Background
In the pediatric population, complex appendicitis is common, especially in children < 7 years old [
1]. Approximately 35% of children with acute appendicitis present with the complex form. Although a uniform definition of complex appendicitis is lacking, in most studies it represents a spectrum ranging from gangrenous appendicitis to perforated appendicitis with generalized peritonitis. Generally, complex appendicitis can be divided into two main subgroups: without appendiceal mass and/or abscess (75%) and with appendiceal mass and/or abscess (25%) [
1].
In general, complex appendicitis and its treatment are associated with significant morbidity (complications occurring in up to 30% of patients), prolonged length of hospital stay, and high costs [
2]. Heterogeneity in the treatment of children with an appendiceal mass and/or abscess (e.g., initially non-operative treatment versus early appendectomy) still exists in daily practice. Some (pediatric) surgeons prefer initially non-operative treatment consisting of intravenous antibiotics (with or without percutaneous drainage), since this strategy is associated with less complications [
3]. Others favor early appendectomy because a second trip to the hospital in order to perform an interval appendectomy can be avoided and, if the interval appendectomy is not performed as same day procedure, a shorter length of hospital stay is expected. This is one of the main reasons why early appendectomy is recommended by the Dutch guideline on the diagnosis and treatment of acute complex appendicitis as well [
4]. This recommendation is merely based on expert opinion and in contrast to the limited and low-quality evidence.
In 2010 Simillis et al. published a meta-analysis that focused specifically on the treatment of appendiceal mass and abscess in both the adult and pediatric population. This meta-analysis could only include eight low-quality studies in the pediatric population and found that initial non-operative treatment was associated with a lower rate of overall complications (OR 0.21: 95%CI 0.11–0.38), wound infections (OR 0.22: 95%CI 0.07–0.66), and abscess formation (OR 0.11: 95%CI 0.04–0.35) compared to early appendectomy [
3]. Since then, additional studies regarding the treatment of appendiceal mass and abscess in the pediatric population have been published that might provide novel insights [
5,
6].
Therefore the aim of this systematic review and meta-analysis is to provide a complete overview of available literature regarding the treatment of the specific group of children presenting with appendiceal mass and abscess (identified according to predefined criteria) and to evaluate the effect of initial non-operative treatment (iv antibiotics with or without percutaneous drainage) (NOT) compared to early appendectomy (EA) on the rate of complications.
Methods
The protocol of this systematic review and meta-analysis was registered at PROSPERO: International prospective register of systematic reviews with identification number CRD42018083522. This systematic review and meta-analysis was reported according to the Preferred Reporting Items for Systematic reviews and Meta-analysis (PRISMA) guidelines [
7]. Ethical approval and written informed consent were not required, as this study only analyzed previously published data.
Type of studies
All studies comparing EA with initial non-operative treatment for the management of appendiceal mass or abscess in children younger than 18 years were eligible for inclusion. Randomized controlled trials, prospective cohort studies and retrospective cohort studies were included in the review, whereas case series, case reports, letters to the editor, and conference abstracts were excluded. Language was restricted to English, German, French, and Dutch. Only studies that reported on our primary outcome, complication rate associated with both treatment strategies, were eligible for inclusion.
Type of participants
Participants were children (< 18 years old) with complex appendicitis with the subtype of appendiceal mass and/or abscess. Only studies that defined their population at least with the terms ‘appendiceal mass/phlegmon’ or ‘appendiceal abscess’ were included. For further specification of these terms, definitions used in the original studies were followed.
Types of interventions
Intervention: Initial NOT strategy consisting of administration of intravenous antibiotics (with or without percutaneous drainage) with in-hospital monitoring and administration of pain medication followed or not followed by interval appendectomy. Duration and type of antibiotics were not defined.
Comparison: Operative treatment strategy, consisting of an immediate (< 48 h after presentation) laparoscopic or open appendectomy with perioperative care according to local protocol. Studies comparing delayed appendectomy (> 48 h after presentation) as primary treatment strategy with NOT were excluded.
Search methods
A comprehensive search was performed in the bibliographic databases PubMed and Embase.com in collaboration with our experienced medical librarian (RV). Databases were searched from inception up to November 7th 2019. The following terms were used (including synonyms and closely related words) as index terms or free text words: “Appendix”, “Appendectomy”, “Laparoscopy”, “Children”. A detailed search strategy is shown in Online Appendix 1. The reference lists of all included articles were cross-checked for identification of additionally relevant studies.
