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Yong Chan Lee |
Professor of Medicine Director, Gastrointestinal Research Laboratory Veterans Affairs Medical Center, Univ. California San Francisco San Francisco, USA |
Jong Pil Im | Seoul National University College of Medicine, Seoul, Korea |
Robert S. Bresalier | University of Texas M. D. Anderson Cancer Center, Houston, USA |
Steven H. Itzkowitz | Mount Sinai Medical Center, NY, USA |
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Correspondence to: Shin Maeda
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Gut Liver 2021;15(6):799-810. https://doi.org/10.5009/gnl20242
Published online April 15, 2021, Published date November 15, 2021
Copyright © Gut and Liver.
Vonoprazan (VPZ), a new potassium-competitive acid blocker, has been approved and used for Helicobacter pylori eradication in Japan. To date, many studies, as well as several systematic reviews and meta-analyses (MAs), have compared VPZ-based 7-day triple therapy with proton pump inhibitor (PPI)-based therapy. An MA of randomized controlled trials (RCTs) comparing first-line VPZ- with PPI-based triple therapy, the latter featuring amoxicillin (AMPC) and clarithromycin (CAM), found that approximately 30% of patients hosted CAM-resistant H. pylori; however, the reliability was poor because of high heterogeneity and a risk of selection bias. VPZ-based triple therapy is superior to PPI-based triple therapy for patients with CAM-resistant H. pylori, but not for those with CAM-susceptible H. pylori. An MA of non-RCTs found that second-line VPZ-based triple therapies were slightly (~2.6%) better than PPI-based triple therapies (with AMPC and metronidazole). However, the reliability of that MA was also low because of selection bias, confounding variables and a risk of publication bias; in addition, it is difficult to generalize the results because of a lack of data on antibiotic resistance. VPZ-based triple therapy (involving AMPC and sitafloxacin) was more effective than PPI-based triple therapy in a third-line setting, but a confirmatory RCT is needed. Non-RCT studies indicated that VPZ-based triple therapy involving CAM and metronidazole may be promising. Any further RCTs must explore the antibiotic-resistance status when evaluating the possible superiority of a potassium-competitive acid blocker.
Keywords: Potassium-competitive acid blocker, Proton pump inhibitors, Helicobacter pylori, Treatment outcome, Drug resistance, microbial
VPZ is a new P-CAB (other P-CABs include SCH28080) that inhibits H+/K+ ATPases in a manner described as rapid (the intragastric pH increased to over 4.0 within 4 hours14), strong (the intragastric pH increased to over 5 and was maintained for 99% of the time when VPZ [20 mg] was given twice daily15), or stable (not affected by the CP2C19 genotype14,16). VPZ was the second P-CAB to be approved worldwide (revaprazan was approved first, in South Korea).
At pH >5,
SCH28080 is the prototype P-CAB that was developed in the 1980s. This drug is short-acting and was never approved. Linaprazan was found to be as effective as esomeprazole (40 mg) in patients with non-erosive reflux disease; however, its clinical development was later suspended.18 Revaprazan (a P-CAB) was approved in South Korea in 2005 for the treatment of gastroduodenal ulcers and gastritis. However, endoscopic submucosal dissection revealed that the drug was no more efficacious than 20 mg rabeprazole for treating ulcers.19 In 2018, a new P-CAB, tegoprazan, was approved for
P-CAB based data are mainly with VPZ based and in Japanese population. First-line VPZ based regimens compared to PPI based (Table 1), and second-line VPZ based regimens compared to PPI based (Table 2) are studies with Japanese population. In these studies, 7-day triple therapies are used. In Japan, 7-day first-line triple therapy consisting of VPZ or a PPI, AMPC, and CAM and 7-day second-line triple therapy consisting of VPZ or a PPI, AMPC, and MNZ are covered by national insurance. Esomeprazole, rabeprazole, lansoprazole, or omeprazole serves as the PPI. The approved doses are VPZ 20 mg bid (twice a day; 40 mg/day), esomeprazole 20 mg bid (40 mg/day), rabeprazole 10 mg bid (20 mg/day), omeprazole 20 mg bid (40 mg/day), AMPC 750 mg bid (1,500 mg/day), CAM 200 mg or 400 mg bid (400 mg/day or 800 mg/day), and MNZ 250 mg bid (500 mg/day).
Table 1 First-Line Vonoprazan-Based Compared to PPI-Based Eradication Regimen
First author (year) | Method | CAM susceptible | VPZ-based eradication regimen | PPI-based eradication regimen | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Regimen | ITT/FAS analysis | PP analysis | Regimen | ITT/FAS analysis | PP analysis | ||||||||||
No. | ER (95% CI), % | No. | ER (95% CI), % | No. | ER (95% CI), % | No. | ER (95% CI), % | ||||||||
Murakami (2016)9† | RCT | Sensitive | VPZ/AMPC/CAM | 205 | 97.6 (94.4–99.2)* | NA | NA | LPZ/AMPC/CAM | 185 | 97.3 (93.8–99.1)* | NA | NA | |||
Resistant | VPZ/AMPC/CAM | 100 | 82.0 (73.1–89.0)* | NA | NA | LPZ/AMPC/CAM | 115 | 40.0 (31.0–49.6)* | NA | NA | |||||
NA | VPZ/AMPC/CAM | 19 | 94.7 (74.0–99.9)* | NA | NA | LPZ/AMPC/CAM | 20 | 85.0 (62.1–96.8)* | NA | NA | |||||
Total | VPZ/AMPC/CAM | 324 | 92.6 (89.2–95.2)* | NA | NA | LPZ/AMPC/CAM | 320 | 75.9 (70.9–80.5)* | NA | NA | |||||
Noda (2016)26† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 44 | 100 (92.0–100) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 25 | 88.0 (68.8–97.5) | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 32 | 87.5 (71.0–96.5) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 13 | 53.8 (25.1–80.8) | |||||
NA | VPZ/AMPC/CAM | NA | NA | 70 | 84.3 (73.6–91.9) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 1,267 | 73.9 (71.4–76.2) | |||||
Total | VPZ/AMPC/CAM | NA | NA | 146 | 89.7 (87.9–91.3) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 1,305 | 73.9 (66.0–80.8) | |||||
Matsumoto (2016)27† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 57 | 100 (94.9–100) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 212 | 87.8 (82.5–91.8) | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 97 | 40.2 (30.4–50.7) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 46 | 76.1 (61.2–87.4) | |||||
NA | VPZ/AMPC/CAM | 125 | 89.6 (82.9–94.3) | 125 | 89.6 (82.9–94.3) | LPZ or RPZ or EPZ/AMPC/CAM | 295 | 71.9 (66.4–76.9) | 290 | 73.1 (67.6–78.1) | |||||
Total | VPZ/AMPC/CAM | 125 | 89.6 (82.9–94.3) | 279 | 74.6 (69.0–79.6) | LPZ or RPZ or EPZ/AMPC/CAM | 295 | 71.9 (66.4–76.9) | 548 | 79.0 (75.4–82.4) | |||||
Sugimoto (2017)30 | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 19 | 82.5 (66.9–98.7) | NA | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 14 | 78.6 (49.2–95.3) | NA | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | NA | NA | 43 | 83.7 (69.3–93.2) | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | NA | NA | 76 | 82.9 (72.5–90.6) | NA | NA | NA | NA | NA | |||||
