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DOI: 10.1055/a-2102-1691
Endoscopic vacuum therapy for anastomotic leakage after upper gastrointestinal surgery
Abstract
Background Recently, endoscopic vacuum therapy (EVT) was introduced as treatment for anastomotic leakage after upper gastrointestinal (GI) surgery. The aim of this study was to describe the initial experience with EVT for anastomotic leakage after upper GI surgery in a tertiary referral center.
Methods Patients treated with EVT for anastomotic leakage after upper GI surgery were included retrospectively (January 2018–June 2021) and prospectively (June 2021–October 2021). The primary end point was the EVT success rate. Secondary end points included mortality and adverse events.
Results 38 patients were included (31 men; mean age 66 years): 27 had undergone an esophagectomy with gastric conduit reconstruction and 11 a total gastrectomy with esophagojejunal anastomosis. EVT was successful in 28 patients (74 %, 95 %CI 57 %–87 %). In 10 patients, EVT failed: deceased owing to radiation pneumonitis (n = 1), EVT-associated complications (n = 2), and defect closure not achieved (n = 7). Mean duration of successful EVT was 33 days, with a median of six EVT-related endoscopies. Median hospital stay was 45 days.
Conclusion This initial experience with EVT for anastomotic leakage after upper GI surgery demonstrated a success rate of 74 %. EVT is a promising therapy that could prevent further major surgery. More experience with the technique and its indications will likely improve success rates in the future.
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Introduction
Surgery provides the best chance of cure for esophagogastric cancer [1] [2] [3]. Anastomotic leakage is one of the most common complications and is associated with severe morbidity and mortality [4] [5].
EVT is a novel endoscopic treatment, based on negative pressure wound therapy, that stimulates wound healing, exudate control, and perfusion [6]. EVT is an effective therapy for anastomotic leakage after colorectal surgery [7]. Recently, EVT was introduced as a treatment modality for anastomotic leakage after upper gastrointestinal (GI) surgery. Results so far, also when compared to stents, are promising with success rates of up to 100 % [8] [9] [10]; however, the literature mostly consists of small case series.
In our center, since 2018, EVT has gradually become the treatment of choice for anastomotic leakage after upper GI surgery. The aim of this study was to describe the initial experience with EVT for anastomotic leakage after upper GI surgery in a tertiary referral center.
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Methods
Patients
All patients treated with EVT for anastomotic leakage after upper GI surgery at Amsterdam UMC between January 2018 and October 2021 were included: retrospectively (January 2018 to June 2021) and prospectively (until October 2021). Data were collected from a prospectively maintained database of patients undergoing upper GI surgery, including salvage resections; details regarding EVT were collected retrospectively. The diagnosis of anastomotic leakage was based on computed tomography (CT) scan findings, such as extraluminal oral contrast, and/or endoscopic findings, such as visualization of a transmural defect.
This study was assessed by the local medical ethics committee, who waived the need for formal ethical review.
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Surgery
Surgery was performed according to the Enhanced Recovery After Surgery protocol and Dutch guidelines for esophagogastric cancer [11]. Surgery was performed minimally invasively, unless an open procedure was warranted. Esophagectomy was preferably performed by a transthoracic approach with two-field lymph node dissection, and gastric conduit reconstruction with an intrathoracic anastomosis (Ivor Lewis). If there was a proximal tumor or radiation field, a cervical anastomosis (McKeown) was performed.
For gastric cancer, total gastrectomies with Roux-en-Y reconstruction were included. When indicated (e. g. large esophagogastric junction tumors), distal esophagectomy and total gastrectomy with Roux-en-Y reconstruction, or esophageal–cardia resection with gastric conduit reconstruction were performed via a left thoracoabdominal approach.
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EVT procedures
EVT procedures were performed with the patients under deep propofol sedation or general anesthesia. The sponge used was the EsoSponge (EsoSPONGE; Braun B. Melsungen, Germany), a polyurethane sponge of 50 mm in length and 13 mm in diameter.
During the initial endoscopy, the defect and extraluminal cavity were cleaned. The EVT technique was determined by the endoscopist, taking into consideration the defect and cavity width and the extent of the debris. Generally, patients with defects large enough for endoscope passage and big extraluminal cavities initially underwent extraluminal therapy, while patients with small defects and cavities proceeded straight to intraluminal therapy ([Fig. 1]).
Source: Esophageal Research Team Amsterdam UMC.
