Abstract
Background
The material and the surgical technique used to close an abdominal wall incision are important determinants of the risk of developing an incisional hernia. Optimising closure of abdominal wall incisions holds a potential to prevent patients suffering from incisional hernias and for important costs savings in health care.
Methods
The European Hernia Society formed a Guidelines Development Group to provide guidelines for all surgical specialists who perform abdominal incisions in adult patients on the materials and methods used to close the abdominal wall. The guidelines were developed using the Grading of Recommendations Assessment, Development and Evaluation (GRADE) approach and methodological guidance was taken from Scottish Intercollegiate Guidelines Network (SIGN). The literature search included publications up to April 2014. The guidelines were written using the AGREE II instrument. An update of these guidelines is planned for 2017.
Results
For many of the Key Questions that were studied no high quality data was detected. Therefore, some strong recommendations could be made but, for many Key Questions only weak recommendations or no recommendation could be made due to lack of sufficient evidence.
Recommendations
To decrease the incidence of incisional hernias it is strongly recommended to utilise a non-midline approach to a laparotomy whenever possible. For elective midline incisions, it is strongly recommended to perform a continuous suturing technique and to avoid the use of rapidly absorbable sutures. It is suggested using a slowly absorbable monofilament suture in a single layer aponeurotic closure technique without separate closure of the peritoneum. A small bites technique with a suture to wound length (SL/WL) ratio at least 4/1 is the current recommended method of fascial closure. Currently, no recommendations can be given on the optimal technique to close emergency laparotomy incisions. Prophylactic mesh augmentation appears effective and safe and can be suggested in high-risk patients, like aortic aneurysm surgery and obese patients.
For laparoscopic surgery, it is suggested using the smallest trocar size adequate for the procedure and closure of the fascial defect if trocars larger or equal to 10 mm are used. For single incision laparoscopic surgery, we suggest meticulous closure of the fascial incision to avoid an increased risk of incisional hernias.
Similar content being viewed by others
Introduction
Background
Incisional hernias are a frequent complication of abdominal wall incisions, but a wide range of incisional hernia rates are reported [1–6]. The weighted mean incisional hernia rate at 23.8 months was 12.8 % in a systematic review and meta-regression study [7], but incidence rates up to 69 % have been reported in high-risk patients with prospective long-term follow-up [8]. The reported incidence is determined by several factors: the patient population studied, the type of abdominal wall incision, the length of follow-up and the method of incisional hernia diagnosis. Risk factors for incisional hernias include postoperative surgical site infection, obesity and abdominal aortic aneurysm [9–11]. Nevertheless, it seems that the suture material and the surgical technique used to close an abdominal wall incision, are the most important determinants of the risk of developing an incisional hernia [1, 12]. The development of an incisional hernia has an important impact on the patients’ quality of life and body image [13]. Furthermore, the repair of incisional hernias still has a high failure rate with long term recurrence rates above 30 %, even when mesh repair is performed [14–16]. Optimising the surgical technique to close abdominal wall incisions using evidence based principles, holds a potential to prevent patients suffering from incisional hernias and the potential sequelae of incisional hernia repairs [17]. The mean direct and indirect costs for the repair of an average incisional hernia in an average patient in France in 2011 was € 7,089 [18]. Thus, reducing the incisional hernia rate by optimising the closure of abdominal wall incisions holds a great potential for costs savings in the use of health care facilities and in reducing postoperative disability.
The European Hernia Society (EHS) originated from the “Groupe de la recherche de la paroi abdominal” (GREPA), which was founded in 1979 with the aim: “The promotion of abdominal wall surgery, the study of anatomic, physiologic and therapeutic problems related to the pathology of the abdominal wall, the creation of associated groups which will promote research and teaching in this field, and the development of interdisciplinary relations”. During the autumn board meeting of the EHS in September 2013 in Italy it was decided to extend our mission to actively promote the prevention of incisional hernias by the Sperlonga statement: “Maybe we should first learn and teach how to prevent incisional hernias, rather than how to treat them?”
Objective
The objective is to provide guidelines for all surgical specialists who perform abdominal incisions in adult patients on the optimal materials and methods used to close the abdominal wall. The goal is to decrease the occurrence of both burst abdomen and incisional hernia. The guidelines refer to patients undergoing any kind of abdominal wall incision, including visceral surgery, gynaecological surgery, aortic vascular surgery, urological surgery or orthopaedic surgery. Both open and laparoscopic surgeries are included in these guidelines.
Methods
As EHS secretary of Quality, Filip Muysoms, under the auspices of the European Hernia Society board, proposed the Guidelines Development Group. The project was presented to the EHS board and accepted during the board meeting in Sperlonga, Italy, on September 28th 2013. The members of the Guidelines Development Group were chosen to recruit key opinion leaders and researchers on the subject from Europe. A geographical distribution across European countries was attempted and some younger surgeons having performed research on the subject were included in the Guidelines Development Group. Many of the members have contributed previously in producing guidelines on a national and international level. The Guidelines Development Group included abdominal wall surgeons, upper gastro-intestinal surgeons, hepato-biliary surgeons, colorectal surgeons and a vascular surgeon.
During a Kick Off meeting of the Guidelines Development Group in the Bonham Hotel in Edinburgh on October 28th 2013, the members attended a seminar on the methodological aspect of developing guidelines by Robin T Harbour, the Lead Methodologist of the Scottish Intercollegiate Guidelines Network (SIGN) [19]. The AGREE II instrument was used from the start of the project to guide our methodology and structure of producing the guidelines [20]. AGREE II gives as definition for the Quality of a guideline: “The confidence that the potential biases of guideline development have been addressed adequately and that the recommendations are both internally and externally valid, and are feasible for practice.” During this first meeting Key Questions were formulated and translated into 24 patients-intervention-comparison-outcome (PICO) formats. For each Key Question at least three Guidelines Development Group members were assigned as investigators and specific search terms were formulated. The Key Questions with their PICO’s and assigned authors are listed in addendum 1.
On November 11th 2013, a meeting in Glasgow at the SIGN headquarters was held with the steering committee of the Guidelines Development Group to discuss the search strategy. A clinical librarian working for SIGN performed the primary literature research for all Key Questions. This involved a search for systematic reviews and/or meta-analyses on the Key Questions in Medline, Embase, NIHR CRD, NICE and The Cochrane library. The PRISMA flow diagram is shown in Fig. 1 and the search terms used are in addendum 2. The Guidelines Development Group members evaluated the systematic reviews for their relevance to the Key Questions and a qualitative assessment was done using the SIGN checklist No 1 for systematic reviews and meta-analyses [19]. Only systematic reviews of High Quality were used as basis for the guidelines development. A second search (no filters) on the Key Questions was performed for relevant RCT’s published after the end of the search performed for the systematic reviews involved. If no High Quality systematic review was identified for a Key Question, the working group members performed a separate systematic review using the PRISMA statement methodology [21]. To avoid lengthening of this guidelines manuscript, the results of these systematic reviews will be submitted as a separate manuscript on behalf of “The Bonham Group”, which are the members of the Guidelines Development Group. The members working together on a Key Question provided a Summary of Findings table from the results of the literature search, which were presented and discussed during the second group meeting.
PRISMA flow diagram for the search for systematic reviews and/or meta-analyses performed by Scottish Intercollegiate Guidelines Network (SIGN) for the Guidelines Development Group of the European Hernia Society guidelines on the closure of abdominal wall incisions. The search was performed in November 2013 and included searches in Medline, Embase, NIHR CRD, NICE and The Cochrane library
The second Guidelines Development Group meeting was held in Edinburgh on April 25th 2014. For evaluation of evidence, the Grading of Recommendations Assessment, Development and Evaluation (GRADE) approach was used [22]. For each Key Question, a level of evidence was proposed using the GRADE approach and four levels of quality of the body of evidence were used: high, moderate, low, very low (Table 1). Based on the research evidence, the clinical experience and patient values the Guidelines Development Group formulated a recommendation for each Key Question. In the GRADE approach only three levels of recommendation are used: strong recommendation, weak recommendation and no recommendation.
The results of the guidelines proposed by the Guidelines Development Group were presented during the 36th Annual International Congress of the European Hernia Society in Edinburgh on May 31st 2014. The manuscript was subsequently written by the first author in a uniform manner for all Key Questions and send for review and agreement by all co-authors. Prior to submission, the manuscript of the guidelines was externally reviewed by experts and evaluated using the AGREE II instrument.
Results
The results of the searches are shown in the PRISMA flow diagram in Fig. 1. From the 97 records detected by the SIGN process, 69 records were excluded based on the title and abstract as not being relevant to the guidelines. The remaining 28 systematic reviews [1, 23–49] were assessed by full text for their relevance to the Key Questions and if retained were assessed qualitatively using the SIGN checklist No 1 [19]. Additional searches on PubMed and by checking the references of all manuscripts were performed by the members of the Guidelines Development Group assigned to each Key Question. Relevant studies published up until April 2014 were included to provide the Summary of Evidence tables.
