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CC BY-NC-ND 4.0 · Endosc Int Open 2023; 11(10): E952-E962
DOI: 10.1055/a-2125-0161
Original article

Adherence to guideline recommendations for Barrett's esophagus (BE) surveillance endoscopies: Effects of dedicated BE endoscopy lists

I.N. Beaufort
1   Department of Gastroenterology and Hepatology, Sint Antonius Ziekenhuis, Nieuwegein, Netherlands (Ringgold ID: RIN6028)
2   Department of Gastroenterology and Hepatology, University Medical Centre Utrecht, Utrecht, Netherlands (Ringgold ID: RIN8124)
,
A.N. Milne
3   Department of Pathology, Sint Antonius Ziekenhuis, Nieuwegein, Netherlands (Ringgold ID: RIN6028)
,
Y.A. Alderlieste
4   Department of Gastroenterology and Hepatology, Beatrixziekenhuis, Gorinchem, Netherlands (Ringgold ID: RIN159172)
,
J.E. Baars
5   Department of Gastroenterology and Hepatology, Amphia Ziekenhuis, Breda, Netherlands (Ringgold ID: RIN89411)
,
P.R. Bos
6   Department of Gastroenterology and Hepatology, Ziekenhuis Gelderse Vallei, Ede, Netherlands (Ringgold ID: RIN3096)
,
J.P.W. Burger
7   Department of Gastroenterology and Hepatology, Rijnstate, Arnhem, Netherlands (Ringgold ID: RIN1322)
,
N.C.M. van Heel
8   Department of Gastroenterology and Hepatology, Gelre Ziekenhuizen, Apeldoorn, Netherlands (Ringgold ID: RIN72485)
,
M. Ledeboer
9   Department of Gastroenterology and Hepatology, Deventer Ziekenhuis, Deventer, Netherlands (Ringgold ID: RIN2976)
,
R.J. Lieverse
10   Department of Gastroenterology and Hepatology, Ziekenhuisgroep Twente, Almelo, Netherlands (Ringgold ID: RIN1154)
,
P.C. van de Meeberg
11   Department of Gastroenterology and Hepatology, Slingeland Ziekenhuis, Doetinchem, Netherlands (Ringgold ID: RIN2987)
,
J.J. Meeuse
12   Department of Internal Medicine, Ziekenhuis Rivierenland, Tiel, Netherlands (Ringgold ID: RIN36694)
,
A.H.J. Naber
13   Department of Gastroenterology and Hepatology, Tergooi MC, Hilversum, Netherlands (Ringgold ID: RIN3913)
,
H.J.M. Pullens
14   Department of Gastroenterology and Hepatology, Meander MC, Amersfoort, Netherlands (Ringgold ID: RIN1170)
,
R.C.H. Scheffer
15   Department of Gastroenterology and Hepatology, Jeroen Bosch Ziekenhuis, 's-Hertogenbosch, Netherlands (Ringgold ID: RIN10233)
,
M. Sikkema
16   Department of Gastroenterology and Hepatology, Elisabeth-TweeSteden Ziekenhuis, Tilburg, Netherlands (Ringgold ID: RIN7898)
,
R.E. Verbeek
17   Department of Gastroenterology and Hepatology, Groene Hart Ziekenhuis, Gouda, Netherlands (Ringgold ID: RIN3573)
,
M.A.M.T. Verhagen
18   Department of Gastroenterology and Hepatology, Diakonessenhuis Utrecht Zeist Doorn, Utrecht, Netherlands (Ringgold ID: RIN8118)
,
W. van de Vrie
19   Department of Gastroenterology and Hepatology, Albert Schweitzer Ziekenhuis, Dordrecht, Netherlands (Ringgold ID: RIN2998)
,
M. Willems
20   Department of Gastroenterology and Hepatology, Ziekenhuis Sint Jansdal, Harderwijk, Netherlands (Ringgold ID: RIN72496)
,
B.L.A.M. Weusten
1   Department of Gastroenterology and Hepatology, Sint Antonius Ziekenhuis, Nieuwegein, Netherlands (Ringgold ID: RIN6028)
2   Department of Gastroenterology and Hepatology, University Medical Centre Utrecht, Utrecht, Netherlands (Ringgold ID: RIN8124)
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Abstract

Background and study aims For non-dysplastic Barrett’s Esophagus (BE) patients, guidelines recommend endoscopic surveillance every 3 to 5 years with four-quadrant random biopsies every 2 cm of BE length. Adherence to these guidelines is low in clinical practice. Pooling BE surveillance endoscopies on dedicated endoscopy lists performed by dedicated endoscopists could possibly enhance guideline adherence, detection of visible lesions, and dysplasia detection rates (DDRs).

Patients and methods Data were used from the ACID-study (Netherlands Trial Registry NL8214), a prospective trial of BE surveillance in the Netherlands. BE patients with known or previously treated dysplasia were excluded. Guideline adherence, detection of visible lesions, and DDRs were compared for patients on dedicated and general endoscopy lists.

Results A total of 1,244 patients were included, 318 on dedicated lists and 926 on general lists. Endoscopies on dedicated lists showed significantly higher adherence to the random biopsy protocol (85% vs. 66%, P <0.01) and recommended surveillance intervals (60% vs. 47%, P <0.01) compared to general lists. Detection of visible lesions (8.8% vs. 8.1%, P=0.79) and DDRs were not significantly different (6.9% and 6.6%, P=0.94). None (0.0%) of the patients scheduled on dedicated lists and 10 (1.1%) on general lists were diagnosed with esophageal adenocarcinoma (P=0.07). In multivariable analysis, dedicated lists were significantly associated with biopsy protocol adherence and adherence to surveillance interval recommendations with odds ratios of 4.45 (95% confidence interval [CI] 2.07–9.57) and 1.64 (95% CI 1.03–2.61), respectively.

Conclusions Dedicated endoscopy lists are associated with better adherence to the random biopsy protocol and surveillance interval recommendations.


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Keywords

Endoscopy Upper GI Tract - Reflux disease - Barrett's and adenocarcinoma - Diagnosis and imaging (inc chromoendoscopy, NBI, iSCAN, FICE, CLE)

Introduction

Over the past decades, the incidence of esophageal adenocarcinoma (EAC) has increased in Western populations [1] [2]. Prognosis of patients with EAC depends largely on the stage of diagnosis. The overall 5-year survival rate is poor at approximately 20% [3]. Yet, mortality rates are exceedingly low in EAC for which endoscopic therapy is considered feasible [4] [5].

Barrett’s esophagus (BE) is an established risk factor for EAC. To detect EAC in an early and treatable stage, periodic surveillance endoscopies are advised for BE patients [6] [7] [8] [9] [10]. In the Netherlands, the majority of BE surveillance endoscopies are performed in community hospitals. These patients are solely non-dysplastic BE (NDBE) patients, since BE patients with known or suspected dysplasia and EAC are referred to tertiary referral centers for treatment and follow-up.

