Short-Term Outcomes of Colorectal Stenting Using a Low Axial Force Self-Expandable Metal Stent for Malignant Colorectal Obstruction: A Japanese Multicenter Prospective Study
by
, ,
Takashi Sasaki
1,†
,
Shuntaro Yoshida
2,†,
Hiroyuki Isayama
3,*,
Akiko Narita
4,
Tomonori Yamada
5,
Toshiyuki Enomoto
6,
Yorinobu Sumida
7,
Rika Kyo
8,
Toshio Kuwai
9,
Masafumi Tomita
10,
Rintaro Moroi
11,
Mamoru Shimada
12,
Nobuto Hirata
13 and
Yoshihisa Saida
6 1
Department of Hepato-Biliary-Pancreatic Medicine, Cancer Institute Hospital of Japanese Foundation for Cancer Research, Tokyo 135-8550, Japan
2
Department of Endoscopy and Endoscopic Surgery, Graduate School of Medicine, The University of Tokyo, Tokyo 113-8655, Japan
3
Department of Gastroenterology, Graduate School of Medicine, Juntendo University, Tokyo 113-8431, Japan
4
Department of Gastroenterology, Graduate School of Medicine, The University of Tokyo, Tokyo 113-8655, Japan
5
Department of Gastroenterology, Japanese Red Cross Aichi Medical Center Nagoya Daini Hospital, Aichi 466-8650, Japan
6
Department of Surgery, Toho University Ohashi Medical Center, Tokyo 153-8515, Japan
7
Department of Gastroenterology, National Hospital Organization, Kyushu Medical Center and Clinical Research Center, Fukuoka 810-8563, Japan
8
Department of Gastroenterology, Saiseikai Yokohamashi Nanbu Hospital, Kanagawa 234-0054, Japan
9
Department of Gastroenterology, National Hospital Organization, Kure Medical Center and Chugoku Cancer Center, Hiroshima 737-0023, Japan
10
Department of Surgery, Kobe Tokushukai Hospital, Hyogo 655-0017, Japan
11
Division of Gastroenterology, Department of Internal Medicine, Graduate School of Medicine, Tohoku University, Miyagi 980-8574, Japan
12
Department of Surgery, Toyonaka Keijinkai Hospital, Osaka 560-0004, Japan
13
Department of Gastroenterology, Kameda Medical Center, Chiba 296-8602, Japan
*
Author to whom correspondence should be addressed.
†
These authors contributed equally to this work.
J. Clin. Med. 2021, 10(21), 4936; https://doi.org/10.3390/jcm10214936
Submission received: 14 October 2021
/
Accepted: 15 October 2021
/
Published: 26 October 2021
(This article belongs to the Section Gastroenterology & Hepatopancreatobiliary Medicine)
Abstract
:(1) Background: Endoscopic colorectal stenting with high technical success and safety is essential in discussing the oncological outcomes for the management of malignant colorectal obstruction. Mechanical properties of self-expandable metal stents are usually considered to affect clinical outcomes. (2) Methods: A multicenter, prospective study was conducted in Japan. A self-expandable metal stent with low axial force was inserted endoscopically. The primary endpoint was clinical success, defined as the resolution of symptoms and radiological findings within 24 h. Secondary endpoints were technical success and adverse events. Short-term outcomes of 7 days were evaluated in this study. (3) Results: Two hundred and five consecutive patients were enrolled. Three patients were excluded, and the remaining 202 patients were evaluated. The technical and clinical success rates were 97.5% and 96.0%, respectively. Major stent-related adverse events included stent migration (1.0%), insufficient stent expansion (0.5%), and stent occlusion (0.5%). No colonic perforation was observed. There were two fatal cases (1%) which were not related to stent placement. (4) Conclusions: The placement of self-expandable metal stents with low axial force is safe with no perforation and showed high technical and clinical success rates in short-term outcomes for the management of malignant colorectal obstruction.
1. Introduction
Acute colorectal obstruction causes nausea, vomiting, abdominal pain, and bowel dilation. Urgent decompressive procedures are required in this situation because it can result in bacterial translocation, electrolyte and fluid imbalance, colonic necrosis, and perforation. Malignancy is the most common cause of colorectal obstruction, and there are two causes of malignant colorectal obstructions: colorectal cancer and extra-colonic malignancies such as gastric, pancreaticobiliary, and gynecologic malignancies. The colorectal obstruction caused by advanced colorectal cancer occurs in 8–13% of cases, accounting for approximately 25% of all intestinal occlusions [1]. The most frequent cause of colorectal neoplastic obstruction is related to tumors of the sigmoid/rectal joint, splenic flexure (70%), middle rectum (10%), and anal canal (5%) [2].