Which diagnostic modality is the most suitable to detect incisional hernias?
No systematic reviews on diagnostic modalities for incisional hernias were found. The PRISMA flow diagram is shown in addendum 3 (Key Question A). Fifteen records were included in the qualitative analysis [3–6, 50–60]. Only four studies were retained as High Quality and are listed in the Summary of Findings table (Table 2) [5, 50–52].
The quality of most studies investigating the diagnostic accuracy of imaging techniques was low to very low. Only some provided a sensitivity analysis. Because no studies compared different diagnostic modalities in a similar methodology and with similar study arms, no pooling of data was useful or possible. In general, most studies show that medical imaging will increase the rate of detection of incisional hernias compared to physical examination. In an everyday clinical setting this is usually not important, because most asymptomatic hernias do not require treatment and their diagnosis is thus not necessary.
CT scan is reliable and reproducible, whereas ultrasound is more operator-dependant. However, CT scan will induce a radiation load to the patients and ultrasound is more accessible in most health care settings. A good standardisation and dynamic evaluation by ultrasound of the abdominal wall is needed, as described by Beck et al. [51] as the dynamic abdominal sonography for hernia (DASH) technique.
The difference in accuracy between physical examination and imaging technique is most important in the context of comparative studies evaluating incisional hernia rate. Next to the method of incisional hernia diagnosis the length of follow-up is important. Fink et al. [2] reported in a follow-up study of two prospective trials an increase from 12.6 % at 12 months to 22.4 % at 36 months (p < 0.001) and concluded that follow-up for 3 years should be mandatory in any study evaluating the rate of postoperative incisional hernia after midline laparotomy.
Does the type of abdominal wall incision influence the incidence of incisional hernias or burst abdomen?
Laparotomy incisions can be classified as midline, transverse, oblique or paramedian incisions [61]. The PRISMA flow diagram is shown in addendum 3 (Key Question B). Six systematic reviews have compared midline laparotomies to alternative incisions [26, 27, 31, 36, 38, 61], but only two were considered High Quality [26, 27]. A recent systematic review by Bickenback et al. [26] compared midline, transverse (including oblique) and paramedian incisions. This review included all relevant studies from previous reviews and no additional RCT’s were detected that were published after this review. The literature search of this systematic review [26] identified studies published until 2009 and 24 RCT’s directly comparing different laparotomy incisions were included in the analysis. The incisional hernia rates after non-midline incisions were significantly lower compared to the incisional hernia rates after midline incisions, for both transverse incisions (RR = 1.77; 95 % CI:1.09–2.87) and paramedian incisions (RR = 3.41; 95 % CI: 1.02–11.45) [26]. However, data on burst abdomen (deep wound dehiscence or fascial dehiscence) were not significantly different between the different incisions types.
A Cochrane review by Brown et al. [27] published in 2005 and updated in 2011, compared transverse versus midline incisions, but excluded studies comparing paramedian incisions. A decreased incisional hernia rate after transverse incisions was reported compared to midline incisions (OR = 0.49; 95 % CI: 0.30–0.79).
Both reviews concluded that non-midline incisions significantly reduced the risk of incisional hernia compared to midline incisions, but did not influence the risk of burst abdomen. Interestingly, the Cochrane conclusions were more moderate, due to methodological and clinical heterogeneity of the studies and the risk of potential bias.
What is the optimal technique to close a laparotomy incision?
Ten systematic reviews on the techniques and/or the materials to close abdominal wall incisions were identified [1, 32, 34, 37, 38, 42, 43, 48, 62, 63]. The PRISMA flow diagram is shown in addendum 3 (Key Question C–G). The data from the different systematic reviews are very incoherent and conclusions are often completely contradictory. The overall quality of most systematic reviews is low and therefore, several should be rejected as evidence to create guidelines. A major problem to identify the evidence from the literature is the fact that most prospective studies compared several variables between the study arms. Moreover, the populations studied are often very different: midline only or including other incisions, emergency or elective surgery, and different operative indications.
The current guidelines on techniques and materials are based on the systematic reviews by Diener et al. [1] and van’t Riet et al. [48] which were evaluated as High Quality. Both systematic reviews included only studies involving midline laparotomies and the review by Diener et al. was the only one to distinguish between elective or emergency surgery. The systematic review by Sajid et al. [43] was used for the question on suture materials and a recent Cochrane review by Gurusamy et al. [63] was used for the question on peritoneal closure.
Using separate PICO’s the shortcoming of many study designs to deliver clear answers becomes obvious. Another shortcoming in most studies on closure of laparotomies is the failure to monitor the technical details of the suturing technique, like the SL/WL ratio and the stitch size. As demonstrated by Israelsson [64] this might be an important confounding factor in studies comparing different suture materials. An updated systematic review taking into account the mentioned shortcomings of individual studies might be performed, but for these guidelines the conclusions are based on the data from the currently available systematic reviews. The protocol for an ongoing Cochrane review [65] was published in 2006 but the final data have not yet been published.
Continuous suturing versus interrupted sutures
Both meta-analyses concluded that continuous suturing for closure of midline laparotomies was beneficial compared to interrupted closure [1, 48]. Diener et al. [1] found a significant lower incisional hernia rate for continuous suturing (OR 0.59: p = 0.001) in elective surgery. Most of the included studies were at high risk of bias because the interrupted study arm used rapidly absorbable multifilament sutures and the continuous arm used either non-absorbable or slowly absorbable monofilament sutures. van’t Riet et al. [48] included studies involving emergency laparotomies and did not find any difference in incisional hernia rate between interrupted and continuous suturing. Continuous suturing was recommended because it was significantly faster.
Closure versus non-closure of the peritoneum
The Cochrane review by Gurusamy et al. [63] concluded that there was no short-term or long-term benefit in peritoneal closure. Five studies were included but were heterogeneous in type of incision (midline and non-midline) and included both elective and emergency laparotomies. In all studies, the peritoneum was closed as a separate layer in the study arm with peritoneal closure.
Mass closure versus single layer closure
The search for the most appropriate layers to be sutured when closing a laparotomy is hampered by the lack of good definitions on what constitutes a mass closure, layered closure or single layer closure. No clinical studies directly comparing different closure methods were found.
For future research the Guidelines Development Group proposes the following definitions:
-
-
Mass closure: the incision is closed with a suture bite including all layers of the abdominal wall except the skin.
-
-
Layered closure: the incision is closed with more than one separate layer of fascial closure
-
-
Single layer aponeurotic closure: the incision is closed by suturing only the abdominal fascia in one layer.
Suture length to wound length ratio (SL/WL)
The beneficial effect of a high SL/WL ratio on reducing the incidence of incisional hernias has been recognised for a long time [66], but evidence from clinical prospective studies remains scarce and most of the work addressing the topic comes from the Clinic of Sundsvall in Sweden [64, 67, 68]. A RCT, performed in Sundsvall, demonstrated the importance of the SL/WL ratio in reducing incisional hernia rate. The critical value was determined to be at a ratio of 4/1 [64]. Although a SL/WL ratio ≥4 is often mentioned in the protocol of prospective studies, many fail to document that the SL/WL ratio was recorded for the individual study patients.
Small bites versus large bites
Millbourn et al. [69] demonstrated that closure of a midline laparotomy with a “small bites” technique resulted in significant less incisional hernias (5.6 vs 18.0 %; p < 0.001) and less surgical site infections (5.2 vs 10.2 %; p = 0.02). In the small bite technique the laparotomy wound is closed with a single layer aponeurotic suturing technique taking bites of fascia of 5–8 mm and placing stitches every 5 mm.
What is the optimal suture material to close a laparotomy incision?
The PRISMA flow diagram for our search on suture materials is shown in Addendum 3 (Key Question H–K). Despite significant heterogeneity and confounders in most systematic reviews identified, a study by Sajid et al. [43] focused solely on the suture material. Table 3 defines the suture materials used in the included studies.
Rapidly absorbable suture versus non-absorbable or slowly absorbable sutures
Diener et al. [1] reported a significantly lower incisional hernia rate with slowly absorbable sutures (OR 0.65: p = 0.009) in elective surgery. Subgroup analysis performed by van’t Riet et al. [48] comparing only continuous suturing studies, detected only one RCT by Wissing et al. [70] using continuous suturing in both study arms. This study, which included 21 % of emergency operations, showed significantly more incisional hernias with rapidly absorbable sutures compared to non-absorbable sutures (p = 0.001) and compared to slowly absorbable sutures (p = 0.009).
Non-absorbable versus slowly absorbable sutures
No difference in incisional hernia rate for continuous suturing of midline incisions with slowly absorbable versus non-absorbable sutures (p = 0.75) was identified [48]. However, an increased incidence of prolonged wound pain (p < 0.005) and suture sinus formation (p = 0.02) with non-absorbable sutures was reported [48]. Another meta-analysis (which included non-midline incisions) identified no difference in incisional hernia rate between slowly absorbable polydioxanone and non-absorbable sutures (OR 1.10: p = 0.43) [43]. Once again, non-absorbable sutures had a significant higher risk of suture sinus formation (OR 0.49: p = 0.01) [43].