According to current international guidelines, adequate NDBE surveillance endoscopies encompass minute inspection of the BE segment with targeted biopsies in the presence of visible lesions [6] [7] [8] [9] [10]. In addition, random four-quadrant biopsies should be obtained every 2 cm of BE length [6] [7] [8] [9] [10]. In the absence of dysplasia, surveillance endoscopies should be repeated at 5- and 3-year intervals, for BE segments of 1 to 3 cm and 3 to 10 cm, respectively [6] [10]. Patients with extremely long-segment NDBE (i.e. ≥10 cm) should be referred to a tertiary referral center for follow-up [8] [10].

It is well recognized that, in daily practice, adherence to the guideline recommendations of four-quadrant random biopsies and surveillance intervals recommendations is low. Although previous studies have shown increased dysplasia detection rates in case of adherence to the random biopsy protocol [8] [11] [12], a recent meta-analysis reported that an adequate number of biopsies is obtained in only half of BE surveillance endoscopies [13]. Similarly, adherence to recommendations on the BE surveillance intervals was estimated to be only 55% in the same meta-analysis [13].

The organization of BE surveillance care may differ per community hospital. In most hospitals in the Netherlands, incidental BE surveillance endoscopies are performed on general endoscopy lists, mixed with endoscopies for other indications, and performed by all endoscopists. Yet in some hospitals, BE surveillance endoscopies are clustered on a dedicated endoscopy list. These dedicated BE endoscopy lists are performed by few experienced endoscopists with special interest in BE.

This clustering of BE surveillance endoscopies on dedicated endoscopy lists could potentially improve BE surveillance care by increased guideline awareness and adherence. In addition, it could lead to enhanced recognition of dysplastic lesions, because few endoscopists gain considerable experience in performing BE surveillance endoscopies. The aim of our study, therefore, was to evaluate both adherence to the random biopsy protocol and to the recommended surveillance intervals in BE surveillance endoscopies performed in community hospitals, and to compare these measures between surveillance endoscopies performed on dedicated BE lists and those scheduled on general endoscopy lists. We also wished to compare detection rates of visible lesions and dysplasia between these two groups.


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Patients and methods

For the current study, we used data from the ACID-study database (Netherlands Trial Registry NL8214), an ongoing prospective study on BE surveillance. The ACID-study is a stepped wedge cluster randomized study that evaluates the added value of acetic acid chromoendoscopy for the detection of dysplasia and EAC in BE patients. In total 18, Dutch community hospitals participate in this study, with data entry since October 2019. The study was approved by the medical ethics review boards of all participating hospitals. All patients provided written consent for data collection.

General endoscopy lists and dedicated BE lists

In 15 of the 18 participating community hospitals, BE surveillance was organized such that surveillance endoscopies were scheduled on general endoscopy lists performed by general endoscopists, including residents in training. General lists included incidental BE surveillance procedures mixed with endoscopies for other indications. The performing endoscopist was not necessarily the same endoscopist deciding on future surveillance intervals based on the histopathological results. The time allocation for each surveillance procedure varied among hospitals and ranged between 15 and 30 minutes.

In the other three community hospitals, BE surveillance was performed on dedicated BE lists. Dedicated BE lists were defined as endoscopy lists in which multiple BE surveillance endoscopies are clustered and consistently performed by the same endoscopists (i.e. one or two endoscopists per hospital). These dedicated endoscopists also decided on subsequent surveillance intervals based on histopathological findings. Similar to general endoscopy lists, time allocated to each surveillance endoscopy varied between 15 and 30 minutes. There was no standardized protocol for use of sedation. None of the dedicated BE endoscopists received additional training or guidance with respect to BE surveillance compared to general endoscopists. More importantly, none of the dedicated BE endoscopists were expert endoscopists in the treatment of neoplastic BE.

Dedicated BE endoscopy lists were not initiated for the purpose of the current study and no changes were made in routine clinical care.


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Study population

We included patients with a biopsy-proven diagnosis of BE (i.e. Prague C&M classification [14] ≥C0M1 with intestinal metaplasia on histological examination) who were scheduled for regular BE surveillance. There was no upper limit for BE length to be considered eligible. We excluded: 1) patients previously treated for dysplasia or EAC; 2) patients with an intensified follow-up regimen due to previous dysplasia; 3) patients newly diagnosed with BE; and 4) patients in whom other factors precluded an adequate surveillance endoscopy, i.e. esophageal varices or reflux esophagitis grade C or D precluding endoscopic biopsies, or massive food retention during endoscopy.

Patients were categorized into two groups, depending on the way BE surveillance was organized in the respective hospitals. If BE surveillance endoscopies were scheduled on mixed, general endoscopy lists conducted by general endoscopists, patients were classified as “general endoscopy list patients”; if the BE care was organized with BE surveillance endoscopies clustered on dedicated endoscopy lists performed by dedicated endoscopists, patients were classified as “dedicated endoscopy list patients”.


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Histopathological assessment

Biopsies obtained during surveillance endoscopies were routinely assessed by community hospital pathologists in all participating centers. Expertise and training of pathologists regarding BE neoplasia was similar for hospitals with general and dedicated lists. To ensure correct diagnosis of dysplasia, all biopsies with suspected dysplasia of any grade, or reported as “indefinite for dysplasia,” were centrally reviewed by at least one additional pathologist with expertise in gastrointestinal pathology.


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Outcomes and definitions

Primary outcomes were adherence to the random four-quadrant biopsy protocol and to the recommended surveillance intervals.

Random four-quadrant biopsy protocol adherence was defined as a minimum of four random biopsies every 2 cm of circumferential BE extent, plus at least one biopsy every 2 cm of BE tongues. The actual number of random biopsies taken during the endoscopy was compared to the minimum number of biopsies that should be obtained according to our definition. A ratio <1 was defined as non-adherent; a ratio ≥1 as adherent. In the presence of visible lesions, targeted biopsies and random biopsies were summed.

We considered surveillance intervals as adequate if surveillance endoscopies were performed within 4.5 to 5.5 years for BE segments <3 cm, and within 2.5 to 3.5 years for long-segment BE (≥3 cm), as in accordance with current guidelines [6] [10]. Non-adherence to surveillance intervals was defined as any interval outside this range. Patients with BE segments ≥10 cm who received follow-up endoscopies were classified as adherent if the endoscopy was performed between 1.5 and 3.5 years. We chose this wider range as no specific guideline recommendations are available for these patients. Patients with a previous diagnosis of “indefinite for dysplasia” were excluded from the analyses concerning surveillance intervals.