Endoscopic colorectal stenting using self-expandable metal stents (SEMSs) has become widely performed for the relief of these symptoms [3]. Colorectal stent placement is widely accepted for both palliation (PAL) and as a bridge to surgery (BTS). SEMS placement as a BTS can avoid stoma creation and render oral intake possible before surgery. Colorectal stenting for PAL also maintains the patient’s quality of life. Colorectal stent placement is also performed for the obstruction caused by colorectal cancer and extra-colonic malignancies. The European Society of Gastrointestinal Endoscopy (ESGE) guidelines suggest considering colorectal stent placement as an alternative to palliative surgical decompression for extra-colonic malignancy obstruction despite the technical and clinical success rates being lower than those reported for colorectal cancer obstruction [1,2]. There are also various types of SEMSs, but it is not yet concluded which one is the best. The studies carried out so far have not shown a significant advantage for the fully covered SEMSs as compared to the uncovered SEMSs. No difference was observed in the clinical success rate between the two types of SEMSs (96% vs. 92%) and the fully covered SEMSs showed a higher migration rate (21% vs. 2%) and a trend of a lower tumor infiltration rate (4% vs. 15%) than the uncovered SEMSs [2].
Safe and successful stent placement is essential to achieve these benefits. Colonic perforation is one of the most serious complications of colorectal stent placement. Colonic perforation affects both the short-term and long-term prognosis [4]. One of the causes of perforation after SEMS placement is consistent contact between the imbedded SEMS and the colorectal mucosa. Mechanical properties of SEMSs are considered to affect the clinical outcomes of stent placement in biliary and esophageal stenting [5,6]. Axial force is the force generated when a bent SEMS is straightened. High axial force is considered a risk factor for perforation in the gastrointestinal tract [7], and thus a SEMS with a lower axial force would be expected to reduce the perforation rate.
A Niti-S Enteral Colonic Uncovered Stent, D-type (Taewoong Medical, Inc., Gimpo, Korea) is an uncovered SEMS composed of a nickel-titanium alloy (nitinol). This SEMS is a hook and cross type stent, which results in low axial force [8]. We conducted a prospective, multicenter study of colorectal stent placement using this SEMS with low axial force. In this evaluation, we focused on the short-term (7-day follow-up) safety and efficacy of this SEMS for the management of malignant colorectal obstruction.
2. Materials and Methods
2.1. Study Design
This prospective, observational, single-arm, multicenter study was conducted by the Japan Colonic Stent Safe Procedure Research Group, which received support from the Japan Gastroenterological Endoscopy Society. Before starting this prospective study, this group had developed technical guidelines for safe colonic stenting (http://colon-stent.com/, accessed on 1 August 2021) and tried to share tips with the group members for stent placement and points to avoid complications. This study was conducted at 33 institutions (8 academic centers, 25 community hospitals) of these group members. The study was approved by the institutional review board at each institution. Written informed consent to undergo the procedure and participate in this study was obtained from each patient before the procedure. This study was registered in the University Hospital Medical Information Network Clinical Trial Registry (UMIN 000011304).
2.2. Inclusion and Exclusion Criteria
Patients with no history of previous colorectal stenting who required treatment of malignant colorectal obstructions were enrolled in this study. A computed tomography was performed before stent placement. Malignancy of intrinsic origin was confirmed via endoscopic biopsy or macroscopic tumor findings. In cases of extrinsic tumor origin, malignancy was confirmed by computed tomography or other imaging modalities. Both indications of a BTS and PAL were included in this study. Exclusion criteria at the time of stent placement were as follows: (i) suspicion of enteral ischemia, (ii) suspected or impending perforation, (iii) the presence of intra-abdominal abscess/perforation, and (iv) any contraindication to endoscopic treatment.
2.3. Endoscopic Procedure
All patients received the same uncovered SEMS (Niti-S Enteral Colonic Uncovered Stent, D-type). The stent was 18 or 22 mm in diameter and 60, 80, 100, or 120 mm in length. The outer diameter of the delivery system was 10 Fr for the 22 mm diameter SEMS and 9 Fr for the 18 mm diameter SEMS. The overall length of the delivery system was 250 cm. Stent placement was performed under fluoroscopic and endoscopic guidance, in accordance with the standard procedure. A biopsy prior to stent placement was allowed. Biopsies were performed after traversing the stricture by the guidewire, because bleeding from the stricture made it difficult to identify the orifice of the stricture. To identify the stricture precisely, intraluminal or extraluminal marking using an endoscopic clip, a lipiodol, or a radiopaque marker was used at the endoscopist’s discretion. Stricture dilation before stent placement was not allowed. Although the use of CO2 insufflation was recommended, it was not mandatory.