Monofilament versus multifilament sutures
Monofilament sutures are believed to be associated with a lower surgical site infection rate than multifilament sutures [12]. However, none of the systematic reviews commented on this issue specifically. If the previous recommendation to use slowly absorbable sutures for closure of elective midline laparotomies is followed, this question becomes superfluous because the slowly absorbable sutures are all monofilament sutures.
Concerning the size of the suture, no studies comparing directly the size of the sutures used to close abdominal wall incisions were identified during our searches. For the “small bites” technique, Isrealsson et al. [12] suggest to use a suture size USP 2/0 (USP = United States Pharmacopeia).
Sutures impregnated with antibiotics
Sutures coated with Triclosan as an antimicrobial agent have been introduced to decrease the rate of surgical site infection in surgery. A recent meta-analysis has demonstrated a significant beneficial effect in the prevention of surgical site infection after all kinds of surgery [71]. Surgical site infection is a risk factor for subsequent development of incisional hernias and therefore the use of antibiotics impregnated sutures to close laparotomies might be beneficial in the prevention of incisional hernias. Recently Diener et al. [72] published a large RCT on 1,224 patients undergoing an elective midline laparotomy comparing polydioxanone sutures with versus without triclosan impregnation. No reduction in the incidence of surgical site infection was reported (OR 0.91: CI 0.66–1.25; p = 0.39). Four other RCT’s have compared sutures with or without triclosan in laparotomy closure, either with polyglactin sutures (Vicryl) [73, 74] or with polydioxanone (PDS) [75, 76]. A meta-analysis on all five studies performed by Diener et al. showed a significant decrease in surgical site infection (OR 0.67: CI 0.47–0.98). No data on incisional hernias are available from these studies.
Limitations of the statements in these guidelines on suture technique and suture materials
The statements are limited by the quality of the data on which they are based. In total, 61 RCT’s have been identified that compared suture materials or techniques to close laparotomy incisions. Many studies have more than one variable between study arms and therefore, analysing them in meta-analyses is difficult. Moreover, many studies have flaws in the methodology increasing the risk of bias. We would like to encourage researchers that plan studies on abdominal wall closure to improve the methodology of their study protocol. Preferably, study arms are only different in the variable under investigation, either a suture technique or a suture material. Moreover, we recommend documenting the technical details such as SL/WL ratio, the number of stitches used in the patients and to provide a follow-up of at least 24 months.
Although some of the systematic reviews detected included non-midline incisions [43] or emergency operations [48], these guidelines are currently limited to elective midline laparotomies. For emergency operations and non-midline incisions there is currently not enough data available.
Suture needles and retention sutures
Blunt tip versus sharp needles
Only one systematic review assessing the type of needle used to close the abdominal wall [23] and one RCT comparing blunt needles with sharp needles were identified. The PRISMA flow diagram is shown in Addendum 3 (Key Question L). The RCT reported no difference in SSI rate between blunt and sharp needles [77].
Is there a place for retention sutures when closing a laparotomy?
No systematic review on the use of retention sutures was found. The PRISMA flow diagram of our additional search is shown in Addendum 3 (Key Question M). Eight records were screened by full text [78–85]. Three RCTs on the prevention of burst abdomen using either retention sutures or a reinforced tension line suture in patients with increased risk for wound dehiscence and burst abdomen were identified [78–80]. Follow-up was too short to evaluate incisional hernia rate. The Summary of Findings is listed in Table 4. Two studies showed favourable results [78, 79], but one study reported a high number of adverse events when using retention sutures [80].
Postoperative care
Postoperative management and instructions for patients are not supported by high quality prospective data, but rely mostly on surgeons’ habits, tradition and common beliefs [86–88]. Long-term follow-up studies are needed to research the impact on the occurrence of incisional hernias of prescribing abdominal binders or restricting postoperative activity. The additional searches as shown in PRISMA flow diagrams in Addendum 3 (Key Question N, O, P) did not reveal any relevant study on long-term outcome. Some studies on the short-term benefits of abdominal binders were found.
Subcutaneous drains in laparotomy incisions
Prophylactic routine placement of subcutaneous drains after laparotomy is occasionally used to decrease wound complications: infection, hematoma, seroma or wound dehiscence [86]. However, there are several disadvantages to the routine use of subcutaneous drains. Namely, they cause patient discomfort and pain at removal, they hinder early mobilisation and demand additional nursing care. Therefore, their use should be driven by a proven benefit.
One systematic review [89] and several RCTs [90–98] on the use of subcutaneous drains in abdominal surgery were found. They cover a wide range of operative indications: liver surgery, colorectal surgery, cholecystectomy, gynaecological surgery, caesarean section, and gastric bypass surgery. With few exceptions, most studies did not show a benefit for the use of subcutaneous drains. However, none of these studies had incisional hernias or burst abdomen as primary or secondary endpoint.
Postoperative binders
One systematic review on the use of abdominal binders was found [87]. The review included four RCT’s [99–102] and a national survey by questionnaire on the use of abdominal binders in French surgical practice [87]. One additional recent RCT was identified [103].
The French survey reported that postoperative support of the wound with an abdominal binder is common practice after major laparotomies in many surgical departments (94 % use them in some patients). It is expected to reduce postoperative pain and to improve early mobilisation of the patients. Moreover, 83 % of users expect a benefit in the prevention of abdominal wall dehiscence [87].
No significant improvement for the short-term benefits was found by the small RCTs from the review [98–101]. The additional study by Clay et al. [102] found a significant lower Visual Analogue Scale (VAS) score for pain at the fifth postoperative day and no adverse effect on postoperative lung function. No studies were found that had burst abdomen or incisional hernias as primary or secondary endpoints.
Postoperative restriction of activity
No prospective studies were found on the restriction of physical activity after abdominal incisions. Nevertheless, it is advocated by some surgeons to decrease the risk of incisional hernias, but there is no consensus on the level or the duration of the restriction [88]. Postoperative restriction might have an adverse impact on the return to normal activity and delay the return to work.
Prophylactic mesh augmentation
The PRISMA flow diagram for prophylactic mesh augmentation is shown in Addendum 3 (Key Question Q–T). Three systematic reviews on the topic were found [24, 39, 104].
-
1.
Nachappian et al. [39] did not assess of the quality of the individual studies and included non published data. Therefore, this review did not qualify for inclusion in this guideline.
-
2.
The systematic review by Bhangu et al. [24] is of High Quality and offers a good and extensive evaluation of the quality of the individual studies included. However, the quality of the non RCTs was usually low and these studies were not used as evidence for these guidelines.
-
3.
Timmermans et al. [104] published a good meta-analysis on five RCT’s using polypropylene mesh, including a RCT published in 2013 by Abo-Ryia et al. [105].
One additional RCT published after the review by Timmermans et al. [106] was identified. In this RCT, one hundred and sixty patients were included. This is the first trial on non-selected elective midline laparotomies (with a majority of oncological patients). All the other trials have only included patients deemed at high risk for incisional hernias. In this RCT by Caro-Tarrago et al. the mesh augmentation was performed with a light weight polypropylene mesh in the onlay position. A significant reduction in incisional hernias at 12 months was observed clinically and with CT scan in favour of prophylactic mesh, 1.5 vs 35.9 % (p < 0.0001). A significantly higher number of postoperative seroma was detected in the mesh group, 11.3 vs 28.8 % (p < 0.01). No major complications related to the mesh augmentation were reported.
The details of the six published RCT’s using polypropylene mesh including 506 patients are listed in Table 5 [105–110]. Using Review Manager 5.2 software a new meta-analysis was performed. The data for this meta-analysis were extracted from the Timmermans et al. meta-analysis and the additional RCT [104, 106]. A meta-analysis on the outcomes of incisional hernia, seroma and SSI was performed. The pooled analyses data are shown in a Forrest plot for each outcome in Fig. 2. Prophylactic mesh augmentation is effective in the prevention of incisional hernias (RR 0.17: CI 0.08–0.37). An increased incidence of postoperative seroma is identified, but the majority of these are from the single study by Caro-Tarrago et al. [106] where the mesh was placed in an onlay position, with a weight of 45.9 % on the cumulative Risk Ratio for seroma (RR = 1.71; 95 %CI: 1.06–2.76) (Fig. 2c).
Forrest plots of a meta-analysis performed by the Guidelines Development Group on prophylactic mesh augmentation with polypropylene mesh after laparotomy. Analysis on the outcomes of incisional hernia, seroma and surgical site infection was performed
Although the data are favourable and consistent for prophylactic mesh augmentation, the Guidelines Development Group decided that larger trials are needed to make a strong recommendation to perform prophylactic mesh augmentation for all patients within certain risk groups.
Which mesh type, which mesh position and which type of mesh fixation?
