Second-Line Surgical Management After Midurethral Sling Failure

Joonbeom Kwon; Yeonjoo Kim; Duk Yoon Kim

doi:10.5213/inj.2040278.139

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Int Neurourol J > Volume 25(2); 2021 > Article

Kwon, Kim, and Kim: Second-Line Surgical Management After Midurethral Sling Failure

Review Article

Int Neurourol J 2021; 25(2): 111-118.

Published online: March 29, 2021

DOI: https://doi.org/10.5213/inj.2040278.139

Second-Line Surgical Management After Midurethral Sling Failure

Joonbeom Kwon¹

, Yeonjoo Kim¹, Duk Yoon Kim²

¹Department of Urology, Daegu Fatima Hospital, Daegu, Korea

²Department of Urology, Catholic University of Daegu School of Medicine, Daegu, Korea

Corresponding author: Joonbeom Kwon

Department of Urology, Daegu Fatima Hospital, 99 Ayang-ro, Dong-gu, Daegu 41199, Korea
E-mail: aziru98@gmail.com

Submitted: August 3, 2020 Revised August 23, 2020 Accepted after revision: August 24, 2020

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

ABSTRACT

Currently, the midurethral sling (MUS) is widely used as a standard treatment in patients with stress urinary incontinence (SUI). Several studies have reported the failure rate of MUS to be approximately 5%–20%. In general, sling failure can be defined as persistent SUI after surgery or a temporary improvement in incontinence followed by recurrence. Failure is also often considered to include cases requiring secondary surgery due to mesh exposure, postoperative voiding difficulty, de novo urgency/urge incontinence, and severe postoperative pain. Because of the lack of large-scale, high-quality research on this topic, no clear guidelines exist for second-line management. To date, transurethral bulking agent injections, tape shortening, repeat MUS, pubovaginal sling (PVS) using autologous fascia, and Burch colposuspension are available options for second-line surgery. Repeat MUS is the most widely used second-line surgical method at present. Bulking agent injections have lower durability and efficacy than other treatments. Tape shortening demonstrates a relatively low success rate, but comparable outcomes if the period from first treatment to relapse is short. In patients with intrinsic sphincter deficiency, PVS and retropubic (RP) MUS can be considered first as second-line management because of their higher success rate than other treatments. When revision or reoperation is required due to prior mesh-related complications, PVS or colposuspension, which is performed without a synthetic mesh, is appropriate for second-line surgery. For patients with detrusor underactivity, a readjustable sling can be a better option because of the high risk of postoperative voiding dysfunction in PVS or RP slings.

Keywords: Urinary incontinence; Suburethral sling; Recurrence

INTRODUCTION

It has been reported that 13.6% of women suffer from stress urinary incontinence (SUI) in their lifetime [1]. The surgical standard for treating SUI has changed from the pubovaginal sling (PVS) and Burch colposuspension to the midurethral sling (MUS) because of comparable cure rates and lower surgical morbidity after the introduction of the MUS in 1996 [2-4]. The short-term cure rates for MUS have been reported to be high (70%–98%) [5]. However, its cure rate declines over time. The long-term objective and subjective cure rates for retropubic (RP) and transobturator (TO) slings were found to be 61.6% and 76.5%, and 64.4% and 81.3%, respectively [6]. Failure was reported in 5%–20% of patients [7]. Repeat MUS, PVS, Burch colposuspension, tape shortening, and transurethral bulking agent injections can be considered as second-line surgical procedures. However, there is not yet a consensus on which salvage intervention should be selected.

Different definitions and categories of surgical failure after MUS have been used in the literature. Sling failure can clearly be defined as persistent or recurrent SUI. Meanwhile, mesh complications, voiding difficulty, and bothersome lower urinary tract symptoms, which reduce patient satisfaction, can be defined as sling failure in a broad sense. It seems reasonable to consider salvage treatment options after clearly addressing the reason for the failure of the previous procedure. Therefore, this review intends to help clinicians choose a more appropriate salvage procedure in various situations.