2.4. Data Collection and Statistical Analysis
All clinical data were collected prospectively using an electronic data capture system. The data were self-reported by each investigator and the data center confirmed that there were no discrepancies. At enrolment, the treatment intent (BTS or PAL) was determined based on the stage of the malignancy, comorbidities, and, in some cases, patient choice. The extent of obstruction was classified into two groups: complete and incomplete obstruction. Complete colonic obstruction was confirmed by either of the following events: inability to pass flatus, inability of water-soluble contrast to pass proximal to the lesion, and inability to visualize the proximal lumen endoscopically [9]. The remaining cases were defined as incomplete obstruction. The ColoRectal Obstruction Scoring System (CROSS) was used to assess oral intake level and abdominal symptoms before and after the procedure: CROSS 0, requiring continuous decompression; CROSS 1, no oral intake; CROSS 2, liquid or enteral nutrient intake; CROSS 3, soft solids, low-residue, and full diet with symptoms of stricture; and CROSS 4, soft solids, low-residue, and full diet without symptoms of stricture [3].
The primary endpoint was clinical success, defined as the resolution of symptoms and radiological findings within 24 h. The secondary endpoint was technical success, defined as stent deployment across the entire length of the stricture on the first attempt. All adverse events during the study period were collected and the following conditions were considered stent-related adverse events: perforation, stent migration, insufficient stent expansion, stent occlusion, infection/fever, and abdominal pain.
Continuous variables were expressed as means and standard deviations (SD). Continuous and nominal variables were compared using the Kruskal–Wallis or χ2 test as appropriate. In this evaluation, the follow-up period was 7 days to evaluate the short-term outcomes of efficacy and safety. All analyses were performed using the JMP software (ver. 12.2.0; SAS Institute, Chicago, IL, USA).
3. Results
3.1. Baseline Characteristics
A flowchart of the patient registry is shown in Figure 1. The patients were enrolled from October 2013 to May 2014. Two hundred and five patients were enrolled in total. Three patients were then excluded because of loose stenosis identified on colonoscopy (n = 2) and fistula (n = 1). The per-protocol analysis (PPA) cohort comprised the remaining 202 patients. Treatment intent was a BTS in 115 (56.9%) patients and PAL in 87 (43.1%) patients. No patient dropped out during the 7-day follow-up period.
The patient characteristics of the PPA cohort at baseline are presented in Table 1. The mean (SD) age was 71.1 (13.9) years, and 104 (51.5%) of the patients were male. Obstructive symptoms were recorded in 193 (95.5%) patients. Regarding the CROSS classification, 69 (34.2%) patients were CROSS 0, 53 (26.2%) were CROSS 1, and 36 (17.8%) were CROSS 2. Seven (3.5%) patients with CROSS 4 had SEMSs inserted at the discretion of each doctor. Colorectal obstruction was caused by primary colorectal cancer in 173 (85.6%) patients, locally recurrent colorectal cancer in 2 (1.0%) patients, benign ulcer in 1 (0.5%) patient, and other malignant diseases in 26 (12.9%) patients. In total, 113 (55.9%) patients had localized cancer, while 88 (43.6%) patients had primary cancer with distant metastases (liver 21.8%, lung 10.9%) or peritoneal carcinomatosis (20.8%).
Tumor characteristics of the PPA cohort are presented in Table 2. Complete obstruction was present in 177 patients (87.6%). Tumor origin of extrinsic malignancy was involved in 28 (13.9%) patients. The causes of extrinsic obstruction were gastric cancers (n = 15), pancreatic cancers (n = 4), recurrent colorectal cancers (n = 2), bile duct cancers (n = 2), gynecological cancers (n = 2), and other cancers (n = 3). In total, 198 (98.0%) patients had one stricture, and 4 (2.0%) patients had two strictures. In total, 206 strictures were identified. The most common site of obstruction was the sigmoid colon (including the sigmoid-descending junction, 32.5%). The proportion of left-sided (from splenic flexure to rectum) and right-sided (from cecum to transverse colon) colorectal obstructions were 71.4% (BTS; n = 81, PAL; n = 66) and 28.6% (BTS; n = 34, PAL; n = 25), respectively.
Digestive tract decompression was performed before stent placement in 33 (16.3%) patients using a nasogastric (2.0%), nasointestinal (8.9%), or transanal (5.4%) tube. Cleansing enemas and oral bowel cleansing were performed before the procedure in 92 (45.5%) patients and 18 (8.9%) patients, respectively.