The appropriate sponge size was determined and, if necessary, it was trimmed based on the cavity width. Therapy was considered adequate if the cavity collapsed after application of the vacuum.
Sponge placement was performed using the EsoSponge overtube or a grasping forceps, as preferred by the endoscopist. After sponge placement, the tube of the sponge was guided from the oral cavity to the nose and fixed with a plaster onto the nose. Correct positioning was confirmed under endoscopic vision and vacuum was applied. The pressure of the pump (ActiV.A.C.; 3 M Health Care, St. Paul, Minnesota, USA) was generally −50 mmHg (intracavitary sponge) to −75 mmHg (intraluminal sponge). Intraluminal sponges were exchanged once per week, and intracavitary sponges were exchanged twice per week.
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Outcome parameters
The primary outcome parameter was successful EVT treatment, defined as closure of the defect primarily by EVT. Closure was confirmed by endoscopic inspection and/or CT imaging. Therapy was considered unsuccessful if the defect persisted or increased under EVT or if adequate vacuum therapy was not achieved.
Secondary outcome parameters included additional treatment modalities, adverse events (AEs), and combined in-hospital and 30-day mortality. AEs were defined as any event interfering with the scheduled treatment and were classified by degree of consequences [12]. Incidents were defined as unplanned events not interfering with the planned procedure. For technical complications, a sponge was deemed “dislocated” if an incorrect position was endoscopically observed; minimally visible suction effect on the epithelium was classified as “dysfunction of the vacuum system.” Furthermore, factors possibly associated with the primary outcome were assessed.
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Statistical analysis
Statistical analyses were performed using SPSS Statistics Version 28 (SPSS Inc., Chicago, Illinois, USA). Descriptive data were expressed as numbers with percentages and exact 95 %CI, with median and interquartile rage (IQR) for data with a skewed distribution, and mean (SD) for data with a symmetric distribution. Binomial univariate logistic regression was used to calculate differences between successful and unsuccessful treatment per variable. P values were two-sided and considered statistically significant when < 0.05.
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Results
Respectively, 363 and 68 patients underwent esophagectomy and total gastrectomy in the study period, of whom 56 developed anastomotic leakage (13 %, 95 %CI 10 %–17 %) (Fig. 1 s, see online-only Supplementary material). There were 38 patients treated with EVT, who were included in this study. [Table 1] details the characteristics of the included patients.
|
Total |
Esophagectomy |
Total gastrectomy |
Total gastrectomy with distal esophagectomy |
|
|
Age, mean (SD), years |
66 (9) |
65 (10) |
68 (10) |
71 (7) |
|
Sex, n (%) |
||||
|
31 (82) |
22 (81) |
5 (71) |
4 (100) |
|
7 (18) |
5 (19) |
2 (29) |
0 (0) |
|
Risk factors for development of anastomotic leakage, n (%) |
||||
|
28 (74) |
20 (74) |
5 (71) |
3 (75) |
|
4 (11) |
2 (7) |
1 (14) |
1 (25) |
|
11 (29) |
5 (19) |
4 (57) |
2 (50) |
|
15 (40) |
8 (30) |
5 (71) |
2 (50) |
|
2 (5) |
0 (0) |
2 (29) |
0 (0) |
|
3 (8) |
3 (11) |
0 (0) |
0 (0) |
|
29 (76) |
20 (74) |
5 (71) |
4 (100) |
|
Indication for surgery, n (%) |
||||
|
30 (79) |
20 (74) |
6 (86) |
4 (100) |
|
5 (13) |
5 (19) |
0 (0) |
0 (0) |
|
1 (3) |
1 (4) |
0 (0) |
0 (0) |
|
1 (3) |
1 (4) |
0 (0) |
0 (0) |
|
1 (3) |
0 (0) |
1 (14) |
0 (0) |
|
Neoadjuvant therapy, n (%) |
||||
|
26 (68) |
26 (96) |
0 (0) |
1 (25) |
|
5 (13) |
1 (4) |
4 (57) |
0 (0) |
|
7 (18) |
0 (0) |
3 (43) |
3 (75) |
|
Esophagectomy technique, n (%) |
||||
|
22 (58) |
22 (81) |
N/A |
N/A |
|
5 (13) |
5 (19) |
N/A |
N/A |
|
Surgical approach, n (%) |
||||
|
34 (89) |
26 (96) |
7 (100) |
1 (25) |
|
2 (5) |
0 (0) |
0 (0) |
2 (50) |
|
2 (5) |
1 (4) |
0 (0) |
1 (25) |
MANEC, mixed adenoneuroendocrine carcinoma; N/A, not applicable.