No comparative studies are published between different mesh type, mesh position or method of mesh fixation. Pans et al. [111] found no significant protective effect on incisional hernia rate by intra-peritoneal augmentation with a polyglactin mesh (Vicryl; Ethicon) on incisional hernia rate in a RCT on obesity surgery (n = 288). Llaguna et al. [112] placed a biological mesh (Alloderm; LifeCell) in a retro-muscular position in bariatric patients. In this non-randomised comparative study (n = 106 of which 44 with mesh) a significantly lower incisional hernia rate was observed in the mesh group, 2.3 vs 17.7 % (p = 0.014). All other studies published used a polypropylene mesh, most often a small pore/heavy weight mesh: Prolene; Ethicon [110], Premilene; B. Braun [107], no name mentioned [105, 108, 109]. Only Caro-Tarrago et al. [106] used a large pore/light weight mesh: Biomesh Light P8; Cousin Biotech.
There is a large variation between the studies on the mesh position for the prophylactic mesh augmentation. Onlay, retro-muscular and pre-peritoneal mesh positioning was performed in two studies each. No studies on the use of intra-peritoneal augmentation with a non absorbable synthetic mesh are reported. Only one study on the use of intra-peritoneal augmentation with an absorbable synthetic mesh is reported [111]. The mesh was in all studies fixed with sutures to the fascia except for the study of Pans et al. [111] which used no fixation. No studies on mesh augmentation with glue or a self-fixating mesh are reported.
Trocar wounds for laparoscopic surgery and single port surgery
The PRISMA flow diagram for the Key Questions on laparoscopic surgery and single incision surgery are shown in Addendum 3 (Key Question U–W and K, Q, X).
Trocar size and trocar type
The first search for systematic reviews resulted in five records [33, 40, 41, 46, 49] and 25 additional records were screened by full text [113–137]. Several studies comment on the incidence of trocar-site hernia for various trocar sizes. However, the quality of many studies is insufficient and challenges the validity of results. Shortcomings of the individual studies include retrospective study design, short or unclear length of follow-up and inappropriate or no information on diagnostic methods to detect incisional hernias. Most importantly, available data derive from studies in which the same patient serves as case and control; i.e. the incidence of trocar-site hernia is measured for different sizes of trocars inserted at different abdominal sites in the same patient. This may impose significant bias, related to the strength of the abdominal wall and the wound repair mechanisms at varying sites of the abdominal wall, in particular the linea alba to other parts of the abdominal wall.
Helgstrand et al. [33] performed a systematic review on the incidence of trocar-site hernia. Although they found a risk reduction after sutured closure and a lower hernia rate for 5-mm versus larger diameter trocars, no meta-analysis was undertaken. The poor quality and design of the majority of the included reports preclude further in-depth evaluation for supporting evidence. No RCT’s have investigated the incidence of trocar-site hernia after insertion of blunt versus bladed trocars and no RCT’s or case-control studies have investigated the incidence of trocar-site hernia with reference to trocar size or diameter. Available data derived from univariate and multivariate analyses of cohort studies, which have investigated the effect of potential risk factors for trocar-site hernia. Obesity, age above 60 years diabetes, long duration of surgery, and the need for fascia enlargement for specimen extraction were identified as risk factors for the development of trocar-site hernia [120, 137].
Closure of trocar incisions
There are no good quality comparative studies investigating different suture materials or techniques for closure of trocar fascia defects. Armananzas et al. [113] reported in a recently published RCT a benefit for prophylactic intraperitoneal placement of a ventral patch at the umbilical site in high-risk patients to reduce the incidence of trocar-site hernia from 18.5 to 4.4 % (OR 10.1: CI 2.15–47.6; p < 0.001). Larger sample-sized studies with a good risk–benefit assessment and longer follow-up are needed to confirm and support a stronger recommendation.
Single incision laparoscopic surgery and incisional hernia
The incidence of trocar-site hernia after single port surgery has been mostly investigated as a secondary outcome measure in the setting of RCTs and 3 High Quality meta-analyses were found [138–140]. Two meta-analyses of RCTs have found no difference in the incidence of trocar-site hernia between single port and multiple port surgery, although a trend in favour of multiple port surgery was demonstrated [138, 139]. The most recent meta-analysis included 19 RCTs involving 676 patients and found a higher incidence of trocar site hernia following single port surgery [140].
Discussion
Key results
A list of the statements from these guidelines is provided in Addendum 4 as a PDF file.
Limitations
Not many strong recommendations could be made due to lack of sufficient evidence on many of the PICO questions. It is somewhat confusing to notice that the first strong recommendation in these guidelines is to avoid midline laparotomies in favour of alternative incisions and that all other recommendations are only valid for elective midline incisions. Indeed most research is focused on midline laparotomies. A midline laparotomy is still the favoured approach for most surgeons. It allows quick entrance to the abdominal cavity and extension of the incision is easy if this is required for the operation. Nevertheless, the linea alba is probably the most vulnerable and least vascularized part of the abdominal wall. Some refer to incisional hernias as “a midline crisis”. Optimising closure of abdominal wall incisions would appear to hold a large potential in reducing the incidence of incisional hernias and the subsequent need for incisional hernia repair. This has obvious benefits for the individual patient relating to an improved quality of life, avoidance of secondary operations and at a macro-economical level a significant reduction in costs for health care resources. It is not easy to see the impact of each recommendation separately. Therefore, implementation of the optimised abdominal wall closure is probably best done by teaching all involved specialists a standardised technique described as the “Principles” of abdominal wall closure [17]. This incorporates all recommendations, although the Guidelines Development Group is aware that the level of evidence for the different aspects is sometimes low to very low. David Sackett, a pioneer in evidence-based medicine wrote: “…any external guideline must be integrated with individual clinical expertise in deciding whether and how it matches the patient’s clinical state, predicament, and preferences, and thus whether it should be applied”. [141].
Discussions
For most Key Questions on the technique and material to close abdominal wall incisions, the grading of the Quality of Evidence and the choice of recommendation was straightforward. For several recommendations, while the quality of evidence was low, there was good consensus between the members of the Guidelines Development Group on the formulated statements. For prophylactic mesh augmentation there was disagreement on the strength of recommendation (weak or strong). For this reason, an additional meta-analysis was performed (Fig. 2). Although the effect size in favour of mesh augmentation is large and consistent over the studies, the Guidelines Development Group felt that larger trials are needed to support a strong recommendation for prophylactic mesh augmentation in high-risk patients. Indeed, the number of patients in the reported studies for each risk group separately (e.g. abdominal aortic aneurysm, obesity surgery, oncological surgery) seems too low to recommend prophylactic mesh augmentation in all these patient groups. Nevertheless, we are aware that several large RCT’s are on-going and this grade of recommendation might be changed in the light of future publications.
No recommendations could be made on non-midline incisions due to insufficient evidence. Nevertheless, it seems reasonable to promote similar material (slowly absorbable suture) and techniques (continuous aponeurotic closure with small bites and SL/WL >4/1) for closure of non-midline incisions.
No recommendations could be made on the type or the size of the needle used to close abdominal incisions. No studies comparing the size of the sutures were identified in our searches.
No recommendation could be made for emergency surgery, which is often a contaminated procedure. The Guidelines Development Group consider that the use of retention sutures or of reinforced tension line sutures, should be prospectively studied in patients at high risk for development of burst abdomen. A risk model and score for burst abdomen has been developed by van Ramshorst et al. [142] and could be used as basis for including patients in these studies.
No recommendations could be made on the postoperative care after laparotomies. Long-term follow-up studies are needed to assess the impact on the occurrence of incisional hernias of prescribing abdominal binders or restricting or indeed encouraging early postoperative activity.
Applicability
To adopt the guidelines and “evidence based principles” for abdominal wall closure, surgeons must be convinced that these are valid recommendations with a large impact on the outcome for the patients. These guidelines are an attempt to create awareness amongst surgeons about these principles. Adaptation can be done by systematic quality control of the suturing technique as described by van Ramshorst et al. [143]. The EuraHS, European registry for abdominal wall hernias, has developed an online platform for registration and outcome measurement of abdominal wall surgery [144]. An additional route in the database on the closure of abdominal wall incisions and for prophylactic mesh augmentation will be provided from 2015 onwards. It is hoped that such a registry database will facilitate the data collection for prospective studies.
Validity of the guidelines
Prior to submission of the manuscript the guidelines were evaluated and scored using the AGREE II instrument. The results of these assessments are presented in Table 6. Several large multi-centre studies on the closure of abdominal wall incisions are currently on-going. High Quality data on the use of the “small bites” technique in midline incisions, on the closure of laparotomies in emergency and on prophylactic mesh augmentation will be published in the coming years. The Guidelines Development Group has decided to update these guidelines in 2017 and present the results during the 39th Annual Congress of the European Hernia Society in Vienna in May 2017.