3.2. Clinical Outcomes of Stent Placement
Stent placement was technically successful in 197 (97.5%) patients (Table 3). As previously noted, balloon dilation of the colonic stricture was not performed before stent placement. An intraluminal stricture marker was used in 106 (52.5%) patients and an extraluminal marker was used in 22 (10.9%) patients. The mean (SD) procedure time was 36.5 (21.6) min in the technical success cohort. The mean (SD) stricture length measured during the procedure was 4.8 (2.6) cm. Eight (4.0%) patients required two SEMSs and 3 (1.5%) patients required three SEMSs. The most commonly used SEMSs were 8 cm in length (34.2%) and 22 mm in diameter (92.6%).
Technical failure was observed in five patients: inability to approach the stricture endoscopically (n = 1), deterioration of respiratory status before stent placement (n = 1), inability to release the stent (n = 1), inadequate stent placement (n = 1), and stent migration (n = 1). One patient with pancreatic cancer failed to pass the sigmoid colon by colonoscopy due to peritoneal carcinomatosis and to reach the stricture of the transverse colon. In the case that failed to release the Niti-S D type stent (22 mm in diameter, 10 cm in length) at a rectosigmoid stricture, a WallFlex colonic stent (22 mm in diameter, 9 cm in length) was placed instead. Inadequate stent placement occurred in one patient due to the underestimation of the stricture length.
Clinical success was achieved in 194 (96.0%) patients. Excluding the five technical failure cases, three patients did not obtain clinical success due to insufficient stent expansion (n = 1), stent migration (n = 1), and acute respiratory failure (n = 1). In the patient (86-year-old female) with acute respiratory failure, the general condition changed immediately after stent placement. Unfortunately, the patient died in spite of a successful stent placement; there was no finding of perforation or other complication related to the stent placement. There were no site-specific features of both technical and clinical failure in our population.
Adverse events were estimated in all the enrolled patients. There were no cases of perforation by colonoscopy insertion and the manipulation of the guidewire or catheter in this series of cases. However, there was one fatal case which discontinued the procedure due to the deterioration of the respiratory condition before stent placement. Among the PPA cohort (n = 202), 12 (5.9%) adverse events were observed in 11 patients (5.4%), including gastrointestinal obstruction at a proximal site in 3 (1.5%), stent migration in 2 (1.0%), and abdominal pain in 2 (1.0%). Insufficient stent expansion, stent occlusion due to fecal impaction, sepsis due to obstructive colitis, acute respiratory failure, and pneumonia were observed in one (0.5%) patient each. Although an additional SEMS was added in two cases of stent migration, the symptoms did not resolve in one case with insufficient stent expansion. A transanal tube insertion was performed in this case before surgery. Stent occlusion due to fecal impaction was managed endoscopically without further intervention. The causes of gastrointestinal obstruction at a proximal site were gastric outlet obstruction due to gastric cancer (n = 1) on day 5 after stenting, small intestinal obstruction due to colorectal cancer (n = 1) on day 6 after stenting, and obstruction of the transverse colon due to another colorectal cancer (n = 1) on day 5 after stenting. Gastric outlet obstruction was treated with additional gastroduodenal stent placement; the others were managed surgically. The patient (89-year-old female) with insufficient stent expansion suffered from sepsis due to obstructive colitis; emergency surgery was subsequently performed for stoma formation. Although there was no finding of perforation during surgery, she died of septic shock.
4. Discussion
The present study showed that colorectal stenting for malignant colorectal obstruction using a SEMS with low axial force (Niti-S Enteral Colonic Uncovered Stent, D-type) was highly effective and safe in short-term evaluation. The rates of technical success (97.5%) and clinical success (96.0%) were slightly better than those of other reports on colorectal stenting in prospective multicenter studies with technical success rates of 93–94.8% and clinical success rates of 90.5–95% [10,11]. These data were also comparable with those of our previous multicenter study using a WallFlex colonic stent with a technical success of 97.9% and a clinical success of 95.5% [12]. However, care must be taken in their interpretation since the patient backgrounds, the status of the colorectal obstruction, and the follow-up periods were different in each study. Adverse events were observed in 11 (5.4%) patients, including stent migration, insufficient stent expansion, and stent occlusion due to fecal impaction. No perforation was caused by the procedure or stent itself within 7 days after stent placement. Although two fatal cases were included in this study, they were not directly related to the stent placement. It can be explained by the fact that acute colorectal obstruction sometimes occurs in patients with extremely severe general condition. Since both patients were super elderly (86 and 89 years old), great care should be taken especially in the treatment of the super-elderly patients.
