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Erschienen in: International Urogynecology Journal 5/2011

Open Access 01.05.2011 | Original Article

Site-specific prolapse surgery. II. Vaginal paravaginal repair augmented with either synthetic mesh or remodelling xenograft

verfasst von: Richard I. Reid, Kehui Luo

Erschienen in: International Urogynecology Journal | Ausgabe 5/2011

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Abstract

Introduction and hypothesis

This study aims to answer the question, “Does tissue augmentation improve the mechanical repair of displacement cystourethrocoele?”

Methods

A retrospective cohort study comparing 108 bridging graft vaginal paravaginal repairs (89 tissue-inductive xenografts and 19 polypropylene mesh) to 59 native tissue historical controls was conducted. Main outcome measures were same-site prolapse recurrence and time to failure. Initial reliability was evaluated by chi-squared test, 10-year durability by Kaplan–Meier survival analysis and risk factors by Cox regression.

Results

Late recurrence was 17.7% lower with augmentation (logrank test χ 2 = 8.4, p value = 0.0038 < 0.05, adjusted regression analysis χ 2 = 2.94; p value = 0.0866 <0.10), implicating collagen degeneration in repair failure.

Conclusions

Rebuilding the pubocervical septum, from arcus to arcus and pubic ramus to pericervical ring, satisfies the mechanical but not the metabolic hernia principles. Bridging grafts simplify technical repair (reducing prolapse persistence from 10.2% to 4.6%), and also rejuvenate adjacent connective tissue (reducing late recurrence from 22.6% to 4.9%).
Hinweise
Part I of this article can be found at DOI 10.​1007/​s00192-010-1347-2.

Introduction

Pelvic floor disorders are a cluster of urinary, sexual or defaecation problems that arise mainly out of structural damage or neuromuscular disruption to the pelvic floor, rather than through any malfunction of the specific organs themselves. One in two parous women (versus one in ten men) experiences some type of pelvic floor disorder during her lifetime. At entry examination, 41% of the participants in the Women’s Health Initiative study had clinically significant prolapse [1]. Anterior vaginal wall was the most commonly affected segment. Fifty-five percent of subjects had a dominant single bulge and another 20% had a cystocoele as part of a diffuse pattern of support failure. This is important because cystocoele repair is relatively unsuccessful. However, pelvic surgeons are seldom confronted with their own operative failures; women tend to suffer in silence, or seek referral elsewhere. Nonetheless, 29% of the 150,000 insured women at Kaiser Permanente North West in 1995 needed at least one repeat surgery [2]. Applying an epidemiologic “rule of thumb” from the hernia literature, that another 40% of failures would not have returned [3], overall success rate was perhaps ~60%. Historically, case series reporting on plication-type cystocoele repair claimed success rates around 75–100%. More rigorous examination in recent randomised controlled trials has shown anterior colporrhaphy to be less effective than previously believed. Two recent RCTs report anatomic success rates of just 57% at 1 year [4] and 39% at 2 years [5]. Prevalence of pelvic floor disorders increases in a linear fashion with age [6] but consultations for pelvic floor disorders have a Gaussian distribution [7], suggesting that many women over 60 years lose faith in the treatments offered and hence no longer attend.
Cystocoele repair has been problematic for several reasons [8]. Pelvic anatomy is complex, difficulty increases with time and tissue weakness, and reparative efforts have been confounded by 100 years of mechanically misdirected surgical strategies. In normal women, the pubovisceral muscles compensate pressure-induced stress on the mid-vaginal fascial supports by narrowing the genital hiatus, while the levator plate acts as a dynamic backstop to dissipate Valsalva forces. Net effect is that the pelvic floor muscles absorb most of the expulsive load on the pelvic organs, and it is very difficult for the body to compensate any muscle damage. Endopelvic fascia is also important, but in a less direct way. Pelvic connective tissue is basically an embryologic mesentery, which tethers the pelvic viscera to the axial skeleton. Its main suspensory role is to stabilise the organs over the posterior levator plate, where the pelvic floor muscles work most effectively. Given that muscle damage sustained at childbirth is not presently reparable, our strategies for re-suspending the sagging pelvic organs depend unduly on connective tissue strength. Unfortunately, endopelvic fascia is not structurally suited to chronic load-bearing, making the task of prolapse repair intrinsically difficult. Any connective tissue weakness would be expected to exacerbate this inherent flaw, potentially undermining even the most skillful traditional repair. Experience accrued by herniologists in averting healing failure due to collagen weakness might therefore have useful lessons for the pelvic reconstructive surgeon.
Retrospective analysis of an 11-year database showed sutured vaginal paravaginal repair (VPVR) to be a genuinely curative treatment for severe displacement cystocele. Whether a 69.5% success rate from native tissue vaginal VPVR truly justifies the additional surgical effort involved in paravaginal repair instead of anterior colporrhaphy (as a palliative treatment) or mesh-augmented paravaginal repair (as a more robust curative procedure) is debatable. General surgeons have identified connective tissue weakness adjacent to the suture lines as an important factor in failed hernia repair (discussed at length elsewhere) [8]. There is evidence that collagen weakness sometimes develops in longstanding prolapse, raising the question of whether pelvic reparative strategies should also address this phenomenon. We hypothesised that measures to strengthen the central fascia of the anterior vaginal wall trapezoid would improve repair durability, over and above what was attainable by site-specific repair of the causative fascial defects.

