Safety and efficacy of liquid nitrogen spray cryotherapy-assisted balloon dilation for refractory anastomotic strictures

Article information

Clin Endosc. 2024;57(5):694-696
Publication date (electronic) : 2024 June 12
doi : https://doi.org/10.5946/ce.2024.012
1Department of Medicine, University of Oklahoma College of Medicine, Oklahoma City, OK, USA
2Department of Pediatrics, University of Oklahoma College of Medicine, Oklahoma City, OK, USA
3Section of Cardiac, Thoracic & Vascular Surgery, Department of Surgery, University of Oklahoma College of Medicine, Oklahoma City, OK, USA
4Section of Digestive Diseases and Nutrition, Department of Medicine, University of Oklahoma College of Medicine, Oklahoma City, OK, USA
Correspondence: Christopher Adam Bouvette Department of Medicine, University of Oklahoma College of Medicine, 800 Stanton L. Young Blvd AAT 6300, Oklahoma City, OK 73104, USA E-mail: Christopher.a.bouvette@gmail.com
Received 2024 January 10; Revised 2024 March 3; Accepted 2024 April 1.

Endoscopic dilation remains the primary approach for the treatment of gastrointestinal anastomotic strictures. However, strictures are commonly encountered challenges, often resulting in substantial morbidity and healthcare utilization. Recently, the use of liquid nitrogen spray-assisted balloon dilation, termed cryo-dilation, was described as an emerging adjunct in the management of refractory benign strictures.1 However, the role and utility of cryo-dilation in such management remain unclear.

In this study, we retrospectively analyzed a single-center case series to assess the safety and utility of cryo-dilation for managing refractory strictures at anastomotic sites. The study methodology was approved and overseen by the University of Oklahoma Health Sciences Center Institution Review Board (IRB00000588; 16650), and waiver of informed consent was also approved. Refractory anastomotic strictures were defined as those that remained symptomatic in spite of four or more endoscopic dilation procedures. Single-operator cryo-dilation was performed under general anesthesia using the truFreeze Spray Cryotherapy System (STERIS Healthcare) with an active venting tube. This involved application of a liquid nitrogen spray for 30 seconds, followed by a 60-second thaw, for a total of three cycles. Following the final thaw, dilation with a 4 cm controlled radial expansion balloon was performed, with the maximum inflation size left to the discretion of the endoscopist (Fig. 1). We compared the number of dilation procedures required by each patient in the six months preceding and succeeding cryo-dilation. Data on post-procedural complications were collected via chart review.

Fig. 1.

Treatment protocol (patient no. 1). (A) Procedure image before treatment showing a benign recalcitrant stricture at an esophago-colonic anastomotic site. (B) Procedure image showing liquid nitrogen application in the freezing phase. (C) Procedure image after the thawing phase showing dilation with a 4 cm controlled radial expansion balloon. (D) Procedure image post-dilation showing the treatment effect with improved patency of the stenotic site.

The study comprised seven patients (average age, 56.9 years). The distribution of anastomotic sites was as follows: esophago-gastric in four patients, esophago-colonic in one patient, gastro-jejunal in one patient, and ileo-colonic in one patient. The average inner diameter of the stricture before cryo-dilation was 7.1 mm. The average maximum dilation size reached was 15.2 mm, with a range of 12 to 18 mm. In the six months leading up to cryo-dilation, patients underwent a mean of seven dilation procedures, ranging from 2 to 16. Over the six months after cryo-dilation, the mean number of dilation procedures had decreased significantly to 0.6, with a range of 0 to 2. Four patients remained symptom free, with no dilation requirements at the six-month mark. Three patients reported a return of symptoms, necessitating repeat dilation. No instances of early or delayed bleeding or perforation were documented (Table 1). One patient experienced post-procedural pain, which was managed conservatively in the outpatient setting.

Cohort characteristics, prior intervention, and dilation requirement before and after cryo-dilation

Balloon dilation with traditional, wire-guided, and through-the-scope dilators remains at the forefront of anastomotic stricture management. In the setting of recalcitrant strictures, several approaches augment therapy. Dilation coupled with intralesional steroid injections is speculated to inhibit inflammation and hinder progressive fibrosis. Under a similar motif, intralesional mitomycin C injections act by suppressing fibroblast proliferation and fibroblastic collagen synthesis.2 Studies of both techniques suggest they increase the asymptomatic duration and reduce the frequency of future dilation requirements. Esophageal stents have also been incorporated, driven by dilation failure or as an adjunct to dilation efforts. Stents support esophageal remodeling and may hinder the progression of a refractory lesion.2,3 However, this method is limited by incidences of stent migration and patient intolerance secondary to pain.4 Among the methods used to manage recalcitrant strictures, incisional therapy (radial incision and cutting method) is well described. Studies have demonstrated incisional therapy to have equivocal risk to that of traditional dilation methods, with potentially highest efficacy for strictures at anastomotic sites.5,6 Self-dilation is highly efficacious but remains patient dependent with respect to implementation. When all interventions fail, surgical revision remains definitive.