Conclusions
To decrease the incidence of incisional hernias it is recommended to utilise a non-midline approach to a laparotomy whenever possible. For elective midline incisions, it is strongly recommended to perform a continuous suturing technique and to avoid the use of rapidly absorbable sutures. It is suggested that the use of a slowly absorbable monofilament suture in a single layer aponeurotic closure technique without separate closure of the peritoneum and using a small bites technique with a SL/WL ratio at least 4/1 is the current recommended method of fascial closure. Currently, no recommendations can be given on the optimal technique to close emergency laparotomy incisions. Prophylactic mesh augmentation appears effective and safe and can be suggested in high-risk patients like, aortic aneurysm surgery and obese patients.
Other information
Funding
The meetings of the Guidelines Development Group and the search performed by SIGN were supported financially by the European Hernia Society. No additional funding for the development of these guidelines was received from any other source.
References
Diener MK, Voss S, Jensen K, Buchler MW, Seiler CM (2010) Elective midline laparotomy closure: the inline systematic review and meta-analysis. Ann Surg 251:843–856
Fink C, Baumann P, Wente MN, Knebel P, Bruckner T, Ulrich A, Werner J, Büchler MW, Diener MK (2014) Incisional hernia rate 3 years after midline laparotomy. Br J Surg 101:51–54
Pereira JA, Pera M, Grande L (2013) Incidence of incisional hernia after open and laparoscopic colorectal cancer resection (Spanish language). Cir Esp 91:44–49
Claes K, Beckers R, Heindryckx E, Kyle-Leinhase I, Pletinckx P, Claeys D, Muysoms F (2014) Retrospective observational study on the incidence of incisional hernias after colorectal carcinoma resection with follow-up CT scan. Hernia Jan 21 (Epub ahead of print)
den Hartog D, Dur AHM, Kamphuis AGA, Tuinebreijer WE, Kreis RW (2009) Comparison of ultrasonography with computed tomography in the diagnosis of incisional hernias. Hernia 13:45–48
Bloemen A, Van Dooren P, Huizinga BF, Hoofwijk AGM (2012) Comparison of ultrasonography and physical examination in the diagnosis of incisional hernia in a prospective study. Hernia 16:53–57
Bosanquet D, Aboelrahman T, Ansell J, Cornish J, Davies L, Frewer K, Frewer N, Glasbey J, Harries R, Stimpson A, Russell D, Russell I, Torkington J (2014) Systematic review and meta regression of factors affecting midline incisional hernia rates: an analysis of 14,618 patients. Hernia 18(suppl 2):S12–S15
Alnassar S, Bawahab M, Abdoh A, Guzman R, Al Tuwaijiri T, Louridas G (2012) Incisional hernia postrepair of abdominal aortic occlusive and aneurysmal disease: five-year incidence. Vascular 20:273–277
Höer J, Lawong G, Klinge U, Schumpelick V (2002) Factors influencing the development of incisional hernia. A retrospective study of 2,983 laparotomy patients over a period of 10 years. Chirurg 73:474–480
Antoniou GA, Georgiadis GS, Antoniou SA, Granderath FA, Giannoukas AD, Lazarides MK (2011) Abdominal aortic aneurysm and abdominal wall hernia as manifestations of a connective tissue disorder. J Vasc Surg 54:1175–1181
Henriksen NA, Helgstrand F, Vogt KC, Jorgensen LN, Bisgaard T (2013) Risk factors for incisional hernia repair after aortic reconstructive surgery in a nationwide study. J Vasc Surg 57:1524–1530
Israelsson LA, Millbourn D (2013) Prevention of incisional hernias: how to close a midline incision. Surg Clin North Am 93:1027–1040
van Ramshorst GH, Eker HH, Hop WC, Jeekel J, Lange JF (2012) Impact of incisional hernia on health-related quality of life and body image: a prospective cohort study. Am J Surg 204:144–150
Flum DR, Horvath K, Koepsell T (2003) Have outcomes of incisional hernia repair improved with time? A population-based analysis. Ann Surg 237:129–135
Burger JW, Luijendijk RW, Hop WC, Halm JA, Verdaasdonk EG, Jeekel J (2004) Long-term follow-up of a randomized controlled trial of suture versus mesh repair of incisional hernia. Ann Surg 240:578–583
Helgstrand F, Rosenberg J, Kehlet H, Strandfelt P, Bisgaard T (2012) Reoperation versus clinical recurrence rate after ventral hernia repair. Ann Surg 256:955–958
Meijer EJ, Timmermans L, Jeekel J, Lange JF, Muysoms FE (2013) The principles of abdominal wound closure. Acta Chir Belg 113:239–244
Data presented by J-F Gillion during the 36th Annual Congress of the European Hernia Society in Edinburgh on May 31st 2014. (Publication in preparation: J-F Gillion, D. Sanders, M. Miserez, F. Muysoms; The Bonham Group. The economic burden of incisional hernia repair.)
Scottish Intercollegiate Guidelines Network (SIGN). http://www.sign.ac.uk/
Brouwers M, Kho ME, Browman GP, Burgers JS, Cluzeau F, Feder G, Fervers B, Graham ID, Grimshaw J, Hanna S, Littlejohns P, Makarski J, Zitzelsberger L (2010) AGREE II: Advancing guideline development, reporting and evaluation in healthcare. Can Med Assoc J 182:E839–E842. http://www.agreetrust.org/
Liberati A, Altman DG, Tetzlaff J, Mulrow C, Gøtzsche PC, Ioannidis JP, Clarke M, Devereaux PJ, Kleijnen J, Moher D (2009) The PRISMA statement for reporting systematic reviews and meta-analyses of studies that evaluate health care interventions: explanation and elaboration. J Clin Epidemiol 62:e1–e34. http://www.prisma-statement.org/
Guyatt GH, Oxman AD, Vist G, Kunz R, Falck-Ytter Y, Alonso-Coello P, Schünemann HJ (2008) Rating quality of evidence and strength of recommendations GRADE: an emerging consensus on rating quality of evidence and strength of recommendations. BMJ 336:924–926. http://www.gradeworkinggroup.org/
Anderson ER, Gates S (2004) Techniques and materials for closure of the abdominal wall in caesarean section. Cochrane Database Syst Rev 18:CD004663
Bhangu A, Fitzgerald JE, Singh P, Battersby N, Marriott P, Pinkney T (2013) Systematic review and meta-analysis of prophylactic mesh placement for prevention of incisional hernia following midline laparotomy. Hernia 17:445–455
Bhangu A, Nepogodiev D, Futaba K (2012) Systematic review and meta-analysis of the incidence of incisional hernia at the site of stoma closure. World J Surg 36:973–983
Bickenbach KA, Karanicolas PJ, Ammori JB, Jayaraman S, Winter JM, Fields RC, Govindarajan A, Nir I, Rocha FG, Brennan MF (2013) Up and down or side to side? A systematic review and meta-analysis examining the impact of incision on outcomes after abdominal surgery. Am J Surg 206:400–409
Brown SR, Goodfellow PB (2005) Transverse verses midline incisions for abdominal surgery. Cochrane Database Syst Rev 4:CD005199
Cheng H, Rupprecht F, Jackson D, Berg T, Seelig MH (2007) Decision analysis model of incisional hernia after open abdominal surgery. Hernia 11:129–137
Finan KR, Kilgore ML, Hawn MT (2009) Open suture versus mesh repair of primary incisional hernias: a cost-utility analysis. Hernia 13:173–182
Friedrich M, Muller-Riemenschneider F, Roll S, Kulp W, Vauth C, Greiner W, Willich S, von der Schulenburg JM (2008) Health technology assessment of laparoscopic compared to conventional surgery with and without mesh for incisional hernia repair regarding safety, efficacy and cost-effectiveness. GMS Health Technol Assess 4:Doc01
Grantcharov TP, Rosenberg J (2001) Vertical compared with transverse incisions in abdominal surgery. Eur J Surg 167:260–267
Gupta H, Srivastava A, Menon GR, Agrawal CS, Chumber S, Kumar S (2008) Comparison of interrupted versus continuous closure in abdominal wound repair: a meta-analysis of 23 trials. Asian J Surg 31:104–114
Helgstrand F, Rosenberg J, Bisgaard T (2011) Trocar site hernia after laparoscopic surgery: a qualitative systematic review. Hernia 15:113–121
Hodgson NC, Malthaner RA, Ostbye T (2000) The search for an ideal method of abdominal fascial closure: a meta-analysis. Ann Surg 231:436–442
