CC BY-NC-ND 4.0 · Endosc Int Open 2021; 09(04): E583-E598
DOI: 10.1055/a-1352-2944
Review

Clinical efficacy and safety of magnetic sphincter augmentation (MSA) and transoral incisionless fundoplication (TIF2) in refractory gastroesophageal reflux disease (GERD): a systematic review and meta-analysis

Saurabh Chandan
 1   Division of Gastroenterology and Hepatology, CHI Creighton University Medical Center, Omaha, Nebraska, United States
,
Babu P. Mohan
 2   Division of Gastroenterology and Hepatology, University of Utah School of Medicine, Salt Lake City, Utah, United States
,
Shahab R. Khan
 3   Department of Medicine, Brigham and Women's Hospital, Boston, Massachusetts, United States
,
Lokesh K. Jha
 4   Gastroenterology, Parkview Health, Fort Wayne, Indianapolis, United States
,
Amaninder J. Dhaliwal
 1   Division of Gastroenterology and Hepatology, CHI Creighton University Medical Center, Omaha, Nebraska, United States
,
Mohammad Bilal
 5   Gastroenterology, Beth Israel Deaconess Medical Center, Boston, Massachusetts, United States
,
Muhammad Aziz
 6   Internal Medicine, University of Toledo, Toledo, Ohio, United States
,
Andrew Canakis
 7   Internal Medicine, Boston University Medical Center, Boston, Massachusetts, United States
,
Sumant Arora
 8   Gastroenterology & Hepatology, University of Iowa, Iowa City, Iowa, United States
,
Sarah Malik
 1   Division of Gastroenterology and Hepatology, CHI Creighton University Medical Center, Omaha, Nebraska, United States
,
Lena L. Kassab
 9   Internal Medicine, Mayo Clinic, Rochester, Minnesota, United States
,
Suresh Ponnada
10   Internal Medicine, Carilion Roanoke Memorial Hospital, Roanoke, Virginia, United States
,
Ishfaq Bhat
 1   Division of Gastroenterology and Hepatology, CHI Creighton University Medical Center, Omaha, Nebraska, United States
,
Alexander T. Hewlett
 1   Division of Gastroenterology and Hepatology, CHI Creighton University Medical Center, Omaha, Nebraska, United States
,
Neil Sharma
 5   Gastroenterology, Beth Israel Deaconess Medical Center, Boston, Massachusetts, United States
,
Stephanie McDonough
 2   Division of Gastroenterology and Hepatology, University of Utah School of Medicine, Salt Lake City, Utah, United States
,
Douglas G. Adler
 2   Division of Gastroenterology and Hepatology, University of Utah School of Medicine, Salt Lake City, Utah, United States
› Author Affiliations
 

Abstract

Background and study aims Proton pump inhibitors (PPI) are effective medical therapy options for gastro-esophageal reflux disease (GERD). However, 20 % to 40 % of patients report symptoms despite taking daily PPI. Transoral incisionless fundoplication (TIF2) and magnetic sphincter augmentation (MSA) are less invasive options for the treatment of refractory GERD and are increasingly gaining popularity.

Methods We conducted a comprehensive search of several databases to identify relevant studies. Our primary aim was to compare the efficacy of both interventions reported as improvement in Gastroesophageal Reflux Disease-Health Related Quality of Life (GERD-HRQL) score, overall patient satisfaction, improvement in post-procedure regurgitation, and fraction of patients completely off PPI therapy at follow up.

Results Twenty-four studies with 1942 patients were included in the final analysis. Both MSA and TIF2 had comparable technical success and clinical success based on improvement in GERD-HRQL scores i. e. 98.8 % (CI 95.6,99.7) vs 98.5 % (CI 95.7,99.5) and 80.4 % (CI 66,89.6) vs 77.7 % (CI 64.1,87.2), respectively. A significantly greater proportion of patients reported improvement in regurgitation, i. e. 91.1 % (CI 83.8,95.3) vs 73.1 % (CI 62.5,81.7) and were able to completely discontinue PPI therapy with MSA compared to TIF2 i. e. 91.3 % (CI 81.5,96.2) vs 63.8 % (CI 51.6,74.4). Patients’ BMI and presence of a hiatal hernia did not have any effect on procedural outcomes.

Conclusion Both procedures performed at par when comparing clinical success in terms of improvement in GERD-HRQL scores. In terms of overall patient satisfaction, post procedure regurgitation and cumulative number of patients off PPI therapy, MSA outperforms TIF2.


#

Introduction

An estimated 9 million visits to the primary care physician are attributed to gastroesophageal reflux disease (GERD) and when severe, this condition can significantly impair a person’s quality of life [1]. Treatment with proton pump inhibitor (PPI) therapy has been the mainstay of medical therapy for decades. Although most patients with acid reflux respond satisfactorily to PPI therapy, 20 % to 42 % may be considered "difficult to treat” [2] [3] [4]. While cheap and generally safe, there have been some concerns with PPI therapy, including increased infectious complications, nutritional deficiencies, as well as a potential risk of osteoporosis and dementia with long term use [5].

Patients who fail medical therapy or those who are referred to as having “refractory” GERD are often considered for anti-reflux surgery (which can be performed either via open or laparoscopic surgery or endoscopically). Surgical fundoplication is a highly efficacious procedure and remains the current gold standard in the surgical management of GERD [6]. Unlike PPI therapy, surgically manipulating the lower esophageal sphincter (LES) significantly reduces the number of reflux events, rather than merely reducing the acidity of the refluxate [7]. Traditional surgical fundoplication can at times result in complications such as postoperative dysphagia, recurrent heartburn and wrap disruption [8] [9] [10].