Secondary outcomes were detection rates of visible lesions and dysplasia. The presence of visible lesions was defined as the presence of one or more visible lesions per patient. Dysplasia was defined as the presence of low-grade dysplasia (LGD), high-grade dysplasia (HGD) or EAC diagnosed on targeted or random biopsies, reviewed by expert gastrointestinal pathologists.


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Data collection

Study data were collected and managed using REDCap electronic data capture tools hosted at St. Antonius Hospital [15] [16].

Data were registered prospectively from October 2019 to July 2022. Information about each patient was entered in the database only once. Data on follow-up endoscopies were not registered.

All data collection was done by one research fellow in a standardized format. Variables with missing data or outliers were manually checked to ensure data are accurate.


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Statistical analysis

Means and standard deviations were used to describe normally distributed baseline characteristics. Medians with 25th and 75th percentiles (p25-p75) were reported for variables with a skewed distribution.

Differences in outcome variables between study groups were compared by Chi-square tests, Fisher’s exact tests, Wilcoxon rank sum tests or Mood’s Median tests where appropriate. In addition, guideline adherence and dysplasia detection rates were compared by using a hierarchical mixed-effects logistic regression model with a random intercept per hospital, to correctly account for both multilevel data and for possible confounders. In any case, we included the use of acetic acid chromoendoscopy as a covariate for the multivariable analyses evaluating dysplasia detection and adherence to the random biopsy protocol, since this could be a possible confounder introduced by study design.

Because data were collected prospectively and in a standardized format, the percentage of missing data was expected to be a small proportion of the dataset. Missing values were omitted from the analyses if the missing rate was 5% or less.


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Results

Patients

Of the 1,413 patients included in the ACID-study between October 2019 and July 2022, 1,244 patients met our inclusion criteria ([Fig. 1]). A total of 318 included patients (26%) were scheduled on dedicated BE lists; 926 patients (74%) were scheduled on general endoscopy lists.

Zoom Image
Fig. 1 Patient inclusion.

Characteristics of the included patients and their endoscopies are shown in [Table 1]. Mean age, gender, and median BE length were comparable. Endoscopies on dedicated lists had a shorter total procedure time compared to endoscopies on general lists, with a median of 6 minutes (p25–p75 5–9) versus 7 minutes (p25–p75 5–10), respectively (P <0.01). Acetic acid chromoendoscopy was used in 33% of endoscopies on dedicated endoscopy lists versus 7% on general lists (P <0.01). While sedation was more often administered on dedicated lists (74% versus 57% on general lists, P <0.01), high-definition endoscopes were more frequently used on general lists (99% versus 96% on dedicated lists, P <0.01).

Table 1 Patient characteristics and endoscopic data.

Total cohort
n=1244

Dedicated BE lists
n=318

General lists
n=926

P value
(dedicated vs. general)

ASA, American Society of Anesthesiologists; BE, Barrett’s esophagus; HD, high-definition; SD, standard deviation.

Demographics

Age, years, mean (SD)

65 (10)

65 (11)

65 (10)

0.34

Female sex, n (%)

385 (30.9)

90 (28.3)

295 (31.9)

0.27

ASA-score, n (%)

0.06

  • 1

192 (15.4)

45 (14.2)

147 (15.9)

  • 2

912 (73.3)

250 (78.6)

662 (71.5)

  • 3

80 (6.4)

12 (3.8)

68 (7.3)

  • 4

1 (0.1)

0 (0.0)

1 (0.1)

59 (4.7%) missing

11 (3.5%) missing

48 (5.2%) missing

Time since BE diagnosis, years, median (p25–p75)

8 (4–12)

8 (4–12)

8 (4–12)

0.96

8 (0.6%) missing

1 (0.3%) missing

7 (0.8%) missing

Surveillance endoscopies

BE length, cm, median (p25–p75)

  • Prague C

1 (0–4)

1 (0–3)

1 (0–4)

0.09

  • Prague M

3 (2–5)

3 (2–5)

3 (2–5)

0.33

Esophagitis, n (%)

0.80

Total

96 (7.7)

23 (7.2)

73 (7.9)

  • A

41 (3.3)

9 (2.8)

32 (3.5)

  • B

42 (3.4)

13 (4.1)

29 (3.1)

  • C

4 (0.3)

1 (0.3)

3 (0.3)

  • Grade not reported

9 (0.7)

0 (0.0)

9 (1.0)

Sedation, n (%)

<0.01

Midazolam/fentanyl

761 (61.2)

234 (73.6)

527 (56.9)

Propofol

85 (6.8)

26 (8.2)

59 (6.4)

No sedation

398 (32.0)

58 (18.2)

340 (36.7)

HD endoscopy, n (%)

1218 (97.9)

305 (95.9)

913 (98.6)

<0.01

13 (1.0%) missing

3 (0.9%) missing

10 (1.1%) missing

Acetic acid chromoendoscopy, n (%)

169 (13.6)

104 (32.7)

65 (7.0)

<0.01

Duration endoscopy, min, median (p25–p75)

7 (5–10)

6 (5–9)

7 (5–10)

<0.01

41 (3.3%) missing

3 (0.9%) missing

38 (4.1%) missing


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Guideline adherence

Adherence to the random four-quadrant biopsy protocol was significantly better in endoscopies scheduled on dedicated BE lists, 85% versus 66% on general endoscopy lists (P <0.01) ([Table 2]). In both groups, adherence to the random biopsy protocol decreased significantly (P <0.01 for trend) with increasing BE length ([Fig. 2]).

Table 2 Adherence to the random biopsy protocol and surveillance interval recommendations.

Outcomes

Total cohort
n=1244

Dedicated BE lists
n=318

General lists
n=926

P value (dedicated vs. general)

*Adherence was defined as four-quadrant random biopsies every 2 cm of circumferential BE extent, plus at least one biopsy every 2 cm of BE tongues. In the presence of visible lesions, target biopsies and random biopsies were summed.

Adherence was defined as 3 years +/- 6 months, 5 years +/-6 months for BE length <3 cm and ≥3 to 10 cm respectively, and between 1.5 and 3.5 years for BE ≥10 cm.

40 cases with missing values and 16 cases with ‘indefinite for dysplasia’ as previous histology result were excluded from this analysis.

BE, Barrett’s esophagus; SD, standard deviation.

