93.4% and 88.5% for the bulbar and the posterior vsEPA group, respectively. These results are in line with the success rates reported by the ICUD and other centers3,4,8,9,10,11,12,14,15,16. Although Andrich et al. reported failures to occur within the first year after surgery, 2 failures were observed between the second and the fifth postoperative year, underlining the need for a prolonged follow-up in these patients, which is in line with suggestions from Han et al.26,27. It is plausible that a rigid follow-up scheme with cystoscopy would lead to earlier diagnoses of recurrence28. However, every transurethral procedure, even flexible cystoscopy, is potentially harmful to the urethra. Both this and the prevention of overusing technical investigations are the rationale behind the follow-up scheme at Ghent University Hospital, administering further technical investigations only in the case of a suspicion of stricture recurrence.
The major limitation of vsEPA is the anastomosis: it is of the utmost importance to complete the anastomosis without any tension and with 2 well-vascularized urethral ends. Even by splitting the corpora cavernosa, this technique is limited to strictures up to 5 cm. Furthermore, in posterior urethral strictures, the bulbar arteries, as well as the cavernous vasculo-nervous bundles, may already be obliterated due to the pelvic fracture, abolishing the potential benefits of a vessel-sparing approach. Moreover, the anatomical proximity of the membranous urethra to the cavernous vasculo-nervous bundles and the urinary sphincter should be taken into account and, if possible, a sphincter-sparing variant of posterior vsEPA might be superior in terms of continence preservation29. In addition, Blakely et al. reported dorsal onlay graft urethroplasty to be beneficial for continence preservation as well, though in a limited number of patients (n = 16)30. Future studies directly comparing the surgical outcome of the vessel-sparing and transecting technique are required, as are studies comparing the functional outcome of both techniques with validated questionnaires. So far, Le et al. performed a randomized controlled trial (RCT) in 23 patients with traumatic posterior urethral strictures15. In the near future, an RCT will be set up for bulbar urethral strictures in which vsEPA and tEPA will be compared for both their surgical and functional outcome.
To conclude, vsEPA, as outlined in the protocol, provides excellent success rates with low complication rates for isolated short bulbar and posterior urethral strictures.
The authors have nothing to disclose.
The authors have no acknowledgments.
iso-Betadine Dermicum 125 ml (1) | Meda Pharma | A-472825 | |
Sterile gown (3) | According to surgeon's preference | NA | |
Sterile gloves (3 pairs) | According to surgeon's preference | NA | |
Sterile drapes (4) | Medline | AGBBA073A | |
Bard-Parker scalpel number 3 (1) | Zepf Medical Instruments | 06-1003-00 | |
Bard-Parker scalpel number 4 (1) | KLS Martin Group | 10-100-04 | |
Scalpel blade number 15 (1) | Swann-Morton | 0205 | |
Scalpel blade number 24 (1) | Swann-Morton | 0211 | |
Surgical forceps 14 cm (2) | KLS Martin Group | 12-301-14 | |
Monopolar electrocauter Valleylab (1) | Medtronic | E2100 | |
Electrocauter blade 15 cm (1) | Comepa | CO 150i | |
Debakey forceps 20 cm (2) | Düfner | 06232-20 | |
3-layered compress 30 x 45 cm (5) | Mölnlycke Health Care | 175260 | |
Surgical compress 10 x 10 cm (10) | Hartmann | 232088 | |
Mayo-Hegar needle driver 18 cm (1) | Zepf Medical Instruments | 24-1804-18 | |
Mayo-Hegar needle driver 25 cm (1) | Zepf Medical Instruments | 24-1804-25 | |
Jones scissor 18 cm (1) | Düfner | 04940-18 | |
Mayo-Stille scissor 17 cm (1) | Zepf Medical Instruments | 08-1700-17 | |
Lone Star retractor (1) | CooperSurgical, Trumbull, CT, USA | 72403867 | |
Lone Star elastic stays (4) | CooperSurgical, Trumbull, CT, USA | 3311-1G | |
Vessel loop 45 cm (1) | Braun | 1095137 | |
Halsted-Mosquito (6) | KLS Martin Group | 13-317-21 | |
20Fr silicone urethral catheter (1) | Yushin Medical Co. | 1037B-20 | |
3Fr ureteral catheter (1) | Teleflex | 223602 | |
20Fr metal sound (1) | Custom made | NA | |
Vicryl 4-0 wire (6) | Ethicon | V734D | |
Vicryl 3-0 wire (2) | Ethicon | VCP316H | |
Vicryl Rapide 3-0 wire (1) | Ethicon | VF2260 | |
10Fr Drain needle (1) | Vygon | 658.10 | |
10Fr Suction drain (1) | Oriplast | 203102 | |
Vacuum flask 400 ml (1) | Oriplast | 213215AL/QL | |
Zetuvit 10 x 20 cm (1) | Hartmann | 413771 |