Study selection and data extraction
Two reviewers (PA, TS) selected eligible articles independently; these were initially screened on title and abstract according to the predefined inclusion and exclusion criteria. Following this initial selection full texts were screened. After final selection of the included articles, two independent reviewers (PA, TS) extracted data using a predefined data extraction form. Data extraction included the following variables, but this list is not exhaustive: general information (author, year, methodology, patient characteristics, definition of appendiceal mass and/or abscess, treatment strategies, follow-up), primary outcome (complication rate), and secondary outcomes (i.e., length of hospital stay, recurrent appendicitis, and readmission rates). Discrepancies in both study selection and data extraction were resolved by consensus, and in case of disagreement a third reviewer was consulted (RG). Authors were contacted by email in case of missing outcome data. Correspondence did not lead to additional data.
Outcomes and definitions
The primary outcome parameter was the overall complication rate in both treatment groups, defined as the proportion of patients experiencing at least one complication.
Complications of NOT included but were not limited to failure of NOT, i.e., patients not responding to the initial antibiotic treatment (with or without initial percutaneous drainage) and thus requiring additional interventions (e.g., additional drainage procedures, delayed appendectomy), and complications after interval appendectomy (as defined by the original authors).
Complications of operative treatment included but were not limited to extensive bowel resection and reoperations (as defined by the original authors).
Overall complications in both treatment groups included but were not limited to intra-abdominal abscess formation (IAA), superficial site infection (SSI) and ileus, as defined by the original authors.
If possible, complications were listed according to the Clavien–Dindo scale [
8]. Grade 1: Any deviation from normal postoperative course without the need for farmacological treatment or a surgical/radiological intervention, Grade 2: Requiring farmacological treatment, Grade 3: Requiring surgical/radiological intervention, Grade 4: Life-threatening complication requiring ICU-admittance, Grade 5: Death of a patient.
Secondary outcomes included initial and total length of hospital stay (days) (total length of stay included interval appendectomy), readmission rate (defined as number of discharged patients that were admitted to the hospital again with complaints related to the previously experienced appendicitis), recurrent appendicitis (defined as number of patients who experienced symptomatic recurrence of disease with histopathologically proven recurrent appendicitis after completion of the initial course of antibiotics), number and type of imaging studies (ultrasound, Computed Tomography (CT), and Magnetic Resonance Imaging (MRI)), usage of pain medication (number of doses and type of pain medication (acetaminophen, non-steroidal anti-inflammatory drugs (NSAIDs), and morphine)), unexpected findings during surgery or at histopathological examination, number of surgical and/or radiological interventions, and Quality of Life (as defined by the original authors).
Risk of bias and quality of evidence assessment
Two reviewers (PA, TA) applied the Cochrane Collaboration’s Risk of Bias Tool 2.0 for randomized controlled trials and the Risk Of Bias In Non-randomised Studies of Interventions (ROBINS-I) tool depending on the study design [
9,
10]. Specifically bias due to confounding and bias in selection of participants were of importance. Bias due to confounding was considered low in randomized controlled trials, and moderate in prospective cohort studies and retrospective cohort studies that adjusted for baseline characteristics. Retrospective cohort studies that did not adjust for baseline characteristics were assessed as serious risk of bias. For all included studies risk of bias due to selection was assessed as low, moderate or serious according to the moment that patients were diagnosed with appendiceal mass or abscess:
-
Low risk of selection bias: all patients included in the study were diagnosed with appendiceal mass or abscess (by physical examination or imaging) before the start of the intervention (i.e., non-operative treatment or early appendectomy).
-
Moderate risk of selection bias: at least 50% of patients, but not all were diagnosed before the start of the intervention. Meaning that less than 50% of patients were diagnosed with appendiceal mass or abscess during or after the intervention.
-
Serious risk of selection bias: less than 50% of patients had a diagnosis of appendiceal mass or abscess before the start of the intervention. Thus more than 50% of patients were diagnosed with appendiceal mass or abscess during or after the intervention. Both risk of bias tools were applied on the outcome level (overall complication rate) independently by the two authors. Conflicts were resolved by discussion until consensus. In case of persistent disagreement a third author (RG) was consulted.
Evidence of the studies and their original conclusions were rated according to the Oxford Centre for Evidence-Based Medicine Levels of Evidence Table [
11].
Certainty of the evidence and conclusions of this systematic review and meta-analysis was evaluated using the Grading of Recommendations Assessment, Development and Evaluation (GRADE) method. GRADEpro software was used to create a Summary of Findings table for all pooled outcome measures and sensitivity analyses of studies at moderate risk of bias. The five GRADE considerations (study limitations, consistency of effect, imprecision, indirectness, and publication bias) were used to grade the evidence and conclusions. All decisions to downgrade the quality of the evidence were justified using footnotes.