Sue (2017)24† | PST | Sensitive | VPZ/AMPC/CAM | NA | NA | 180 | 88.9 (83.4–93.1) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 56 | 73.2 (59.7–84.2) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | 623 | 84.9 (81.9–87.6) | 376 | 87.2 (83.4–90.4) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | 608 | 78.8 (75.3–82.0) | 603 | 79.4 (76.0–82.6) | |||||
Total | VPZ/AMPC/CAM | 623 | 84.9 (81.9–87.6) | 612 | 86.4 (83.5–89.1) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | 608 | 78.8 (75.3–82.0) | 603 | 79.4 (76.0–82.6) | |||||
Sue (2018)25† | RCT | Sensitive | VPZ/AMPC/CAM | 55 | 87.3 (75.5–94.7) | 54 | 88.9 (77.4–95.8) | LPZ or RPZ or EPZ/AMPC/CAM | 51 | 76.5 (62.5–87.2) | 45 | 86.7 (73.2–94.9) | |||
Resistant | VPZ/AMPC/CAM | 41 | 82.9 (67.9–92.8) | 41 | 82.9 (67.9–92.8) | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | 96 | 85.4 (76.7–91.8) | 95 | 86.3 (77.7–92.5) | LPZ or RPZ or EPZ/AMPC/CAM | 51 | 76.5 (62.5–87.2) | 45 | 86.7 (73.2–94.9) | |||||
Tanabe (2018)31 | RST | Sensitive | NA | NA | NA | NA | NA | LPZ or RPZ or EPZ/AMPC/CAM | 162 | 93.8 (90.1–97.5) | 159 | 95.6 (90.1–97.5) | |||
Resistant | NA | NA | NA | NA | NA | LPZ or RPZ or EPZ/AMPC/MNZ | 50 | 92.0 (80.8–97.8) | 48 | 95.8 (85.7–99.5) | |||||
NA | VPZ/AMPC/CAM | 363 | 91.5 (88.6–94.3) | 341 | 97.4 (95.7–99.1) | LPZ or RPZ or EPZ/AMPC/CAM | 568 | 74.1 (70.3–77.7) | 510 | 82.5 (79.0–85.7) | |||||
Total | VPZ/AMPC/CAM | 363 | 91.5 (88.6–94.3) | 341 | 97.4 (95.7–99.1) | LPZ or RPZ or EPZ/AMPC/CAM | 780 | 79.4 (76.5–82.2) | 717 | 86.3 (83.8–88.8) | |||||
Shinmura (2019)28† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 165 | 93.2 (88.2–96.1) | NA | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 123 | 85.8 (78.5–91.0) | NA | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | NA | 85.0 (81.8–87.8) | 253 | 90.1 (85.8–93.5) | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | NA | 85.0 (81.8–87.8) | 541 | 90.2 (87.4–92.5) | NA | NA | NA | NA | NA | |||||
Saito (2019)32† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 28 | 100 (88.9–100) | EPZ/AMPC/CAM | NA | NA | 97 | 93.8 (87.0–97.7) | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 25 | 100 (88.7–100) | EPZ/AMPC/CAM | NA | NA | 65 | 38.5 (26.7–51.4) | |||||
NA | VPZ/AMPC/CAM | 290 | 79.0 (73.8–83.5) | 206 | 85.4 (79.9–90.0) | EPZ/AMPC/CAM | 288 | 65.6 (59.5–70.8) | 110 | 66.4 (56.7–75.1) | |||||
Total | VPZ/AMPC/CAM | 290 | 79.0 (73.8–83.5) | 259 | 88.4 (83.9–92.0) | EPZ/AMPC/CAM | 288 | 65.6 (59.5–70.8) | 272 | 69.5 (63.6–74.9) | |||||
Suzuki (2020)29† | RCT | Sensitive | VPZ/AMPC/CAM | NA | NA | 122 | 95.1 (89.6–98.2) | NA | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 42 | 76.2 (60.5–87.9) | NA | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | 167 | 89.2 (83.5–93.5) | NA | NA | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | 167 | 89.2 (83.5–93.5) | 164 | 90.2 (84.6–94.3) | NA | NA | NA | NA | NA | |||||
Suzuki (2016)33† | RST | NA (total) | VPZ/AMPC/CAM | 175 | 89.1 (84.5–93.8) | 171 | 91.2 (87.0–95.5) | LPZ or RPZ/AMPC/CAM | 175 | 70.9 (64.1–77.6) | 173 | 71.7 (64.9–78.4) | |||
Shinozaki (2016)34† | RST | NA (Total) | VPZ/AMPC/CAM | 117 | 82.9 (74.8–89.2) | 114 | 85.0 (77.2–91.1) | LPZ or RPZ or EPZ/AMPC/CAM | 456 | 70.6 (66.0–74.6) | 435 | 74.0 (69.6–78.1) | |||
Shichijo (2016)35† | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 422 | 87.2 (83.6–90.2) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 2,293 | 72.4 (70.5–74.2) | |||
Yamada (2016)36† | RST | NA (total) | VPZ/AMPC/CAM | 335 | 85.7 (81.5–89.2) | 318 | 90.3 (86.4–93.3) | LPZ or RPZ or EPZ/AMPC/CAM | 1,720 | 73.2 (71.0–75.3) | 1,647 | 76.4 (74.3–78.4) | |||
Tsujimae (2016)37† | RST | NA (total) | VPZ/AMPC/CAM | 443 | 84.6 (81.4–88.3) | 439 | 86.3 (82.8–89.4) | EPZ/AMPC/CAM | 431 | 79.1 (75.0–82.9) | 427 | 79.9 (75.7–83.6) | |||
Katayama (2017)38 | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 258 | 90.6 (86.3–93.9) | NA | NA | NA | NA | NA | |||
Kajihara (2017)39† | RST | NA (total) | VPZ/AMPC/CAM | 111 | 94.6 (88.6–98.0) | 110 | 95.5 (89.7–98.5) | RPZ/AMPC/CAM | 98 | 86.7 (78.4–92.7) | 98 | 86.7 (78.4–92.7) | |||
Ono (2017)40† | RST | NA (total) | VPZ/MNZ/CAM | 14 | 92.9 (66.1–99.8) | 14 | 92.9 (66.1–99.8) | LPZ or RPZ/MNZ/CAM | 13 | 46.2 (19.2–74.9) | 11 | 54.6 (23.4–83.3) | |||
Sakurai (2017)41† | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 546 | 87.9 (84.9–90.5) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 807 | 66.9 (63.5–70.2) | |||
Maruyama (2017)42† | RCT | NA (total) | VPZ/AMPC/CAM | 72 | 95.8 (88.3–99.1) | 70 | 95.7 (88.0–99.1) | LPZ or RPZ/AMPC/CAM | 69 | 69.6 (57.3–80.1) | 63 | 71.4 (58.7–82.1) | |||
Nishizawa (2017)43† | RST | NA (total) | VPZ/AMPC/CAM | 353 | 62.3 (57.0–67.4) | 246 | 89.4 (84.9–93.0) | LPZ or RPZ/AMPC/CAM | 2,173 | 47.1 (45.0–49.2) | 1,532 | 66.8 (64.4–69.1) | |||
Tanabe (2017)44 | RST | NA (total) | VPZ/AMPC/CAM | 694 | 82.7 (84.7–89.7) | 641 | 94.4 (92.6–96.2) | NA | NA | NA | NA | NA | |||
Ozaki (2018)45 | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 1,688 | 90.8 (89.3–92.2) | RPZ or EPZ/AMPC/CAM | NA | NA | 147 | 72.8 (64.8–79.8) | |||
Mori (2018)46 | RST | NA (total) | VPZ/AMPC/CAM | 308 | NA | 275 | 91.0 (86.9–94.0) | LPZ/AMPC/CAM | 272 | NA | 249 | 84.7 (79.7–89.0) | |||
Shinozaki (2018)47 | RST | NA (total) | VPZ/AMPC/CAM | 174 | 83.3 (76.9–88.5) | 171 | 84.8 (78.5–89.8) | NA | NA | NA | NA | NA | |||
Kusunoki (2019)48† | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 415 | 92.5 (89.6–94.9) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 757 | 83.9 (81.1–86.5) | |||
Nishida (2019)49 | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 326 | 71.9 (68.3–75.2) | LPZ or RPZ/AMPC/CAM | NA | NA | 644 | 90.2 (86.5–93.0) | |||
Mori (2019)50† | RST | NA (total) | VPZ/AMPC/CAM | 1,676 | 81.4 (79.4–83.2) | NA | 89.1 (87.4–90.6) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | 2,043 | 62.7 (60.6–64.8) | NA | 69.4 (67.2–71.5) | |||
Furuta (2019)51 | RST | NA (total) | VPZ/AMPC/CAM | 56 | 91.9 (80.4–97.0) | 55 | 92.7 (82.4–98.0) | NA | NA | NA | NA | NA |
All papers that investigated the efficacy of first-line vonoprazan-containing eradication therapy until January 2020 were listed. A total of 4 RCTs and 26 RSTs investigated the efficacy of first-line VPZ-containing therapy. There were many RSTs but few RCTs (Murakami 2016, Maruyama 2017, Sue 2018, Suzuki 2020). Because CAM resistance is becoming a global clinical problem for
CAM, clarithromycin; VPZ, vonoprazan; PPI, proton pump inhibitor; ITT, intention-to-treat analysis; FAS, full analysis set; PP, per-protocol analysis; ER, eradication rate; CI, confidence interval; RCT, randomized controlled trial; PST, prospective interventional trial; RST, retrospective cohort trial; AMPC, amoxicillin; LPZ, lansoprazole; RPZ, rabeprazole; EPZ, esomeprazole; OPZ, omeprazole; MNZ, metronidazole; NA, not available.