To help circumvent these complications, magnetic sphincter augmentation (MSA) with the LINX device (Torax Medical) was approved by the US Food and Drug Administration in 2012 for patients with mild to moderate GERD. This device is composed of a string of beads containing a sealed core of magnetic neodymium iron boride, which are interlinked with independent titanium wires. These magnets produce a very precise force of inward attraction (~40 g at full contraction, 7 g at full expansion), which augments the closure of the lower esophageal sphincter. The beads are interconnected by small mobile wires that allow the device to expand so as to permit the passage of a food bolus as well as physiologic functions like belching or vomiting [11].

Transoral Incisionless Fundoplication (TIF) was first introduced in 2007. The procedure involves tissue manipulation using an endoscopic suturing device called EsophyX (Endogastric Solutions, Redmond, Washington, United States). TIF attempts to restore competency to the LES, preventing reflux of gastric contents. Eligible candidates include those with intractable reflux symptoms, no or mild esophagitis with hiatal hernia < 2 cm in length and abnormal acid reflux [12] [13].

While there have been several studies reporting clinical success and safety profile for both MSA and TIF, no randomized controlled trials have directly compared the two interventions. The goal of this study was to evaluate the clinical outcomes of these procedures, reported as improvement in cumulative GERD Health-Related Quality of Life (GERD-HRQL) scores, patient reported symptom improvement, and overall patient reported satisfaction as well as total number of patients off PPI therapy at maximum follow up, by meta-analysis methods.


#

Methods

Search strategy

The literature was searched by a medical librarian for studies that reported on the use of magnetic sphincter augmentation (MSA) and trans-oral fundoplication (TIF) in the treatment of gastroesophageal reflux disease (GERD). Searches were run in December 2019 in ClinicalTrials.gov, Ovid EBM Reviews, Ovid Embase (1974 +), Ovid Medline (1946 + including epub ahead of print, in-process & other non-indexed citations), Scopus (1970 +) and Web of Science (1975 +). Results were limited to English language. All results were exported to Endnote where 815 obvious duplicates were removed leaving 869 citations. The full search strategy is available in Supplementary Appendix 1. The MOOSE checklist was followed and is provided as Supplementary Appendix 2 [14]. Reference lists of evaluated studies were examined to identify other studies of interest.


#

Study selection

In this meta-analysis, we included studies that evaluated the clinical outcomes of MSA and TIF in patients undergoing treatment for refractory GERD. Studies were included irrespective of inpatient/outpatient setting, study sample-size, follow-up time, and geography as long as they provided the clinical outcomes data needed for the analysis.

Our exclusion criteria were as follows: (1) studies that evaluated TIF1 procedure; (2) studies where TIF was performed with concurrent hiatal hernia repair [15] [16] [17]; (3) studies where MSA was performed with concurrent hiatal hernia repair [18] [19] [20]; (4) studies that did not report on the clinical outcomes of interest; (5) studies performed in the pediatric population (Age < 18 years); and (6) studies not published in English language. In cases of multiple publications from a single research group reporting on the same patient, same cohort and/or overlapping cohorts, data from the most recent and/or most appropriate comprehensive report were retained. The retained studies were selected by two authors (BPM, SC) based on the publication timing (most recent) and/ or the sample size of the study (largest). In situations where a consensus could not be reached, overlapping studies were included in the final analysis and any potential effects were assessed by sensitivity analysis of the pooled outcomes by leaving out one study at a time.


#

Data abstraction and quality assessment

Data on study-related outcomes from the individual studies were abstracted independently onto a standardized form by at least four authors (BPM, SRK, SC, MB). Authors (SC, LLK, LKJ and SA) cross-verified the collected data for possible errors and two authors (BPM, SC) did the quality scoring independently.

The Newcastle-Ottawa scale for cohort studies was used to assess the quality of studies [21]. This quality score consisted of eight questions, the details of which are provided in Supplementary Table 1.


#

Outcomes assessed

The outcomes assessed were as follows:

  1. Pooled rates of clinical success as determined by > 50 % improvement in cumulative GERD-HRQL score

  2. Pooled rate of clinical success as determined by patient satisfaction (per Alimentary Satisfaction (AS) score [22] or reported as “Dissatisfied, Neutral, Satisfied” [23] [24] [25] at follow-up

  3. Pooled rate of clinical success as determined by percentage of patients

reporting improvement in regurgitation at follow up as determined by Reflux Disease Questionnaire (RDQ) [26] [27] [28], Foregut Symptom Questionnaire (FSQ) [29] [30], Regurgitation Score [23] [24] [31]

  1. Pooled rate of number of patients completely off PPI therapy at follow up

  2. Pooled rates of technical success of MSA and TIF2

  3. Pooled rate of post-procedural dysphagia

  4. Meta-regression analysis to assess effect of BMI on outcomes of in both study

  5. cohorts

  6. Meta-regression analysis to assess the effect of presence of pre-procedure

hiatal hernia on clinical success in both study cohorts


#

Assessment methodology and definitions

The collected data were matched between the groups (MSA, TIF2) before statistical analysis. Comparison analysis was performed by sub-group analysis between the pooled outcomes of MSA and TIF2. This model of comparison is comparable to a retrospective case-control study with matched groups and should be considered non-causal [32].