Methods

Study design is a retrospective cohort analysis of augmented versus native tissue VPVRs. The cohorts were generated from a database of 275 consecutive site-specific prolapse repairs over an 11-year period (1997–2007). Data collection was regarded as a quality assurance project, and therefore exempted from Human Research Ethics Committee review. In all, there were 59 native tissue repairs and 108 tissue-augmented VPVRs. The key date with respect to treatment assignment was January 2004, when the first tissue-inductive biomesh (Surgisis ES®: Cook Medical Incorporated, Bloomington, IN) was licensed in Australia. Prior to this date, VPVR was done by re-suture of native tissues using the “three point” technique. After January 2004, sutured VPVR was abandoned in favour of a bridging graft technique. Surgisis ES® was the favoured graft in most privately insured women and some public cases (89 women). In the synthetic mesh subgroup, a relatively lightweight monofilament, macroporous polypropylene knit (Gynemesh®: Ethicon, Somerville, NJ) was used in 15 women and a hernia weight Amid class I knit (Marlex®, CR Bard Inc, Murray Hill, NJ) was used in four women. These four Marlex® cases were treated before 2002 (i.e., prior to the availability of prolapse-specific polypropylene meshes). Hernia weight mesh was used to forestall an extreme risk of poor outcome, these four women having failed a total of 16 previous sutured prolapse repairs. Despite differences in mesh weight, we included these four Marlex® cases in the augmentation group. There is no evidence that differences in mesh weight materially impact repair outcome [8]. All four had a successful anatomic outcome, but the mesh had to be removed in two women. Omitting the Marlex® cases would have made our results appear more favourable than they actually were.
Primary measures of outcome were: same site (anterior segment) prolapse recurrence, time to failure and any significant surgical complication. Secondary measures of outcome were different sites (postero-apical segment), anatomic recurrence and persistent or de novo pelvic organ dysfunction. In that data collection began before POPQ staging had become widely established, anatomic outcome was gauged by the Baden Walker “halfway” system. Objective anatomic success was defined as either ideal support (B-W stage 0) or mild laxity (B-W stage 1). Functional success was determined from answers to a symptom inventory, completed at presentation and at yearly follow-up. Mean follow-up time was 55 months (range = 4–120 months) for native tissue and 23 months (range = 3–44 months) for augmented cases.
Statistical analysis examined short-term reliability and long-term durability of cystocele repair. The reliability with which an effective mechanical repair had been achieved initially was gauged at the 6-month postoperative visit, using chi-squared test of independence and logistic regression. Long-term anatomical durability of an initially successful repair was examined with the Kaplan–Meier survival curves and log rank test, then further evaluated using the Cox proportional hazards model.