*FAS; †Studies were used for meta-analyses.
Table 2 Second-Line Vonoprazan-Based Compared to PPI-Based Eradication Regimen
First author (year) | Method | MNZ susceptible | First-line | VPZ-based eradication regimen | PPI-based eradication regimen | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Regimen | ITT/FAS analysis | PP analysis | Regimen | ITT/FAS analysis | PP analysis | |||||||||||
No. | ER (95% CI), % | No. | ER (95% CI), % | No. | ER (95% CI), % | No | ER (95% CI), % | |||||||||
Murakami (2016)9 | PST | Sensitive | VPZ | VPZ/AMPC/MNZ | 45 | NA | NA | NA | NA | NA | NA | NA | NA | |||
Resistant | VPZ | VPZ/AMPC/MNZ | 4 | NA | NA | NA | NA | NA | NA | NA | NA | |||||
NA | VPZ | VPZ/AMPC/MNZ | 1 | NA | NA | NA | NA | NA | NA | NA | NA | |||||
Total | VPZ | VPZ/AMPC/MNZ | 50 | 98.0 (89.4–99.9)* | NA | NA | NA | NA | NA | NA | NA | |||||
Yamada (2016)36 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 66 | 89.4 (79.4–95.6) | 61 | 96.7 (88.7–99.6) | LPZ or RPZ or EPZ/AMPC/MNZ | 386 | 89.9 (86.4–92.7) | 374 | 92.8 (89.7–95.2) | |||
Tsujimae (2016)37 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 46 | 89.1 (76.4–96.4) | 45 | 91.1 (78.8–97.5) | EPZ/AMPC/MNZ | 54 | 83.3 (70.7–92.1) | 51 | 88.2 (76.1–95.6) | |||
Katayama (2017)38 | RST | NA (total) | VPZ | VPZ/AMPC/MNZ | NA | NA | 23 | 87.0 (66.4–97.2) | NA | NA | NA | NA | NA | |||
Sakurai (2017)41 | RST | NA (total) | NA | VPZ/AMPC/MNZ | NA | NA | 76 | 96.1 (88.9–99.2) | LPZ or RPZ or EPZ/AMPC/MNZ | NA | NA | 185 | 91.6 (86.3–95.0) | |||
Nishizawa (2017)43 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 85 | 71.8 (61.0–81.0) | 63 | 96.8 (89.0–99.6) | LPZ or RPZ/AMPC/MNZ | 650 | 73.7 (70.1–77.0) | 529 | 90.5 (87.7–92.9) | |||
Sue (2017)24 | PST | NA (total) | NA | VPZ/AMPC/MNZ | 216 | 80.5 (74.6–85.6) | 211 | 82.4 (76.6–87.9) | LPZ or RPZ or EPZ/AMPC/MNZ | 146 | 81.5 (74.2–87.4) | 145 | 82.1 (74.8–87.9) | |||
Tanabe (2017)44 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 73 | 90.4 (83.7–97.2) | 68 | 97.1 (93.0–101.1) | NA | NA | NA | NA | NA | |||
Ozaki (2017)45 | RST | NA (total) | VPZ | VPZ/AMPC/MNZ | NA | NA | 94 | 86.3 (77.5–92.4) | NA | NA | NA | NA | NA | |||
Mori (2018)46 | RST | NA (total) | VPZ | VPZ/AMPC/MNZ | NA | NA | 23 | 87.0 (66.4–97.2) | NA | NA | NA | NA | NA | |||
PPI | NA | NA | NA | NA | NA | RPZ/AMPC/MNZ | NA | NA | 33 | 87.9 (71.8–96.6) | ||||||
Kusunoki (2019)48 | RST | NA (total) | NA | VPZ/AMPC/MNZ | NA | NA | 48 | 93.8 (82.8–98.7) | LPZ or RPZ or EPZ/AMPC/MNZ | NA | NA | 108 | 90.7 (83.6–95.5) | |||
Mori (2019)50 | RST | NA (total) | NA | VPZ/AMPC/MNZ | NA | 80.0 | 1,292 | 90.1 (88.3–91.7) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | 77.6 | 2,280 | 86.6 (85.1–88.0) | |||
Saito (2019)32 | RST | NA (total) | NA | VPZ/AMPC/MMZ | 60 | 81.7 (69.6–90.5) | 54 | 90.7 (79.7–96.9) | EPZ/AMPC/MNZ | 74 | 89.2 (79.8–95.2) | 73 | 90.4 (81.2–96.1) |
All papers that investigated the efficacy of second-line vonoprazan-containing eradication therapy up until March 2019 were listed. A total of 1 PST and 12 RSTs investigated the efficacy of second-line VPZ-containing therapy. There were many RSTs but no RCTs. In 8 studies (Yamada 2016, Tsujimae 2016, Sakurai 2017, Nishizawa 2017, Sue 2017, Kusunoki 2019, Mori 2019, Saito 2019), statistical significance was not found between the VPZ and PPI regimens. This may be because although CAM and AMPC are acid-sensitive antimicrobial agents, MNZ is not an acid-sensitive antimicrobial agent. However, there were no RCTs containing susceptibility information. The first-line regimen is important for the
MNZ, metronidazole; VPZ, vonoprazan; PPI, proton pump inhibitor; ITT, intention-to-treat analysis; FAS, full analysis set; PP, per-protocol analysis; ER, eradication rate; CI, confidence interval; PST, prospective interventional trial; RST, retrospective cohort trial; AMPC, amoxicillin; LPZ, lansoprazole; RPZ, rabeprazole; EPZ, esomeprazole; OPZ, omeprazole; CAM, clarithromycin; NA, not available.
*FAS.
Studies reviewed in this article are based on a Japanese population, so the Japanese
As mentioned above, we ask: “is P-CAB really superior to a PPI in terms of
The CAM-resistance status is very important when exploring whether first-line 7-day triple therapy consisting of VPZ, AMPC, and CAM are superior to PPI-based regimens. Attempts to generalize results in the absence of CAM- and AMPC-resistance data33-51 are both difficult and misleading. Generalization may be possible in very limited circumstances only (the trial sites and lesions are identical). The CAM-resistance rate is increasing in Japan, and antibiotic-resistance rates vary by lesion.9,24-32 Generalization to other countries is even less appropriate.