#

Statistical analysis

We used meta-analysis techniques to calculate the pooled estimates in each case following the methods suggested by DerSimonian and Laird using the random-effects model [33]. When the incidence of an outcome was zero in a study, a continuity correction of 0.5 was added to the number of incident cases before statistical analysis [34].

We assessed heterogeneity between study-specific estimates by using Cochran Q statistical test for heterogeneity, 95 % prediction interval (PI), which deals with the dispersion of the effects, and the I2 statistics. [35] [36] In this, values of < 30 %, 30 % to 60 %, 61 % to 75 %, and > 75 % were suggestive of low, moderate, substantial, and considerable heterogeneity, respectively.

Publication bias was ascertained, qualitatively, by visual inspection of funnel plot and quantitatively, by the Egger test [37]. When publication bias was present, further statistics using the fail-Safe N test and Duval and Tweedie’s ‘Trim and Fill’ test was used to ascertain the impact of the bias [38]. Three levels of impact were reported based on the concordance between the reported results and the actual estimate if there were no bias. The impact was reported as minimal if both versions were estimated to be same, modest if effect size changed substantially but the final finding would still remain the same, and severe if basic final conclusion of the analysis is threatened by the bias [39]. P < 0.05 was used a-priori to define significance between the groups compared.

When possible, meta-regression analysis was carried out to study the effects of clinical variables on pooled outcomes. Single variable analysis was done assuming other variables to be constant using a random-effects model. A Knapp-Hartung 2-tailed P < 0.05 was considered statistically significant.

All analyses were performed using Comprehensive Meta-Analysis (CMA) software, version 3 (BioStat, Englewood, New Jersey, United States).


#
#

Results

Search results and population characteristics

From an initial pool of 1684 studies, 869 records were screened and 64 full-length articles were assessed. A total of 24 studies (1942 patients) were included in the analysis. 1074 patients (566 males, 508 females) underwent treatment with MSA (9 studies) and 868 patients (379 males, 489 females) underwent treatment with TIF2 (15 studies).

The schematic diagram demonstrating our study selection is illustrated in Supplementary Fig. 1. Baseline population characteristics were comparable between the MSA and TIF2 cohorts. The mean and/or median age ranged from 44 to 63 years in the MSA cohort and 36 to 68 years in the TIF2 cohort. The mean duration of GERD pre-treatment ranged from 5 to 14.2 years in the MSA cohort and 5 to 11.2 years in the TIF2 cohort. A total of 389 patients in the MSA cohort and 462 patients in the TIF2 cohort had hiatal hernias. In the TIF2 group, 158 patients had a Hill Grade III/IV hiatal hernia. Further details along with the population characteristics are described in [Table 1a], [Table 1b] and [Table 2].

Table 1a

Study details – Patient characteristics

Design, Period, Center, Country

Device

Age

Total (N)

N @ F/u

M/F

GERD Duration (Years)

BID PPI duration (Years)

Barrett's (N)

Hiatal Hernia

GEJ Hill Grade

BMI (kg/m2)

MSA – No# Beads/TIF – Fasteners

Esophagitis (Pre-MSA)

Pre-Procedure

Post-Procedure

I

II

III

IV

Grade A

Grade B

Grade C

Grade D

MSA/LINX (9 Studies)

Asti, 2016

Prospective, Mar 2007 and Jul 2014, Single center, Italy.

LINX

44 ± 20

135

135 (1y), 118 (2y), 94 (3y), 59 (4y)

44/91

5.0 (7.0)

4.0 (5.5)

6

23.94 ± 4.54

NR

Bell, 2019

Prospective, RCT, Jul 2015 to Feb 2017, Multicenter, USA.

LINX

46 (21–76)

50 (Total), 47 (MSA Procedure)

47

31/19

29

28 ± 4.3

NR

10

9

Ganz, 2016

Prospective, Jan 2009 to Sep 2009 (Data From 2013), Multicenter, USA and Netherlands.

LINX

53 (18 – 75)

100

85

52/48

10 (1–40)

5 ( < 1–20)

0

28 (20 – 35)

NR

20

40

Louie, 2019

Prospective, Mar 2013 to Aug 2015, Multicenter, USA.

LINX

48.5 (19.7–71.6)

200

182

102/98

11.9 (0.5–50.0)

8.5 (0.5–30.0)

27.4 (18–39)

NR

36

11

2

1

Reynolds, 2016

Retrospective, Jan 2010 to Jun 2013, Multicenter, USA.

NR

53

52

48

33/20

16

35

26

NR

50

Riegler, 2015

Prospective, As of July 2013, Multicenter, Austria, Germany, Italy, UK.

LINX

46.6 ± 13.9

202

202

125/77

8.7 ± 7.8

6.3 ± 5.4

2

174

25.7 ± 3.8

NR

65

19

1

1

Schwameis, 2018

Retrospective, Mar 2012 to Sep OR Nov 2017, Single center, Austria.

LINX

45 (IQR 38–58)

68

62

46/22

52

25 (IQR 22–29)

15 (12–16)

Smith, 2014

Prospective, Oct 2011 and Jun 2013, Single center, USA.

LINX

53.7 (18–86)

66

65

28/38

3

44

26.0 (17.6–34.1)

NR

Warren, 2016

Retrospective, Apr 2007 to Dec 2014, Multicenter, USA.

LINX

54 (42–64)

201

169

105/96

18

55

7

19

42

32

32

NR

18

13

4

2

TIF (15 Studies)

Raza, 2018

Retrospective, Nov 2016 to May 2018, Single Center, USA.

EsophyX

51 (25–69)

34

34

14/20

NR

NA

Toomey, 2014

Prospective – Case-controlled study, 2010 to 2013, Single center, USA.