Data analysis
In case less than 50% of included studies reported on one of the outcome measures, meta-analyses were not performed. Furthermore, if statistical heterogeneity exceeded 70%, it was decided not to show the pooled effect estimate. Review Manager version 5.3.5 was used for the performance of the meta-analyses. The Mantel–Haenszel method was used to compute risk ratios and their corresponding 95% CI for dichotomous outcomes and to calculate weighted mean differences with 95% CI for continuous data. Means and variances were calculated according to the Cochrane Handbook for Systematic Reviews of Intervention [
9]. Heterogeneity was assessed with the Higgins
I2 inconsistency test. When
I2 was more than 50%, statistical heterogeneity was considered substantial. Meta-analyses were performed using a random-effects model. Publication bias was assessed with funnel plots.
Sensitivity analyses were performed to examine the treatment effects on the primary outcome (overall complications) excluding studies with serious risk of bias (i.e., perioperative selection of patients), studies published before 2000, and studies without a well described definition of appendiceal abscess or mass. For the secondary outcomes sensitivity analyses were limited to studies with low or moderate risk of bias, by excluding the studies with serious risk of bias, and to studies published after 2000. Studies were divided into those reporting on patients presenting with appendiceal mass, those focusing on appendiceal abscess, and those analyzing a combination of both. Subsequently, overall complications were analyzed for these subgroups of studies.
Additionally an analysis was performed wherein the primary outcome (overall complication rate) was divided in IAA, wound infection, and ileus.
Discussion
In daily practice, there is still no consensus regarding the optimal treatment strategy for children presenting with an appendiceal abscess or mass due to complex appendicitis. Studies regarding this topic are scarce, of low quality and the heterogeneity between studies is substantial. Therefore results of these studies and our review should be interpreted with caution. But, based on the available low-quality data, it seems that initial NOT may reduce the overall complication rate compared to EA in the overall group (thus appendiceal abscess and mass), without significantly increasing neither the total length of hospital stay nor the readmission rate, but the evidence is very uncertain. Nonetheless, the scarce and low-quality evidence emphasizes the importance of well-designed high quality studies and, for in the meantime, shared decision making.
To our knowledge, this review was the first to focus solely on the treatment of the specific subgroup of pediatric patients with appendiceal mass and abscess. Three slightly comparable meta-analyses have been published on this topic. However, one of those focused on both the adult and pediatric population and performed a subgroup analysis for children with appendiceal mass and/or abscess [
3]. The other two more recent meta-analyses focused on the treatment of complex appendicitis in the pediatric population but focused on complex appendicitis in general and therefore included both patients with mass and/or abscess but also those without (only free perforation)) [
24,
25].
All three meta-analysis have comparable results, which are in line with our review. The first mentioned meta-analysis was published in 2010 and included seven studies, of which four that were also included in our meta-analysis. They found a lower overall complication rate for initial NOT as well (OR 0.21 [95%CI 0.11–0.38]) [
3]. The two more recent studies performed a subgroup/sensitivity analysis for studies reporting on children with a mixture of appendiceal mass and/or abscess, including eight (of which two were included in our meta-analysis) and four studies (all included in our meta-analysis), respectively, and found a lower overall complication rate for initial NOT as well (OR 0.27 [95%CI 0.08–0.85] [
24] and RR 0.06 [95%CI 0.02–0.23] [
25]). Our review support these findings and contributes due to the fact that our meta-analysis displays a more accurate estimation of the overall effect size compared to the others. Our predefined inclusion criteria selected a less heterogeneous group of solely children with appendiceal mass and/or abscess and we included a total number of 14 studies, whereas previous meta-analyses only included four [
25], seven [
3], and eight studies [
24] in a subgroup analysis of a mixture of children with appendiceal mass, abscess, and both.
Furthermore our review has also integrated a subgroup analysis for the patients with an appendiceal mass and abscess individually, which has not been done in previous studies. Interestingly, in our subgroup analyses the only group with a significantly different overall complication rate between initial NOT and EA was the group with a mixture of appendiceal mass, abscess and both. Although this may have been caused by a type two error, in our review no significant difference was found in the subgroups of children with only an appendiceal mass or appendiceal abscess.