Biopsies per 2 cm maximum BE length, mean (SD)

3.8 (1.8)

4.3 (1.8)

3.6 (1.7)

<0.01

Adherence to random biopsy protocol*, n (%)

878 (70.6)

270 (84.9)

608 (65.7)

<0.01

Adherence to surveillance intervals†‡ , n (%)

BE length <3 cm

  • Adherence

138 (36.8)

51 (52.0)

87 (31.4)

<0.01

  • Too short

191 (50.9)

41 (41.8)

150 (54.2)

0.048

  • Too long

46 (12.3)

6 (6.1)

40 (14.4)

0.048

BE length ≥3 cm

  • Adherence

459 (56.4)

136 (63.8)

323 (53.8)

0.01

  • Too short

111 (13.7)

26 (12.2)

85 (14.2)

0.55

  • Too long

243 (29.9)

51 (23.9)

192 (32.0)

0.03
Zoom Image
Fig. 2 Adherence to random 4Q biopsy protocol stratified by maximum BE length. Adherence was defined as four quadrant random biopsies every 2 cm of circumferential BE extent, plus at least one biopsy every 2 cm of BE tongues. In the presence of visible lesions, target biopsies and random biopsies were totalled.

[Fig. 3] shows the number of years since the previous endoscopy for both general lists and dedicated BE lists patients, stratified by BE length. For patients with BE segments <3 cm, the median time since the previous endoscopy was 4.8 years (p25–p75 3.3–5.0 years) and 4.3 years (p25–p75 3.2–5.2 years) for dedicated BE lists and general lists, respectively (P=0.049). For patients with BE length ≥3 cm, median time since the previous endoscopy was similar for dedicated lists (3.2 years [p25–p75 2.9–3.4]) and general lists (3.2 years [p25–p75 3.0–3.7]) (P=0.39).

Zoom Image
Fig. 3 Boxplots showing the time since previous endoscopy in years for general endoscopy lists and for dedicated BE endoscopy lists, stratified by BE length. Within each box, the median time since previous endoscopy is indicated by the horizontal black line. The box encompasses the 25th and 75th percentiles of each group, whereas the vertical lines represent the values within 1.5 of the interquartile range of the 25th and the 75th percentiles. The dots denote outliers that fall above the upper fence or below the lower fence.

Adherence to surveillance intervals according to our predefined definition was higher in endoscopies on dedicated lists (60% vs. 47%, P <0.01). Higher adherence rates were seen in endoscopies on dedicated lists compared to general lists for both BE segments <3 cm (52% vs. 31%, P <0.01) and BE segments ≥3 cm (64% vs. 54%, P=0.01) ([Table 2]). In BE segments <3 cm, non-adherence to surveillance interval recommendations mainly resulted from surveillance intervals that were too short, in both dedicated and general lists ([Fig. 4]). In BE segments ≥3 cm, surveillance intervals that were too long were the main reason of non-adherence in both groups. The median deviations from our predefined upper limit and lower limit of adequate surveillance intervals are presented in Supplementary Table 1.

Zoom Image
Fig. 4 Adherence to surveillance interval recommendations for general and dedicated BE endoscopy lists. Surveillance intervals were considered adequate if surveillance endoscopies were performed within 4.5 to 5.5 years for BE segments <3 cm, within 2.5 to 3.5 years for BE segments ≥3 cm to 10 cm, and within 1.5 to 3.5 years for BE segments ≥10 cm.

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Visible lesions and dysplasia detection

The prevalence of visible lesions detected during endoscopy was similar in both groups, with visible lesions detected in 28 patients (8.8%) and 75 patients (8.1%) on dedicated and general lists, respectively (P=0.79) ([Table 3]). The visible lesions were found to be dysplastic in two of 28 patients on dedicated lists (7.1%) and 20 of 75 patients (27%) on general endoscopy lists (P=0.06).

Table 3 Detection of visible lesions and dysplasia detection rates in BE patients scheduled on dedicated and general lists.

Outcomes

Total cohort
n=1244

Dedicated BE lists
n=318

General lists
n=926

P value
(dedicated vs. general)

*Highest grade of dysplasia per patient.

BE, Barrett’s esophagus; EAC, esophageal adenocarcinoma; HGD, high-grade dysplasia; LGD, low-grade dysplasia; NA, not applicable.

Visible lesions, n (%)

103 (8.3)

28 (8.8)

75 (8.1)

0.79

Dysplastic visible lesions, n (%)

20/103 (19.4)

2/28 (7.1)

20/75 (26.7)

0.06

Dysplasia*, n (%)

Total

83 (6.7)

22 (6.9)

61 (6.6)

0.94

  • LGD

57 (4.6)

19 (6.0)

38 (4.1)

0.22

  • HGD

16 (1.3)

3 (0.9)

13 (1.4)

0.77

  • EAC

10 (0.8)

0 (0.0)

10 (1.1)

0.07

Dysplasia detection on targeted biopsy*, n (%)

Total

21/83 (25.3)

1/22 (4.5)

20/61 (32.8)

0.01

  • LGD

2/57 (3.5)

0/19 (0.0)

2/38 (5.3)

0.55

  • HGD

10/16 (62.5)

1/3 (33.3)

9/13 (69.2)

0.52

  • EAC

9/10 (90.0)

NA

9/10 (90.0)

NA

Overall, dysplasia detection rates were comparable between groups (6.9% vs. 6.6%, P=0.94) ([Table 3]). On dedicated lists, most dysplastic cases were LGD. There were no diagnoses of EAC (0.0%) among dedicated list patients, whereas a total of 10 EACs (1.1%) were found during endoscopies on general lists (P=0.07). Characteristics of the previous surveillance endoscopy of all EAC and HGD cases are listed in [Table 4]. Median BE length of patients with EAC and HGD was C3M5 (p25–p75 C2–6 and M3–7). For these patients, median time since previous endoscopy for BE segments <3 cm was 5.2 years (p25–p75 2.7–5.2) and for BE segments ≥3 cm 3.3 years (p25–p75 3.0–3.9). Two patients had their last surveillance endoscopy >15 years prior to their diagnosis of EAC. In 13 patients (54%) with a diagnosis of HGD or EAC, an insufficient number of biopsies was obtained during the previous endoscopy. All three patients (100%) diagnosed with HGD on dedicated lists could be treated by endoscopic resection with or without ablative therapy of the remaining BE segment, whereas this was the case for 16 of 23 patients (70%) diagnosed with HGD or EAC on general lists.

Table 4 Characteristics of the previous BE surveillance endoscopy prior to HGD- or EAC diagnosis

Patient

Endoscopy list

Diagnosis

Previous BE length (Prague classification)

Surveillance interval (years)

Previous histology

No. biopsies previous endoscopy

Adherence biopsy protocol during previous endoscopy*

Final histological diagnosis

Final treatment

*Adherence was defined as four-quadrant random biopsies every 2 cm of circumferential BE extent, plus at least one biopsy every 2 cm of BE tongues. In the presence of visible lesions, target biopsies and random biopsies were summed.

Poorly differentiated.

Refrained from additional surgery, patient preference.

§No additional treatment due to patient comorbidities and/or patient preference.