Results

Group comparison (using chi-squared test) showed no statistical difference in the distribution of potentially confounding variables including age, body mass index (BMI) >25 kg/m2, ≥ stage III descensus, prior or concomitant hysterectomy, prior failed surgery, severe urinary incontinence or suspected collagen weakness (p values > 0.05), except for multi-compartment repair (χ 2 = 10.324, p value = 0.003; Table 1). Given that the primary surgical philosophy was to “leave the entire tract intact” after the index operation, overt or incipient apical support weakness was repaired in 146 subjects (21 by uterosacral ligament culdoplasty and 125 by sacrospinous ligament fixation). Prolapse recurrence in the group needing only cystocele repair did not differ significantly from that when concomitant culdoplasty or sacrospinous ligament fixation was performed [six of 21 (71%) vs five of 21 (76%) vs 17 of 125 (86%); χ 2 = 3.742, p value = 0.309 > 0.05].
Table 1
Group comparison of baseline demographics and potentially confounding factors
Baseline demographics and potential confounders
Augmented vaginal paravaginal repair
Native tissue vaginal paravaginal repair
P value
Mean age
60.5 years
61.9 years
0.309 (n.s.)
Multi-compartment prolapse
101/108 (93.5%)
45/59 (76.3%)
0.003 (sig.)
Concomitant hysterectomy
25/108 (23.1%)
14/59 (23.7%)
0.932 (n.s.)
Prior hysterectomy
45/108 (41.7%)
26/59 (44.1%)
0.764 (n.s.)
Prior failed surgery
41/108 (38.0%)
20/59 (33.9%)
0.602 (n.s.)
Suspected collagen weakness
30/108 (27.8%)
13/59 (22.0%)
0.417 (n.s.)
≥ Stage 3 descensus
79/108 (73.1%)
44/59 (74.6%)
0.841 (n.s.)
Severe incontinence
34/108 (31.5%)
23/59 (39.0%)
0.328 (n.s.)
BMI > 25 kg/m2
70/108 (64.8%)
41/59 (69.5%)
0.541 (n.s.)
sig. significant, n.s. not significant
Vaginal paravaginal repair (VPVR) by either technique exhibited genuine curative potential for cystocoele, as evidenced by absolute flattening of the Kaplan–Meier survival curve at 20 months in the augmented group and at 38 months in the native tissue group (Fig. 1). The likelihood of restoring normal anterior compartment anatomy at 6 months was unaffected by use of a bridging graft [103 of 108 (95.4%) vs 53 of 59 (89.8%); χ 2 = 1.903, p value = 0.292 > 0.05]. However, twelve sutured VPVRs failed over the succeeding 32 months (three at 7–12 months; four at 13–24 months; four at 25–36 months and one at 37–48 months), reducing 10-year success rate to 69.6%. In contrast, there were only five late augmentation failures—two at 6–12 months and three at 13–24 months (Table 2). Cumulative probability of objective anatomic success was 0.94 at 1 year and 0.91 at 2, 3, and 4 years in the augmented group versus 0.85 at 1 year and 0.78, 0.71 and 0.69 at 2, 3, and 4 years after native tissue repair, respectively. Logrank test confirmed that this divergence of survival analysis curves over time was statistically significant (χ 2 = 8.4, p value = 0.0038 < 0.05). Augmented repair also appeared superior by unadjusted regression analysis (χ 2 = 4.24; p = 0.0395 < 0.05). But adding age, patient domicile and multi-compartment repair outcomes to the Cox proportional hazards model slightly changed the hazards ratio (from 0.430 to 0.465), and the difference between groups was only significant at the 10% level (p = 0.0866 < 0.10; Table 3). All potential confounder variables had high p values and wide 95% confidence intervals that crossed unity by a large margin, implicating the dual effect of small sample size and high censoring as major contributory factors. The impact of selection bias in this study is difficult to establish because of the non-random treatment assignment.
Table 2
Time to failure in the 28 unsuccessful repairs
Procedure
Failure pattern
Total failures
Number in group
≤6 months
6–12 months
13–24 months
25–36 months
37–48 months
≥48 months
Native tissue group
Native tissue VPVR
6
3
4
4
1
0
18
59
Augmented group
Gynemesh® or Marlex® augmentation
3a
0
0
0
0
0
3
19
Surgisis® augmentation
2
2
3
0
0
0
7
89
Combined augmentation group
5
2
3
0
0
0
10
108
Total
11
5
7
4
1
0
28
167
aMesh was removed from three cases (one for chronic pain, one for contracture, one for vesico-vaginal fistula). Each of these cases was counted here as a ‘technical failure’ rather than as a ‘technical success with an accompanying complication’
Table 3
Cox regression analyses of long-term outcome before (A) and after (B) adjusting for the possible confounders
Analysis of maximum likelihood estimates
Variable
Parameter estimate
Standard error
Wald chi-squared
P value
Hazard ratio
95% hazard range ratio
Cox regression: before adjusting for multisegment prolapse
Survival difference between augmented & native tissue VPVR
−0.8429
0.4093
4.242
0.0395a
0.430
0.193
0.960
Cox regression: after adjusting for patient age, domicile and multi-compartment repair
Augmented versus native tissue VPVR
−0.7651
0.4465
2.9363
0.0866b
0.465
