Endoscopic Removal of a Proximally Migrated Metal Stent during Balloon Sweeping after Stent Trimming

Article information

Clin Endosc. 2013;46(4):418-422
Publication date (electronic) : 2013 July 31
doi : https://doi.org/10.5946/ce.2013.46.4.418
Department of Internal Medicine, Soonchunhyang University Cheonan Hospital, Soonchunhyang University College of Medicine, Cheonan, Korea.
Correspondence: Tae Hoon Lee. Division of Gastroenterology, Department of Internal Medicine, Soonchunhyang University Cheonan Hospital, Soonchunhyang University College of Medicine, 31 Suncheonhyang 6-gil, Dongnam-gu, Cheonan 330-930, Korea. Tel: +82-41-570-3662, Fax: +82-41-574-5762, thlee9@schmc.ac.kr
Received 2012 May 25; Revised 2012 June 19; Accepted 2012 June 23.

Abstract

Placement of a self-expanding metal stent (SEMS) is an effective method for palliation of a malignant biliary obstruction. However, metal stents can cause various complications, including stent migration. Distally migrated metal stents, particularly covered SEMS, can be removed successfully in most cases. Stent trimming using argon plasma coagulation may be helpful in difficult cases despite conventional methods. However, no serious complications related to the trimming or remnant stent removal method have been reported due to the limited number of cases. In particular, proximal migration of a remnant fragmented metal stent after stent trimming followed by balloon sweeping has not been reported. We report an unusual case of proximal migration of a remnant metal stent during balloon sweeping following stent trimming by argon plasma coagulation. The remnant metal stent was successfully removed with rotation technique using a basket and revised endoscopically.

INTRODUCTION

Biliary stents are widely used for palliation of malignant biliary obstructions. Self-expanding metal stent (SEMS) have a longer patency than plastic stents and offer adequate palliation in patients with an unresectable malignant distal bile duct obstruction.1

However, SEMSs and plastic stents may cause complications such as stent migration, tumoral or nontumoral reocclusion, stent-induced ulceration, duodenal obstruction, perforation, and upper gastrointestinal bleeding.2-5 In particular, covered SEMS (cSEMS) tend to migrate more frequently than uncovered SEMS (uSEMS). To resolve these complications, several techniques for SEMS removal have been described in the literature. SEMS were successfully removed by using a polypectomy snare, large-mouthed rat tooth forceps, biopsy forceps or an endoscopic suture-cutting device.6-9 Although removal of these complicated cSEMS is usually successful and easier than removing a uSEMS in most cases, some cases of cSEMS may be difficult to remove using conventional methods.6-11 Several studies have reported that difficult cases of distally migrated SEMS can be treated by argon plasma coagulation (APC) trimming. However, there has been no report about endoscopic removal of proximally migrated, trimmed SEMS during balloon sweeping after APC trimming, which may be difficult to handle using conventional methods.

We report an unusual complicated case of proximal migration of a remnant metal stent during balloon sweeping following complete stent trimming by APC, the case which was successfully removed by using a basket and revised endoscopically.

CASE REPORT

A 74-year-old woman was admitted due to jaundice and epigastric pain which lasted for 7 days. Laboratory tests revealed the following: white blood cell count, 5.84×109/L (reference range, 4.0 to 10.8×109/L); aspartate aminotransferase, 123 IU/L; alanine aminotransferase, 144 IU/L; total bilirubin, 5.2 mg/dL; alkaline phosphatase, 488 IU/L; amylase, 315 U/L; lipase, 689 U/L; carbohydrate antigen 19-9, 35.86 U/mL; and carcinoembryonic antigen, 1.65 ng/mL. An abdominal computed tomography scan showed a ~2.1-cm low-attenuated mass lesion abutting on the superior mesenteric vein with dilatation of the intrahepatic bile duct, common bile duct (CBD) and pancreatic duct (PD), which suggested pancreas neoplasm. Subsequent endoscopic retrograde cholangiopancreatography (ERCP) showed short segmental distal CBD narrowing and diffuse irregular narrowing of the PD with marked upstream ductal dilatation (Fig. 1). After a 5-Fr single pigtail 7-cm-long stent was inserted into the PD following brushing cytology and an 8.5-Fr Tannenbaum, 7-cm-long (Cook Endoscopy, Winston-Salem, NC, USA) stent was inserted into the CBD, her symptoms improved and the obstructive jaundice resolved. Finally, we diagnosed her as a pancreas adenocarcinoma with CBD obstruction.