BE, Barrett’s esophagus; EAC, esophageal adenocarcinoma; EMR, endoscopic mucosal resection; ESD, endoscopic submucosal dissection; HGD, high-grade dysplasia; LGD, low-grade dysplasia; NR, not reported; NA, not applicable; T1Am2, invasion in lamina propria; T1Am3, invasion in muscularis mucosae; T1Bsm2, submucosal invasion > 500 µm and ≤ 1000µm; T1Bsm3, submucosal invasion > 1000 µm; T1BN1, submucosal cancer with regional lymph node metastasis; T2N1, cancer invading the muscularis propria with regional lymph node metastasis; T3N0M1, cancer invading the adventitia with distant metastasis.

1

General list

EAC

C0M4

3.1

No dysplasia

4

Yes

T1BN1

Surgery

2

General list

EAC

C8M8

3.3

No dysplasia

11

No

T1Am3

ESD + Surgery

3

General list

EAC

C3M3

3.2

No dysplasia

3

No

T1Am2

EMR + RFA

4

General list

EAC

C7M9

4.9

No dysplasia

3

No

T1Am3

ESD

5

General list

EAC

NR

16.0

NR

3

NR

T1Am3

EMR + RFA

6

General list

EAC

NR

15.9

NR

NR

NR

T2N1

Surgery

7

General list

EAC

C1M4

3.4

No dysplasia

4

No

T1Am3

EMR + cryoablation

8

General list

EAC

C2M3

4.1

No dysplasia

5

Yes

T1Bsm2

ESD + Surgery

9

General list

EAC

C1M2

5.3

No dysplasia

4

No

LGD

EMR + cryoablation

10

General list

EAC

C2M5

3.1

No dysplasia

12

Yes

T3N0M1

Palliative chemoradiation

11

General list

HGD

C4M4

5.2

Indefinite

4

No

T1Am2

EMR + RFA

12

General list

HGD

C0M2

0.3

Indefinite

1

Yes

HGD

EMR

13

General list

HGD

C6M6

3.0

No dysplasia

9

No

NA

NA§

14

General list

HGD

C6M7

3.2

No dysplasia

12

No

T1Am3

EMR + RFA

15

General list

HGD

C2M2

5.2

No dysplasia

5

Yes

HGD

EMR + RFA

16

General list

HGD

C8M8

2.3

No dysplasia

6

No

T1Bsm3

EMR

17

General list

HGD

C3M5

3.3

No dysplasia

9

Yes

HGD

EMR + cryoablation

18

General list

HGD

C1M7

1.4

No dysplasia

12

Yes

NA

NA§

19

General list

HGD

C5M6

4.2

No dysplasia

12

Yes

T1Am3

EMR

20

General list

HGD

C6M7

3.2

No dysplasia

14

Yes

T1Am3

EMR + RFA

21

General list

HGD

C12M16

0.6

No dysplasia

6

No

T1Am3

EMR

22

General list

HGD

C3M6

3.5

No dysplasia

4

No

T1Am3

EMR + Surgery

23

General list

HGD

C3M5

2.3

No dysplasia

5

No

T1Am3

EMR + RFA

24

Dedicated BE list

HGD

C3M4

3.4

No dysplasia

12

Yes

HGD

EMR + RFA

25

Dedicated BE list

HGD

C2M4

0.7

No dysplasia

9

Yes

No dysplasia

EMR

26

Dedicated BE list

HGD

C4M6

3.7

No dysplasia

5

No

T1Am3

EMR + RFA

Of all 83 patients with dysplastic changes, 21 patients (25%) were diagnosed with targeted biopsies rather than random biopsies. Patients with dysplasia on general endoscopy lists were more often diagnosed using targeted biopsies compared to patients with dysplasia on dedicated lists (20/61 patients [33%] vs. one of 22 patients [5%], P <0.01). Nine of 10 EAC patients (90%) on general endoscopy lists presented with visible lesions. There were no significant differences in the detection of LGD or HGD with targeted biopsies between the two groups ([Table 3]).


#

Logistic regression analyses

In both univariable and multivariable analysis, dedicated BE endoscopy lists were significantly associated with random biopsy protocol adherence, with odds ratios (ORs) of 3.43 (95% confidence interval [CI] 1.77–7.21) and 4.45 (95% CI 2.07–9.57), respectively ([Table 5]). Dedicated BE endoscopy lists were also significantly associated with adherence to recommended surveillance intervals (OR 1.75, 95% CI 1.12–2.78 for univariable analysis and OR 1.64, 95% CI 1.03–2.61 for multivariable analysis). ORs for total dysplasia detection in relation to dedicated BE lists were 1.05 (95% CI 0.61–1.82) and 0.96 (95% CI 0.53–1.70) and did not reach statistical significance. Finally, the lower odds of HGD/EAC detection on dedicated BE endoscopy lists were not statistically significant in univariable and multivariable analysis.

Table 5 Crude and multivariable analyses for random biopsy protocol adherence, surveillance interval adherence and dysplasia detection in relation to dedicated BE endoscopy lists using general endoscopy lists as reference group.

Univariable OR

95% CI

Multivariable OR

95% CI

*Corrected for age, gender, ASA-score, time since baseline endoscopy, use of sedation, BE length, use of acetic acid chromoendoscopy, visible abnormalities.

Corrected for age, gender, ASA-score, time since baseline endoscopy.

Corrected for age, gender, ASA-score, time since baseline endoscopy, use of sedation, BE length, use of acetic acid chromoendoscopy.

ASA, American Society of Anesthesiologists; BE, Barrett’s esophagus; CI, confidence interval; EAC, esophageal adenocarcinoma; HGD, high-grade dysplasia; OR, odds ratio.

Random biopsy protocol adherence

General endoscopy lists

1.00

ref

1.00

ref

Dedicated BE lists

3.43

1.77–7.21

4.45*

2.07–9.57

Surveillance interval adherence

General endoscopy lists

1.00

ref

1.00

ref

Dedicated BE lists

1.75

1.12–2.78

1.64

1.03–2.61

Total dysplasia detection

General endoscopy lists

1.00

ref

1.00

ref

Dedicated BE lists

1.05

0.61–1.82

0.96

0.53–1.70

HGD/EAC detection

General endoscopy lists

1.00

ref

1.00

ref

Dedicated BE lists

0.37

0.09–1.17

0.49

0.14–1.76

#
#

Discussion

In this prospective, multicenter study, we compared NDBE surveillance endoscopies scheduled on dedicated and general endoscopy lists in a community setting, rather than tertiary referral centers. We found that adherence to the random four-quadrant biopsy protocol and to the recommended surveillance intervals is significantly better in endoscopies on dedicated BE lists compared to those on general lists. The prevalence of visible lesions and total dysplasia detection rates did not differ between the two groups. Of all detected dysplasia, detection by targeted biopsies was higher on general endoscopy lists. Finally, although not significant, our study suggests that HGD and EAC are more often diagnosed in patients scheduled on general endoscopy lists.