MAs of RCTs evaluated high-quality evidence. In 2019, Lyu
Table 1 shows that many non-RCTs have been performed, but retrospective cohort studies lacking information on antibiotic resistance are misleading, as the CAM-resistance rates might have differed. Several MAs lack antibiotic-resistance data and are as misleading as single retrospective cohort studies lacking this information. The MA by Dong
The MA by Li
No MA presented a funnel plot; we suspect that publication bias explains many of the differences between RCTs and non-RCTs. Many retrospective studies have been presented in Japanese conferences in Japanese, of which few are published. Most studies are neither prospective nor registered. Well-designed, registered, prospective studies with pre-planned analysis methods would reduce publication bias. In summary, MAs that include non-RCTs are unreliable given their high heterogeneity and publication bias, and it is difficult to generalize the results when antibiotic-resistance data are lacking.
In 2017, Dong
As we noted in “2.1. Mechanism of P-CAB action in patients with various lesions,” the mechanism of this superiority is that rapid, strong, and stable acid block by P-CAB results in AMPC and CAM becoming more effective, because at pH >5,
In summary, VPZ-based therapy is superior to PPI-based therapy in patients with CAM-resistant
In 2017, Dong
We performed an RCT to explore whether a clinically significant difference was apparent between VPZ-based and PPI-based triple therapies for CAM-susceptible
Non-RCTs are at risk of several forms of bias that are lacking in RCTs. The differences between RCT and non-RCT analyses reflect these biases.
Rapid, strong, and stable acid block by P-CAB results in AMPC and CAM becoming more effective, because at pH >5,
In summary, VPZ-based triple therapies are not superior to PPI-based SSTs in terms of eradicating CAM-susceptible
Two MAs of non-RCTs comparing 7-day triple therapy consisting of VPZ, AMPC, and MNZ with 7-day triple therapy consisting of a PPI, AMPC, and MNZ have appeared. In 2017, Dong
In 2020, Shinozaki
Several MAs seem to be very reliable in terms of low heterogeneity, but the conclusions differ. Publication bias may be in play, as retrospective studies with negative results may not be accepted by journals. Indeed, many positive results were published after one MA;55 one MA of retrospective studies published in 202052 contained high numbers of subjects (1,147/2,293 cases of VPZ-based therapy and 2,251/3,854 cases of PPI-based therapy). Selection bias and confounding variables may be in play in other retrospective studies.
As shown in Table 2, that MA was almost entirely based on retrospective cohort trials and lacked data on antibiotic resistance; the groups were thus not matched in this context. Antibiotic-resistance data are essential when generalizing the results to countries or regions that vary in terms of the MNZ- or AMPC-resistance rate. In addition, the MA divided the patients into two groups based on VPZ- or PPI-based first-line therapy. Most studies do not do this; any assumption that the two groups are similar may be misleading. If first-line VPZ-based therapy is superior to PPI-based therapy, eradication is more difficult in those who fail first-line VPZ-based therapy. In summary, the finding of slight (~2.6%) superiority of VPZ-based therapy was unreliable given the selection bias, confounding variables, and risk of publication bias, and the results are difficult to generalize because of a lack of antibiotic-resistance data.
In 2019, we reported an RCT comparing third-line VPZ- with PPI-based 7-day triple therapies consisting of AMPC after first-line triple therapy (AMPC and CAM) and second-line triple therapy (AMPC and MNZ) failures.61 The VPZ and AMPC doses were the same as those of the first- and second-line regimens; the STFX dose was 100 mg bid (200 mg/day). The eradication rates were 75.8% (95% CI, 57.7 to 88.9) for VPZ therapy versus 53.3% (95% CI, 34.3 to 71.7) for PPI therapy in the ITT analysis (p=0.071), and 83.3% (95% CI, 65.3 to 94.4) versus 57.1% (95% CI, 37.2 to 75.5), respectively, in the PP analysis (p=0.043). In a retrospective study, Saito
In 2017, Ono
Any attempt to answer the question “Is P-CAB really superior to a PPI in terms of
An MA of RCTs comparing VPZ- and PPI-based first-line triple therapies consisting of AMPC and CAM may be generalizable to populations comprising approximately 30% of CAM-resistant subjects, but reliability is poor because of high heterogeneity and a risk of selection bias (poor allocation concealment). First-line VPZ-based triple therapy involving AMPC and CAM are superior to PPI-based regimens in patients with CAM-resistant
We thank Eijin Hashimoto (Yokohama City University School of Medicine, Yokohama, Japan) for the assistance with preparation of the tables.
No potential conflict of interest relevant to this article was reported.
Gut and Liver 2021; 15(6): 799-810
Published online November 15, 2021 https://doi.org/10.5009/gnl20242
Copyright © Gut and Liver.
Department of Gastroenterology, Yokohama City University Graduate School of Medicine, Yokohama, Japan
Correspondence to:Shin Maeda
ORCID https://orcid.org/0000-0002-0246-1594
E-mail shinmaeda2-gi@umin.ac.jp
This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
Vonoprazan (VPZ), a new potassium-competitive acid blocker, has been approved and used for Helicobacter pylori eradication in Japan. To date, many studies, as well as several systematic reviews and meta-analyses (MAs), have compared VPZ-based 7-day triple therapy with proton pump inhibitor (PPI)-based therapy. An MA of randomized controlled trials (RCTs) comparing first-line VPZ- with PPI-based triple therapy, the latter featuring amoxicillin (AMPC) and clarithromycin (CAM), found that approximately 30% of patients hosted CAM-resistant H. pylori; however, the reliability was poor because of high heterogeneity and a risk of selection bias. VPZ-based triple therapy is superior to PPI-based triple therapy for patients with CAM-resistant H. pylori, but not for those with CAM-susceptible H. pylori. An MA of non-RCTs found that second-line VPZ-based triple therapies were slightly (~2.6%) better than PPI-based triple therapies (with AMPC and metronidazole). However, the reliability of that MA was also low because of selection bias, confounding variables and a risk of publication bias; in addition, it is difficult to generalize the results because of a lack of data on antibiotic resistance. VPZ-based triple therapy (involving AMPC and sitafloxacin) was more effective than PPI-based triple therapy in a third-line setting, but a confirmatory RCT is needed. Non-RCT studies indicated that VPZ-based triple therapy involving CAM and metronidazole may be promising. Any further RCTs must explore the antibiotic-resistance status when evaluating the possible superiority of a potassium-competitive acid blocker.
Keywords: Potassium-competitive acid blocker, Proton pump inhibitors, Helicobacter pylori, Treatment outcome, Drug resistance, microbial
VPZ is a new P-CAB (other P-CABs include SCH28080) that inhibits H+/K+ ATPases in a manner described as rapid (the intragastric pH increased to over 4.0 within 4 hours14), strong (the intragastric pH increased to over 5 and was maintained for 99% of the time when VPZ [20 mg] was given twice daily15), or stable (not affected by the CP2C19 genotype14,16). VPZ was the second P-CAB to be approved worldwide (revaprazan was approved first, in South Korea).