0.194
1.116
Comparing 45–65 year with <45 years age group
0.3638
0.5965
0.3721
0.542
1.439
0.447
4.632
Comparing >65 year with <45 years age group
0.2379
0.6053
0.1545
0.694
1.269
0.387
4.155
Sydney distant domicile vs Sydney local
−0.5881
0.6562
0.8030
0.370
0.555
0.153
2.010
Rural domicile vs Sydney local
−0.1614
0.4624
0.1219
0.727
0.851
0.344
2.106
Rural domicile vs Sydney distant
−0.7051
0.7734
0.8312
0.362
0.494
0.109
2.250
Multi-compartment relapse vs single site
−0.3888
0.499
0.6062
0.436
1.475
0.554
3.925
aSignificance level of 5% was used here
bSignificance weakened to the 10% significance level because of small sample size and heavy censoring in years 3, 4 and 5
Both surgical techniques relieved bulge discomfort, with augmented VPVR being somewhat better (Table 4a). Seventy-six percent of women either remained or were rendered dry to mechanical provocation following VPVR, with a weak trend in favour of the augmentation group (Table 4b). Thirteen women with persisting stress urinary incontinence opted for bulking injection or mid-urethral sling placement as a follow-up procedure. ‘Overactive bladder wet’ symptoms were resolved or greatly ameliorated in 56% of the 109 women who had urge urinary incontinence at presentation. There was a trend in favour of augmented VPVR, falling just short of p = 0.05 (Table 4c). Finally, pre-existing dyspareunia was resolved in 13 of 21 augmented VPVR and in three of eight native tissue repairs; however, six individuals in the first and two in the second group developed de novo dyspareunia (largely attributable to the use of synthetic mesh). This represented a 28% decrease in the overall dyspareunia rate (from 29 to 21 complainants).
Table 4
Effect of surgical repair on bulge, stress urinary incontinence and overactive bladder wet symptoms
Surgical technique
Relevant symptom
Total
Resolved
Failed
Symptom control in the 144 women with bulge discomfort (χ 2 = 5.43; p value = 0.02 < 0.05)
Augmented VPVR
86 (93.5%)
6
92
Native tissue VPVR
42 (80.8%)
10
52
Total
128
16
144a
Ultimate stress urinary incontinence status within the entire sample (χ 2 = 2.15; p value = 0.14 > 0.05)
Augmented VPVR
86 (79.6%)
22
108
Native tissue VPVR
41 (69.5%)
18
59
Total
127
40
167
Ultimate symptom control in 109 women with overactive bladder wet (χ 2 = 3.68; p value = 0.06 > 0.05)
Augmented VPVR
45 (62.5%)
27
72
Native tissue VPVR
16 (43.2%)
21
37
Total
61
48
109b
a Twenty-three of the 167 women did not complain of bulge discomfort, reducing subject number to 144
bFifty-eight of the 167 women did not complain of bulge discomfort, reducing subject number to 109
Anatomic outcome appeared to improve with tighter conformity to the hernia principles (Table 5). Suture-only paravaginal repair was successful in only 41of 59 (69.5%) at 10 years. Augmentation with synthetic mesh delivered almost perfect anatomic outcomes, but the polypropylene had to be removed in three of 19 women—reducing ultimate success rate to 84.2%. Best performing biomaterial proved to be Surgisis® ES (Cook Medical Incorporated, Bloomington, IN). Surgisis® ES is an acellular lyophilized xenograft harvested from porcine small intestinal submucosa and fabricated into a strong 4-ply multilaminate. Second-generation biologicals like Surgisis® ES have tissue-inductive properties not found in denatured xenografts [9]. The robust capacity for constructive remodelling yielded anatomic success in 82 of 89 (92.1%) women, and rapid bio-absorption of the implanted xenograft (usually within 3 months) protected against mesh morbidity.
Table 5
The ‘Hernia Principles’
The “Hernia Principles”
Traditional principles
Traditional principles were primarily concerned with dissective technique and gentleness of tissue handling
Avoid wound infection
The first of the ‘Hernia Principles’ concentrated on how to minimise infection risk, through optimal tissue handling. Important strategies were: gentle sharp dissection, use of fine suture, no mass pedicle ligation and strict avoidance of haematoma or seroma.
Protect repair from intra-abdominal pressure
Surgeons of the early 19th century ligated the hernial sac at the external ring, perhaps sacrificing the testicle. The hernial bulge was reduced by imbrication of the external oblique aponeurosis, somewhat analogous to culdoplasty and plication repair of prolapse. Four-year recurrence rates approached 100%, and this strategy was soon abandoned. However, when surgeons learned how to dissect the inguinal canal safely, these concepts evolved into more secure techniques (ligating the hernial sac at the internal ring and narrowing the internal/external rings).
Repair tears in investing fascia