DEFINITION OF FAILURE

The reason for the various failure rates is that the definition of failure is not uniform. What is a failed sling? Postoperative SUI can be an example of failure. Some researchers have defined a relapse of urine leakage within 12 months as sling failure, which they distinguished from recurrent SUI, which was used to refer to the reoccurrence of urine leakage at over 12 months from the first sling [8]. Some authors have defined both persistent SUI and recurrent SUI as sling failure, regarding persistent SUI as the symptom occurring within 6 weeks after the first sling, and recurrent SUI as the symptom occurring after 6 weeks [9]. Others have defined retreatment at any time after previous MUS as a sling failure [10]. Situations that need secondary surgery, such as deterioration of lower urinary tract symptoms, severe postoperative pain, and mesh-related complications, can also be included as sling failure [11].

Failure should be assessed using a detailed history, physical examinations, and subjective or objective criteria, including voiding diaries, validated tools about patient satisfaction, stress test, a 24-hour pad test, cystoscopy, and urodynamic study.

RISK FACTORS OF FAILURE

In a single-center retrospective study of 1,225 MUS patients (955 RP slings and 270 TO slings), the multivariate analysis noted that body mass index >25 kg/m² (odds ratio [OR], 2.9), mixed urinary incontinence (OR, 2.4), prior surgery for continence (OR, 2.2), intrinsic sphincter deficiency (ISD) (OR, 1.9), and diabetes (OR, 1.8) were significant independent predictors of sling failure [12]. A prospective study of 597 patients who underwent MUS (280 in the RP arm, 285 in the TO arm) revealed that previous incontinence surgery (OR, 1.99), maximum Q-tip excursion <30° (OR, 1.89), Medical Epidemiologic and Social Aspect of Aging questionnaire urge score >10 (OR, 1.97), and pad weight (OR, 1.06 per 10 g) were predictors of overall failure [13]. Preoperative urge incontinence may be a risk of sling failure. In patients with mixed urinary incontinence, the postoperative cure rate was lower in long-term follow-up after MUS than in pure SUI patients (85% vs. 30%) [14]. Not all postoperative voiding difficulties require surgical intervention, and most cases resolve by temporal catheterization. The incidence of postoperative voiding difficulty decreased from 20% on day 1 to 2% by 6 weeks [15]. In a populationbased cohort of 188,454 women who underwent a sling, revision or removal of the sling was required in a cumulative 3.7% of participants in 9 years of follow-up (1.3% for urinary retention vs. 2.5% for mesh erosion) [16]. In the Trial of Midurethral Sling study, the RP approach demonstrated a higher incidence of postoperative voiding dysfunction. A surgical intervention was necessary for voiding difficulty in 3% of patients who received RP slings and in 0% of those who received TO slings within 24 months of follow-up [17]. Concomitant prolapse surgery, age, preoperative peak urinary flow rate, and the Charlson comorbidity index score were reported as potential predictors of postoperative voiding difficulties [18-20]. Younger age, concurrent prolapse surgery, diabetes, previous bariatric surgery, and an RP sling were regarded as risk factors for vaginal mesh exposure [16,21,22].

SECOND-LINE SURGICAL MANAGEMENT

Transurethral Bulking Agent Injections

Because it is less invasive, suitable for the office setting, and available under local anesthesia, bulking agent injections have been considered a viable option for failed MUS. A retrospective study of 73 patients who received Macroplastique and collagen injections reported complete resolution in 18 (24.7%) and symptom improvement in 52 (71.2%) at the first postinjection follow-up visit (4.2 months after injection) [23]. In another retrospective study comparing urethral bulking agent injections (n=67) to repeat MUS (n=98) in 165 patients who underwent a secondary procedure for failed MUS, failure was reported in 26 patients (38.8%) after bulking agent injections and 11 patients (11.2%) after repeat MUS [24]. Despite the low cure rate, subjective satisfaction or improvement has been reported to be relatively high in short-term results [25]. However, the objective cure rate was much lower than that found for repeat MUS [24]; moreover, few long-term results have been reported. Some studies have stated that repeat injections are necessary due to the decrease in efficacy with time [23,26-28]. Therefore, bulking agent injections are not adequate considering the long-term cure rate, except for some selected cases.