EsophyX

68 (61 ± 14.7)

20

20

7/13.

11 (13 ± 14.0)

3

25 (25 ± 2.3)

NA

Hunter, 2015

Prospective – RCT, Jun 2011 to Sep 2013, Multicenter, USA.

EsophyX2

52 (22 – 74)

87

87

47/40

10 (0.6 – 37)

9 (1 – 30)

60

4

57

25

27.1 (20.3 – 35.5)

23 (13–37)

10

7

Rinsma, 2014

Prospective, 2008 to 2012, Single center, Netherlands.

EsophyX2

41 (23–66)

15

15

11/4.

 > 6 m

9

1

7

5

2

26.2 ± 1.1

3

4

1

Wilson, 2014

Prospective, Jan 2010 to Feb 2011, Multicenter, USA.

EsophyX2

53 (18 – 75)

100

96

35/65

9 (1 – 35)

9 (1 – 15)

75

5

65

12

0

18.0 to 35.1

12 to 20

Bell, 2014

Prospective, Jan 2010 to Apr 2011, Multicenter, USA.

EsophyX2

53.1 (13.4)

127

100

41/86

10 ( +/-6.9)

8.3 ( +/-5.9)

6

NR

83

8

82

15

0

26.8 ± 4.3

20 (11–27)

18

45

6

0

Barnes, 2011

Retrospective, Nov 2008 to Dec 2009, Multicenter, USA.

EsophyX2

60 (21–87)

124

110

29/81

9 (1–35)

8 (1–25)

4

0

70

0

89

21

0

27.5 (19.0–47.9)

12–20

42

20

2

0

Ebright, 2017

Retrospective, Feb 2009 to Apr 2012, single center, USA

EsophyX2

48 (22–84)

80

41

41/39

NR

NR

23

1

9

18

8

Hakansson, 2015

Prospective RCT, Jan 2011 to Jan 2013, Multicenter, Sweden, Belgium, France.

EsophyX

41 (21–67)

22

21

8/14.

10 (2–25)

6 (2–20)

17

0

4

11

26.6 (18.6–33.9)

21 (16–36)

5

1

Hoppo, 2010

Prospective, Apr 2008 to Jul 2009, Multicenter, USA and Australia.

EsophyX

48.2 (26–81)

19

19

11/8

4

24.6 (19.6–29.4)

Petersen, 2012

Prospective, Mar 2009 to Aug 2010, Single center, USA.

EsophyX

47 (19 – 62)

22

19

6/17.

2

3

0 (Preoperative), 20 (Postoperative)

13 (Preoperative), 2 (Postoperative)

7 (Preoperative), 0 (Postoperative)

3 (Preoperative), 0 (Postoperative)

29 (20 – 43)

Stefanidis, 2017

Prospective, Dec 2008 to Feb 2012, Single center, Greece.

EsophyX

36 (23–55)

45

44

29/16

5 (1–24)

3 (1–20)

45

26.2 (18.3–34.9)

12–18

14

19

Testoni, 2019

Retrospective, Jan 2007 to Dec 2012, Single center, Italy.

EsophyX

45 ± 16

50

45 (2 & 3y), 34 (5y), 24 (7y), 12 (10y)

35/15

28

3

34

12

1

22 ± 3

12 ± 4

10/11

1/11

Trad, 2018

Prospective, Randomized, Aug 2012, Multicenter, USA.

EsophyX2

51.5 (10.3)

63

44

27/33

11.2 (9.8)

8.6 (6.5)

1

NR

5

32

28.5 (3.7)

21 ± 4

Witteman, 2015

Prospective – RCT, 2008 to 2011, Multicenter, Netherlands and USA.

EsophyX2

42.4 ± 13.3

60

53 (6 m); 45 (12 m)

38/22

4.5 (0.05–18.95)

42

3

29

15

3

26 ± 3.7

18 (7–26)

10

9

GERD, gastroesophageal reflux disease; PPI, proton pump inhibitor; GEJ, gastroesophageal junction; BMI, body mass index; MSA, magnetic sphincter augmentation; LOS, length of stay; AE, adverse event; GERD-HRQL, Gastroesophageal Reflux Disease-Health Related Quality of Life; RCT, randomized clinical trial; NR, not reported; NA, not applicable

Table 1b

Study details – Outcomes

Clinical Success

Technical Success

Clinical Success

Clinical Success

Post-Procedure Off PPI

Operative Time (mins) (range)

Maximum Follow Up (months)

Length of Stay (Days)

Adverse Events

Post procedure dysphagia

GERD-HRQL

Patient Satisfaction

No regurgitation

MSA/LINX (9 Studies)

Asti, 2016

59/135

135/135

NR

NR

NR

42 ± 34

44

2

0

NR

Bell, 2019

38/47

47/47

NR

37/47 (RDQ)

43/47

NR

6

NR

1

15

Ganz, 2016

70/84

100/100

70/84

NR

74/85 (3y)

36 (7 – 125)

60

1

0

4

Louie, 2019

169/200

200/200

NR

112/123 (FSQ)

159/182

NR

12

1

0

30

Reynolds, 2016

NR

52/52

43/52

NR

41/48

66 ± 23

12

0.7 ± 0.4

0

22

Riegler, 2015

NR

NR

NR

111/117 (FSQ)

165/202

NR

12

NR

1

14

Schwameis, 2018

62/62

68/68

59/62 (AS)

44/46

54/62

27 (11–55)

13 (4.2–45)