In 1887, Bassini conceived of a genuinely curative hernia operation, analogous to site-specific prolapse repair. Instead of obliterating the inguinal canal, Bassini restored the physiological flap valve mechanism of the normal groin. There were two essential dictates: mobilising the fascia transversalis to re-create a strong inguinal floor and re-enforcing the roof by suturing the conjoint tendon (under tension) to the inguinal ligament. These concepts have evolved to the mainstay of traditional hernia principles: namely, to sew identical tissue within the same layer, using interrupted stitches of permanent suture, without undue suture line tension in any direction. However, re-approximation of torn tissues in hernia or prolapse repair always produces wound tension, regardless of how well the operation is done.
Re-anchor the torn investing fascia back onto skeleton
In addition to repairing the tears within transversalis fascia, surgeons also learned to circumvent infero-medial recurrences by stitching the medial parietal wall of Bassini’s repair onto either inguinal or Cooper’s ligament. This strategy is analogous to paravaginal repair of a cystocele.
Principles of tension- free mesh repair
Tension-free hernia repair was first used to reduce suture line tension, but serendipitously delivered the benefit of tissue augmentation
Isolate mesh from contact with a hollow viscus
Placing alloplastic mesh in proximity carries a risk of late entero-cutaneous fistula. Hence, proximity to any hollow viscus mandates either a composite synthetic mesh (with a non-adhesive barrier) or a ‘second generation’ biological.
Limit bacterial colonisation of the mesh
Multifilament polyester meshes are ‘wettable’—leading to softer scar reactions, but a heightened risk of granulomatous infection, if colonised by bacteria. Conversely, monofilament polypropylene mesh is ‘non-wettable’—leading to harder scar formation, but a partial resistance to bacterial colonisation. Polyester is absolutely contraindicated in anything other than a clean wound. Polypropylene can be placed in a clean contaminated field, but late mesh infection may occur. However second generation remodelling biomesh is safe in all but the most purulent of wounds.
Minimise the “compliance mis-match” between mesh and native tissue
Mesh weight, stiffness and construction must suit tissue resilience at the surgical site, and the degree of movement expected at the graft–host interface. In groin hernia, low weight, macroporous, monofilament, polypropylene (Amid type 1) meshes have worked well, but these same materials are less appropriate for the genital tract.
Choice of mesh must suit surgical objectives
In planning the surgery, the exact reason why an implant is being used must be a clearly defined objective. In particular, the surgeon must differentiate between using the mesh as a neoligament (in which case, the implant will be subjected to strong static forces) versus using the mesh as a bridging graft (in which case, the implant will be subjected to repetitive dynamic forces).
Mesh implant must overlap the defect on all sides
The size and shape mesh must be sufficient to completely cover the hernial defect, and to overlap strong tissue on all sides. As a rule of thumb, hernia surgeons have usually regarded an overlap of 3–5 cm as sufficient.
Stabilise against doubling, wrinkling & undue shrinkage
The mesh must be anchored with interrupted permanent sutures, to prevent subsequent inflammatory reaction from shrinking the mesh or from wrinkling it into a painful mass (a “meshoma”).
Mesh must be placed in a tension- free manner
Gynaecologists have misinterpreted the term “tension-free” to mean not suturing an implant to adjacent tissues. This is an important error. The correct surgical meaning is that the mesh must be kept mesh loose (to allow for subsequent contracture), and shaped into a slight bowl-like curvature into the mesh (to allow for increased postural tone when the patient is ambulatory). The implant is then secured against movement in any direction with permanent suture, so as to remain tension-free after the patient comes off the operating table.
Overall, there were eight (4.8%) perioperative surgical complications—three (5.1%) occurring in the 59 native tissue group and five (4.6%) in the 108 augmented repairs. While there was no statistical difference between these small numbers, it is a surgical reality that the use of a bridging graft made the operation of vaginal paravaginal repair quicker and easier to perform. None of these adverse events were unique to the operative technique. Of the dissection-related surgical complications, there were two pelvic hematomas and one transient ureteral obstruction (from swelling of adjacent tissues). There were two (50%) mesh-related complications in the four women who had Marlex® implants (one vaginal pain lasting 3 years and one vesico-vaginal fistula occurring after 6 years) and one (6.7%) mesh-related complications among the 15 women who had Gynemesh® implants (a mesh contracture). No biomaterial-related problems were seen in the 89 women having Surgisis ES® implants.