Fig. 1

Endoscopic retrograde cholangiopancreatography findings. (A) About 1.5-cm-long short segmental distal common bile duct narrowing with upstream bile duct dilatation. (B) Diffuse irregular narrowing of the pancreatic duct (PD) with marked upstream PD dilatation.

Two months later, she underwent repeat ERCP for stent exchange using a 60-mm-long, 10-mm diameter cSEMS (Bonastent; Standard Sci Tech Inc., Seoul, Korea), because she refused surgical operation. However, she was readmitted in 2 months due to epigastric pain, fever, and jaundice. A subsequent endoscopy showed a partial distally migrated cSEMS that was impossible to access and revise through the migrated stent. We decided to remove the stent but failed with forceps and a snare.

Thus, stent trimming was performed with an APC system (ERBE Elektromedizin GmbH, Tübingen, Germany). The power setting was 60 W, and the argon gas flow was set to 2 L/min. The amputated stump margin was set about 10 mm from the papilla. Stent amputation progressed in a circumferential manner until it was completely cut after 10 minutes (Fig. 2). The stent fragment was removed with a retrieval net. Then, a retrieval balloon was used to remove the clogging sludge following insertion of a guidewire through the remnant fragmented stent. However, while moving the balloon back and forth, the remnant stent migrated proximally very abruptly and floated to the dilated CBD. Immediate retrieval of the stent was not attempted because of the sharp cutting plane edge. Two 7-Fr double pigtail stents (9- and 10-cm long, respectively; Cook Endoscopy) were inserted in both intrahepatic bile ducts through the proximally migrated metal stent (Fig. 3). However, the patient was readmitted twice because of cholangitis and obstructive jaundice after 1 month, so removal of the proximally migrated metal stent was planned. Following removal of the double pigtail stent with rat tooth forceps, the stricture was dilated to 8 mm with a balloon catheter (Hurricane biliary balloon dilatation catheter; Boston Scientific, Natick, MA, USA). The proximal end of the floating metal stent was captured with a basket, rotated 180° in the CBD, and then removed successfully (Figs. 4, 5). No procedure related complications occurred during the removal of the migrated stent, and then a uSEMS was inserted successfully. Since then, no complications have been observed for 5 months.

Fig. 2

Duodenoscopic findings. (A) Partial distally migrated biliary covered self-expanding metal stent (cSEMS). (B) Stent trimming by argon plasma coagulation. (C) Completely fragmented cSEMS stent after trimming.

Fig. 3

Endoscopic retrograde cholangiopancreatography findings. (A) The proximally migrated metal stent after trimming, and the guidewire passed through the migrated stent. (B) Two 7-Fr double-pigtail stents were inserted into both intrahepatic ducts through the migrated stent.

Fig. 4

Endoscopic retrograde cholangiopancreatography finding of migrated stent removal. (A) The proximally migrated stent was floating in the common bile duct and was captured with a Dormia basket. (B) The proximal portion of the floating stent was captured by the basket and then rotated 180° in the common bile duct. (C) The stent was retrieved from its proximal end after complete rotation.

Fig. 5

Gross appearance of the proximally migrated amputated covered self-expanding metal stent.

DISCUSSION

SEMS placement has the advantage of greater long-term patency and cost-effectiveness compared to placement of a plastic stent for the palliative treatment of malignant distal biliary strictures.1,2 Nevertheless, some complications, such as occlusions and migration of SEMS, can be problematic. Proximal migration is a less common mode of migration and less frequently reported by other investigators. There was limited number of cases about removal of proximally migrated SEMS and also these migrated stents had a normal configuration. Bakhru et al.12 reported one patient who experienced proximal migration 58 days following cSEMS insertion but did not describe retrieval technique. Ho et al.13 reported that proximal migration of partially covered SEMS occurred in seven cases (1.7%), and migrated stents was extracted by balloon dilation combined with rat tooth extraction.