1

0

2

Smith, 2014

NR

66/66

60/65

NR

54/65

NR

5.8 (1 – 18.6)

0.75

0

4

Warren, 2016

169/201

201/201

NR

NR

150/169

60

12

0.54

1

1

TIF (15 Studies)

Raza, 2018

34/34

34/34

NR

NR

NR

42.7±8.3

NR

1

0

None

Toomey, 2014

NR

NR

13/20

NR

NR

71 ± 18.4

NR

1 ± 1.1

0

NR

Hunter, 2015

NR

NR

NR

58/87 (RDQ)

NR

49 (21–119)

6

1

5

2

Rinsma, 2014

NR

NR

12/15

NR

10/15

NR

6

NR

0

0

Wilson, 2014

62/85

100/100

82/96

46/58 (Regurgitation Score)

74/96

NR

12

1

1

2

Bell, 2014

63/96

127/127

63/102 (Diss/Satis/Neutral)

62/88 (Regurgitation Score)

69/98

46 (18 – 90)

24

1–2

0

0

Barnes, 2011

88/110

123/124

79/110 (Diss/Satis/Neutral)

81/94 (Regurgitation Score)

102/110

45 (21–122)

7 (5–17)

1

Epigastric pain 62n (50 % of patients), left shoulder pain 19n (15 %), sore throat 5n (4 %), nausea 1n (1 %), pneumonia 1n (1.24 %)

0

Ebright, 2017

NR

80/80

NR

NR

15/39

75 (36–180)

24 (6–68)

1 (± 1.4)

6 degraded wrap, 5 urinary retention, 1fever, 1ieus, 1 aspiration pneumonia

NR

Hakansson, 2015

NR

22/22

NR

NR

13/22

69 (34–133)

6

1

4 dysphagia, 4 bloating, 2 flatulence, 10 post op pain, 1 vomiting

4

Hoppo, 2010

14/19

19/19

8/19 (Good/Poor)

9/19 (Symptom)

5/19

98.3 (50–193)

10.8 (4–19)

1 (1–3)

10 heartburn , regurgitation 10, dysphagia 1, and atypical symptoms 3

1

Petersen, 2012

NR

20/22

NR

10/17 (Symptom)

8/19

--

6.7

1 (0–2)

3 nausea, 4 bloating

3

Stefanidis, 2017

44/44

44/45

39/44 (Satis/Diss)

NR

32/44

60 (45–100)

59 (36–75)

3 (2–5)

1 pneumothorax, 1 hematemesis, epigastric pain 39, pharynx irritation 22

NR

Testoni, 2019

12/12

49/51

NR

NR

5/12

69 ± 19 (Data from 2015)

120

NR

1 pneumothorax

NR

Trad, 2018

31/44

63/63

NR

37/43 (RDQ)

12/19

38 (20–68)

60

NR

0

NR

Witteman, 2015

20/37

60/60

NR

NR

28/37

33.4 (17–75)

6

NR

Pneumoperitoneum (1), Pneumonia (3), Epigastric Pain (1)

NR

GERD, gastroesophageal reflux disease; PPI, proton pump inhibitor; GEJ, gastroesophageal junction; BMI, body mass index; MSA, magnetic sphincter augmentation; LOS, length of stay; AE, adverse event; GERD-HRQL, Gastroesophageal Reflux Disease-Health Related Quality of Life; RCT, randomized clinical trial; NR, not reported; NA, not applicable

Table 2

Study details: pre-procedure and post-procedure patient scores.

GERD-HRQL (Max f/u)

DeMeester score (Max f/u)

GERSS score

RSI score

Pre-procedure

Post-procedure

Pre-procedure

Post-procedure

Pre-procedure

Post-procedure

Pre-procedure

Post-procedure

MSA/LINX (9 Studies)

Asti, 2016

21.00 (9.00)

0 (4)

31.4 (25.3)

--

--

--

--

--

Bell, 2019

23.5 ± 10.1 {On PPI} // 31.6 ± 10.4 {Off PPI}

6

40.3 (28.1–53.0) (47)

--

--

--

--

--

Ganz, 2016

--

--

36.6 (16.3 – 83.8)

13.5 (1y)

--

--

--

--

Louie, 2019

26.0 ± 6.5

4.0 ± 9.7

33.4 [8.7, 113.0]

12.0 [0.2, 59.7]

--

--

--

--

Reynolds, 2016

17

4 ± 6

--

--

--

--

--

--

Riegler, 2015

20

3

--

--

--

--

--

--

Schwameis, 2018

24 (16–30)

3 (IQR 0–6)

--

--

--

--

--

--

Smith, 2014

26

6

32.3 (1.4 – 67)

--

--

--

--

--

Warren, 2016

21 (15–25)

3

34 (21–51)

--

--

--

--

--

TIF (15 Studies)

Raza, 2018

31.8±11.4

3.2±2.8

--

--

--

--

--

--

Toomey, 2014

--

--

35 (63 ± 60.6)

---

--

--

--

--

Hunter, 2015

25 (0 – 41) {On PPI} // 29 (347) {Off PPI}

--

33.6

23.9

22 (3 – 54) {On PPI} // 30 (5 – 60) {Off PPI}

--

--

--

Rinsma, 2014

27.5 ± 1.8

13.2 ± 2.4

--

--

--

--

--

--

Wilson, 2014

26 (0 – 47)

15 (0 – 44)

--

--

26 (2–60)

4 (0–54)

20 (0–41)

5 (0–44)

Bell, 2014

26 (10–47)

6 (0–36)