Discussion

Our null hypothesis was that strengthening the central fascia of the anterior vaginal wall trapezoid would not further improve repair durability, over and above what was attainable by re-suture of the causative fascial avulsions. Study results refute this null hypothesis. Use of any form of augmentation significantly outperformed native tissue VPVR, as shown in Fig. 1 [χ 2 = 8.4, p value = 0.0038 < 0.05]. Similar results from augmented VPVR have been published elsewhere. Simsiman et al. [10] reported a 78% 2-year success with cross-linked porcine dermis (Pelvicol®: CR Bard, Murray Hill, NJ) and Clemons [11] reported a 59% 4-year success with cadaveric human dermis (Alloderm®: Boston Scientific, Natick, MA), a second-generation graft.
The use of implanted materials to re-enforce sagging pelvic support is intuitively logical. Biomaterials (particularly trocar-driven mesh kits) are being used with increasing frequency—despite a paucity of long-term supportive data and the growing safety concerns reported in several systematic reviews [1215]. The main strength of our study is that we measured the impact of tissue augmentation materials on site-specific native tissue repair over an adequate observation period (5 years). Another strong point is that this study evaluated tissue-inductive xenografts as opposed to the now obsolete first-generation biological implants. Given that minimally altered and chemically adulterated xenografts evoke completely different host immune responses, it is erroneous to combine these two products into a single classification category [9]. This information is well-known to biomaterials scientists, but poorly reported in the medical literature. Like all retrospective investigations, this article has limitations. By the middle of the study period, the first author had become dissatisfied with the “return on effort” from native tissue VPVR. At about this time, two new augmentation materials gained regulatory approval in Australia—Gynemesh® (a flexible light weight synthetic mesh, better suited to prolapse repair) and Surgisis® ES (a tissue-inductive xenograft). In January 2004, surgical technique was therefore changed from sutured repair to a bridging graft technique. However, Surgisis® ES was more expensive than Gynemesh®, meaning that choice of mesh was sometimes influenced by patient insurance status. It has been learned in hernia surgery that mesh weight, material stiffness and weave/knit construction must suit the tissue resilience and the degree of movement expected at the graft–host interface. Medium-weight macroporous monofilament polypropylene meshes have worked well in groin hernia repair; but when implanted into the more mobile tissues of a ventral hernia, their torsional rigidity can cause bothersome abdominal wall stiffness [8]. Given that Marlex and Gynemesh are both polypropylene meshes of similar construction (i.e., macroporous monofilament knits), the four women implanted with a hernia weight mesh before 2002 were analysed as a single “synthetic mesh” group. Studies to date have not demonstrated that a reduction in mesh weight delivers lower morbidity [9]. This decision was taken because their omission would have spuriously elevated the relative success of bridging graft VPVR, from 98 of 108 (90.7%) to 96 of 104 (92.3%), as well as omitting the worst of our surgical complications (a mesh-induced vesico-vaginal fistula).
Breaking the stubborn cycle of prolapse recurrence will require an improved understanding of the precise mechanism(s) of failure. Was the site-specific repair unable to secure a sound repair of the existing mechanical defects, or did an initially successful operation subsequently break down due to biochemical weakness in the pelvic connective tissues? Looking at 6-month follow-up (a reasonable surrogate for persistence, as opposed to recurrence) [9, 16], initial failure rate was comparable in the two groups [103 of 108 (95.4%) vs 53 of 59 (89.8%); χ 2 = 1.903, p value = 0.292 > 0.05]. This observation suggests that both sutured and bridging graft repair were effective methods for overcoming the perennial technical difficulty of locating and mobilising the torn fascial edges. Thereafter, there were five additional failures in the augmented group and 12 in the native tissue group. Delayed failures are a reasonable surrogate for recurrence, as opposed to persistence. That late recurrence was 17.7% lower in the augmented group [five of 103 (4.9%) versus 12 of 53 (22.6%); logrank test χ 2 = 8.4, p value = 0.0038 < 0.05, unadjusted regression analysis χ 2 = 4.24; p value = 0.0395 < 0.05 and adjusted regression analysis χ 2 = 2.94; p value = 0.0866 < 0.10] suggests that deterioration in collagen quality within the chronically prolapsed bladder hammocks may be a second important factor in repair failure (Fig. 1). Obtaining an ideal outcome would appear to depend upon correcting both failure mechanisms. This situation is not dissimilar to the problems that general surgeons face with hernia repair.
Hernia is the protrusion of an internal organ (usually small intestine) through a weakness in the abdominal wall. Formation reflects both a mechanical and a metabolic event [8, 16]. The mechanical event can be a congenital weakness at the internal ring or a traumatic/post-incisional break in the transversalis fascia. Any protruding tongue of peritoneum generally remains subclinical for years; however, progression to symptomatic hernia becomes likely if abdominal wall muscle strength can no longer contain the forces generated during Valsalva straining or at loading of the torso during heavy exertion. Hernia formation is also favoured by any metabolic compromise of the adjacent connective tissue quality—either genetic [8] or acquired [17]. Somewhat analogous to hernia, cystocoele is a protrusion of the vesical neck and/or bladder base through a site-specific tear in the fascial envelope of the vagina. Progression from subclinical support damage to symptomatic prolapse takes decades, and is largely driven by the operation of diverse secondary events [8].