1 Malnutrition was defined as underweight (body mass index [BMI] < 18.5 kg/m2) and overweight (BMI > 25 kg/m2).
Primary outcome
Successful treatment was achieved in 28 /38 patients (74 %, 95 %CI 57 %–87 %). In 10 patients, EVT failed (26 %, 95 %CI 13 %–43 %), owing to AEs (n = 2), death during (but not due to) EVT (n = 1), and unachieved defect closure (n = 7). The patients with unachieved defect closure underwent additional surgery after a median of 3 (IQR 2–4) EVT-related endoscopies. More details on the patients with unsuccessful EVT are described in Table 1 s.
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Secondary outcomes
Prior to EVT, three patients underwent intraluminal stenting (n = 2) and/or resection of the ischemic part of the gastric conduit with re-anastomosis (n = 2). The reason for the use of stenting before EVT was familiarity with the stent and little experience with EVT at that time. The stents prior to EVT were in situ for 5 and 19 days. One patient underwent intraluminal stenting for 5 days in between EVT sessions, because of hesitation regarding vacuum function with a chest tube present. In all of these cases, intraluminal stenting was discontinued because of leakage around the stent.
Two severe AEs occurred because of EVT (5 %, 95 %CI 1 %–18 %): a tracheoesophageal fistula, resulting in a re-operation with repair of the bronchial defect, gastric conduit resection, and cervical esophagostomy; an iatrogenic defect expansion owing to the overtube during a sponge exchange, after which a re-operation with re-anastomosis was performed. Two incidents occurred (5 %, 95 %CI 1 %–18 %): an esophageal ulcer due to the suction catheter and a minor hemorrhage during sponge removal.
The combined mortality rate was 8 % (3 /38; 95 %CI 2 %–21 %). One patient died after 2 weeks of EVT treatment owing to radiation pneumonitis, while improvement of the defect had been observed. One patient died 19 days after completion of successful EVT owing to pulmonary embolism. Another patient died because of acute respiratory distress syndrome 2.5 months after completion of successful EVT. One or more technical complications occurred in 24 patients, including sponge rupture during removal (n = 4), dysfunction of the vacuum system (n = 6), and sponge dislocation (n = 16), of which two were dislodged by the patient pulling the suction catheter.
[Table 2] displays a comparison of the clinical factors for successful and unsuccessful treatment. In univariate analysis, no factor showed a significant association with the outcome. Among the successful EVT treatments, a median of six (IQR 3–11) EVT-related endoscopies were performed during a mean (SD) of 33 (24) days of treatment (Table 2 s).
IQR, interquartile range; CRP, C-reactive protein; WBC, white blood cell count.
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Discussion
In this study, the initial experience with EVT for anastomotic leakage after upper GI surgery in a tertiary referral center is described. EVT appeared efficient and safe in this implementation phase, with a success rate of 74 % and an AE rate of 5 %.
Although these results correspond with previous studies, with success rates of 60 % to 100 % and AE rates of 0 % to 6 %, some studies found higher success rates [8] [9] [10] [13] [14]. These studies included tailor-made EVT techniques, whereas the cohort described in this paper used only the EsoSponge; however, we believe that the relatively low success rate is due mainly to the implementation phase. During this implementation phase, we felt a learning curve was present, as reported previously by Reimer et al. [15]. The lessons learnt in this phase included the prevention of possible causes of failure, such as dislocation of the sponge.
In this cohort, a relatively high number of sponge ruptures occurred. To prevent this, we have developed a technique to safely remove the sponge without rupture. Before sponge removal, a distal attachment cap is placed on the endoscope and, subsequently, the endoscope is maneuvered between the sponge and the mucosa to carefully separate the sponge from the (esophageal) wall. After all sides of the sponge have been loosened, the sponge is easily removed, without needing to firmly pull it, and rupture is prevented.
Comparison of the EVT success and failure groups might indicate factors that contribute to therapy failure, which could help determine the best indications for EVT. In this cohort, no significant differences were found between these groups; however, because of the small sample sizes in the subgroups, it is possible that factors that actually do contribute to therapy failure were not statistically significant. For example, more esophagojejunal anastomoses, shorter time to diagnosis, higher C-reactive protein (CRP) at diagnosis, and more “intermediate” and “large” defects are striking in the failure group and could possibly be predictors for therapy failure. Book et al. [16] showed similar results. They identified 116 patients treated with EVT and found use of the intracavitary technique at first endoscopy, more complications, and higher CRP and WBC count at diagnosis significantly influenced EVT failure. Jung et al. [17] found a significant influence of neoadjuvant treatment, intraluminal technique, and increased CRP at diagnosis on therapy failure in 119 patients.