At pH >5,
SCH28080 is the prototype P-CAB that was developed in the 1980s. This drug is short-acting and was never approved. Linaprazan was found to be as effective as esomeprazole (40 mg) in patients with non-erosive reflux disease; however, its clinical development was later suspended.18 Revaprazan (a P-CAB) was approved in South Korea in 2005 for the treatment of gastroduodenal ulcers and gastritis. However, endoscopic submucosal dissection revealed that the drug was no more efficacious than 20 mg rabeprazole for treating ulcers.19 In 2018, a new P-CAB, tegoprazan, was approved for
P-CAB based data are mainly with VPZ based and in Japanese population. First-line VPZ based regimens compared to PPI based (Table 1), and second-line VPZ based regimens compared to PPI based (Table 2) are studies with Japanese population. In these studies, 7-day triple therapies are used. In Japan, 7-day first-line triple therapy consisting of VPZ or a PPI, AMPC, and CAM and 7-day second-line triple therapy consisting of VPZ or a PPI, AMPC, and MNZ are covered by national insurance. Esomeprazole, rabeprazole, lansoprazole, or omeprazole serves as the PPI. The approved doses are VPZ 20 mg bid (twice a day; 40 mg/day), esomeprazole 20 mg bid (40 mg/day), rabeprazole 10 mg bid (20 mg/day), omeprazole 20 mg bid (40 mg/day), AMPC 750 mg bid (1,500 mg/day), CAM 200 mg or 400 mg bid (400 mg/day or 800 mg/day), and MNZ 250 mg bid (500 mg/day).
Table 1 . First-Line Vonoprazan-Based Compared to PPI-Based Eradication Regimen.
First author (year) | Method | CAM susceptible | VPZ-based eradication regimen | PPI-based eradication regimen | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Regimen | ITT/FAS analysis | PP analysis | Regimen | ITT/FAS analysis | PP analysis | ||||||||||
No. | ER (95% CI), % | No. | ER (95% CI), % | No. | ER (95% CI), % | No. | ER (95% CI), % | ||||||||
Murakami (2016)9† | RCT | Sensitive | VPZ/AMPC/CAM | 205 | 97.6 (94.4–99.2)* | NA | NA | LPZ/AMPC/CAM | 185 | 97.3 (93.8–99.1)* | NA | NA | |||
Resistant | VPZ/AMPC/CAM | 100 | 82.0 (73.1–89.0)* | NA | NA | LPZ/AMPC/CAM | 115 | 40.0 (31.0–49.6)* | NA | NA | |||||
NA | VPZ/AMPC/CAM | 19 | 94.7 (74.0–99.9)* | NA | NA | LPZ/AMPC/CAM | 20 | 85.0 (62.1–96.8)* | NA | NA | |||||
Total | VPZ/AMPC/CAM | 324 | 92.6 (89.2–95.2)* | NA | NA | LPZ/AMPC/CAM | 320 | 75.9 (70.9–80.5)* | NA | NA | |||||
Noda (2016)26† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 44 | 100 (92.0–100) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 25 | 88.0 (68.8–97.5) | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 32 | 87.5 (71.0–96.5) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 13 | 53.8 (25.1–80.8) | |||||
NA | VPZ/AMPC/CAM | NA | NA | 70 | 84.3 (73.6–91.9) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 1,267 | 73.9 (71.4–76.2) | |||||
Total | VPZ/AMPC/CAM | NA | NA | 146 | 89.7 (87.9–91.3) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 1,305 | 73.9 (66.0–80.8) | |||||
Matsumoto (2016)27† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 57 | 100 (94.9–100) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 212 | 87.8 (82.5–91.8) | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 97 | 40.2 (30.4–50.7) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 46 | 76.1 (61.2–87.4) | |||||
NA | VPZ/AMPC/CAM | 125 | 89.6 (82.9–94.3) | 125 | 89.6 (82.9–94.3) | LPZ or RPZ or EPZ/AMPC/CAM | 295 | 71.9 (66.4–76.9) | 290 | 73.1 (67.6–78.1) | |||||
Total | VPZ/AMPC/CAM | 125 | 89.6 (82.9–94.3) | 279 | 74.6 (69.0–79.6) | LPZ or RPZ or EPZ/AMPC/CAM | 295 | 71.9 (66.4–76.9) | 548 | 79.0 (75.4–82.4) | |||||
Sugimoto (2017)30 | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 19 | 82.5 (66.9–98.7) | NA | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 14 | 78.6 (49.2–95.3) | NA | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | NA | NA | 43 | 83.7 (69.3–93.2) | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | NA | NA | 76 | 82.9 (72.5–90.6) | NA | NA | NA | NA | NA | |||||
Sue (2017)24† | PST | Sensitive | VPZ/AMPC/CAM | NA | NA | 180 | 88.9 (83.4–93.1) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 56 | 73.2 (59.7–84.2) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | 623 | 84.9 (81.9–87.6) | 376 | 87.2 (83.4–90.4) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | 608 | 78.8 (75.3–82.0) | 603 | 79.4 (76.0–82.6) | |||||
Total | VPZ/AMPC/CAM | 623 | 84.9 (81.9–87.6) | 612 | 86.4 (83.5–89.1) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | 608 | 78.8 (75.3–82.0) | 603 | 79.4 (76.0–82.6) | |||||
Sue (2018)25† | RCT | Sensitive | VPZ/AMPC/CAM | 55 | 87.3 (75.5–94.7) | 54 | 88.9 (77.4–95.8) | LPZ or RPZ or EPZ/AMPC/CAM | 51 | 76.5 (62.5–87.2) | 45 | 86.7 (73.2–94.9) | |||
Resistant | VPZ/AMPC/CAM | 41 | 82.9 (67.9–92.8) | 41 | 82.9 (67.9–92.8) | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | 96 | 85.4 (76.7–91.8) | 95 | 86.3 (77.7–92.5) | LPZ or RPZ or EPZ/AMPC/CAM | 51 | 76.5 (62.5–87.2) | 45 | 86.7 (73.2–94.9) | |||||
Tanabe (2018)31 | RST | Sensitive | NA | NA | NA | NA | NA | LPZ or RPZ or EPZ/AMPC/CAM | 162 | 93.8 (90.1–97.5) | 159 | 95.6 (90.1–97.5) | |||
Resistant | NA | NA | NA | NA | NA | LPZ or RPZ or EPZ/AMPC/MNZ | 50 | 92.0 (80.8–97.8) | 48 | 95.8 (85.7–99.5) | |||||
NA | VPZ/AMPC/CAM | 363 | 91.5 (88.6–94.3) | 341 | 97.4 (95.7–99.1) | LPZ or RPZ or EPZ/AMPC/CAM | 568 | 74.1 (70.3–77.7) | 510 | 82.5 (79.0–85.7) | |||||
Total | VPZ/AMPC/CAM | 363 | 91.5 (88.6–94.3) | 341 | 97.4 (95.7–99.1) | LPZ or RPZ or EPZ/AMPC/CAM | 780 | 79.4 (76.5–82.2) | 717 | 86.3 (83.8–88.8) | |||||