Previous studies evaluating the introduction of dedicated BE endoscopy lists also demonstrated higher rates of random biopsy protocol adherence in dedicated BE endoscopies [17] [18]. Ooi et al. compared biopsy protocol adherence of endoscopies on dedicated lists with a historical cohort of general lists [17]. The authors showed increased adherence from 10% to 77%. Britton et al. also demonstrated increased biopsy protocol adherence on dedicated lists, 72% versus 42% on general lists [18]. While these results indicate an improvement in BE surveillance care, both studies were prospective intervention studies rather than observational cohort studies, thereby potentially enlarging clinical effects. Moreover, the studies lacked correction for confounding factors in the analyses. Our study, therefore, is a better representation of clinical practice by reflecting the long-term improvement in BE surveillance care on dedicated endoscopy lists. We also present effect estimates based on multivariable regression analyses in order to correct for possible confounding.

Our study did not reveal a higher prevalence of visible lesions, nor a higher dysplasia detection rate on dedicated lists compared to general lists. Similar to our study, Britton et al. did not find a significant difference in dysplasia detection between dedicated and general lists [18]. Ooi et al. demonstrated a dysplasia detection rate of 18% on dedicated BE lists, compared to 8% in the historical cohort of endoscopies on general lists [17]. Importantly, one of the participating hospitals in the study of Ooi et al. was a tertiary referral center for dysplastic BE patients, which may have introduced some degree of selection bias. Moreover, in that study, procedure time was prolonged in dedicated lists, and endoscopists received training in lesion detection from a BE expert endoscopist.

Although we did not demonstrate a higher overall dysplasia detection rate, we did find a trend toward higher HGD- and EAC detection rates on general endoscopy lists, which appears counterintuitive. Because our study has a non-randomized design, this could be attributed to selection bias. However, all included patients with known or previously treated dysplasia were excluded from analysis. We also excluded the initial (diagnostic) BE endoscopies, as these endoscopies are believed to contain a higher prevalence of dysplasia and EAC [19] [20] and are mostly scheduled on general endoscopy lists. In an attempt to explain the higher HGD and EAC detection rates on general endoscopy lists, we evaluated the histology results, surveillance interval, and number of random biopsies obtained on the previous surveillance endoscopy. In the majority of cases, an insufficient number of biopsies was obtained or the time interval since the previous endoscopy was too long according to the surveillance interval recommendations. The former finding suggests sampling error on the previous endoscopy. The enhanced adherence to the random biopsy protocol in combination with the higher rates of adherence to the surveillance interval recommendations on dedicated endoscopy lists could account for the frequent diagnoses of LGD rather than HGD and EAC. In this way, dedicated endoscopy lists could prevent the progression to HGD and EAC by early LGD diagnosis and subsequent referral for treatment and follow-up.

Surprisingly, we found that BE patients with dysplasia were more often diagnosed with targeted biopsy on general lists compared to dedicated lists, while one could hypothesize that this would be vice versa. One explanation could be that endoscopists on general lists inspect the BE segment more thoroughly. However, there was a higher prevalence of advanced dysplastic cases (i.e. HGD and EAC) in general lists compared to dedicated lists. Nine of 10 EAC cases on general lists presented as obvious visible lesions and were subsequently detected on targeted biopsy. We know from previous studies that HGD and EAC frequently present as visible lesions, while LGD is often invisible [5] [21]. Therefore, the higher proportion of targeted dysplasia detection on general lists could also be explained by the difference in degree of dysplasia.

Although better in dedicated lists than in general lists, adherence to the random biopsy protocol in general was poor, especially in long-segment BE. This is even more remarkable because all endoscopists were aware of the fact that they participated in a prospective study and that their performance would be analyzed. This, taken together with the tendency toward too short surveillance intervals, especially for the short BE segments, underscores the need for education of general endoscopists to improve guideline adherence.

To the best of our knowledge, this is the largest prospective study evaluating the effect of dedicated BE endoscopy lists on BE surveillance care. Data were collected prospectively in a standardized format, with few missing data. Other strengths of our study include revision of all dysplastic cases by expert pathologists, and the multivariable mixed-model analyses to account for multilevel data and possible confounding factors.

The main limitation of this study is its non-randomized design. We aimed to compensate for this shortcoming by our well-considered inclusion and exclusion criteria and multivariable analyses in which we could correct for possible confounding factors. In addition, our definition of random four-quadrant biopsy protocol adherence could be seen as lenient, as according to our definition of only one biopsy per 2 cm of BE tongues as sufficient. We deemed this as the absolute minimum number of biopsies that should be obtained. Next, in some hospitals, the BE surveillance intervals could unintentionally have been prolonged due to the COVID-19 pandemic in which surveillance endoscopies were postponed, although this applied to endoscopic services in all participating hospitals irrespective of type of endoscopy list (i.e. general list or dedicated list). Finally, no reliable data were available on the use of virtual chromoendoscopy. However, if virtual chromoendoscopy were used more regularly during dedicated BE endoscopies, that should be seen as a characteristic of dedicated BE lists rather than confounding.


#

Conclusions

Given the results of our study, we can conclude that clustering of BE surveillance endoscopies on dedicated lists has the potential to improve BE surveillance care by enhancing guideline adherence. Improved adherence to the four-quadrant biopsy protocol and surveillance interval recommendations might potentially result in less oversurveillance of short-segment BE and increased detection of dysplasia at an early stage.


#
#

Conflict of Interest

The authors declare that they have no conflict of interest.

