The Learning Curve for Peroral Endoscopic Myotomy in Latin America: A Slide to the Right?

Article information

Clin Endosc. 2021;54(5):701-705
Publication date (electronic) : 2021 June 3
doi : https://doi.org/10.5946/ce.2020.290
1Robert Wood Johnson University Hospital, New Brunswick, NJ, USA
2Weill Cornell Medical College, New York, NY, USA
3La Policia, Bogota, Colombia
4Borland-Groover, Jacksonville, FL, USA
5Juarez Hospital, Mexico City, Mexico
6Belo Horizonte Hospital, Belo Horizonte, Brazil
7Hospital Escuela Dr. Ramon Madariaga, Posadas, Argentina
8Gemelli University Hospital, Roma, Italy
9Santander Hospital, Reynosa, Mexico
10San Ignacio University Hospital, Bogota, Columbia
11Gastromedica Clinic, Managua, Nicaragua
12Gastrointestinal Endoscopy Unit, University of Sao Paulo, Sao Paulo, Brazil
13Instituto Ecuatoriano de Enfermedades Digestivas, Guayaquil, Ecuador
Correspondence: Michel Kahaleh Robert Wood Johnson University Hospital, 1 RWJ Plaza, MEB 464, New Brunswick, NJ 08901, USA Tel: +1-732-235-3976, Fax: +1-732-235-5537, E-mail: mkahaleh@gmail.com
Received 2020 November 4; Revised 2021 February 5; Accepted 2021 February 6.

Abstract

Background/Aims

Peroral endoscopic myotomy (POEM) has been increasingly used for achalasia in Latin America, where Chagas disease is prevalent, and this makes POEM more challenging. The aim of this study was to determine the learning curve for POEM in Latin America.

Method:

Patients undergoing POEM in Latin America with a single operator were included from a prospective registry over 4 years. Non-linear regression and cumulative sum control chart (CUSUM) analyses were conducted for the learning curve.

Results

A total of 125 patients were included (52% male; mean age, 59 years), of which 80 had type II achalasia (64%), and 38 had Chagas disease (30%). The average pre-procedure and post-procedure Eckardt scores were 6.79 and 1.87, respectively. Technical success was achieved in 93.5% of patients, and clinical success was achieved in 88.8%. Adverse events occurred in 27 patients (22%) and included bleeding (4 patients), pneumothorax (4 patients), mucosal perforation (13 patients), mediastinitis (2 patients), and leakage (4 patients).

The CUSUM chart showed a median procedure time of 97 min (range, 45-196 min), which was achieved at the 61st procedure. Procedure duration progressively decreased, with the last 10 procedures under 50 min approaching a plateau (p-value <0.01).

Conclusions

Mastering POEM in Latin America requires approximately 61 procedures for both POEM efficiency and to accomplish the procedure within 97 minutes.

INTRODUCTION

Peroral endoscopic myotomy (POEM) has been a minimally invasive treatment option for patients with achalasia for the past 10 years. Although comparable to laparoscopic Heller’s myotomy (LHM) in terms of efficacy, POEM has the advantages of minimal invasiveness, allowance for a longer myotomy, and the ability to perform a posterior or anterior myotomy [1-6]. After 10 years of consistent safety and efficacy, POEM is now being performed worldwide and has been increasingly used in Latin America where Chagas disease is prevalent. Reports on POEM for Chagas disease are scarce [7-21]. POEM in Chagas disease is technically more challenging than in patients with achalasia, due to a higher rate of submucosal scarring [21], most likely related to chronic esophagitis caused by esophageal stasis (clinical observation, unpublished data). Two recently published studies have shown that Chagas disease-related achalasia responds better to POEM [15,22]. Nonetheless, the learning curve of gastroenterologists performing the procedure has not been well studied [16-21]. The aim of this study was to determine the learning curve for POEM among operators in Latin America.