Safe and highly successful stent placement is a prerequisite for discussing the long-term outcomes of colorectal stenting. In order to obtain a high success rate, it is important to improve the skills and understand the difficult situation of colorectal stenting. Colorectal stent placement is a procedure usually performed by many types of doctors including surgeons and endoscopists who are specialized in colonoscopy or endoscopic retrograde cholangiopancreatology (ERCP). There was a report that the complications of colorectal stenting are lower when treated by a doctor who is proficient in ERCP [9]. On the contrary, it was reported that colorectal stent placement could be safely and effectively performed with short procedure time in patients with malignant colorectal obstruction after performing more than 30 procedures of endoscopic colorectal stenting [13]. We established a study group including colorectal surgeons and endoscopists who are specialized in colonoscopy and ERCP. We held a workshop to discuss and share tips on colorectal stenting and launched a website (http://colon-stent.com/, accessed on 1 August 2021) describing the standard methods of stent placement to generalize the procedure among the members. As a result, two prospective studies conducted with our study group demonstrated high technical success rates (97.5–97.9%) and clinical success rates (95.5–96.0%). It is also important to understand factors associated with technical difficulty: previous reports extracted them as complete obstruction (CROSS 0), an extra-colonic origin of the tumor, the presence of carcinomatosis, tumor site in the right colon, long stricture, and the necessity of multiple stent placements [14,15]. In such cases, it is better to perform the procedure with more experienced doctors of colorectal stenting.
Mechanical properties of SEMSs are another aspect which might affect the clinical outcomes of stent placement [16]. We previously evaluated the mechanical properties of several colorectal SEMSs [8]. The structure of the Niti-S D type is a hook and cross type, while that of a WallFlex colonic stent is a cross type. In this in vitro evaluation, the Niti-S D type stent was assigned to a group with low axial force and moderate radial force. On the other hand, the WalFlex colonic stent was assigned to a group of strong axial force and moderate radial force. We also defined a new parameter, “axial force zero border”, as the angle at which the axial force applied to the intestinal wall almost becomes zero [8]. The axial force of a SEMS gets higher when the angle of the bent SEMS is greater. As the angle of the bent SEMS gets smaller, the axial force gets lower, and it almost becomes zero at the “axial force zero border”. Therefore, when the angle of the bent SEMS is greater than the axial force zero border of the SEMS, the pressure load on the intestinal wall is sustained, which might result in perforation due to the injury of the intestinal wall. The Niti-S D type was evaluated as showing one of the largest angles of axial force zero border, which means that this SEMS places a low sustained load on the intestinal wall even when the angle of the bent SEMS is large. On the other hand, the WallFlex colonic stent was evaluated as having one of the smallest angles of axial force zero border, which means that this SEMS places a high sustained load on the intestinal wall when the angle of the bent SEMS is large. Previous prospective studies using the WallFlex colonic stent reported that the perforation rate was 2.1–3.9%, including the results of our group study (2.1%) [10,11,12]. The accumulated perforation rate of these three studies was 2.7% in total (Table 4). The present study of the Niti-S D type stent including 202 patients revealed that perforation did not occur during the short follow-up period. One meta-analysis categorized the WallFlex, ComVi stent, and Niti-S D type stent as SEMSs with higher perforation rates (>10%) compared to those of the Hanarostent and a Niti-S covered stent [17]. They concluded that the perforation rate of colorectal stenting was 7.4%, and stent design, benign etiology, and bevacizumab were identified as risk factors for perforation. We reviewed other recent publications describing colorectal stenting using the Niti-S D type stent (Table 4) [18,19,20,21,22,23,24,25,26,27,28,29]. The perforation rate of the accumulated population including the present study was 1.9%, which was slightly lower than that of the WallFlex colonic stent. There were also high differences in perforation rate observed between studies and most of the studies except the present study included a small number of patients. Moreover, some studies included procedure-related perforations [23,24,25,26]. It is necessary to distinguish between procedure-related and stent-related complications, especially when discussing the influence of the mechanical properties of SEMSs. Further evaluations of the relationship between the mechanical properties of SEMSs and clinical outcomes are needed in detail along with the accumulation of clinical data in the future.
The structure of the SEMS can also affect the technical success rate of the procedure. Since the Niti-S D type is a hook and cross type, it has a higher release resistance from the delivery system than the WallFlex colonic stent with a cross structure. Therefore, in limited cases, it may occur that the Niti-S D type cannot be deployed from the delivery system when the flexion is tight. In fact, there was one case in this study in which the Niti-S D type could not be deployed and the WallFlex colonic stent was used instead.