Shinmura (2019)28† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 165 | 93.2 (88.2–96.1) | NA | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 123 | 85.8 (78.5–91.0) | NA | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | NA | 85.0 (81.8–87.8) | 253 | 90.1 (85.8–93.5) | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | NA | 85.0 (81.8–87.8) | 541 | 90.2 (87.4–92.5) | NA | NA | NA | NA | NA | |||||
Saito (2019)32† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 28 | 100 (88.9–100) | EPZ/AMPC/CAM | NA | NA | 97 | 93.8 (87.0–97.7) | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 25 | 100 (88.7–100) | EPZ/AMPC/CAM | NA | NA | 65 | 38.5 (26.7–51.4) | |||||
NA | VPZ/AMPC/CAM | 290 | 79.0 (73.8–83.5) | 206 | 85.4 (79.9–90.0) | EPZ/AMPC/CAM | 288 | 65.6 (59.5–70.8) | 110 | 66.4 (56.7–75.1) | |||||
Total | VPZ/AMPC/CAM | 290 | 79.0 (73.8–83.5) | 259 | 88.4 (83.9–92.0) | EPZ/AMPC/CAM | 288 | 65.6 (59.5–70.8) | 272 | 69.5 (63.6–74.9) | |||||
Suzuki (2020)29† | RCT | Sensitive | VPZ/AMPC/CAM | NA | NA | 122 | 95.1 (89.6–98.2) | NA | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 42 | 76.2 (60.5–87.9) | NA | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | 167 | 89.2 (83.5–93.5) | NA | NA | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | 167 | 89.2 (83.5–93.5) | 164 | 90.2 (84.6–94.3) | NA | NA | NA | NA | NA | |||||
Suzuki (2016)33† | RST | NA (total) | VPZ/AMPC/CAM | 175 | 89.1 (84.5–93.8) | 171 | 91.2 (87.0–95.5) | LPZ or RPZ/AMPC/CAM | 175 | 70.9 (64.1–77.6) | 173 | 71.7 (64.9–78.4) | |||
Shinozaki (2016)34† | RST | NA (Total) | VPZ/AMPC/CAM | 117 | 82.9 (74.8–89.2) | 114 | 85.0 (77.2–91.1) | LPZ or RPZ or EPZ/AMPC/CAM | 456 | 70.6 (66.0–74.6) | 435 | 74.0 (69.6–78.1) | |||
Shichijo (2016)35† | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 422 | 87.2 (83.6–90.2) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 2,293 | 72.4 (70.5–74.2) | |||
Yamada (2016)36† | RST | NA (total) | VPZ/AMPC/CAM | 335 | 85.7 (81.5–89.2) | 318 | 90.3 (86.4–93.3) | LPZ or RPZ or EPZ/AMPC/CAM | 1,720 | 73.2 (71.0–75.3) | 1,647 | 76.4 (74.3–78.4) | |||
Tsujimae (2016)37† | RST | NA (total) | VPZ/AMPC/CAM | 443 | 84.6 (81.4–88.3) | 439 | 86.3 (82.8–89.4) | EPZ/AMPC/CAM | 431 | 79.1 (75.0–82.9) | 427 | 79.9 (75.7–83.6) | |||
Katayama (2017)38 | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 258 | 90.6 (86.3–93.9) | NA | NA | NA | NA | NA | |||
Kajihara (2017)39† | RST | NA (total) | VPZ/AMPC/CAM | 111 | 94.6 (88.6–98.0) | 110 | 95.5 (89.7–98.5) | RPZ/AMPC/CAM | 98 | 86.7 (78.4–92.7) | 98 | 86.7 (78.4–92.7) | |||
Ono (2017)40† | RST | NA (total) | VPZ/MNZ/CAM | 14 | 92.9 (66.1–99.8) | 14 | 92.9 (66.1–99.8) | LPZ or RPZ/MNZ/CAM | 13 | 46.2 (19.2–74.9) | 11 | 54.6 (23.4–83.3) | |||
Sakurai (2017)41† | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 546 | 87.9 (84.9–90.5) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 807 | 66.9 (63.5–70.2) | |||
Maruyama (2017)42† | RCT | NA (total) | VPZ/AMPC/CAM | 72 | 95.8 (88.3–99.1) | 70 | 95.7 (88.0–99.1) | LPZ or RPZ/AMPC/CAM | 69 | 69.6 (57.3–80.1) | 63 | 71.4 (58.7–82.1) | |||
Nishizawa (2017)43† | RST | NA (total) | VPZ/AMPC/CAM | 353 | 62.3 (57.0–67.4) | 246 | 89.4 (84.9–93.0) | LPZ or RPZ/AMPC/CAM | 2,173 | 47.1 (45.0–49.2) | 1,532 | 66.8 (64.4–69.1) | |||
Tanabe (2017)44 | RST | NA (total) | VPZ/AMPC/CAM | 694 | 82.7 (84.7–89.7) | 641 | 94.4 (92.6–96.2) | NA | NA | NA | NA | NA | |||
Ozaki (2018)45 | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 1,688 | 90.8 (89.3–92.2) | RPZ or EPZ/AMPC/CAM | NA | NA | 147 | 72.8 (64.8–79.8) | |||
Mori (2018)46 | RST | NA (total) | VPZ/AMPC/CAM | 308 | NA | 275 | 91.0 (86.9–94.0) | LPZ/AMPC/CAM | 272 | NA | 249 | 84.7 (79.7–89.0) | |||
Shinozaki (2018)47 | RST | NA (total) | VPZ/AMPC/CAM | 174 | 83.3 (76.9–88.5) | 171 | 84.8 (78.5–89.8) | NA | NA | NA | NA | NA | |||
Kusunoki (2019)48† | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 415 | 92.5 (89.6–94.9) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 757 | 83.9 (81.1–86.5) | |||
Nishida (2019)49 | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 326 | 71.9 (68.3–75.2) | LPZ or RPZ/AMPC/CAM | NA | NA | 644 | 90.2 (86.5–93.0) | |||
Mori (2019)50† | RST | NA (total) | VPZ/AMPC/CAM | 1,676 | 81.4 (79.4–83.2) | NA | 89.1 (87.4–90.6) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | 2,043 | 62.7 (60.6–64.8) | NA | 69.4 (67.2–71.5) | |||
Furuta (2019)51 | RST | NA (total) | VPZ/AMPC/CAM | 56 | 91.9 (80.4–97.0) | 55 | 92.7 (82.4–98.0) | NA | NA | NA | NA | NA |
All papers that investigated the efficacy of first-line vonoprazan-containing eradication therapy until January 2020 were listed. A total of 4 RCTs and 26 RSTs investigated the efficacy of first-line VPZ-containing therapy. There were many RSTs but few RCTs (Murakami 2016, Maruyama 2017, Sue 2018, Suzuki 2020). Because CAM resistance is becoming a global clinical problem for
CAM, clarithromycin; VPZ, vonoprazan; PPI, proton pump inhibitor; ITT, intention-to-treat analysis; FAS, full analysis set; PP, per-protocol analysis; ER, eradication rate; CI, confidence interval; RCT, randomized controlled trial; PST, prospective interventional trial; RST, retrospective cohort trial; AMPC, amoxicillin; LPZ, lansoprazole; RPZ, rabeprazole; EPZ, esomeprazole; OPZ, omeprazole; MNZ, metronidazole; NA, not available..
*FAS; †Studies were used for meta-analyses..
Table 2 . Second-Line Vonoprazan-Based Compared to PPI-Based Eradication Regimen.