Supporting information

  • References

  • 1 Bollschweiler E, Wolfgarten E, Gutschow C. et al. Demographic variations in the rising incidence of esophageal adenocarcinoma in white males. Cancer 2001; 92: 549-555 (PMID: 11505399)
    CrossrefPubMedGoogle Scholar
  • 2 Derakhshan MH, Arnold M, Brewster DH. et al. Worldwide inverse association between gastric cancer and esophageal adenocarcinoma suggesting a common environmental factor exerting opposing effects. Am J Gastroenterol 2016; 111: 228-239
    CrossrefPubMedGoogle Scholar
  • 3 Then EO, Lopez M, Saleem S. et al. Esophageal cancer: an updated surveillance epidemiology and end results database analysis. World J Oncol 2020; 11: 55-64 DOI: 10.14740/wjon1254. (PMID: 32284773)
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  • 4 Phoa KN, Pouw RE, Bisschops R. et al. Multimodality endoscopic eradication for neoplastic Barrett oesophagus: results of a European multicentre study (EURO-II). Gut 2016; 65: 555-562 DOI: 10.1136/gutjnl-2015-309298. (PMID: 25731874)
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  • 5 Van Munster S, Nieuwenhuis E, Weusten BLAM. et al. Long-term outcomes after endoscopic treatment for Barrett’s neoplasia with radiofrequency ablation ± endoscopic resection: Results from the national Dutch database in a 10-year period. Gut 2022; 71: 265-276
    CrossrefPubMedGoogle Scholar
  • 6 Shaheen NJ, Falk GW, Iyer PG. et al. Diagnosis and management of Barrett’s esophagus: an updated ACG guideline. Am J Gastroenterol 2022; 117: 559-587 DOI: 10.14309/ajg.0000000000001680. (PMID: 35354777)
    CrossrefPubMedGoogle Scholar
  • 7 Qumseya B, Sultan S, Bain P. et al. ASGE guideline on screening and surveillance of Barrett’s esophagus. Gastrointest Endosc 2019; 90: 335-359 DOI: 10.1016/j.gie.2019.05.012. (PMID: 31439127)
    CrossrefPubMedGoogle Scholar
  • 8 Fitzgerald RC, Di Pietro M, Ragunath K. et al. British Society of Gastroenterology guidelines on the diagnosis and management of Barrett’s oesophagus. Gut 2014; 63: 7-42 DOI: 10.1136/gutjnl-2013-305372. (PMID: 24165758)
    CrossrefPubMedGoogle Scholar
  • 9 Spechler S, Sharma P, Rhonda F. et al. American gastroenterological association medical position statement on the management of Barrett’s esophagus. Gastroenterology 2011; 140: 1084-1091
    CrossrefPubMedGoogle Scholar
  • 10 Weusten BLAM, Bisschops R, Coron E. et al. Endoscopic management of Barrett’s esophagus: European Society of Gastrointestinal Endoscopy (ESGE) position statement. Endoscopy 2017; 49: 191-198
    Artikel in Thieme ConnectPubMedGoogle Scholar
  • 11 Abrams JA, Kapel RC, Lindberg GM. et al. Adherence to biopsy guidelines for Barrett’s esophagus surveillance in the community setting in the United States. Clin Gastroenterol Hepatol 2009; 7: 736-742 DOI: 10.1016/j.cgh.2008.12.027. (PMID: 19268726)
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  • 12 Abela JE, Going JJ, Mackenzie JF. et al. Systematic four-quadrant biopsy detects Barrett’s dysplasia in more patients than nonsystematic biopsy. Am J Gastroenterol 2008; 850-855
    CrossrefPubMedGoogle Scholar
  • 13 Roumans CAM, Van Der Bogt RD, Steyerberg EW. et al. Adherence to recommendations of Barrett’s esophagus surveillance guidelines: A systematic review and meta-analysis. Endoscopy 2020; 52: 17-28 DOI: 10.1055/a-0995-0134. (PMID: 31529444)
    Artikel in Thieme ConnectPubMedGoogle Scholar
  • 14 Sharma P, Dent J, Armstrong D. et al. The development and validation of an endoscopic grading system for Barrett’s esophagus: The Prague C & M criteria. Gastroenterology 2006; 131: 1392-1399 DOI: 10.1053/j.gastro.2006.08.032. (PMID: 17101315)
    CrossrefPubMedGoogle Scholar
  • 15 Harris PA, Taylor R, Thielke R. et al. Research electronic data capture (REDCap) - a metadata-driven methodology and workflow process for providing translational research informatics support. J Biomed Inform 2009; 42: 377-381 DOI: 10.1016/j.jbi.2008.08.010. (PMID: 18929686)
    Google Scholar
  • 16 Harris PA, Taylor R, Minor BL. et al. The REDCap consortium: building an international community of software platform partners. J Biomed Inform 2019; 95: 103208 DOI: 10.1016/j.jbi.2019.103208. (PMID: 31078660)
    CrossrefPubMedGoogle Scholar
  • 17 Ooi J, Wilson P, Walker G. et al. Dedicated Barrett’s surveillance sessions managed by trained endoscopists improve dysplasia detection rate. Endoscopy 2017; 49: 524-528 DOI: 10.1055/s-0043-103410. (PMID: 28399610)
    Artikel in Thieme ConnectPubMedGoogle Scholar
  • 18 Britton J, Chatten K, Riley T. et al. Dedicated service improves the accuracy of Barrett’s oesophagus surveillance: A prospective comparative cohort study. Frontline Gastroenterol 2019; 10: 128-134 DOI: 10.1136/flgastro-2018-101019. (PMID: 31205652)
    CrossrefPubMedGoogle Scholar
  • 19 Desai M, Lieberman DA, Kennedy KF. et al. Increasing prevalence of high-grade dysplasia and adenocarcinoma on index endoscopy in Barrett’s esophagus over the past 2 decades: data from a multicenter U.S. consortium. . Gastrointest Endosc 2019; 89: 257-263.e3
    CrossrefPubMedGoogle Scholar
  • 20 Parasa S, Desai M, Vittal A. et al. Estimating neoplasia detection rate (NDR) in patients with Barrett’s oesophagus based on index endoscopy: A systematic review and meta-analysis. Gut 2019; 68: 2122-2128
    CrossrefPubMedGoogle Scholar
  • 21 Schölvinck DW, Van Der Meulen K, Bergman JJGHM. et al. Detection of lesions in dysplastic Barrett’s esophagus by community and expert endoscopists. Endoscopy 2017; 49: 113-120
    PubMedGoogle Scholar

Correspondence

I.N. Beaufort, MD
Department of Gastroenterology and Hepatology, Sint Antonius Ziekenhuis
Nieuwegein
Netherlands   

Publikationsverlauf

Eingereicht: 19. Januar 2023

Angenommen nach Revision: 19. Juni 2023

Artikel online veröffentlicht:
11. Oktober 2023

© 2023. 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/).