In the 2014 ESGE guidelines, SEMS placement is recommended as a preferred treatment for PAL cases, but it is not recommended for BTS cases as a standard treatment of symptomatic left-sided malignant colorectal obstruction [1]. Based on the accumulation of evidence, an updated version of the ESGE guidelines was published in 2020 [2]. It recommends stenting as a BTS to be discussed, within a shared decision-making process, as a treatment option in patients with potentially curable left-sided obstructing colon cancer as an alternative to emergency resection. The ESGE also suggests consideration of colorectal stenting for malignant obstruction of the proximal colon either as a BTS or PAL setting. However, long-term outcomes of colorectal stenting for malignant colorectal obstruction are still a big clinical issue. The cumulative incidence of overall recurrence in patients with perforation was significantly higher than that in patients undergoing emergency surgery or stenting without perforation [30]. The median time of stent-related perforation after stent placement is reported as 3 (range, 0–960) days in a meta-analysis [17]. Although it is also necessary to take care for delayed perforation affected by the treatment (e.g., chemotherapy and radiotherapy) after stent placement, the safe and highly successful stent placement is still considered to be the most important point.
This study includes several limitations. First, the present study was a single-arm observational study and no comparison was performed with other SEMSs such as high axial force SEMSs. However, this study prospectively evaluated a large number of patients (202 patients) compared with previous reports. Second, this study was conducted by highly experienced members who are familiar with colorectal stenting, which might affect the high technical and clinical success rate. Third, the clinical success was defined as the resolution of symptoms and radiological findings within 24 h. This judgement was performed by each investigator and patients’ symptoms were not evaluated using a questionnaire. Although it was limited, there were cases of CROSS 4 included in this study. It might be inaccurate to judge the clinical success in these patients. Finally, only short-term outcomes of colorectal stenting using a SEMS with low axial force were evaluated in this study. Since good short-term outcomes are a major premise for discussing the long-term outcomes of colorectal stenting, we have summarized the short-term outcomes in this study. The evaluation of long-term outcomes for this population is now ongoing.
In conclusion, this prospective multicenter study revealed that endoscopic colorectal stenting using a SEMS with low axial force for the management of malignant colorectal obstruction showed high short-term efficacy and safety with a low perforation rate.
Author Contributions
Conception and design of the study, analysis and interpretation of the data, and drafting of the article, T.S., S.Y., H.I., A.N. and Y.S. (Yoshihisa Saida); conception and design of the study, data collection, and critical revision, T.Y., T.E., Y.S. (Yorinobu Sumida), R.K., T.K., M.T., R.M., M.S. and N.H. All authors have read and agreed to the published version of the manuscript.
Funding
This study was conducted with Japan Gastroenterological Endoscopy Society funding support, the Japanese Foundation for Research and Promotion of Endoscopy Grant, and the Colonic Stent Safe Procedure Research Group membership dues.
Institutional Review Board Statement
The study was conducted according to the guideline of the Declaration of Helsinki and was approved by the Ethics Committee in each institution. The protocol code was Ohashi 13-43 and the date of approval was 19 August 2013 in the Toho University Ohashi Medical Center.
Informed Consent Statement
Informed consent was obtained from all patients involved in this study.
Data Availability Statement
Data sharing is not applicable.
Acknowledgments
The authors acknowledge Miyuki Tsuchida (Department of Gastroenterology, The University of Tokyo) for her role as a clinical study coordinator and data manager and Masafumi Yanagisawa for his assistance in website management.
Conflicts of Interest
T.S. received personal fees from Boston Scientific Japan, Co., Ltd., Century Medical, Inc., Cook Medical Japan, Kawasumi Laboratories, Inc., and Create Medic, Co., Ltd. S.Y. received personal fees from Boston Scientific Japan, Co., Ltd., Century Medical, Inc., Cook Medical Japan, and Olympus Medical Systems Co., Ltd. H.I. received personal fees from Boston Scientific Japan, Co., Ltd., Century Medical, Inc., TAEWOONG, Co., Ltd., FUJIFILM Healthcare, Co, Ltd., JAPAN LIFELINE, Co., Ltd., ZEON MEDICAL, Inc., Create Medic, Co., Ltd., Olympus, Co., Ltd., and Olympus Medical Science Sales Co., Ltd.; received research grants from Boston Scientific Japan, Co., Ltd., Century Medical, Inc., FUJIFILM Healthcare, Co., Ltd., and ZEON MEDICAL, Inc.; and received a guidance fee of technique from Kawasumi Laboratories, Inc. T.K. received personal fees from Boston Scientific Japan, Co., Ltd., Century Medical, Inc., and Japan Lifeline, Co., Ltd. Y.S. (Yoshihisa Saida) received personal fees from Boston Scientific Japan, Co., Ltd. and Century Medical, Inc.; received grants from Boston Scientific Japan, Co., Ltd., Century Medical, Inc., Japan Lifeline, Co., Ltd., Kawasumi Laboratories, Inc., Create Medic, Co., Ltd., Zeon Medical, Co., Ltd., Olympus Medical Systems, Co., Ltd., and FUJIFILM Healthcare, Co., Ltd.; and received consulting fees from Japan Lifeline, Co., Ltd., Olympus Medical Systems, Co., Ltd., and JIMPO, Co., Ltd. The other authors declare no conflicts of interest.