This study describes the outcomes of consecutive patients treated during the implementation phase of EVT into the routine treatment of anastomotic leakage at a tertiary referral center. The protocol was optimized during this implementation phase and some important lessons were learned. For example, the use of a grasping forceps to introduce the sponge under endoscopic visualization replaced the overtube as the preferred placement technique. In addition, intracavitary EVT was found to be of great importance for adequate treatment when a cavity was present. The intraluminal technique should be applied only when a cavity is small enough to collapse with the vacuum.
Close and efficient collaboration between the surgical and gastroenterological departments is also essential to optimize individualized management of patients with EVT. The implementation of EVT can be associated with logistic challenges. In 45 % (95 %CI 29 %–61 %) of the patients in our cohort, the first sponge placement occurred outside of the regular endoscopy program, requiring flexibility of both the endoscopy and anesthesiology teams. Moreover, the regular sponge exchanges with the patient under deep propofol sedation or general anesthesia are difficult to schedule. Therefore, having a dedicated team of trained interventional endoscopists and designated endoscopy slots is helpful in organizing optimal care for EVT patients.
This study has several strengths. Because this study describes a consecutive cohort of patients in the implementation phase of EVT, it allows us to share important lessons on EVT treatment. Furthermore, all patients were treated by a group of experienced interventional endoscopists, in close collaboration with the surgical team. Lastly, to our knowledge, this study is the first to compare the characteristics of the EVT failure and success groups in patients with anastomotic leakage only.
This study also has limitations. First, as there is no control group, no conclusions can be drawn regarding the comparison of EVT with other treatment options for anastomotic leakage. Second, owing to the mostly retrospective nature of the study, selection and information bias could have occurred.
Currently, our group is working on a white book with technical and logistic tips and tricks to facilitate EVT implementation in other centers, where implementation may be hampered by logistical challenges and difficulties in obtaining adequate training. Wider application of the technique, as well as prospective registration, will enable future studies in larger cohorts of patients. Moreover, this will enable the evaluation of new devices for EVT, such as open-pore film drainage, which provides the benefits of a longer small-lumen device and less sponge ingrowth [18], and the VACStent, which combines the sealing effect of a stent with negative pressure wound therapy at the defect site, keeping the stent in place with the vacuum and allowing for oral intake [19]. Furthermore, the pre-emptive use of EVT may help prevent anastomotic leakage after upper GI surgery [20].
In conclusion, EVT is a paradigm shifting treatment for anastomotic leakage after upper GI surgery, with a success rate of 74 % in this study during implementation of the technique. Currently many aspects of EVT are experience-based, rather than evidence-based. Future studies will provide more evidence on the best indications and techniques for EVT, which, along with more experience, will likely improve outcomes in the future.
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Conflict of interest
R.E. Pouw is a consultant for MicroTech Europe and Medtronic bv., has received speakerʼs fees from Pentax, and is on the advisory board of EsoCap AG. M.I. van Berge Henegouwen is a consultant for Mylan, Johnson & Johnson, Alesi Surgical, BBraun, and Medtronic, and has received unrestricted research grants from Stryker (all fees paid to the institution). L.M.D. Pattynama, F. Daams, S.S. Gisbertz, J.J.G.H.M. Bergman, and W.J. Eshuis declare that they have no conflict of interest.
Acknowledgments
We thank Jude Shadwell for preparing the graphics.