Focusing on the secondary outcomes, we are the first to describe the number of interventions, imaging studies, and doses of pain medication. Other secondary outcomes such as readmission rate were previously described and found to be higher in the EA group, which could not be confirmed by our review. Additionally, our review found a longer total length of hospital stay after NOT, although results could not be pooled due to significant heterogeneity. This longer length of stay after NOT could be explained by the second admission that was scheduled for interval appendectomy in almost all included studies, as initial length of stay did not differ between treatment groups. This systematic review and meta-analysis could only include one study that did not routinely perform an interval appendectomy. This study found a recurrence rate of 34% in a group of 38 patients during a mean follow-up period of 3.4 ± 1.7 years [
5]. However, recent studies, including a large randomized controlled trial, have shown that a wait-and-see approach is justified after non-operative treatment for appendiceal mass, as recurrence rates are low and unexpected findings (such as malignancies) are rarely found after interval appendectomy in the pediatric population [
26‐
30]. This wait-and-see approach after NOT would possibly reduce the potential benefit of a shorter total length of hospital stay after EA.
Contrary to the pediatric population, initial NOT is the standard of care for adult patients presenting with appendiceal mass and or abscess. Systematic reviews and meta-analyses have shown that EA results in a significantly higher overall complication rate, and more specifically a greater incidence of ileus/bowel obstruction, IAA, and wound infection [
3,
31]. In the pediatric population, opponents of the initial NOT strategy hypothesize that the omentum is relatively smaller and underdeveloped in young children. Therefore a contained appendiceal mass is rarely seen perioperatively, which should lead to a significantly lower postoperative complication rate in these children [
32,
33]. Thus it can be hypothesized that EA might be preferable in young children, and on the other hand older children and adolescents might benefit from NOT. Although available evidence is limited, this hypothesis could not be validated by our review as a higher overall complication rate after EA was found for young children as well [
14,
22].
Furthermore, it can be expected that differences in operation techniques (i.e., open versus laparoscopic appendectomy) can be of influence on the complication rate. Previous studies found a significantly lower complication rate after laparoscopic appendectomy (15.30%) compared to open appendectomy (29.33%) for complex appendicitis [
34]. However, due to the limited data available, the EA group could not be divided into laparoscopic and open appendectomy in our systematic review and meta-analysis.
The most important and major concern of not only this review but all studies reporting on the treatment of appendiceal mass and abscess is the lack of consensus regarding the definition of both appendiceal mass and abscess. In addition the terms ‘mass’ and ‘phlegmon’ are frequently used as substitutes in the current literature. The lack of an uniform definition leads to considerable heterogeneity between studies [
35,
36]. Therefore interpretation of results and especially comparison of different study populations is difficult. In our review we attempted to solve this problem by using predefined criteria for appendiceal mass and abscess in our selection process. However, most studies did not provide a detailed definition and only reported the terms appendiceal ‘mass’, ‘phlegmon’, and ‘abscess’. As a result we had to restrict our predefined criteria and included only studies that at least mentioned those terms to describe their study population. In our opinion, it is of utmost importance that consensus is reached regarding uniform definitions for appendiceal mass and abscess (e.g., through a Delphi study which we are currently planning) and that future studies make use of them. These uniform definitions can help to include comparable study populations in future studies, which are needed to draw proper conclusions regarding the optimal treatment strategy for children with appendiceal mass and abscess.
Apart from the mentioned lack of consensus regarding the definition of appendiceal mass, the results of this review are hampered by the heterogeneity between the included studies. Differences in methodology, in- and exclusion criteria, age, duration and type of antibiotics could all influence the outcome of the study. Several studies included both children with appendiceal mass and abscess, whereas others specified to one of both conditions. It was decided to pool data of both subgroups, because of the limited number of studies that reported specifically on one of the subgroups. Because of this limitation, subgroup analyses were performed for studies reporting on appendiceal mass, appendiceal abscess, and a combination of both.
In addition, differences in the diagnosis of appendiceal mass and abscess were found between studies. Whereas some studies only included patients that had ultrasound or CT-proven appendiceal mass and abscess, others included patients with a palpable mass or a mass that was found perioperatively. Moreover the majority of studies did not report the clinical status of patients at presentation, the size of the mass and abscess, and demographics and did not control for these confounders in their analysis. Due to their retrospective design and the aforementioned concerns, most studies were prone to significant selection bias.
Furthermore the majority of included studies were small retrospective cohort studies. Only two prospective cohort studies, and one pilot randomized controlled trial could be included in this review. All studies were assessed as having moderate to serious risk of bias. This illustrates the necessity of high quality prospective studies regarding this topic.
In conclusion, high quality evidence regarding the optimal treatment strategy for children presenting with appendiceal mass or abscess is missing and substantial heterogeneity exists between studies. Initial NOT of children with an appendiceal mass or abscess may reduce the overall complication rate compared to EA, but the evidence is very uncertain. The results of this review illustrate the necessity of a uniform definition of appendiceal mass and abscess, and subsequent large prospective studies are needed to determine the optimal treatment strategy for children presenting with an appendiceal mass or abscess.
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