First author (year) | Method | MNZ susceptible | First-line | VPZ-based eradication regimen | PPI-based eradication regimen | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Regimen | ITT/FAS analysis | PP analysis | Regimen | ITT/FAS analysis | PP analysis | |||||||||||
No. | ER (95% CI), % | No. | ER (95% CI), % | No. | ER (95% CI), % | No | ER (95% CI), % | |||||||||
Murakami (2016)9 | PST | Sensitive | VPZ | VPZ/AMPC/MNZ | 45 | NA | NA | NA | NA | NA | NA | NA | NA | |||
Resistant | VPZ | VPZ/AMPC/MNZ | 4 | NA | NA | NA | NA | NA | NA | NA | NA | |||||
NA | VPZ | VPZ/AMPC/MNZ | 1 | NA | NA | NA | NA | NA | NA | NA | NA | |||||
Total | VPZ | VPZ/AMPC/MNZ | 50 | 98.0 (89.4–99.9)* | NA | NA | NA | NA | NA | NA | NA | |||||
Yamada (2016)36 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 66 | 89.4 (79.4–95.6) | 61 | 96.7 (88.7–99.6) | LPZ or RPZ or EPZ/AMPC/MNZ | 386 | 89.9 (86.4–92.7) | 374 | 92.8 (89.7–95.2) | |||
Tsujimae (2016)37 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 46 | 89.1 (76.4–96.4) | 45 | 91.1 (78.8–97.5) | EPZ/AMPC/MNZ | 54 | 83.3 (70.7–92.1) | 51 | 88.2 (76.1–95.6) | |||
Katayama (2017)38 | RST | NA (total) | VPZ | VPZ/AMPC/MNZ | NA | NA | 23 | 87.0 (66.4–97.2) | NA | NA | NA | NA | NA | |||
Sakurai (2017)41 | RST | NA (total) | NA | VPZ/AMPC/MNZ | NA | NA | 76 | 96.1 (88.9–99.2) | LPZ or RPZ or EPZ/AMPC/MNZ | NA | NA | 185 | 91.6 (86.3–95.0) | |||
Nishizawa (2017)43 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 85 | 71.8 (61.0–81.0) | 63 | 96.8 (89.0–99.6) | LPZ or RPZ/AMPC/MNZ | 650 | 73.7 (70.1–77.0) | 529 | 90.5 (87.7–92.9) | |||
Sue (2017)24 | PST | NA (total) | NA | VPZ/AMPC/MNZ | 216 | 80.5 (74.6–85.6) | 211 | 82.4 (76.6–87.9) | LPZ or RPZ or EPZ/AMPC/MNZ | 146 | 81.5 (74.2–87.4) | 145 | 82.1 (74.8–87.9) | |||
Tanabe (2017)44 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 73 | 90.4 (83.7–97.2) | 68 | 97.1 (93.0–101.1) | NA | NA | NA | NA | NA | |||
Ozaki (2017)45 | RST | NA (total) | VPZ | VPZ/AMPC/MNZ | NA | NA | 94 | 86.3 (77.5–92.4) | NA | NA | NA | NA | NA | |||
Mori (2018)46 | RST | NA (total) | VPZ | VPZ/AMPC/MNZ | NA | NA | 23 | 87.0 (66.4–97.2) | NA | NA | NA | NA | NA | |||
PPI | NA | NA | NA | NA | NA | RPZ/AMPC/MNZ | NA | NA | 33 | 87.9 (71.8–96.6) | ||||||
Kusunoki (2019)48 | RST | NA (total) | NA | VPZ/AMPC/MNZ | NA | NA | 48 | 93.8 (82.8–98.7) | LPZ or RPZ or EPZ/AMPC/MNZ | NA | NA | 108 | 90.7 (83.6–95.5) | |||
Mori (2019)50 | RST | NA (total) | NA | VPZ/AMPC/MNZ | NA | 80.0 | 1,292 | 90.1 (88.3–91.7) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | 77.6 | 2,280 | 86.6 (85.1–88.0) | |||
Saito (2019)32 | RST | NA (total) | NA | VPZ/AMPC/MMZ | 60 | 81.7 (69.6–90.5) | 54 | 90.7 (79.7–96.9) | EPZ/AMPC/MNZ | 74 | 89.2 (79.8–95.2) | 73 | 90.4 (81.2–96.1) |
All papers that investigated the efficacy of second-line vonoprazan-containing eradication therapy up until March 2019 were listed. A total of 1 PST and 12 RSTs investigated the efficacy of second-line VPZ-containing therapy. There were many RSTs but no RCTs. In 8 studies (Yamada 2016, Tsujimae 2016, Sakurai 2017, Nishizawa 2017, Sue 2017, Kusunoki 2019, Mori 2019, Saito 2019), statistical significance was not found between the VPZ and PPI regimens. This may be because although CAM and AMPC are acid-sensitive antimicrobial agents, MNZ is not an acid-sensitive antimicrobial agent. However, there were no RCTs containing susceptibility information. The first-line regimen is important for the
MNZ, metronidazole; VPZ, vonoprazan; PPI, proton pump inhibitor; ITT, intention-to-treat analysis; FAS, full analysis set; PP, per-protocol analysis; ER, eradication rate; CI, confidence interval; PST, prospective interventional trial; RST, retrospective cohort trial; AMPC, amoxicillin; LPZ, lansoprazole; RPZ, rabeprazole; EPZ, esomeprazole; OPZ, omeprazole; CAM, clarithromycin; NA, not available..
*FAS..
Studies reviewed in this article are based on a Japanese population, so the Japanese
As mentioned above, we ask: “is P-CAB really superior to a PPI in terms of
The CAM-resistance status is very important when exploring whether first-line 7-day triple therapy consisting of VPZ, AMPC, and CAM are superior to PPI-based regimens. Attempts to generalize results in the absence of CAM- and AMPC-resistance data33-51 are both difficult and misleading. Generalization may be possible in very limited circumstances only (the trial sites and lesions are identical). The CAM-resistance rate is increasing in Japan, and antibiotic-resistance rates vary by lesion.9,24-32 Generalization to other countries is even less appropriate.
MAs of RCTs evaluated high-quality evidence. In 2019, Lyu
Table 1 shows that many non-RCTs have been performed, but retrospective cohort studies lacking information on antibiotic resistance are misleading, as the CAM-resistance rates might have differed. Several MAs lack antibiotic-resistance data and are as misleading as single retrospective cohort studies lacking this information. The MA by Dong
The MA by Li
No MA presented a funnel plot; we suspect that publication bias explains many of the differences between RCTs and non-RCTs. Many retrospective studies have been presented in Japanese conferences in Japanese, of which few are published. Most studies are neither prospective nor registered. Well-designed, registered, prospective studies with pre-planned analysis methods would reduce publication bias. In summary, MAs that include non-RCTs are unreliable given their high heterogeneity and publication bias, and it is difficult to generalize the results when antibiotic-resistance data are lacking.
In 2017, Dong
As we noted in “2.1. Mechanism of P-CAB action in patients with various lesions,” the mechanism of this superiority is that rapid, strong, and stable acid block by P-CAB results in AMPC and CAM becoming more effective, because at pH >5,
In summary, VPZ-based therapy is superior to PPI-based therapy in patients with CAM-resistant
In 2017, Dong
We performed an RCT to explore whether a clinically significant difference was apparent between VPZ-based and PPI-based triple therapies for CAM-susceptible
Non-RCTs are at risk of several forms of bias that are lacking in RCTs. The differences between RCT and non-RCT analyses reflect these biases.
Rapid, strong, and stable acid block by P-CAB results in AMPC and CAM becoming more effective, because at pH >5,
In summary, VPZ-based triple therapies are not superior to PPI-based SSTs in terms of eradicating CAM-susceptible
Two MAs of non-RCTs comparing 7-day triple therapy consisting of VPZ, AMPC, and MNZ with 7-day triple therapy consisting of a PPI, AMPC, and MNZ have appeared. In 2017, Dong
In 2020, Shinozaki
Several MAs seem to be very reliable in terms of low heterogeneity, but the conclusions differ. Publication bias may be in play, as retrospective studies with negative results may not be accepted by journals. Indeed, many positive results were published after one MA;55 one MA of retrospective studies published in 202052 contained high numbers of subjects (1,147/2,293 cases of VPZ-based therapy and 2,251/3,854 cases of PPI-based therapy). Selection bias and confounding variables may be in play in other retrospective studies.
As shown in Table 2, that MA was almost entirely based on retrospective cohort trials and lacked data on antibiotic resistance; the groups were thus not matched in this context. Antibiotic-resistance data are essential when generalizing the results to countries or regions that vary in terms of the MNZ- or AMPC-resistance rate. In addition, the MA divided the patients into two groups based on VPZ- or PPI-based first-line therapy. Most studies do not do this; any assumption that the two groups are similar may be misleading. If first-line VPZ-based therapy is superior to PPI-based therapy, eradication is more difficult in those who fail first-line VPZ-based therapy. In summary, the finding of slight (~2.6%) superiority of VPZ-based therapy was unreliable given the selection bias, confounding variables, and risk of publication bias, and the results are difficult to generalize because of a lack of antibiotic-resistance data.