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References
- 1 Fabbi M, Hagens ERC, van Berge Henegouwen MI. et al. Anastomotic leakage after esophagectomy for esophageal cancer: definitions, diagnostics, and treatment. Dis Esophagus 2021; 34: doaa039
- 2 Gisbertz SS, Hagens ERC, Ruurda JP. et al. The evolution of surgical approach for esophageal cancer. Ann N Y Acad Sci 2018; 1434: 149-155
- 3 Voeten DM, Gisbertz SS, Ruurda JP. et al. Overall volume trends in esophageal cancer surgery results from the Dutch upper gastrointestinal cancer audit. Ann Surg 2021; 274: 449-458
- 4 Schmidt HM, Gisbertz SS, Moons J. et al. Defining benchmarks for transthoracic esophagectomy: a multicenter analysis of total minimally invasive esophagectomy in low risk patients. Ann Surg 2017; 266: 814-821
- 5 Biere SS, Maas KW, Cuesta MA. et al. Cervical or thoracic anastomosis after esophagectomy for cancer: a systematic review and meta-analysis. Dig Surg 2011; 28: 29-35
- 6 de Moura DTH, de Moura B, Manfredi MA. et al. Role of endoscopic vacuum therapy in the management of gastrointestinal transmural defects. World J Gastrointest Endosc 2019; 11: 329-344
- 7 Kuhn F, Schardey J, Wirth U. et al. Endoscopic vacuum therapy for the treatment of colorectal leaks - a systematic review and meta-analysis. Int J Colorectal Dis 2022; 37: 283-292
- 8 Tavares G, Tustumi F, Tristao LS. et al. Endoscopic vacuum therapy for anastomotic leak in esophagectomy and total gastrectomy: a systematic review and meta-analysis. Dis Esophagus 2021; 34: doaa132
- 9 Scognamiglio P, Reeh M, Karstens K. et al. Endoscopic vacuum therapy versus stenting for postoperative esophago-enteric anastomotic leakage: systematic review and meta-analysis. Endoscopy 2020; 52: 632-642
- 10 Chan SM, Auyeung KKY, Lam SF. et al. Current status in endoscopic management of upper gastrointestinal perforations, leaks and fistulas. Dig Endosc 2022; 34: 43-62
- 11 Ljungqvist O, Scott M, Fearon KC. Enhanced recovery after surgery: a review. JAMA Surg 2017; 152: 292-298
- 12 Cotton PB, Eisen GM, Aabakken L. et al. A lexicon for endoscopic adverse events: report of an ASGE workshop. Gastrointest Endosc 2010; 71: 446-454
- 13 Aziz M, Haghbin H, Sharma S. et al. Safety and effectiveness of endoluminal vacuum-assisted closure for esophageal defects: Systematic review and meta-analysis. Endosc Int Open 2021; 9: E1371-E1380
- 14 do Monte Junior ES, de Moura DTH, Ribeiro IB. et al. Endoscopic vacuum therapy versus endoscopic stenting for upper gastrointestinal transmural defects: Systematic review and meta-analysis. Dig Endosc 2021; 33: 892-902
- 15 Reimer S, Seyfried F, Flemming S. et al. Evolution of endoscopic vacuum therapy for upper gastrointestinal leakage over a 10-year period: a quality improvement study. Surg Endosc 2022; 36: 9169-9178
- 16 Book T, Wortmann N, Winkler M. et al. Endoscopic vacuum assisted closure (E-VAC) of upper gastrointestinal leakages. Scand J Gastroenterol 2021; 56: 1376-1379
- 17 Jung DH, Huh CW, Min YW. et al. Endoscopic vacuum therapy for the management of upper GI leaks and perforations: a multicenter retrospective study of factors associated with treatment failure (with video). Gastrointest Endosc 2022; 95: 281-290
- 18 Loske G, Schorsch T, Rucktaeschel F. et al. Open-pore film drainage (OFD): a new multipurpose tool for endoscopic negative pressure therapy (ENPT). Endosc Int Open 2018; 6: E865-E871
- 19 Lange J, Kahler G, Bernhardt J. et al. The VACStent trial: combined treatment of esophageal leaks by covered stent and endoscopic vacuum therapy. Surg Endosc 2023; 37: 3657-3668
- 20 Muller PC, Morell B, Vetter D. et al. Preemptive endoluminal vacuum therapy to reduce morbidity after minimally invasive Ivor Lewis esophagectomy: including a novel grading system for postoperative endoscopic assessment of GI-anastomoses. Ann Surg 2021; 274: 751-757
Corresponding author
Publication History
Received: 28 September 2022
Accepted after revision: 19 May 2023
Accepted Manuscript online:
30 May 2023
Article published online:
17 July 2023