Georg Thieme Verlag KG
Rüdigerstraße 14, 70469 Stuttgart, Germany

  • References

  • 1 Bollschweiler E, Wolfgarten E, Gutschow C. et al. Demographic variations in the rising incidence of esophageal adenocarcinoma in white males. Cancer 2001; 92: 549-555 (PMID: 11505399)
    CrossrefPubMedGoogle Scholar
  • 2 Derakhshan MH, Arnold M, Brewster DH. et al. Worldwide inverse association between gastric cancer and esophageal adenocarcinoma suggesting a common environmental factor exerting opposing effects. Am J Gastroenterol 2016; 111: 228-239
    CrossrefPubMedGoogle Scholar
  • 3 Then EO, Lopez M, Saleem S. et al. Esophageal cancer: an updated surveillance epidemiology and end results database analysis. World J Oncol 2020; 11: 55-64 DOI: 10.14740/wjon1254. (PMID: 32284773)
    CrossrefPubMedGoogle Scholar
  • 4 Phoa KN, Pouw RE, Bisschops R. et al. Multimodality endoscopic eradication for neoplastic Barrett oesophagus: results of a European multicentre study (EURO-II). Gut 2016; 65: 555-562 DOI: 10.1136/gutjnl-2015-309298. (PMID: 25731874)
    CrossrefPubMedGoogle Scholar
  • 5 Van Munster S, Nieuwenhuis E, Weusten BLAM. et al. Long-term outcomes after endoscopic treatment for Barrett’s neoplasia with radiofrequency ablation ± endoscopic resection: Results from the national Dutch database in a 10-year period. Gut 2022; 71: 265-276
    CrossrefPubMedGoogle Scholar
  • 6 Shaheen NJ, Falk GW, Iyer PG. et al. Diagnosis and management of Barrett’s esophagus: an updated ACG guideline. Am J Gastroenterol 2022; 117: 559-587 DOI: 10.14309/ajg.0000000000001680. (PMID: 35354777)
    CrossrefPubMedGoogle Scholar
  • 7 Qumseya B, Sultan S, Bain P. et al. ASGE guideline on screening and surveillance of Barrett’s esophagus. Gastrointest Endosc 2019; 90: 335-359 DOI: 10.1016/j.gie.2019.05.012. (PMID: 31439127)
    CrossrefPubMedGoogle Scholar
  • 8 Fitzgerald RC, Di Pietro M, Ragunath K. et al. British Society of Gastroenterology guidelines on the diagnosis and management of Barrett’s oesophagus. Gut 2014; 63: 7-42 DOI: 10.1136/gutjnl-2013-305372. (PMID: 24165758)
    CrossrefPubMedGoogle Scholar
  • 9 Spechler S, Sharma P, Rhonda F. et al. American gastroenterological association medical position statement on the management of Barrett’s esophagus. Gastroenterology 2011; 140: 1084-1091
    CrossrefPubMedGoogle Scholar
  • 10 Weusten BLAM, Bisschops R, Coron E. et al. Endoscopic management of Barrett’s esophagus: European Society of Gastrointestinal Endoscopy (ESGE) position statement. Endoscopy 2017; 49: 191-198
    Artikel in Thieme ConnectPubMedGoogle Scholar
  • 11 Abrams JA, Kapel RC, Lindberg GM. et al. Adherence to biopsy guidelines for Barrett’s esophagus surveillance in the community setting in the United States. Clin Gastroenterol Hepatol 2009; 7: 736-742 DOI: 10.1016/j.cgh.2008.12.027. (PMID: 19268726)
    CrossrefPubMedGoogle Scholar
  • 12 Abela JE, Going JJ, Mackenzie JF. et al. Systematic four-quadrant biopsy detects Barrett’s dysplasia in more patients than nonsystematic biopsy. Am J Gastroenterol 2008; 850-855
    CrossrefPubMedGoogle Scholar
  • 13 Roumans CAM, Van Der Bogt RD, Steyerberg EW. et al. Adherence to recommendations of Barrett’s esophagus surveillance guidelines: A systematic review and meta-analysis. Endoscopy 2020; 52: 17-28 DOI: 10.1055/a-0995-0134. (PMID: 31529444)
    Artikel in Thieme ConnectPubMedGoogle Scholar
  • 14 Sharma P, Dent J, Armstrong D. et al. The development and validation of an endoscopic grading system for Barrett’s esophagus: The Prague C & M criteria. Gastroenterology 2006; 131: 1392-1399 DOI: 10.1053/j.gastro.2006.08.032. (PMID: 17101315)
    CrossrefPubMedGoogle Scholar
  • 15 Harris PA, Taylor R, Thielke R. et al. Research electronic data capture (REDCap) - a metadata-driven methodology and workflow process for providing translational research informatics support. J Biomed Inform 2009; 42: 377-381 DOI: 10.1016/j.jbi.2008.08.010. (PMID: 18929686)
    Google Scholar
  • 16 Harris PA, Taylor R, Minor BL. et al. The REDCap consortium: building an international community of software platform partners. J Biomed Inform 2019; 95: 103208 DOI: 10.1016/j.jbi.2019.103208. (PMID: 31078660)
    CrossrefPubMedGoogle Scholar
  • 17 Ooi J, Wilson P, Walker G. et al. Dedicated Barrett’s surveillance sessions managed by trained endoscopists improve dysplasia detection rate. Endoscopy 2017; 49: 524-528 DOI: 10.1055/s-0043-103410. (PMID: 28399610)
    Artikel in Thieme ConnectPubMedGoogle Scholar
  • 18 Britton J, Chatten K, Riley T. et al. Dedicated service improves the accuracy of Barrett’s oesophagus surveillance: A prospective comparative cohort study. Frontline Gastroenterol 2019; 10: 128-134 DOI: 10.1136/flgastro-2018-101019. (PMID: 31205652)
    CrossrefPubMedGoogle Scholar
  • 19 Desai M, Lieberman DA, Kennedy KF. et al. Increasing prevalence of high-grade dysplasia and adenocarcinoma on index endoscopy in Barrett’s esophagus over the past 2 decades: data from a multicenter U.S. consortium. . Gastrointest Endosc 2019; 89: 257-263.e3
    CrossrefPubMedGoogle Scholar
  • 20 Parasa S, Desai M, Vittal A. et al. Estimating neoplasia detection rate (NDR) in patients with Barrett’s oesophagus based on index endoscopy: A systematic review and meta-analysis. Gut 2019; 68: 2122-2128
    CrossrefPubMedGoogle Scholar
  • 21 Schölvinck DW, Van Der Meulen K, Bergman JJGHM. et al. Detection of lesions in dysplastic Barrett’s esophagus by community and expert endoscopists. Endoscopy 2017; 49: 113-120
    PubMedGoogle Scholar

   Lizenzen und Reprints
Zoom Image
Fig. 1 Patient inclusion.
Zoom Image
Fig. 2 Adherence to random 4Q biopsy protocol stratified by maximum BE length. Adherence was defined as four quadrant random biopsies every 2 cm of circumferential BE extent, plus at least one biopsy every 2 cm of BE tongues. In the presence of visible lesions, target biopsies and random biopsies were totalled.
Zoom Image
Fig. 3 Boxplots showing the time since previous endoscopy in years for general endoscopy lists and for dedicated BE endoscopy lists, stratified by BE length. Within each box, the median time since previous endoscopy is indicated by the horizontal black line. The box encompasses the 25th and 75th percentiles of each group, whereas the vertical lines represent the values within 1.5 of the interquartile range of the 25th and the 75th percentiles. The dots denote outliers that fall above the upper fence or below the lower fence.
Zoom Image
Fig. 4 Adherence to surveillance interval recommendations for general and dedicated BE endoscopy lists. Surveillance intervals were considered adequate if surveillance endoscopies were performed within 4.5 to 5.5 years for BE segments <3 cm, within 2.5 to 3.5 years for BE segments ≥3 cm to 10 cm, and within 1.5 to 3.5 years for BE segments ≥10 cm.