Hynes DM, Stroupe KT, Luo P, Giobbie-Hurder A, Reda D, Kraft M, Itani K, Fitzgibbons R, Jonasson O, Neumayer L (2006) Cost effectiveness of laparoscopic versus open mesh hernia operation: results of a department of veterans affairs randomized clinical trial. J Am Coll Surg 203:447–457
Mathai M, Hofmeyr GJ, Mathai NE (2013) Abdominal surgical incisions for caesarean section. Cochrane Database Syst Rev 5:CD004453
Jin JB, Jiang ZP, Chen S (2010) Meta-analysis of suture techniques for midline abdominal incisions. Zhonghua Wai Ke Za Zhi [Chinese J Surg] 48:1256–1261
Le Huu Nho R, Mege D, Ouaïssi M, Sielezneff I, Sastre B (2012) Incidence and prevention of ventral incisional hernia. J Visc Surg 149(5 Suppl):e3–e14
Nachiappan S, Markar S, Karthikesaligam A, Ziprin P, Faiz O (2013) Prophylactic mesh placement in high-risk patients undergoing elective laparotomy: a systematic review. World J Surg 37:1861–1871
Owens M, Barry M, Janjua AZ, Winter DC (2011) A systematic review of laparoscopic port site hernias in gastrointestinal surgery. Surgeon 9:218–224
Pemberton RJ, Tolley DA, van Velthoven RF (2006) Prevention and management of complications in urological laparoscopic port site placement. Eur Urol 50:958–968
Rucinski J, Margolis M, Panagopoulos G, Wise L (2001) Closure of the abdominal midline fascia: meta-analysis delineates the optimal technique. Am Surg 67:421–426
Sajid MS, Parampalli U, Baig MK, McFall MR (2011) A systematic review on the effectiveness of slowly-absorbable versus non-absorbable sutures for abdominal fascial closure following laparotomy. Int J Surg 9:615–625
Seiler CM, Bruckner T, Diener MK, Papyan A, Golcher H, Seidlmayer C, Franck A, Kieser M, Bücher MW, Knaebel HP (2009) Interrupted or continuous slowly absorbable sutures for closure of primary elective midline abdominal incisions: a multicenter randomized trial. Ann Surg 249:576–582
Seiler CM, Deckert A, Diener MK, Knaebel HP, Weigand MA, Victor N, Büchler MW (2009) Midline versus transverse incision in major abdominal surgery: a randomized, double-blind equivalence trial. Ann Surg 249:913–920
Swank HA, Mulder IM, la Chapelle CF, Reitsma JB, Lange JF, Bemelman WA (2012) Systematic review of trocar-site hernia. Br J Surg 99:315–323
Takagi H, Sugimoto M, Kato T, Matsuno Y, Umemoto T (2007) Postoperative incision hernia in patients with abdominal aortic aneurysm and aortoiliac occlusive disease: a systematic review. Eur J Vasc Endovasc Surg 33:177–181
van ‘t Riet M, Steyerberg EW, Nellensteyn J, Bonjer HJ, Jeekel J (2002) Meta-analysis of techniques for closure of midline abdominal incisions. Br J Surg 89:1350–1356
Yamamoto M, Minikel L, Zaritsky E (2011) Laparoscopic 5-mm trocar site herniation and literature review. JSLS 15:122–126
Baucom RB, Beck WC, Holzman MD, Sharp KW, Nealon WH, Poulose BK (2014) Prospective evaluation of surgeon physical exam for detection of incisional hernia. J Am Coll Surg 218:363–366
Beck WC, Holzman MD, Sharp KW, Nealon WH, Dupont WD, Poulose BK (2013) Comparative effectiveness of dynamic abdominal sonography for hernia vs computed tomography in the diagnosis of incisional hernia. J Am Coll Surg 216:447–453
Schreinemacher MH, Vijgen GH, Dagnelie PC, Bloemen JG, Huizinga BF, Bouvy ND (2011) Incisional hernias in temporary stoma wounds: a cohort study. Arch Surg 146:94–99
Bhangu A, Fletcher L, Kingdon S, Smith E, Nepogodiev D, Janjua U (2012) A clinical and radiological assessment of incisional hernias following closure of temporary stomas. Surgeon 10:321–325
Cingi A, Cakir T, Sever A, Aktan AO (2006) Enterostomy site hernias: a clinical and computerized tomographic evaluation. Dis Colon Rectum 49:1559–1563
Cingi A, Solmaz A, Attaallah W, Aslan A, Aktan AO (2008) Enterostomy closure site hernias: a clinical and ultrasonographic evaluation. Hernia 12:401–405
Musella M, Milone F, Chello M, Angelini P, Jovino R (2001) Magnetic resonance imaging and abdominal wall hernias in aortic surgery. J Am Coll Surg 193:392–395
Rodriguez HE, Matsumura JS, Morasch MD, Greenberg RK, Pearce WH (2004) Abdominal wall hernias after open abdominal aortic aneurysm repair: prospective radiographic detection and clinical implications. Vasc Endovasc Surg 38:237–240
Hojer AM, Rygaard H, Jess P (1997) Ct in the diagnosis of abdominal wall hernias: a preliminary study. Eur Rad 7:1416–1418
Young J, Gilbert AI, Graham MF (2007) The use of ultrasound in the diagnosis of abdominal wall hernias. Hernia 11:347–351
Lee L, Mappin-Kasirer B, Liberman AS, Stein B, Charlebois P, Vassiliou M, Fried GM, Feldman LS (2012) High incidence of symptomatic incisional hernia after midline extraction in laparoscopic colon resection. Surg Endosc 26:3180–3185
Burger JW, van’t Riet M, Jeekel J (2002) Abdominal incisions: techniques and postoperative complications. Scand J Surg 91:315–321
Weiland DE, Bay C, Del Sordi S (1998) Choosing the best abdominal closure by meta-analysis. Am J Surg 176:666–670
Gurusamy KS, Cassar Delia E, Davidson BR (2013) Peritoneal closure versus no peritoneal closure for patients undergoing non-obstetric abdominal operations. Cochrane Database Syst Rev Issue 7. Art. No.: CD010424
Israelsson LA (1999) Bias in clinical trials: the importance of suture technique. Eur J Surg 165:3–7
Nelson RL, Vedula SS (2006) Closure methods for laparotomy incisions. Cochrane Database Systc Rev Issue 1 Art. No.: CD005661
Jenkins TP (1976) The burst abdominal wound: a mechanical approach. Br J Surg 63:873–876
Israelsson LA, Jonsson T (1993) Suture length to wound length ratio and healing of midline laparotomy incisions. Br J Surg 80:1284–1286
Israelsson LA, Millbourn D (2012) Closing midline abdominal incisions. Langenbecks Arch Surg 397:1201–1207
Millbourn D, Cengiz Y, Israelsson LA (2009) Effect of stitch length on wound complications after closure of midline incisions: a randomized controlled trial. Arch Surg 144:1056–1059
Wissing J, van Vroonhoven TJ, Schattenkerk ME, Veen HF, Ponsen RJ, Jeekel J (1987) Fascia closure after midline laparotomy: results of a randomized trial. Br J Surg 74:738–741
Wang ZX, Jiang CP, Cao Y, Ding YT (2013) Systematic review and meta-analysis of triclosan-coated sutures for the prevention of surgical-site infection. Br J Surg 100:465–473
Diener MK, Knebel P, Kieser M, Schüler P, Schiergens TS, Atanassov V, Neudecker J, Stein E, Thielemann H, Kunz R, von Frankenberg M, Schernikau U, Bunse J, Jansen-Winkeln B, Partecke LI, Prechtl G, Pochhammer J, Bouchard R, Hodina R, Beckurts KT, Leißner L, Lemmens HP, Kallinowski F, Thomusch O, Seehofer D, Simon T, Hyhlik-Dürr A, Seiler CM, Hackert T, Reissfelder C, Hennig R, Doerr-Harim C, Klose C, Ulrich A, Büchler MW (2014) Effectiveness of triclosan-coated PDS Plus versus uncoated PDS II sutures for prevention of surgical site infection after abdominal wall closure: the randomised controlled PROUD trial. Lancet 384:142–152
Rasić Z, Schwarz D, Adam VN, Sever M, Lojo N, Rasić D, Matejić T (2011) Efficacy of antimicrobial triclosan-coated polyglactin 910 (Vicryl* Plus) suture for closure of the abdominal wall after colorectal surgery. Coll Antropol 35:439–443
Nakamura T, Kashimura N, Noji T, Suzuki O, Ambo Y, Nakamura F, Kishida A (2013) Triclosan-coated sutures reduce the incidence of wound infections and the costs after colorectal surgery: a randomized controlled trial. Surgery 153:576–583
Justinger C, Slotta JE, Ningel S, Graber S, Kollmar O, Schilling MK (2013) Surgical-site infection after abdominal wall closure with triclosan-impregnated polydioxanone sutures: results of a randomized clinical pathway facilitated trial. Surgery 3:589–595
Baracs J, Huszár O, Sajjadi SG, Horváth OP (2011) Surgical site infections after abdominal closure in colorectal surgery using triclosan-coated absorbable suture (PDS Plus) vs. uncoated sutures (PDS II): a randomized multicenter study. Surg Infect (Larchmt) 12:483–489
Stafford MK, Pitman MC, Nanthakumaran N, Smith JR (1998) Blunt-tipped versus sharp-tipped needles: wound morbidity. J Obstet Gynaecol 18:18–19