PATIENTS AND METHODS

Consecutive patients diagnosed with achalasia who underwent POEM with a single operator in Argentina, Bolivia, Brazil, Colombia, Ecuador, Mexico, and Nicaragua between June 2013 and August 2017 were included in a prospective registry (ClinicalTrials.gov Identifier: NCT02162589). The single operator was previously proficient in endoscopic submucosal dissection (ESD). Informed consent for the procedure was obtained from all patients. Patient demographics, procedural information, post-procedural follow-up data, and adverse events were collected for all patients. Technical success was defined as successful completion of the myotomy. Clinical success was defined as an Eckardt score of ≤3 at 3 months.

Procedural technique

All procedures were performed under general anesthesia with endotracheal intubation. CO2 insufflation was used in all cases. A standard gastroscope fitted with a dissection cap was used. Initial upper endoscopy to clear the esophagus was performed, after which a mixture of saline solution and methylene blue was injected anteriorly or posteriorly. A longitudinal incision was made and a 12-cm longitudinal tunnel was created crossing the esophagogastric junction 2 cm into the stomach. The myotomy was performed in this tunnel. Ultimately, the mucosotomy was closed with endoscopic clips [9].

Clinical outcomes and statistical analysis

Demographics, clinical characteristics, pre- and post-procedure Eckardt scores, procedure duration, post-procedure follow-up data, and adverse events were collected. To measure the learning curve, non-linear regression was used with the case number as an independent variable and the procedure time as the dependent variable.

Cumulative sum control chart (CUSUM) analysis was conducted to report small shifts in procedure duration over time. The CUSUM analysis was performed similar to the modeling described by Biau DJ et al. [23]. Non-linear regression, CUSUM analyses test for independent means, and Fisher exact tests for proportions were conducted using Stata 15 (StataCorp LLC, College Station, TX, USA) . The primary outcome was the analysis of the learning curve, which was obtained by measuring the length of the procedure for consecutive procedures. The secondary outcomes were technical clinical efficacy based on the postoperative Eckardt score, adverse event rate, and reintervention rate.

RESULTS

Table 1 summarizes the main results of this study. A total of 125 patients were included (52% male; mean age, 59 years). The most common pathology was type II achalasia (n=80, 64%), followed by type I achalasia (n=9, 7.2%), type III achalasia (n=33, 26.4%), and other esophageal motility disorders (n=3, 2.4%). Chagas disease was present in approximately one-third of the patients (n=38, 30.4%). Most patients had undergone no prior treatment for achalasia (n=84, 67.2%). Previous treatments undergone by patients included prior LHM (n=18, 14.4%), pneumatic dilation (n=17, 13.6%), or botulinum toxin injections (n=6, 4.8%). The average pre-procedure Eckardt score was 6.79.

Summary of Demographics and Results

Technical success was achieved in 93.5% of patients (n=117). A total of 99 patients (79.2%) underwent posterior POEM, and 26 patients underwent anterior POEM (20.8%). The mean procedure duration in all cases was 97 min, ranging from 45 min to 196 min, with a mean of 102.7 min. There was no statistically significant difference (p=0.35) in the mean procedure duration of the Chagas group (mean =108 min; range, 48-196 min), when compared to that in the non-Chagas patients (mean=100.36 min; range, 46-175 min).

Mucosotomy entry was closed with standard endoclips in the majority of patients (n=120, 96%). Only in 5 cases (4%) were the mucosotomy closed with overstitch sutures.

Clinical success was achieved in 111 patients (88.8%). The mean post-procedure Eckardt score was 1.87. The clinical failure rate was higher in the Chagas group than in the non-Chagas group (21% vs. 7%, p=0.03).

On average, the median length of hospital stay was 1.98 days. The median follow-up period was 16 months (standard deviation [SD], 12.89 months).

Adverse events occurred in 27 patients (21.6%) and included mucosal perforation (n=13, 10.4%) closed during a second endoscopy by using clips, severe bleeding (n=4, 3.2%) solved using coagulation graspers and balloon tamponade, pneumothorax (n=4, 3.2%) requiring chest tube placement, leak (n=4, 3.2%) that resolved on repeat endoscopy and clip closure, and mediastinitis (n=2, 1.6%) managed with antibiotic therapy. The incidence of adverse events was higher in the Chagas group than that in the non-Chagas group (37% vs. 15%, p=0.01).