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Figure 1.
A patient flow chart of enrolled patients.
Table 1.
Baseline patient characteristics in the per-protocol analysis of enrolled patients (n = 202).
Table 1.
Baseline patient characteristics in the per-protocol analysis of enrolled patients (n = 202).
| Age, Years, Mean (SD) | 71.1 (13.9) |
| Sex, % (n) | |
| Male | 51.5 (104) |
| Female | 48.5 (98) |
| ECOG PS, % (n) | |
| 0 | 35.6 (72) |
| 1 | 30.7 (62) |
| 2 | 16.8 (34) |
| 3 | 13.9 (28) |
| 4 | 3.0 (6) |
| ASA-PS classification, % (n) | |
| 1 | 44.6 (90) |
| 2 | 39.1 (79) |
| 3 | 14.9 (30) |
| 4 | 1.5 (3) |
| Any symptoms of obstruction, % (n) | 95.5 (193) |
| Deterioration of bowel habit | 91.6 (185) |
| Bloating | 80.7 (163) |
| Abdominal pain/cramp | 75.7 (153) |
| Nausea or vomiting | 46.0 (93) |
| CROSS before stent placement, % (n) | |
| 0 | 34.2 (69) |
| 1 | 26.2 (53) |
| 2 | 17.8 (36) |
| 3 | 18.3 (37) |
| 4 | 3.5 (7) |
| Etiology of colorectal obstruction, % (n) | |
| Primary colorectal cancer | 85.6 (173) |
| Locally recurrent colorectal cancer | 1.0 (2) |
| Other extrinsic origin | 12.9 (26) |
| Benign ulcer | 0.5 (1) |
| Underlying disease, % (n) | |
| Only local cancer | 55.9 (113) |
| Cancer with distant metastases | 43.6 (88) |
| Liver metastasis | 21.8 (44) |
| Lung metastasis | 10.9 (22) |
| Peritoneal carcinomatosis | 20.8 (42) |
| Other metastases | 18.3 (37) |
| Benign lesion, % (n) | 0.5 (1) |
| Treatment history, % (n) | |
| Chemotherapy | 13.9 (28) |
| Radiotherapy | 1.0 (2) |
| Stricture balloon dilation | 0 (0) |
ECOG, Eastern Cooperative Oncology Group; PS, performance status; ASA-PS, American Society of Anesthesiologists Physical Status; CROSS, ColoRectal Obstruction Scoring System.
Table 2.
Tumor characteristics in the per-protocol analysis of enrolled patients (n = 202).
| Complete Obstruction, % (n) | 87.6 (177) |
| Tumor origin, % (n) | |
| Intrinsic malignancy | 85.6 (173) |
| Extrinsic malignancy | 13.9 (28) |
| Benign stricture | 0.5 (1) |
| Single stricture, % (n) | 98.0 (198) |
| Stenosis/tumor localization, * % (n) | |
| Rectum | 7.3 (15/206) |
| Rectosigmoid junction | 12.6 (26/206) |
| Sigmoid colon | 22.8 (47/206) |
| Sigmoid–descending junction | 9.7 (20/206) |
| Descending colon | 12.1 (25/206) |
| Splenic flexure | 6.8 (14/206) |
| Transverse colon | 12.1 (25/206) |
| Hepatic flexure | 5.3 (11/206) |
| Ascending colon | 7.3 (15/206) |
| Cecum | 3.9 (8/206) |
| Ileocecal junction | 0 (0/206) |
* Total number of the stricture: 206 in total because two different strictures were identified in four cases.
Table 3.
Clinical outcomes of stent placement.
| Technical success, % (n) | 97.5 (197/202) |
| Technical failure, % (n) | |
| Inability to approach the stricture endoscopically | 0.5 (1/202) |
| Deterioration of respiratory status before stent placement | 0.5 (1/202) |
| Inability to release the stent | 0.5 (1/202) |
| Inadequate stent placement | 0.5 (1/202) |
| Stent migration | 0.5 (1/202) |
| Clinical success, % (n) | 96.0 (194/202) |
| Clinical failure, % (n) | |
| Patients with technical failure | 2.5 (5/202) |
| Insufficient stent expansion | 0.5 (1/202) |
| Stent migration | 0.5 (1/202) |
| Acute respiratory failure | 0.5 (1/202) |
| Procedure time in the technical success cohort, min., mean (SD) | 36.5 (21.6) |
| Stricture length, cm, mean (SD) | 4.8 (2.6) |
| Strictures and stents placed, % (n) | |
| Double stricture with no stent (technical failure) | 0.5 (1/202) |
| Single stricture with 1 stent | 93.6 (189/202) |
| Single stricture with 2 stents | 3.0 (6/202) |
| Single stricture with 3 stents | 1.0 (2/202) |
| Double stricture with 2 stents | 1.0 (2/202) |
| Double stricture with 3 stents | 0.5 (1/202) |
| Stent type, % (n) | |
| Niti-S Enteral Colonic Uncovered Stent, D type | 99.5 (213/214) |
| 18 mm in diameter | 6.1 (13/214) |
| 22 mm in diameter | 93.4 (200/214) |
| 6 cm in length | 20.1 (43/214) |
| 8 cm in length | 34.6 (74/214) |
| 10 cm in length | 28.0 (60/214) |
| 12 cm in length | 16.8 (36/214) |
| WallFlex colonic stent | 0.5 (1/214) |
| 22 mm in diameter | 0.5 (1/214) |
| 9 cm in length | 0.5 (1/214) |
Table 4.