Unlike plastic stents, SEMSs are relatively hard to extract after being inserted and fixed. Endoscopic removal has been successfully achieved in selected cases, particularly when a cSEMS was the issue.6-8 Several techniques for SEMS removal have been described in the literature. Kahaleh et al.9 successfully removed a SEMS using a polypectomy snare and large-mouthed, rat tooth forceps. uSEMSs have been removed using 'hot' biopsy forceps to extract individual wire filaments from the distal end. Levy and Wiersema14 removed a distally migrated biliary Wallstent using an endoscopic suture-cutting device. Even with cSEMSs, only 4.5% to 22.2% of cases are limited by removal of the stent.6,9

APC has been used successfully to trim SEMS in selected patients, particularly in cases where the prolapsing part of the stent is extremely long and cannot be held with a snare or holding forceps. The safety and usefulness of APC trimming have been confirmed in experimental and clinical studies.6,10,11,15,16 Similarly, we used an APC trimming method in our case, because the SEMS was partially distally migrated, and we failed to remove the stent with a snare and forceps. However, in our case, the remnant stent migrated proximally and was difficult to remove because of sharp cutting plane edge. The proximal migration of a remnant stent might be explained by various factors. First, excessive balloon sweeping inside the remnant stent to remove sludge might have facilitated stent migration. Second, as a predisposing factor, the decreased frictional force between the metal stent and the stented CBD wall due to thermal injury by APC trimming might facilitate migration. In an animal study, which reported gross and histological findings after biliary stent trimming, APC stent trimming had the potential to cause superficial tissue damage by heat transmission through the treated metal stent.15 In these circumstances, excessive balloon sweeping might have facilitated stent migration. Third, relatively short length of malignant stricture due to pancreas malignancy might be an additive factor for proximal migration. Accordingly, after trimming a metal stent, excessive balloon sweeping inside the stent should be performed with caution, particularly with cSEMS.

Retrieval techniques for removal of proximally migrated plastic and metal stents include forceps, a Dormia basket, snare, balloon, and a Soehendra stent retriever.12,17,18 A migrated stent may cause frequent cholangitis, as in our case, even if endoscopic revision is successful. Although two plastic stents were inserted through the migrated metal stent, cholangitis developed twice within 2 months. A remnant stent may affect bile flow and more frequently clog the stent. In our case, the basket-capture technique was used to retrieve the migrated metal stent. After capturing the proximal end of the migrated stent with a basket, the stent was rotated 180° in the markedly dilated proximal CBD and then finally removed, as the distal end of the stent was sharp and may have caused bleeding or perforation during passage through the strictured distal CBD. Proximal migration of a remnant stent with sharp cutting plane edge after stent trimming by APC has not been reported in the English literature, making it difficult to establish ideal methods for stent removal. Our method might have also caused injury to the bile duct during rotation if CBD dilatation was not enough. Folding or crushing with basket or snare can be used for the same purpose. However, considering the sharp edges of cutting plane, our method may be helpful to minimize injury during removal. No complications were observed during the removal of the fragmented stent, and then an uSEMS was placed successfully. As another option, secondary reinsertion of a metal stent through the migrated remnant stent should be considered, if guidewire initially passed through the migrated metal stent.

In conclusion, although endoscopic APC trimming of a distally migrated cSEMS facilitated the removal of the migrated stents that were difficult to remove by conventional methods, a rare complication, such as proximal migration, can develop in association with excessive balloon sweeping in short segmental stricture. When trimming the SEMS to resolve a distal migration, adequate remnant stent material should be ensured to prevent proximal migration during additional endoscopic procedures such as ballooning, particularly with cSEMS. Furthermore, since retrieval of a stent using a basket can be attempted safely, early removal of the migrated stent is necessary to prevent other complications.

Notes

The authors have no financial conflicts of interest.

References

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Article information Continued

Fig. 1

Endoscopic retrograde cholangiopancreatography findings. (A) About 1.5-cm-long short segmental distal common bile duct narrowing with upstream bile duct dilatation. (B) Diffuse irregular narrowing of the pancreatic duct (PD) with marked upstream PD dilatation.

Fig. 2

Duodenoscopic findings. (A) Partial distally migrated biliary covered self-expanding metal stent (cSEMS). (B) Stent trimming by argon plasma coagulation. (C) Completely fragmented cSEMS stent after trimming.

Fig. 3

Endoscopic retrograde cholangiopancreatography findings. (A) The proximally migrated metal stent after trimming, and the guidewire passed through the migrated stent. (B) Two 7-Fr double-pigtail stents were inserted into both intrahepatic ducts through the migrated stent.

Fig. 4

Endoscopic retrograde cholangiopancreatography finding of migrated stent removal. (A) The proximally migrated stent was floating in the common bile duct and was captured with a Dormia basket. (B) The proximal portion of the floating stent was captured by the basket and then rotated 180° in the common bile duct. (C) The stent was retrieved from its proximal end after complete rotation.

Fig. 5

Gross appearance of the proximally migrated amputated covered self-expanding metal stent.