34.4 (32.4)

17.2 (10.8) {24m}

35 (19–60)

5 (0–48)

24 (14–41)

6 (0–3)

Barnes, 2011

28 (0–45)

2 (0–35)

-

-

46 (8–60)

0 (0–12)

29 (3–45)

4 (0–30)

Ebright, 2017

22

10

-

-

--

--

--

--

Hakansson, 2015

--

--

-

--

--

--

--

--

Hoppo, 2010

--

--

--

--

--

--

--

--

Petersen, 2012

--

--

32.5 (14.2– 99.1)

19.3 (0.3 – 76.9)

--

--

--

--

Stefanidis, 2017

27 (2–45)

4 (0–26)

--

--

--

--

--

--

Testoni, 2019

20 ± 13 (ON PPI), 46 ± 19 (OFF PPI)

9.5 ± 6.1

22 ± 12 (Data from 2015)

19 ± 20 (24 m) (Data from 2015)

--

--

--

--

Trad, 2018

27 (4–48)

4 (0–33)

--

--

--

--

22.2

6.3

Witteman, 2015

27.1 (8.4)

10.3 (7.8) (12m}

--

--

--

--

--

--

GERD-HRQL, Gastroesophageal Reflux Disease-Health Related Quality of Life; GERSS, Gastroesophageal Reflux Symptom Score; RSI, Reflux Symptom Index; PPI, proton pump inhibitor.


#

Characteristics and quality of included studies

In the MSA cohort, six studies [26] [29] [30] [40] [41] [42] were prospective and three [22] [43] [44] were retrospective, whereas in the TIF2 cohort, 11 studies were prospective [23] [25] [27] [28] [31] [45] [46] [47] [48] [49] [50] and four were retrospective [24] [51] [52] [53]. There were no TIF or MSA studies based on population data. Based on the New-Castle Ottawa scoring system, all nine MSA studies [22] [26] [29] [30] [40] [41] [42] [43] [44] were considered to be of high quality, 12 TIF studies were of high quality, and three TIF studies [46] [49] [51] were of medium quality. There were no low-quality studies.


#

Meta-analysis outcomes

Clinical success (measure of improvement in GERD HRQL score)

The pooled rate of clinical success with MSA was 80.4 % (95 % CI: 66–89.6) and with TIF2 was 77.7 % (95 % CI 64.1–87.2). The rates were not statistically significantly different ([Fig. 1]). The pooled rate of clinical success with MSA in ≤ 12 months follow-up (3 studies) was 83.3 % (95 % CI 65.3–93); I2 = 0 and in > 12 months follow-up was 75.9 % (95 % CI 50.8–90.5). The pooled rate of clinical success with TIF2 in ≤ 12 months (4 studies) was 71.2 % (95 % CI 57.3–82); I2 = 67 and in > 12 months (4 studies) was 76.1 % (95 % CI 59.6–87.3); I2 = 70. The rates were comparable.

Zoom Image
Fig. 1 Forest plot of clinical success (GERD-HRQL).

#

Clinical success (Overall patient satisfaction reported at follow up)

The pooled rate of clinical success with MSA was 86.3 % (95 % CI 74.8–93.1) and with TIF2 was 72.5 % (95 % CI 61.6–81.3). The rates were not statistically significantly different ([Fig. 2]).

Zoom Image
Fig. 2 Forest plot of clinical success (patient satisfaction).

#

Clinical success (Improvement in post procedure regurgitation symptoms at follow up)

The pooled rate of clinical success with MSA was 91.1 % (95 % CI 83.8–95.3) and with TIF2 was 73.1 % (95 % CI 62.5–81.7). The difference between the cohorts was statistically significant (P = 0.002) ([Fig. 3]).

Zoom Image
Fig. 3 Forest plot of clinical success (regurgitation).

#

Patients off PPI

The pooled proportion of patients off PPI therapy with MSA was 86.5 % (95 % CI 80.4–91) and with TIF2 was 64.4 % (95 % CI 55–72.8). Based on sub-group comparison MSA seemed to be significantly superior to TIF2 (P = 0.001) ([Fig. 4]).

Zoom Image
Fig. 4 Forest plot of patients off PPI therapy at follow-up.

#

Technical success

The pooled rate of technical success for MSA was 98.8 % (95 % CI 95.6–99.7) and for TIF2 was 98.5 % (95 % CI 95.7–99.5) (Supplementary Fig. 2).


#

Post-procedure dysphagia

The pooled rate of dysphagia with MSA was 9.1 % (95 % CI 4.2–18.8) and with TIF was 3.6 % (95 % CI 1.4–8.8). Although greater, the P value was non-significant (P = 0.05) (Supplementary Fig. 3).


#
#

Meta-regression analysis

Patient variables that were amenable to meta-regression analysis were as follows: Patient BMI and presence of hiatal hernia. BMI did not have any statistically significant effect on outcomes of TIF2 (P = 0.7) or MSA (P = 0.1). Also, the presence of hiatal hernia did not affect clinical success in either of the two study cohorts (Supplementary Fig. 4).


#

Validation of meta-analysis results

Sensitivity analysis

To assess whether any one study had a dominant effect on the meta-analysis, we excluded one study at a time and analyzed its effect on the main summary estimate. In this analysis, no single study significantly affected the outcome or the heterogeneity.


#

Heterogeneity

We assessed dispersion of the calculated rates using the confidence interval (CI) and I2 percentage values. The CI gives an idea of the range of the dispersion and I2 tells us what proportion of the dispersion is true vs chance [36]. The PIs are reported with the pooled rates in [Table 3]. Overall, considerable heterogeneity was noted in the analysis.