Previous studies for colorectal stenting using Niti-S D type and WallFlex colonic stents.
| Study | Year | Country | Design | Patients | Perforation | Perforation Rate |
|---|---|---|---|---|---|---|
| Niti-S D type | ||||||
| Lee, K.M. [18] | 2007 | Korea | Prospective | 59 | 0 | 0% |
| Shin, S.J. [19] | 2008 | Korea | Retrospective | 38 | 0 | 0% |
| Pommergaard, H.C. [20] | 2009 | Denmark | Retrospective | 3 | 1 | 33.3% |
| Reza, F. [21] | 2009 | Iran | Prospective | 8 | 0 | 0% |
| Kim, J.S. [22] | 2009 | Korea | Retrospective | 18 | 0 | 0% |
| Moon, C.M. [23] | 2010 | Korea | Prospective | 37 | 1 | 2.7% |
| Jung, M.K. [24] | 2010 | Korea | Retrospective | 17 | 2 | 11.8% |
| Lee, H.J. [25] | 2011 | Korea | Retrospective | 17 | 3 * | 17.6% |
| Park, J.K. [26] | 2011 | Korea | Retrospective | 20 | 0 | 0% |
| Iverson, L.H. [27] | 2011 | Denmark | Retrospective | 4 | 2 | 50.0% |
| Tominaga, K. [28] | 2012 | Japan | Prospective | 24 | 0 | 0% |
| Yoshida, S. [29] | 2013 | Japan | Prospective | 33 | 0 | 0% |
| Present study | 2021 | Japan | Prospective | 202 | 0 | 0% |
| Total | 480 | 9 | 1.9% | |||
| WallFlex colonic stent | ||||||
| Repici, A. [10] | 2008 | Italy | Prospective | 42 | 1 | 2.4% |
| Meisner, S. [11] | 2011 | Global | Prospective | 447 | 15 | 3.4% |
| Matsuzawa, T. [12] | 2015 | Japan | Prospective | 513 | 11 | 2.1% |
| Total | 1002 | 27 | 2.7% |
* Because there is no description about the cases with perforation in the article, we calculated the number from the systematic review [17].
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Sasaki, T.; Yoshida, S.; Isayama, H.; Narita, A.; Yamada, T.; Enomoto, T.; Sumida, Y.; Kyo, R.; Kuwai, T.; Tomita, M.; et al. Short-Term Outcomes of Colorectal Stenting Using a Low Axial Force Self-Expandable Metal Stent for Malignant Colorectal Obstruction: A Japanese Multicenter Prospective Study. J. Clin. Med. 2021, 10, 4936. https://doi.org/10.3390/jcm10214936
AMA Style
Sasaki T, Yoshida S, Isayama H, Narita A, Yamada T, Enomoto T, Sumida Y, Kyo R, Kuwai T, Tomita M, et al. Short-Term Outcomes of Colorectal Stenting Using a Low Axial Force Self-Expandable Metal Stent for Malignant Colorectal Obstruction: A Japanese Multicenter Prospective Study. Journal of Clinical Medicine. 2021; 10(21):4936. https://doi.org/10.3390/jcm10214936
Chicago/Turabian StyleSasaki, Takashi, Shuntaro Yoshida, Hiroyuki Isayama, Akiko Narita, Tomonori Yamada, Toshiyuki Enomoto, Yorinobu Sumida, Rika Kyo, Toshio Kuwai, Masafumi Tomita, and et al. 2021. "Short-Term Outcomes of Colorectal Stenting Using a Low Axial Force Self-Expandable Metal Stent for Malignant Colorectal Obstruction: A Japanese Multicenter Prospective Study" Journal of Clinical Medicine 10, no. 21: 4936. https://doi.org/10.3390/jcm10214936
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