Spray cryotherapy (SCT) has gained favor in the management of Barrett’s esophagus, gastric antral vascular ectasia, and radiation proctitis. Recently, its novel use for the management of a benign refractory stricture at an anastomotic site was described.1 SCT has the unique ability to induce tissue necrosis while preserving the extracellular matrix. The relative resistance of collagen and elastin minimizes an inflammatory response, theoretically circumventing compensatory fibrosis and scarring. In the case of anastomotic strictures, this paradigm has proven both safe and beneficial.

Treatment effects are speculated to be driven by four parameters: the cooling rate, final temperature, time maintained at final temperature, and thawing rate.7 Within the freezing phase, extracellular ice crystals promote an osmotic gradient while intracellular ice crystals disrupt the cellular membranes.7 At the periphery where cellular membranes may remain stable, mitochondrial injury induces cytochrome C release and upregulates apoptosis.8 The thawing cycle promotes an intracellular osmotic fluid shift and introduces further membrane damage through ice crystal fusion.8 Endothelial damage and vascular stasis contribute to localized ischemic necrosis. Dosimetry data in this area remain limited, and existing protocols are delivery system specific. Specifically, it remains uncertain whether freezing, thawing, or the treatment duration plays the largest role in the therapeutic effect. Current SCT indications have been primarily explored within the setting of pathologic epithelia, malignant lesions, or porcine models.9,10 Further studies on SCT physiology as it relates to fibrotic lesions may prove beneficial for optimizing treatment protocols.

Recalcitrant strictures are a challenging problem for both patients and endoscopists. Management usually requires multiple serial dilations, which diminishes the quality of life and bears significant costs. In many cases, frequent and failed dilation procedures are burdensome and can foster discordant patient–provider relationships. This case series suggests that SCT for recalcitrant anastomotic strictures is safe and may offer a more durable response compared with conventional approaches. The reduction in the number and frequency of dilation procedures required may provide significant quality of life improvements for patients and potential cost savings for healthcare systems. However, these findings are limited by the sample size. Furthermore, with only six months of follow-up data, we are limited in concluding on the longevity of the benefits. We hope to expand upon prior reports of use of this intervention and advocate for its continued evaluation. Further studies are needed to validate the technique and to provide a more comprehensive assessment of patient selection, risk profile, and treatment effects.

Overall, the use of liquid nitrogen SCT-assisted balloon dilation for managing refractory anastomotic strictures appears to be a safe and effective approach. However, although we have demonstrated a reduced frequency of short-term dilation requirements across a limited sample, a more comprehensive assessment is needed to verify the durability of this technique.

Notes

Conflicts of Interest

The authors have no potential conflicts of interest.

Funding

None.

Author Contributions

Conceptualization: CAB, AR; Data curation: CAB, JMR; Formal analysis: CAB; Investigation: all authors; Methodology: JMR; Project administration: AR; Supervision: JMR, AR; Visualization: ABN; Writing–original draft: CAB; Writing–review & editing: ABN, JMR, AR.

References

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5. Lee TH, Lee SH, Park JY, et al. Primary incisional therapy with a modified method for patients with benign anastomotic esophageal stricture. Gastrointest Endosc 2009;69:1029–1033.
6. Yano T, Yoda Y, Satake H, et al. Radial incision and cutting method for refractory stricture after nonsurgical treatment of esophageal cancer. Endoscopy 2013;45:316–319.
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9. Raju GS, Ahmed I, Xiao SY, et al. Graded esophageal mucosal ablation with cryotherapy, and the protective effects of submucosal saline. Endoscopy 2005;37:523–526.
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Article information Continued

Fig. 1.

Treatment protocol (patient no. 1). (A) Procedure image before treatment showing a benign recalcitrant stricture at an esophago-colonic anastomotic site. (B) Procedure image showing liquid nitrogen application in the freezing phase. (C) Procedure image after the thawing phase showing dilation with a 4 cm controlled radial expansion balloon. (D) Procedure image post-dilation showing the treatment effect with improved patency of the stenotic site.

Table 1.

Cohort characteristics, prior intervention, and dilation requirement before and after cryo-dilation

Case no. Age (yr) Sex Anastomosis type Reason for resection Prior endoscopic intervention Dilations in 6 mo preceding cryo-dilation (n) Diameter of stricture at time of cryo-dilation (mm) Maximum balloon size (mm) Dilations in 6 mo following cryo-dilation (n)
1 42 Male Esophago-colonic End-stage achalasia Bougienage, balloon dilation, steroid injection, covered stent 16 7 16 2
2 56 Male Esophago-gastric Esophageal adenocarcinoma Bougienage, balloon dilation 8 10 18 1
3 65 Male Esophago-gastric Esophageal adenocarcinoma Bougienage, balloon dilation 6 8 15 0
4 49 Female Esophago-gastric Esophageal adenocarcinoma Bougienage, balloon dilation, covered stent 6 8 18 0
5 62 Male Gastro-jejunal Peptic pyloric stricture Balloon dilation 3 5 12 0
6 55 Male Ileo-colonic Colon adenocarcinoma Balloon dilation 2 5 12 0
7 69 Female Esophago-gastric Esophageal adenocarcinoma Balloon dilation 8 7 16 1