Table 3

Pooled rates of outcomes with CI and PI.

Pooled rates (95 % confidence interval) I2 heterogeneity %

MSA

TIF2

Clinical success

(GERD HRQL)

80.4 % (66–89.6);

6 studies (P = 0.8)

I2 = 94; PI: 23 to 98

 ≤ 12 months (3 studies)

83.3 % (65.3–93); I2 = 0

 > 12 months (3 studies)

75.9 % (50.8–90.5); I2 = 95

77.7 % (64.1–87.2)

9 studies

I2 = 68; PI: 48 to 95

 ≤ 12 months (4 studies)

71.2 % (57.3–82); I2 = 67

 > 12 months (4 studies)

76.1 % (59.6–87.3); I2 = 70

Clinical success

(patient satisfaction)

86.3 % (74.8–93.1);

3 studies (P = 0.06)

I2 = 2; PI: 61 to 96

72.5 % (61.6–81.3)

7 studies

I2 = 75; PI: 41 to 92

Clinical success

(no regurgitation)

91.1 % (83.8–95.3);

4 studies (P = 0.002)

I2 = 68; PI: 56 to 99

73.1 % (62.5–81.7);

7 studies

I2 = 68; PI: 44 to 91

Patients off PPI at follow-up

86.5 % (80.4–91)

8 studies (P = 0.001)

I2 = 0; PI: 78 to 92

64.4 % (55–72.8)

12 studies

I2 = 80; PI: 28 to 91

Technical success

98.8 % (95.6–99.7);

11 studies (P = 0.5)

I2 = 81; PI: 38 to 99

98.5 % (95.7–99.5);

8 studies

I2 = 0; PI: 90 to 99

Postoperative dysphagia

9.1 % (4.2–18.8)

8 studies (P = 0.05)

I2 = 89; PI: 1 to 50

3.6 % (1.4–8.8)

9 studies

I2 = 58; PI: 1 to 34

MSA, magnetic sphincter augmentation; TIF, trans-oral fundoplication; GERD, gastroesophageal reflux disease; HRQL, health related quality of life; PI, 95 % prediction intervals; PPI, proton pump inhibitor.


#

Publication bias

Based on visual inspection of the funnel plot as well as quantitative measurement that used the Egger regression test, there was evidence of publication bias (Supplementary Fig. 4, Eggers 2-tailed P = 0.01). Further statistical analysis using the fail-Safe N test and Duval and Tweedie’s Trim and Fill test revealed that the reported pooled results would not be significantly affected by the unpublished studies.


#
#
#

Discussion

Magnetic sphincter augmentation (MSA) and trans-oral incisionless fundoplication (TIF2) demonstrate comparable efficacy when comparing improvement in cumulative GERD-HRQL scores at follow-up. When comparing outcomes in terms of, post procedure regurgitation and percentage of patients off PPI therapy at follow up, MSA significantly outperforms TIF2. To the best of our knowledge, this study is the first quantitative review presenting a comparison between MSA and TIF2 in the treatment of refractory GERD.

The Gastroesophageal Reflux Disease-Health Related Quality-of-Life (GERD-HRQL) scale is a disease-specific instrument, developed to help overcome the variability in evaluating response to treatments for GERD and has been validated as the only significant predictor of patient satisfaction. A total score is computed for the heartburn symptoms questions based on a scale of 0 to 5, where 0 = no symptoms and 5 = incapacitation to do daily activities. A reduction of the score by 50 % or greater is considered to indicate a successful intervention [54]. In our analysis, based on improvement in GERD-HRQL at longest follow up, pooled clinical success was 80.4 % with MSA and 77.7 % with TIF2 (P = 0.8).

In recent years, there has been a growing body of literature raising concerns about long term PPI use [5]. We found that the pooled percentage of patients who were able to completely stop PPI therapy after MSA was 91.3 % compared to only 63.8 % after undergoing TIF2 (P = 0.001). Given the variability in outcome reporting in the literature, we also factored in overall patient satisfaction that was comparable, and improvement in post-operative regurgitation as measures of clinical success, which was better with MSA.

TIF is associated with fewer postoperative adverse effects such as gas bloating and dysphagia when compared with surgical fundoplication [55]. Dysphagia is thought to be prominent post MSA implantation but generally resolves within a few weeks [41]. We compared post procedure dysphagia between the two study cohorts and demonstrated a non-significant greater rate with MSA (9.1 % vs 3.6 %; P = 0.05). Follow up period ranged from 5.8 to 60 months in the MSA cohort, and 6 to 120 months in the TIF2 cohort.

With regards to adverse events, LINX device was removed in 24 patients, most commonly due to postoperative GERD, chest pain and dysphagia. In the TIF2 cohort, postoperative epigastric pain was the most common adverse event, reported in 114 patients (0.1 %). Pneumothorax in two patients, pneumoperitoneum in 1 patient and postoperative pneumonia was reported in four patients. Ebright et al [52] reported six patients with a degraded wrap, five with urinary retention and one each with postoperative fever, ileus, and aspiration. Overall, there were 229 adverse events reported in the TIF2 cohort of patients.

In 2017, Huang et al, conducted a systematic review and meta-analysis of five randomized trials and 13 prospective studies and found that PPI use after TIF increased over time (albeit at a reduced dose) and the overall patient satisfaction rate was 69 % at 6-month follow-up [2]. This study included results from the first and second (current) generation of TIF devices. While the first-generation device (TIF1) was commercially introduced in 2007, it was not until 2009 that the second generation of the device, TIF2, was made available. Our study included only those patients who underwent the TIF2 procedure.