Shortening of the Previously Implanted MUS

Shortening of pre-existing mesh is a less invasive management strategy than other surgical options. However, only a few small studies have been reported. Lo et al. [29] reported an objective cure rate in 71.4% of 14 failed tension-free vaginal tape (TVT) patients. The mean period from initial to secondary surgery was 4 months, and the mean follow-up period was 19 months (range, 12–39 months). A study outcome of tape shortening for failed TO slings revealed cure rates of 70% and 60% at 1 and 3 years of follow-up. The mean period to tape shortening was 4.2 months (range, 1–12 months) [30]. Another study of 7 patients with mesh tightening and a mean follow-up period of 25 months reported cure in 3 patients (42.9%) cure and improvement in 6 (85.7%). The median interval from TO sling to tape shortening was 6 months [31]. Patterson et al. [32] reported different surgical outcomes of tape shortening depending on whether the first sling was performed using the RP route (a subjective cure rate of 88%) or the TO route (a subjective cure rate of 45%). Han et al. [33] compared 30 patients who underwent tape shortening to 36 who underwent repeat MUS. The mean delay to shortening of the tape was 90.2±77.5 months. The overall cure rate was 46.7% in the patients who underwent tape shortening and 72.2% in those who underwent repeat MUS at 12 months of follow-up (P =0.034). Comparing the study of Han et al. with other studies, some differences can be seen between the reported cure rates. The cure rate may depend on the interval from the first MUS to the secondary intervention, although there has been no comparative study to confirm this possibility.

Repeat MUS

As the MUS using synthetic tape became widespread as the primary management of SUI, the incidence of MUS failure also increased. Due to the lack of a clear guideline regarding salvage options after sling failure, many clinicians have tried MUS as a secondary procedure and so far have shown relatively good results [34,35]. The success rate of repeat MUS reported so far varies widely (40%–90%) among researchers. The reason for this is that the criteria used to define cure or success in each study were different, the follow-up periods were different, and the results were also different depending on whether RP or TO slings were used [9,33,36-40].

A retrospective study with 77 patients who underwent TVT (n=48) or TO tape (n=29) as secondary management revealed overall success rates of 71% and 48%, respectively (P=0.04), meaning that repeat RP slings were more successful than repeat TO slings. The preoperative incidence of ISD was higher in the patients who underwent repeat MUS after sling failure than in those who did not require secondary management (31% vs. 13%, P<0.001). The subjective cure rate was higher in the primary management group (86%) than in the secondary management group (62%) [36]. Conversely, a cohort study of 112 recurrent SUI patients who underwent repeat MUS revealed an overall subjective success rate of 76.8% at 21 months of followup. There was no significant difference in outcomes between RP and TO slings [40]. A retrospective study reviewing 80 patients who underwent repeat MUS showed that repeat MUS had a lower success rate than primary MUS (55% vs. 81%, P< 0.0001). A history of prior anti-incontinence procedures, a positive supine stress test, and a TO sling were independent risk factors for sling failure [39]. Complications such as voiding dysfunction, de novo urgency, urethra, bladder, and vaginal perforation happened more in RP slings, while chronic groin pain occurred more in TO slings [41].

Readjustable Slings and Spiral Slings

In a prospective study of 130 recurrent SUI patients, insertion of an adjustable continence therapy (ACT) device, which consists of 2 adjustable balloons aimed to be located just distal to the urethrovesical junction bilaterally, demonstrated a cure rate of 52% (67 of 130) and an 80% improvement rate at a 1-year follow-up [42]. Another study of 57 patients who had recurrent SUI and received ACT implantation as secondary management reported a 68% success rate after 6 years [43]. Schmid et al. [44] reported an 84% (21 of 25) cure rate in patients who experienced failure of MUS as prior incontinence surgery and were treated with an AMI adjustable sling system as a secondary treatment at 1 year of follow-up. A retrospective study of the Remeex readjustable sling, which was conducted among 205 patients after primary failure of MUS, revealed a cure rate of 71.7% during a mean follow-up of 89 months (range, 26–159 months). Eighty-eight patients (42.9%) required re-adjustment (82 cases of tension increase and 6 cases of tension reduction) [45]. Compared with the standard sling, a readjustable sling seems to result in increased success rates and decreased complications as a salvage procedure because of the ability to readjust inadequate tension, which could induce recurrence of incontinence or postoperative bladder outlet obstruction. However, no comparative studies with other types of MUS have yet been conducted.

The success rates after spiral sling placement were reported to be 70%–75% at 15–26 months of follow-up. Due to the nature of the procedure, there were several complications such as intraoperative bladder neck perforation produced by dorsal urethrolysis, or cases that required urethral reconstruction during a salvage procedure after secondary failure [46,47].