There was no statistically significant difference in reintervention rates between the Chagas group and the non-Chagas group (18% vs. 7%, p=0.06).

The CUSUM analysis (Fig. 1) revealed that the 97-minute procedure time was achieved at the 61st procedure, indicating efficiency. Aside from a few outliers, procedure duration further reduced with consequent procedures with the last 10 procedures under 50 minutes almost approaching a plateau (non-linear regression, p<0.01) (Fig. 2). We assume that further evaluation of the next 40-50 cases could potentially reveal a plateau, indicating mastery.

Fig. 1.

Cumulative sum control chart shows procedure efficiency duration.

Fig. 2.

Inverse curve regression showing procedure time decrease significantly over the course of consecutive procedures.

DISCUSSION

POEM has been well-established as a safe and efficacious procedure for the management of achalasia. In a meta-analysis of 36 studies that included 2,373 patients across 12 countries, 98% of patients with achalasia had clinical success (defined as a reduction in Eckardt score to ≤3) with POEM. The mean Eckardt score decreased from 6.9 ±0.15 preoperatively to 1.0±0.08 at 12 months postoperatively. In addition, there were significant decreases in the average lower esophageal sphincter pressure and the integrated relaxation pressure [24].

Previous studies have suggested that POEM in Chagas patients is technically more challenging due to significant amounts of submucosal scarring [15]. However, studies also suggest that patients with Chagas disease-related achalasia tend to respond better to POEM than to LHM [15].

Another recent study comparing POEM in Chagas vs. non-Chagas achalasia patients highlighted how the post-procedure Eckardt scores, procedure time, and repeat interventions differed between the groups. In the Chagas group, the post-procedure Eckardt score was reduced by 3.57 points compared to 6.03 in the non-Chagas group. Repeat intervention was much higher in the Chagas group than in the non-Chagas group (51% vs. 17%), and the mean POEM procedure time was longer in the Chagas group than in the non-Chagas group (120 minutes vs 94 minutes) [22].

In this study, we saw statistically significant higher adverse events and clinical failure rates in the Chagas group than in the non-Chagas group (37% vs. 15% and 21% vs. 7%, respectively).

There is limited published information on the learning curve of this procedure which includes achalasia patients due to Chagas disease. Kurian et al. looked at the learning curve of POEM and reported mastery of technique after 20 operations, demonstrated by decreased procedural time [11]. Patel et al. evaluated the experience of a single gastroenterologist’s POEM learning curve in which they found that efficiency was achieved after 40 cases and mastery was reached after 60 operations [12]. Zein et al. analyzed multiple methodologies for assessing the learning curve and reported a learning rate of 13 cases and a “plateau” at 102 minutes [13]. Liu et al. found that 100 cases were required to decrease the risk of technical failure, adverse events, and clinical failure, while 70 cases were the threshold for decreasing procedure time [9]. A recent study of 136 patients by Tefas et al. [25] reported a learning curve cut-off of 20 cases. They also noted that the major complication risk rate was higher during the learning curve (13.3%). However, the rate of minor complications was not influenced by operator competency during or after the learning curve cut-off.

Our study differs from the previous POEM learning curve studies as our analyses included Chagas patients, reflecting actual endoscopic experiences in the achalasia patient population in Latin America. Of the 125 patients included in the study, 30% had Chagas disease and the Chagas group had a higher incidence of adverse event rates than the non-Chagas group. There was no statistically significant difference in the procedure times between the groups, and the median procedure time was 97 minutes.

CUSUM analyses showed that a 97 minute procedure time was achieved at the 61st procedure and procedure duration progressively decreased, with the last 10 procedures performed in less than 50 minutes.

There are two limitations to this study. We did not compare multiple operators. Additionally, the expert endoscopist included in this study had prior proficiency in therapeutic endoscopy, including endoscopic submucosal dissection (ESD) and endoscopic mucosal resection (EMR). Thus, the learning curve might underestimate the number of therapeutic endoscopies and POEMs required to achieve POEM proficiency in endoscopists who lack such skills.