In 2019, Guidozzi et al [56] conducted a systematic review and meta-analysis comparing MSA to laparoscopic fundoplication and concluded that the former achieves good GERD symptomatic control similar to that of fundoplication, with 3.3 % of patients requiring device removal. Our study is the first in literature to compare MSA and TIF2 based on similar patient reported outcomes.

The strengths of this review are as follows: systematic literature search with well-defined inclusion criteria, careful exclusion of redundant studies, inclusion of good quality studies with detailed extraction of data and rigorous evaluation of study quality. We calculated not only pooled subjective outcomes based on patient reported clinical symptoms but also objective outcomes i. e. percentage of patients successfully able to stop PPI therapy. We utilized meta-regression analysis to evaluate the effect of pre procedural BMI and presence of hiatal hernia on clinical outcomes. Finally, we excluded all TIF2 and MSA studies where patients underwent concurrent hiatal hernia (HH) repair. This is important because patients undergoing HH repair surgery have improved GERD-HRQL scores and can have post procedural side effects such as dysphagia [57].

There are limitations to this study as well, most of which are inherent to any meta-analysis. Our analysis had studies that were retrospective in nature contributing to selection bias. We compared outcomes based on improvement in GERD-HRQL score and used ≥ 50 % improvement in score as a measure of clinical success. While this was the most consistently reported outcome in the included studies, it is possible that studies reporting < 50 % improvement in GERD-HRQL score for either MSA or TIF2 were missed. While we were able to quantify the proportion of patients who discontinued PPI therapy at follow up, we were unable to objectively study this data in terms of post procedural pH testing data.

Manometry and impedance data were not consistently reported in all studies. Although we report meta-regression analysis, it is important to note that meta-regression analysis is considered a weak statistic in the analysis of patient variables on pooled outcomes. Our analysis has the limitation of non-causal comparison and heterogeneity. Nevertheless, this study is the best available data in literature thus far with respect to the clinical outcomes of MSA and TIF2 in patients with refractory GERD.


#

Conclusion

In conclusion, MSA and TIF2 appear to have similar efficacy based on post procedure GERD-HRQL scores however MSA seems to significantly outperform TIF2 in terms of patient reported outcomes with long term follow up. Overall, 91.3 % of patients were able to stop PPI therapy after MSA as compared to 63.8 % after TIF2. Future well-conducted trials with adequate follow-up time are warranted to establish or refute our findings.


#
#

Competing interests

Dr. Adler is a consultant for Boston Scientific.

Acknowledgments

The authors thank Dana Gerberi, MLIS, Librarian, Mayo Clinic Libraries, for help with the systematic literature search.

Supplementary material

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Corresponding author

Douglas G. Adler MD, FACG, AGAF, FASGE
Professor of Medicine
Director of Therapeutic Endoscopy
Director, GI fellowship Program
Gastroenterology and Hepatology
University of Utah School of Medicine
Huntsman Cancer Center
30N 1900E 4R118
Salt Lake City, Utah 84132
United States   
Fax: +1-801-581-8007   

Publication History

Received: 21 July 2020

Accepted: 09 December 2020

Article published online:
13 April 2021

© 2021. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution-NonDerivative-NonCommercial License, permitting copying and reproduction so long as the original work is given appropriate credit. Contents may not be used for commercial purposes, or adapted, remixed, transformed or built upon. (https://creativecommons.org/licenses/by-nc-nd/4.0/)

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  • References

  • 1 Kethman WHM. New approaches to gastroesophageal reflux disease. J Gastrointest Surg 2017; 21: 1544-1552
  • 2 Huang X, Chen S, Zhao H. et al. Efficacy of transoral incisionless fundoplication (TIF) for the treatment of GERD: a systematic review with meta-analysis. Surg Endosc 2017; 31: 1032-1044
  • 3 Moraes-Filho JP. Refractory gastroesophageal reflux disease. Arq Gastroenterol 2012; 49: 296-301
  • 4 Kahrilas PJ, Howden CW, Hughes N. Response of regurgitation to proton pump inhibitor therapy in clinical trials of gastroesophageal reflux disease. Am J Gastroenterol 2011; 106: 1419-1425 quiz 1426
  • 5 Sheen E, Triadafilopoulos G. Adverse effects of long-term proton pump inhibitor therapy. Dig Dis Sci 2011; 56: 931-950
  • 6 Hunter JG, Trus TL, Branum GD. et al. A physiologic approach to laparoscopic fundoplication for gastroesophageal reflux disease. Ann Surg 1996; 223: 673-685 discussion 685-677
  • 7 Minjarez RC, Jobe BA. Surgical therapy for gastroesophageal reflux disease. GI Motility online 2006; DOI: 10.1038/gimo56.
  • 8 Singhal T, Balakrishnan S, Hussain A. et al. Management of complications after laparoscopic Nissen's fundoplication: a surgeon's perspective. Ann Surg Innov Res 2009; 3: 1
  • 9 Smith CD, McClusky DA, Rajad MA. et al. When fundoplication fails: redo?. Ann Surg 2005; 241: 861-869 discussion 869–871
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Fig. 1 Forest plot of clinical success (GERD-HRQL).
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Fig. 2 Forest plot of clinical success (patient satisfaction).
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Fig. 3 Forest plot of clinical success (regurgitation).
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Fig. 4 Forest plot of patients off PPI therapy at follow-up.