PVS With Autologous Rectus Fascia

The cure rates of PVS using autologous fascia as second-line management have been reported to be 60%–80% [48-52]. A retrospective study of 66 patients (16 pure SUI vs. 50 mixed incontinence) who received an autologous PVS after failed MUS reported an SUI cure rate of 69.7%. Patients with pure SUI showed a higher cure rate (62.6%) than those with mixed incontinence (30.0%) [49]. In another study of 35 patients who underwent autologous fascial sling after failed MUS, an assessment was possible in 21 patients. Preoperatively, 13 patients had a failed RP sling, and 8 had a failed TO sling. There were 13 patients with preoperative mixed urinary incontinence and 12 with urethral hypermobility. Eight patients had concomitant sling excision due to obstruction or pain. Success occurred in 16 patients (76.2%) according to the Patient Global Impression of Improvement questionnaire for a median follow-up of 74 months. Concurrent sling excision, mixed urinary incontinence, age, length of follow-up, and first surgery type (RP vs. TO) had no statistical impact on outcomes [50]. In studies comparing PVS with RP slings, some reported similar success rates and complications between the 2 groups [51], while others noted that PVS had a higher surgical success rate and more complications related to postoperative voiding difficulty [52,53].

Burch Colposuspension

Burch colposuspension as a secondary treatment after failed MUS has shown objective and subjective cure rates of 54%–77% and 85%–93%, respectively [54-57]. No studies have yet compared Burch colposuspension with other incontinence surgery as salvage procedures. The SISTEr (Stress Incontinence Surgical Treatment Efficacy) trial, a multicenter randomized comparative study, was conducted in a total of 655 SUI patients who had not previously received anti-incontinence surgery, and compared 329 patients who received colposuspension with 326 patients who received PVS. In total, 520 patients completed the outcome assessment. The success rate specific to SUI was higher for PVS than for Burch colposuspension (66% vs. 49%, P< 0.001), and adverse events such as urinary tract infections, voiding difficulty, postoperative de novo urgency, and urge incontinence also were higher in patients who received PVS [58]. Compared with MUS, colposuspension exhibited no difference in subjective and objective cure rates even at a long-term followup [59]. Amaye-obu and Drutz [60], in a study of 26 patients, showed that the cure rate of colposuspension declined to 81%, 25%, and 0% as the numbers of previous anti-incontinence operations increased to 1, 2, and 3, respectively. According to this result, it would be better to avoid colposuspension if the patient has received anti-incontinence surgery twice or more. A randomized controlled trial comparing TVT to laparoscopic colposuspension in recurrent SUI patients exhibited similar cure rates and complications in the short-term follow-up [61]. If the recent issue of the increasing risk of mesh-related complications is considered, colposuspension might be a better alternative option as second-line management for failed MUS.

Considerations at the Time of Planning Second-Line Surgery

Concurrent excision or removal of the prior sling

There is no consensus on whether the prior implanted sling should be removed [62,63]. Some agree with removing the prior sling so that the new sling is not prohibited from being placed in a proper position along with the midurethra. On the other hand, the objection has been raised that doing so may increase unnecessary morbidities such as a longer operation time, more bleeding, and possible urethral injury, which would not occur if concurrent excision is not performed. Steele et al. [63] compared subjective improvement in 61 patients who performed repeat MUS, of whom 28% (17 of 61) and 72% (44 of 61) underwent concurrent removal of prior sling or did not, respectively. Using the Urogenital Distress Index, Incontinence Severity Index, and Incontinence Impact Questionnaire, there was no difference in subjective voiding symptoms and operative complications between the 2 groups. In a retrospective study of 66 patients who underwent PVS as a second-line treatment, mesh removal was performed in 27 patients (21 before PVS, 6 concurrent excisions). Mesh excision was not associated with worse outcomes (P=0.013) [49]. Another retrospective study of 21 patients who underwent PVS after failed MUS resulted in no statistical impact according to whether concomitant sling excision was performed (n=8) or not (n=13) (P=0.62) [50]. However, it seems reasonable to remove the first sling if repeat surgery is necessary due to the complications related to mesh exposure, pain, and postoperative voiding difficulty. Jambusaria et al. [64] noted that pain was improved in more than 60% of patients by complete or partial excision of mesh in patients who suffered pain after primary MUS for a mean 29 weeks of follow-up.