CONCLUSIONS

This Latin America learning curve study demonstrated that efficiency was reached at 97 minutes and at a learning rate of 61 cases, with continuing improvement. POEM seems to be a more technically difficult procedure to master in Latin America, requiring a higher volume of cases to reach efficiency, and also seems to be associated with a higher number of adverse events in the initial phase of the learning curve. Most likely, these obstacles are related to the increased anatomical challenges observed in patients with Chagas disease. We recommend that only endoscopists demonstrating proficiency in ESD and EMR should conduct POEM procedures.

Notes

Conflicts of Interest: Amy Tyberg has done consulting work for Nine Point Medical, Endo Gastric Solutions, and Obalon Therapeutics. She is a board director at the Therapeutic EUS Society Inc. Michel Kahaleh has done consulting work for Boston Scientific, Interscope Med, Obalon Therapeutics, and Abbvie. He has received research grants from Boston Scientific, Conmed, Pinnacle, Cook, Gore, Merit, and Olympus. He is the CEO of Innovative Digestive Health Education & Research Inc. and the Therapeutic EUS Society Inc. M. Kahaleh has received grant support from Boston Scientific, Fujinon, W.L. Gore, Mauna Kea, Apollo Endosurgery, Cook Endoscopy, ASPIRE Bariatrics, GI Dynamics, Nine Point Medical, Merit Medical, Interscope Med, Olympus, ERBE, and MI Tech. He is a consultant for Boston Scientific, Concordia Laboratories Inc., ABBvie, and Mauna Kea Tech. None of the funding was related to this study. Monica Gaidhane has done consulting work for Interscope Med. She is the COO of Innovative Digestive Health Education & Research Inc. and the Therapeutic EUS Society Inc. The other authors have no potential conflicts of interest.

Funding

None.

References

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Article information Continued

Fig. 1.

Cumulative sum control chart shows procedure efficiency duration.

Fig. 2.

Inverse curve regression showing procedure time decrease significantly over the course of consecutive procedures.

Table 1.

Summary of Demographics and Results

N=125
Male:Female 65:60
Age (years)
 Mean (SD) 59.14 (12.48)
Achalasia Type 122
 • Type I 9
 • Type II 80
 • Type III 33
 • Jackhammer esophagus 2
 • Nutcracker esophagus 1
Chagas disease (%) 38 (30.4%)
Prior treatments
 • Heller myotomy (%) 18 (14.4%)
 • Pneumatic dilation (%) 17 (13.6%)
 • Botulinum toxin (%) 6 (4.8%)
No prior treatments 84 (67.2%)
Pre-procedure
 Mean Eckardt score (SD) 6.79 (2.05)
 Mean LES pressure (mmHg) 29.04
Orientation
 Anterior:Posterior 26:99
Device for closure
 Clips:Overstitch suture 120:5
Post-procedure (3 months)
 Mean Eckardt score (SD) 1.87 (2.15)
 Mean LES pressure (mmHg) 22.56
Technical success 117 (93.5%)
Clinical success 111 (88.8%)
Complications
 • Bleeding 4
 • Pneumothorax 4
 • Mucosal perforation 13
 • Mediastinitis 2
 • Leak 4
Interventions for complications
 • Hemoclips (mucosal perforations) 12
 • Overscope clips (mucosal perforations) 1
 • Needle decompression (pneumothorax) 1
 • Chest tubes (pneumothorax) 3
 • Coagulation (bleeding) 1
 • Reclips (leaks) 4
 • Antibiotics (mediastinitis) 2
Procedure time (minutes, SD) 102.65 (42.48)
Hospital stay (days, SD) 1.98 (0.97)
Follow up duration (months, SD) 16 (12.89)
Reinterventions
 • Heller myotomy 5
 • Pneumatic dilation 8

LES, lower esophageal sphincter; SD, standard deviation.