Khorgami Z, Shoar S, Laghaie B, Aminian A, Hosseini Araghi N, Soroush A (2013) Prophylactic retention sutures in midline laparotomy in high-risk patients for wound dehiscence: a randomized controlled trial. J Surg Res 180:238–243
Agarwal A, Hossain Z, Agarwal A, Das A, Chakraborty S, Mitra N, Gupta M, Ray U (2011) Reinforced tension line suture closure after midline laparotomy in emergency surgery. Trop Doct 41:193–196
Rink AD, Goldschmidt D, Dietrich J, Nagelschmidt M, Vestweber KH (2000) Negative side-effects of retention sutures for abdominal wound closure. A prospective randomised study. Eur J Surg 166:932–937
Mäkelä JT, Kiviniemi H, Juvonen T, Laitinen S (1995) Factors influencing wound dehiscence after midline laparotomy. Am J Surg 170:387–390
Matsuoka J, Gohchi A, Kamikawa Y, Sakagami K, Orita K (1995) Chopstick retention suture for the closure of abdominal wounds. J Am Coll Surg 181:471–474
Penninckx FM, Poelmans SV, Kerremans RP, Beckers JP (1979) Abdominal wound dehiscence in gastroenterological surgery. Ann Surg 189:345–352
Irvin TT, Stoddard CJ, Greaney MG, Duthie HL (1977) Abdominal wound healing: a prospective clinical study. Br Med J 2:351–352
Hubbard TB Jr, Rever WB Jr (1972) Retention sutures in the closure of abdominal incisions. Am J Surg 124:378–380
Rahbari NN, Knebel P, Diener MK, Seidlmayer C, Ridwelski K, Stoltzing H, Seiler CM (2009) Current practice of abdominal wall closure in elective surgery—is there any consensus? BMC Surgery 9:8
Bouvier A, Rat P, Drissi-Chbihi F, Bonnetain F, Lacaine F, Mariette C, Ortega-Deballon P (2014) Abdominal binders after laparotomy: review of the literature and French survey of policies. Hernia 18:501–506
Pommergaard HC, Burcharth J, Danielsen A, Angenete E, Haglind E, Rosenberg J (2013) No consensus on restrictions on physical activity to prevent incisional hernias after surgery. Hernia 18:495–500
Kosins AM, Scholz T, Cetinkaya M, Evans GR (2013) Evidence-based value of subcutaneous surgical wound drainage: the largest systematic review and meta-analysis. Plast Reconstr Surg 132:443–450
Nakayama H, Takayama T, Okubo T, Higaki T, Midorikawa Y, Moriguchi M, Aramaki O, Yamazaki S (2014) Subcutaneous drainage to prevent wound infection in liver resection: a randomized controlled trial. J Hepatobiliary Pancreat Sci 21:509–517
Numata M, Godai T, Shirai J, Watanabe K, Inagaki D, Hasegawa S, Sato T, Oshima T, Fujii S, Kunisaki C, Yukawa N, Rino Y, Taguri M, Morita S, Masuda M (2014) A prospective randomized controlled trial of subcutaneous passive drainage for the prevention of superficial surgical site infections in open and laparoscopic colorectal surgery. Int J Colorectal Dis 29:353–358
Kaya E, Paksoy E, Ozturk E, Sigirli D, Bilgel H (2010) Subcutaneous closed-suction drainage does not affect surgical site infection rate following elective abdominal operations: a prospective randomized clinical trial. Acta Chir Belg 110:457–462
Baier PK, Gluck NC, Baumgartner U, Adam U, Fischer A, Hopt UT (2010) Subcutaneous Redon drains do not reduce the incidence of surgical site infections after laparotomy. A randomized controlled trial on 200 patients. Int J Colorectal Dis 25:639–643
Chowdri NA, Qadri SA, Parray FQ, Gagloo MA (2007) Role of subcutaneous drains in obese patients undergoing elective cholecystectomy: a cohort study. Int J Surg 5:404–407
Panici PB, Zullo MA, Casalino B, Angioli R, Muzii L (2003) Subcutaneous drainage versus no drainage after minilaparotomy in gynecologic benign conditions: a randomized study. Am J Obstet Gynecol 188:71–75
Gallup DC, Gallup DG, Nolan TE, Smith RP, Messing MF, Kline KL (1996) Use of a subcutaneous closed drainage system and antibiotics in obese gynecologic patients. Am J Obstet Gynecol 175:358–361
Loong RL, Rogers MS, Chang AM (1988) A controlled trial on wound drainage in caesarean section. Aust N Z J Obstet Gynaecol 28:266–269
Shaffer D, Benotti PN, Bothe A Jr, Jenkins RL, Blackburn GL (1987) A prospective, randomized trial of abdominal wound drainage in gastric bypass surgery. Ann Surg 206:134–137
Ali J, Serrette C, Khan TA (1983) The effect of abdominal binders on postoperative pulmonary function. Infect in Surg 2:875–881
Fagevik Olsén M, Josefson K, Wiklund M (2009) Evaluation of abdominal binder after major upper gastrointestinal surgery. Adv in Physiother 11:104–110
Larson CM, Ratzer ER, Davis-Merritt D, Clark JR (2009) The effect of abdominal binders on postoperative pulmonary function. Am Surg 75:169–171
Cheifetz O, Lucy SD, Overend TJ, Crowe J (2010) The effect of abdominal support on functional outcomes in patients following major abdominal surgery: a randomized controlled trial. Physiother Can 62:242–253
Clay L, Gunnarsson U, Franklin KA, Strigård K (2014) Effect of an elastic girdle on lung function, intra-abdominal pressure, and pain after midline laparotomy: a randomized controlled trial. Int J Colorectal Dis 29:715–721
Timmermans L, de Goede B, Eker HH, van Kempen BJ, Jeekel J, Lange JF (2013) Meta-analysis of primary mesh augmentation as prophylactic measure to prevent incisional hernia. Dig Surg 30:401–409
Abo-Ryia MH, El-Khadrawy OH, Abd-Allah HS (2013) Prophylactic preperitoneal mesh placement in open bariatric surgery: a guard against incisional hernia development. Obes Surg 23:1571–1574
Caro-Tarrago A, Olona Casas C, Jimenez Salido A, Duque Guilera E, Moreno Fernandez F, Vicente Guillen V (2014) Prevention of incisional hernia in midline laparotomy with an onlay mesh: a randomized clinical trial. World J Surg 38:2223–2230
Gutiérrez de la Pena C, Medina Achirica C, Dominguez-Adame E, Medina Diez J (2003) Primary closure of laparotomies with high risk of incisional hernia using prosthetic material: analysis of usefulness. Hernia 7:134–136
Strzelczyk JM, Szymanski D, Nowicki ME, Wilczynski W, Gaszynski T, Czupryniak L (2006) Randomized clinical trial of postoperative hernia prophylaxis in open bariatric surgery. Br J Surg 93:1347–1350
El-Khadrawy OH, Moussa G, Mansour O, Hashish MS (2009) Prophylactic prosthetic reinforcement of midline abdominal incisions in high-risk patients. Hernia 13:267–274
Bevis PM, Windhaber RA, Lear PA, Poskitt KR, Earnshaw JJ, Mitchell DC (2010) Randomized clinical trial of mesh versus sutured wound closure after open abdominal aortic aneurysm surgery. Br J Surg 97:1497–1502
Pans A, Elen P, Desaive C, Andre C (1998) Long-term results of polyglactin mesh for the prevention of incisional hernias in obese patients. World J Surg 22:479–483
Llaguna OH, Avgerinos DV, Nagda P, Elfant D, Leitman IM, Goodman E (2011) Does prophylactic biologic mesh placement protect against the development of incisional hernia in high-risk patients? World J Surg 35:1651–1655
Armañanzas L, Ruiz-Tovar J, Arroyo A, García-Peche P, Armañanzas E, Diez M, Galindo I, Calpena R (2014) Prophylactic mesh vs suture in the closure of the umbilical trocar site after laparoscopic cholecystectomy in high-risk patients for incisional hernia. A randomized clinical trial. J Am Coll Surg 218:960–968
Bhoyrul S, Payne J, Steffes B, Swanstrom L, Way LW (2000) A randomized prospective study of radially expanding trocars in laparoscopic surgery. J Gastrointest Surg 4:392–397
Bonjer HJ, Hazebroek EJ, Kazemier G, Giuffrida MC, Meijer WS, Lange JF (1997) Open versus closed establishment of pneumoperitoneum in laparoscopic surgery. Br J Surg 84:599–602
Bowrey DJ, Blom D, Crookes PF, Bremner CG, Johansson JL, Lord RV, Hagen JA, DeMeester SR, DeMeester TR, Peters JH (2001) Risk factors and the prevalence of trocar site herniation after laparoscopic fundoplication. Surg Endosc 15:663–666
Bunting DM (2010) Port-site hernia following laparoscopic cholecystectomy. JSLS 14:490–497
Chiu CC, Lee WJ, Wang W, Wei PL, Huang MT (2006) Prevention of trocar-wound hernia in laparoscopic bariatric operations. Obes Surg 16:913–918
Clark LH, Soliman PT, Odetto D, Munsell MF, Schmeler KM, Fleming N, Westin SN, Nick AM, Ramirez PT (2013) Incidence of trocar site herniation following robotic gynecologic surgery. Gynecol Oncol 131:400–403