Over the course of two centuries, general surgeons have developed a set of operative rules to minimise the contribution of mechanical factors to failed hernia repair (Table 4). The cardinal rule was to repair all site-specific fascial defects, sewing identical tissue within the same layer, using interrupted stitches of permanent suture, without undue suture line tension in any direction. It was also traditional to re-secure the abdominal connective tissues to the axial skeleton by sewing the conjoint tendon to the inguinal ligament. These manoeuvres were broadly successful, but excessive wound tension sometimes impeded healing. Some 25 years ago, surgeons turned to mesh implants as the best way of reducing wound tension and postoperative pain [18]. Such a strategy also made repair of the mechanical defect technically easier and serendipitously reinforced any weakness in the adjacent connective tissues. The key question is whether gynaecologists should adopt these surgical rules, at least at a theoretic level [8]. Results from this study appear to support that contention. Success rates for prolapse repair improved with increasing adherence to the hernia principles. Anterior colporrhaphy meets none of these rules, and is predictably inferior [4, 5]. Native tissue VPVR satisfies the criterion of being a site-specific technique, analogous to a Bassini or Shouldice hernia repair. However, all sutured repairs increase wound tension, and any adjacent collagen weakness remains unresolved. Bridging graft repair is exactly analogous to modern prosthetic hernioplasty; it is completely tension-free and carries the added advantage of simplifying the operative dissection. Results improved with any form of augmentation. All 19 women in the synthetic mesh group had successful anatomic outcomes, reflecting the tension-free attributes and almost indestructible nature of synthetic implants. However, severe mesh morbidity necessitated removal of polypropylene prostheses in three women—reducing ultimate surgical success to 84.2%. Use of Surgisis® ES, a resorbable tissue-inductive xenograft, delivered the best results (92.1% 5-year anatomic success).
From a research perspective, pelvic reconstructive surgeons do not appear to have grasped some profound differences between the various biomaterials available for prolapse repair. In essence, surgical implants are designed to re-attach an avulsed structure to the body wall by attracting the ingrowth of soft tissue. When considering tissue augmentation, it is intuitive to select an inert permanent material, such as synthetic mesh (e.g., polypropylene and polyester). However, such prostheses always evoke an acute foreign body inflammatory reaction [19]. Subsequent healing response is shaped by two main factors: pore size/accessibility and device motion at the implantation site [20, 21]. Placing macroporous monofilament (Amid Type I) mesh within immobile tissues generally results in strong vascular and connective tissue ingrowth (“incorporation”) [22]. However, poor fixation of an implant can lead instead to excessive shearing stress against host tissue, resulting in micro-bursa formation and poor fixation [21]. Biomaterials scientists in the early 1990s deliberately tanned various cadaveric and animal tissues with glutaraldehyde or hexamethylene diisocyanate to delay or permanently retard collagen turnover [23]. But “leatherizing” these biological materials failed to produce the “natural” scaffolds that manufacturers sought [8]. Clinical outcomes were paradoxical. Graft-to-tissue bonding is relatively weak, analogous to healing around a microporous or multifilament (Amid Type II or III) synthetic mesh. Moreover, there is a potential for subsequent graft autolysis, leading to automatic support failure. FitzGerald et al. [24] reported the failure of 45 of 67 (87%) Tutoplast® sacrocolpopexies and 14 of 35 (52%) Tutoplast® slings. Of 16 cases that came to abdominal re-exploration, 15 women had absent or inadequate graft material. Gandhi et al. [25] found that an adjunct patch graft of Tutoplast® did not reduce the risk of recurrent Stage II cystocoele. Similarly, in a prospective series of rectocele repair, Altman et al. [26] had a 41% 3-year failure rate due to autolysis of the implanted Pelvicol® bridging graft. In contrast, preparing an acellular xenograft in a way that preserves both the essential matrix molecules and a virtually intact protein scaffold will evoke a ‘graft acceptance’ response (modulated by Th2 lymphocytes and tissue-inductive M2 macrophages)[9, 27, 28]. M2 macrophage infiltration leads to constructive remodelling, rather than the familiar ‘graft rejection’ reaction (modulated by Th1 lymphocytes and phagocytic M1 macrophages) that inevitably accompanies implantation of alloplastic mesh or denatured collagen. Tissue-inductive implants are engineered to repopulate with host fibroblasts and angioblasts within 2–3 weeks, then remodel into a strong and self-renewable repair within 3–5 months. Hence, programmed resorption of a second-generation biological does not result in repair failure. Rather, this rapid resorption is the key reason why Surgisis® ES evokes a constructive remodelling M2 macrophage response. A slower resorption rate would taint the wound with degenerating biomaterial, thus potentially deviating healing towards the phagocytic M1 macrophage response that produces chronic inflammation and late scar formation around synthetic mesh implants [29, 30]. When implanting a bioactive graft, tissue quality of the repair will depend on the cell source, the growth modulating signals within the graft, the mechanical stresses to which the healing wound is subject and host androgen status [9].