ISD versus urethral hypermobility

ISD is one of the critical causes of primary sling failure. When second-line management is required, an RP sling or PVS can be considered first because of their higher success rates in SUI patients with ISD. A TO sling supports the lower surface of the midurethra horizontally in the resting position, while an RP sling or PVS supports a larger surface of the midurethra circumferentially with a U-shape. Therefore, it seems that urethral resistance is reinforced more by RP slings and PVS. Several clinical studies have reported higher success rates of RP slings and PVS compared to TO slings as secondary management in failed MUS [36,39,51]. If ISD is accompanied after sling failure, an RP sling, PVS, or adjustable sling can be considered first. Contrary, if urethral hypermobility is dominant, colposuspension could be a better alternative option [65].

Mesh complications

In the last decade, the use of commercial mesh for pelvic organ prolapse repair has been suspended in several countries due to the occurrence of some severe mesh-related complications. Some countries have prohibited the use of synthetic mesh even for SUI treatment. The overall rates of mesh erosion or extrusion have been reported to be 2.4% with TO slings versus 2.1% with RP slings. Nevertheless, a Cochrane review with high-level evidence supports the long-term effectiveness and tolerable adverse events of MUS using type I polypropylene mesh [5]. The reasons for the recent increase in mesh-related complications are as follows: First, the incidence of complications has increased due to an increase in synthetic mesh utilization [66]. Second, the problem of the mesh material itself can be considered. Despite discordant opinions on this issue, there is no clear evidence of a causal relationship between polypropylene mesh and systemic inflammation or an abnormal host response, according to a recent review by the International Consultation on Incontinence [67]. Third, the widespread use of synthetic mesh in SUI patients can lead to an increased incidence of inadequate surgical performance by inexperienced surgeons [68,69]. Risk factors affecting mesh-related complications include factors related to wound healing such as diabetes, smoking, nutritional deficiency, and old age, as well as intraoperative factors such as bleeding, hematoma, and trocar perforation into the urinary tract. In a patient with a failed MUS accompanied by mesh-related complications, PVS or colposuspension rather than repeat MUS can be considered first as a salvage treatment [65].

Postoperative lower urinary tract symptoms

After repeat MUS, the rate of de novo urgency and urge incontinence was reported to be 6%–30%, and that of urinary retention was reported to be 10%–14% depending on the study [36,49,70]. As mentioned earlier, the long-term cure rates of RP slings and PVS were reported to be higher than those of TO slings, whereas postoperative voiding difficulty was also reported to be higher for those modalities than for TO slings. Little is known about the comparative outcome of de novo urgency and urge incontinence between secondary RP and TO tape. However, the incidence of storage symptoms after MUS in primary SUI patients was not different between the RP and TO approaches [17,67].

A readjustable sling can be a better option for patients who have recurrent SUI with detrusor underactivity to avoid postoperative voiding difficulties [62]. When a revision is planned due to postoperative voiding difficulties, it should be noted that complete excision of the mesh can produce a higher incidence of SUI recurrence than occurs after partial excision or urethrolysis [64].

CONCLUSIONS

There is not yet any consensus regarding the choice of adequate second-line surgery for failed MUS. However, it is necessary to approach surgical options according to the cause of the previous failure rather than uniformly determining a single treatment option. Since transurethral bulking agent injections or tape shortening can be performed with minimal invasiveness, they may be suitable as office-based procedures, but have lower durability and efficacy than other treatment options. Repeat MUS is still being performed most frequently, and recently, PVS and colposuspension are receiving attention again because issues relating to the mesh-related complications have been highlighted.

NOTES

AUTHOR CONTRIBUTION STATEMENT

· Conceptualization: JK

· Data curation: JK, DYK

· Formal analysis: JK, DYK

· Methodology: JK

· Project administration: JK, DYK

· Writing-original draft: JK

· Writing-review&editing: JK, DYK

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Official Journal of Korean Continence Society & ESSIC (International Society for the Study of BPS) & Korean Society of Urological Research & The Korean Children’s Continence and Enuresis Society & The Korean Association of Urogenital Tract Infection and Inflammation & Korean Society of Geriatric Urological Care
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