Comajuncosas J, Hermoso J, Gris P, Jimeno J, Orbeal R, Vallverdú H, López Negre JL, Urgellés J, Estalella L, Parés D (2014) Risk factors for umbilical trocar site incisional hernia in laparoscopic cholecystectomy: a prospective 3-year follow-up study. Am J Surg 207:1–6
Delmonaco P, Cirocchi R, La Mura F, Morelli U, Migliaccio C, Napolitano V, Trastulli S, Farinella E, Giuliani D, Desol A, Milani D, Di Patrici MS, Spizzirri A, Bravetti M, Sciannameo V, Avenia N, Sciannameo F (2011) Trocarsite hernia after laparoscopic colectomy: a case report and literature review. ISRN Surgery 2011:725601
Eid GM, Collins J (2005) Application of a trocar wound closure system designed for laparoscopic procedures in morbidly obese patients. Obes Surg 15:871–873
Erdas E, Dazzi C, Secchi F, Aresu S, Pitzalis A, Barbarossa M, Garau A, Murgia A, Contu P, Licheri S, Pomata M, Farina G (2012) Incidence and risk factors for trocar site hernia following laparoscopic cholecystectomy: a long-term follow-up study. Hernia 16:431–437
Feste JR, Bojahr B, Turner DJ (2000) Randomized trial comparing a radially expandable needle system with cutting trocars. JSLS 4:11–15
Helgstrand F, Rosenberg J, Kehlet H, Bisgaard T (2011) Low risk of trocar site hernia repair 12 years after primary laparoscopic surgery. Surg Endosc 25:3678–3682
Holzinger F, Klaiber C (2002) Trocar site hernias. A rare but potentially dangerous complication of laparoscopic surgery. Chirurg 73:899–904
Hussain A, Mahmood H, Singhal T, Balakrishnan S, Nicholls J, El-Hasani S (2009) Long-term study of port-site incisional hernia after laparoscopic procedures. JSLS 13:346–349
Johnson WH, Fecher AM, McMahon RL, Grant JP, Pryor AD (2006) VersaStep trocar hernia rate in unclosed fascial defects in bariatric patients. Surg Endosc 20:1584–1586
Kadar N, Reich H, Liu CY, Manko GF, Gimpelson R (1993) Incisional hernias after major laparoscopic gynecologic procedures. Am J Obstet Gynecol 168:1493–1495
Leibl BJ, Schmedt CG, Schwarz J, Kraft K, Bittner R (1999) Laparoscopic surgery complications associated with trocar tip design: review of literature and own results. J Laparoendosc Adv Surg Tech A 9:135–140
Mayol J, Garcia-Aguilar J, Ortiz-Oshiro E, De-Diego Carmona JA, Fernandez-Represa JA (1997) Risks of the minimal access approach for laparoscopic surgery: multivariate analysis of morbidity related to umbilical trocar insertion. World J Surg 21:529–533
Moran DC, Kavanagh DO, Sahebally S, Neary PC (2012) Incidence of early symptomatic port-site hernia: a case series from a department where laparoscopy is the preferred surgical approach. Ir J Med Sci 181:463–466
Moreno-Sanz C, Picazo-Yeste JS, Manzanera-Díaz M, Herrero-Bogajo ML, Cortina-Oliva J, Tadeo-Ruiz G (2008) Prevention of trocar site hernias: description of the safe port plug technique and preliminary results. Surg Innov 15:100–104
Sánchez-Pernaute A, Pérez-Aguirre E, García Botella A, Rodríguez L, Antona EM, Cabeza J, Valladolid DJ, Rubio MA, Delgado I, Torres A (2008) Prophylactic closure of trocar orifices with an intraperitoneal mesh (ventralex) in laparoscopic bariatric surgery. Obes Surg 18:1489–1491
Schmedt CG, Leibl BJ, Däubler P, Bittner R (2001) Access-related complications—an analysis of 6023 consecutive laparoscopic hernia repairs. Min Invas Ther & Allied Technol 10:23–30
Tonouchi H, Ohmori Y, Kobayashi M, Kusunoki M (2004) Trocar site hernia. Arch Surg 139:1248–1256
Uslu HY, Erkek AB, Cakmak A, Kepenekci I, Sozener U, Kocaay FA, Turkcapar AG, Kuterdem E (2007) Trocar site hernia after laparoscopic cholecystectomy. J Laparoendosc Adv Surg Tech A 17:600–603
Garg P, Thakur JD, Garg M, Menon GR (2012) Single-incision laparoscopic cholecystectomy vs conventional laparoscopic cholecystectomy: a meta-analysis of randomized controlled trials. J Gastrointest Surg 16:1618–1628
Trastulli S, Cirocchi R, Desiderio J, Guarino S, Santoro A, Parisi A, Noya G, Boselli C (2013) Systematic review and meta-analysis of randomized clinical trials comparing single-incision versus conventional laparoscopic cholecystectomy. Br J Surg 100:191–208
Milas M, Deveđija S, Trkulja V (2014) Single incision versus standard multiport laparoscopic cholecystectomy: up-dated systematic review and meta-analysis of randomized trials. Surgeon 12:271–289
Sackett DL, Rosenberg WM, Gray JA, Haynes RB, Richardson WS (1996) Evidence based medicine: what it is and what it isn’t. BMJ 312:71–72
van Ramshorst GH, Nieuwenhuizen J, Hop WC, Arends P, Boom J, Jeekel J, Lange JF (2010) Abdominal wound dehiscence in adults: development and validation of a risk model. World J Surg 34:20–27
van Ramshorst GH, Klop B, Hop WCJ, Israelsson LA, Lange JF (2013) Closure of midline laparotomies by means of small stitches: practical aspects of a new technique. Surg Technol Int 23:34–38
Muysoms F, Campanelli G, Champault GG, deBeaux AC, Dietz UA, Jeekel J, Klinge U, Köckerling F, Mandala V, Montgomery A, Morales Conde S, Puppe F, Simmermacher RKJ, Śmietański M, Miserez M (2012) EuraHS: the development of an international online platform for registration and outcome measurement of ventral abdominal wall hernia repair. Hernia 16:239–250
Acknowledgments
We acknowledge Iris Kyle-Leinhase, PhD, study coordinator for abdominal wall research at AZ Maria Middelares in Ghent, Belgium, and project manager for EuraHS, the European Registry for abdominal wall hernias, for her help in searching full text of the papers for review. We acknowledge Robin Harbour, lead methodologist of SIGN for his support and tutoring on guidelines methodology and Juliet Brown, clinical researcher at SIGN in Glasgow for her help in the searches for our guidelines. We acknowledge the external experts for their review and evaluation using the AGREE II instrument of these guidelines prior to submission of the manuscript: Ferdinando Agresta, MD (Department of General Surgery, ULSS19 del Veneto, Adria (RO), Italy), Prof Jaap Bonjer (Department of Surgery, VUmc University Medical Center, Amsterdam, The Netherlands), Prof Wim Ceelen (Department of Surgery, University Hospital Ghent, Belgium), Prof Lars Nannestad Jorgensen (Department of Surgery, Bispebjerg University Hospital, Copenhagen, Denmark).
Conflict of interest
The authors report no conflict of interest in relation to this manuscript.
Author information
Authors and Affiliations
Corresponding author
Electronic supplementary material
Below is the link to the electronic supplementary material.
10029_2014_1342_MOESM1_ESM.docx
Addendum 1: List of Key Questions and PICO’s (Patients-Intervention-Comparison-Outcome) proposed by the Guidelines Development Group for the European Hernia Society guidelines on the closure of abdominal wall incisions (DOCX 114 kb)
10029_2014_1342_MOESM2_ESM.docx
Addendum 2: Search terms used for the search for systematic reviews and/or meta-analyses performed by SIGN for the Guidelines Development Group of the European Hernia Society guidelines on the closure of abdominal wall incisions. The search was performed in November 2013 (DOCX 76 kb)
10029_2014_1342_MOESM3_ESM.docx
Addendum 3: PRISMA flow diagrams for the additional searches performed on the Key Questions by the members of the Guidelines Development Group of the European Hernia Society guidelines on the closure of abdominal wall incisions. Records found until April 2014 were included (DOCX 1148 kb)
10029_2014_1342_MOESM4_ESM.pdf
Addendum 4: PDF file with a summary of European Hernia Society Guidelines on the closure of abdominal wall incisions (PDF 154 kb)
Rights and permissions
About this article
Cite this article
Muysoms, F.E., Antoniou, S.A., Bury, K. et al. European Hernia Society guidelines on the closure of abdominal wall incisions. Hernia 19, 1–24 (2015). https://doi.org/10.1007/s10029-014-1342-5
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10029-014-1342-5