Conclusions

Prolapse begins with intrapartum avulsion of the suspensory visceral mesenteries from their skeletal anchor points, then evolves to symptomatic descensus as host tissues weaken over time. Durable repair appears to demand two things: that the true site of support failure (i.e., the specific fascial tears, not the secondary central bulges) be repaired without tension and that degenerative tissue bordering the site of the original fascial tear be rejuvenated with a tissue augmentation material, appropriate to that implantation site. Traditional anterior colporrhaphy addresses neither of these surgical essentials. The fundamental objective of VPVR is to rebuild the pubocervical septum from arcus to arcus and from pubic ramus to pericervical ring. Suture-only techniques satisfy the mechanical dictates of the hernia principles, but not the metabolic ones. Conversely, use of an appropriate bridging graft perhaps simplified the technical task of VPVR and serendipitously rejuvenated adjacent connective tissue (reducing late recurrence from 22.6% to 4.9%). It is intuitive to choose an inert permanent material, such as synthetic mesh or a denatured biological. Such prostheses always attract phagocytic M1 macrophages, resulting in cicatrization. Conversely, tissue engineering principles dictate that preserving normal collagen structure and functioning matrix molecules within an absorbable xenograft will attract M2 macrophages, with constructive remodelling as the default healing response. This explains how a temporary bridging graft can transform into a permanent aponeurotic layer of host tissue, without the potential for mesh pain or erosion. Thus, the 21.2% improvement in 5-year durability attending xenograft-augmented cystocoele repair is of considerable importance—especially since use of biomaterials made the operation quicker and more readily standardised than VPVRs done with native tissue. Prospective study is warranted.

Acknowledgements

Hui You helped to set up the Excel database, entered all of the study data and assisted in preliminary data exploration.

Conflicts of interests

None.

Open Access

This article is distributed under the terms of the Creative Commons Attribution Noncommercial License which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.
Open AccessThis is an open access article distributed under the terms of the Creative Commons Attribution Noncommercial License (https://​creativecommons.​org/​licenses/​by-nc/​2.​0), which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.

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Metadaten
Titel
Site-specific prolapse surgery. II. Vaginal paravaginal repair augmented with either synthetic mesh or remodelling xenograft
verfasst von
Richard I. Reid
Kehui Luo
Publikationsdatum
01.05.2011
Verlag
Springer-Verlag
Erschienen in
International Urogynecology Journal / Ausgabe 5/2011
Print ISSN: 0937-3462
Elektronische ISSN: 1433-3023
DOI
https://doi.org/10.1007/s00192-010-1346-3

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