© 2023. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution License, permitting unrestricted use, distribution, and reproduction so long as the original work is properly cited. (https://creativecommons.org/licenses/by/4.0/)
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References
- 1 Fabbi M, Hagens ERC, van Berge Henegouwen MI. et al. Anastomotic leakage after esophagectomy for esophageal cancer: definitions, diagnostics, and treatment. Dis Esophagus 2021; 34: doaa039
- 2 Gisbertz SS, Hagens ERC, Ruurda JP. et al. The evolution of surgical approach for esophageal cancer. Ann N Y Acad Sci 2018; 1434: 149-155
- 3 Voeten DM, Gisbertz SS, Ruurda JP. et al. Overall volume trends in esophageal cancer surgery results from the Dutch upper gastrointestinal cancer audit. Ann Surg 2021; 274: 449-458
- 4 Schmidt HM, Gisbertz SS, Moons J. et al. Defining benchmarks for transthoracic esophagectomy: a multicenter analysis of total minimally invasive esophagectomy in low risk patients. Ann Surg 2017; 266: 814-821
- 5 Biere SS, Maas KW, Cuesta MA. et al. Cervical or thoracic anastomosis after esophagectomy for cancer: a systematic review and meta-analysis. Dig Surg 2011; 28: 29-35
- 6 de Moura DTH, de Moura B, Manfredi MA. et al. Role of endoscopic vacuum therapy in the management of gastrointestinal transmural defects. World J Gastrointest Endosc 2019; 11: 329-344
- 7 Kuhn F, Schardey J, Wirth U. et al. Endoscopic vacuum therapy for the treatment of colorectal leaks - a systematic review and meta-analysis. Int J Colorectal Dis 2022; 37: 283-292
- 8 Tavares G, Tustumi F, Tristao LS. et al. Endoscopic vacuum therapy for anastomotic leak in esophagectomy and total gastrectomy: a systematic review and meta-analysis. Dis Esophagus 2021; 34: doaa132
- 9 Scognamiglio P, Reeh M, Karstens K. et al. Endoscopic vacuum therapy versus stenting for postoperative esophago-enteric anastomotic leakage: systematic review and meta-analysis. Endoscopy 2020; 52: 632-642
- 10 Chan SM, Auyeung KKY, Lam SF. et al. Current status in endoscopic management of upper gastrointestinal perforations, leaks and fistulas. Dig Endosc 2022; 34: 43-62
- 11 Ljungqvist O, Scott M, Fearon KC. Enhanced recovery after surgery: a review. JAMA Surg 2017; 152: 292-298
- 12 Cotton PB, Eisen GM, Aabakken L. et al. A lexicon for endoscopic adverse events: report of an ASGE workshop. Gastrointest Endosc 2010; 71: 446-454
- 13 Aziz M, Haghbin H, Sharma S. et al. Safety and effectiveness of endoluminal vacuum-assisted closure for esophageal defects: Systematic review and meta-analysis. Endosc Int Open 2021; 9: E1371-E1380
- 14 do Monte Junior ES, de Moura DTH, Ribeiro IB. et al. Endoscopic vacuum therapy versus endoscopic stenting for upper gastrointestinal transmural defects: Systematic review and meta-analysis. Dig Endosc 2021; 33: 892-902
- 15 Reimer S, Seyfried F, Flemming S. et al. Evolution of endoscopic vacuum therapy for upper gastrointestinal leakage over a 10-year period: a quality improvement study. Surg Endosc 2022; 36: 9169-9178
- 16 Book T, Wortmann N, Winkler M. et al. Endoscopic vacuum assisted closure (E-VAC) of upper gastrointestinal leakages. Scand J Gastroenterol 2021; 56: 1376-1379
- 17 Jung DH, Huh CW, Min YW. et al. Endoscopic vacuum therapy for the management of upper GI leaks and perforations: a multicenter retrospective study of factors associated with treatment failure (with video). Gastrointest Endosc 2022; 95: 281-290
- 18 Loske G, Schorsch T, Rucktaeschel F. et al. Open-pore film drainage (OFD): a new multipurpose tool for endoscopic negative pressure therapy (ENPT). Endosc Int Open 2018; 6: E865-E871
- 19 Lange J, Kahler G, Bernhardt J. et al. The VACStent trial: combined treatment of esophageal leaks by covered stent and endoscopic vacuum therapy. Surg Endosc 2023; 37: 3657-3668
- 20 Muller PC, Morell B, Vetter D. et al. Preemptive endoluminal vacuum therapy to reduce morbidity after minimally invasive Ivor Lewis esophagectomy: including a novel grading system for postoperative endoscopic assessment of GI-anastomoses. Ann Surg 2021; 274: 751-757
Source: Esophageal Research Team Amsterdam UMC.