In 2019, we reported an RCT comparing third-line VPZ- with PPI-based 7-day triple therapies consisting of AMPC after first-line triple therapy (AMPC and CAM) and second-line triple therapy (AMPC and MNZ) failures.61 The VPZ and AMPC doses were the same as those of the first- and second-line regimens; the STFX dose was 100 mg bid (200 mg/day). The eradication rates were 75.8% (95% CI, 57.7 to 88.9) for VPZ therapy versus 53.3% (95% CI, 34.3 to 71.7) for PPI therapy in the ITT analysis (p=0.071), and 83.3% (95% CI, 65.3 to 94.4) versus 57.1% (95% CI, 37.2 to 75.5), respectively, in the PP analysis (p=0.043). In a retrospective study, Saito
In 2017, Ono
Any attempt to answer the question “Is P-CAB really superior to a PPI in terms of
An MA of RCTs comparing VPZ- and PPI-based first-line triple therapies consisting of AMPC and CAM may be generalizable to populations comprising approximately 30% of CAM-resistant subjects, but reliability is poor because of high heterogeneity and a risk of selection bias (poor allocation concealment). First-line VPZ-based triple therapy involving AMPC and CAM are superior to PPI-based regimens in patients with CAM-resistant
We thank Eijin Hashimoto (Yokohama City University School of Medicine, Yokohama, Japan) for the assistance with preparation of the tables.
No potential conflict of interest relevant to this article was reported.
Table 1 First-Line Vonoprazan-Based Compared to PPI-Based Eradication Regimen
First author (year) | Method | CAM susceptible | VPZ-based eradication regimen | PPI-based eradication regimen | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Regimen | ITT/FAS analysis | PP analysis | Regimen | ITT/FAS analysis | PP analysis | ||||||||||
No. | ER (95% CI), % | No. | ER (95% CI), % | No. | ER (95% CI), % | No. | ER (95% CI), % | ||||||||
Murakami (2016)9† | RCT | Sensitive | VPZ/AMPC/CAM | 205 | 97.6 (94.4–99.2)* | NA | NA | LPZ/AMPC/CAM | 185 | 97.3 (93.8–99.1)* | NA | NA | |||
Resistant | VPZ/AMPC/CAM | 100 | 82.0 (73.1–89.0)* | NA | NA | LPZ/AMPC/CAM | 115 | 40.0 (31.0–49.6)* | NA | NA | |||||
NA | VPZ/AMPC/CAM | 19 | 94.7 (74.0–99.9)* | NA | NA | LPZ/AMPC/CAM | 20 | 85.0 (62.1–96.8)* | NA | NA | |||||
Total | VPZ/AMPC/CAM | 324 | 92.6 (89.2–95.2)* | NA | NA | LPZ/AMPC/CAM | 320 | 75.9 (70.9–80.5)* | NA | NA | |||||
Noda (2016)26† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 44 | 100 (92.0–100) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 25 | 88.0 (68.8–97.5) | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 32 | 87.5 (71.0–96.5) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 13 | 53.8 (25.1–80.8) | |||||
NA | VPZ/AMPC/CAM | NA | NA | 70 | 84.3 (73.6–91.9) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 1,267 | 73.9 (71.4–76.2) | |||||
Total | VPZ/AMPC/CAM | NA | NA | 146 | 89.7 (87.9–91.3) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | 1,305 | 73.9 (66.0–80.8) | |||||
Matsumoto (2016)27† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 57 | 100 (94.9–100) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 212 | 87.8 (82.5–91.8) | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 97 | 40.2 (30.4–50.7) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 46 | 76.1 (61.2–87.4) | |||||
NA | VPZ/AMPC/CAM | 125 | 89.6 (82.9–94.3) | 125 | 89.6 (82.9–94.3) | LPZ or RPZ or EPZ/AMPC/CAM | 295 | 71.9 (66.4–76.9) | 290 | 73.1 (67.6–78.1) | |||||
Total | VPZ/AMPC/CAM | 125 | 89.6 (82.9–94.3) | 279 | 74.6 (69.0–79.6) | LPZ or RPZ or EPZ/AMPC/CAM | 295 | 71.9 (66.4–76.9) | 548 | 79.0 (75.4–82.4) | |||||
Sugimoto (2017)30 | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 19 | 82.5 (66.9–98.7) | NA | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 14 | 78.6 (49.2–95.3) | NA | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | NA | NA | 43 | 83.7 (69.3–93.2) | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | NA | NA | 76 | 82.9 (72.5–90.6) | NA | NA | NA | NA | NA | |||||
Sue (2017)24† | PST | Sensitive | VPZ/AMPC/CAM | NA | NA | 180 | 88.9 (83.4–93.1) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 56 | 73.2 (59.7–84.2) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | 623 | 84.9 (81.9–87.6) | 376 | 87.2 (83.4–90.4) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | 608 | 78.8 (75.3–82.0) | 603 | 79.4 (76.0–82.6) | |||||
Total | VPZ/AMPC/CAM | 623 | 84.9 (81.9–87.6) | 612 | 86.4 (83.5–89.1) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | 608 | 78.8 (75.3–82.0) | 603 | 79.4 (76.0–82.6) | |||||
Sue (2018)25† | RCT | Sensitive | VPZ/AMPC/CAM | 55 | 87.3 (75.5–94.7) | 54 | 88.9 (77.4–95.8) | LPZ or RPZ or EPZ/AMPC/CAM | 51 | 76.5 (62.5–87.2) | 45 | 86.7 (73.2–94.9) | |||
Resistant | VPZ/AMPC/CAM | 41 | 82.9 (67.9–92.8) | 41 | 82.9 (67.9–92.8) | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | 96 | 85.4 (76.7–91.8) | 95 | 86.3 (77.7–92.5) | LPZ or RPZ or EPZ/AMPC/CAM | 51 | 76.5 (62.5–87.2) | 45 | 86.7 (73.2–94.9) | |||||
Tanabe (2018)31 | RST | Sensitive | NA | NA | NA | NA | NA | LPZ or RPZ or EPZ/AMPC/CAM | 162 | 93.8 (90.1–97.5) | 159 | 95.6 (90.1–97.5) | |||
Resistant | NA | NA | NA | NA | NA | LPZ or RPZ or EPZ/AMPC/MNZ | 50 | 92.0 (80.8–97.8) | 48 | 95.8 (85.7–99.5) | |||||
NA | VPZ/AMPC/CAM | 363 | 91.5 (88.6–94.3) | 341 | 97.4 (95.7–99.1) | LPZ or RPZ or EPZ/AMPC/CAM | 568 | 74.1 (70.3–77.7) | 510 | 82.5 (79.0–85.7) | |||||
Total | VPZ/AMPC/CAM | 363 | 91.5 (88.6–94.3) | 341 | 97.4 (95.7–99.1) | LPZ or RPZ or EPZ/AMPC/CAM | 780 | 79.4 (76.5–82.2) | 717 | 86.3 (83.8–88.8) | |||||
Shinmura (2019)28† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 165 | 93.2 (88.2–96.1) | NA | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 123 | 85.8 (78.5–91.0) | NA | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | NA | 85.0 (81.8–87.8) | 253 | 90.1 (85.8–93.5) | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | NA | 85.0 (81.8–87.8) | 541 | 90.2 (87.4–92.5) | NA | NA | NA | NA | NA | |||||
Saito (2019)32† | RST | Sensitive | VPZ/AMPC/CAM | NA | NA | 28 | 100 (88.9–100) | EPZ/AMPC/CAM | NA | NA | 97 | 93.8 (87.0–97.7) | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 25 | 100 (88.7–100) | EPZ/AMPC/CAM | NA | NA | 65 | 38.5 (26.7–51.4) | |||||
NA | VPZ/AMPC/CAM | 290 | 79.0 (73.8–83.5) | 206 | 85.4 (79.9–90.0) | EPZ/AMPC/CAM | 288 | 65.6 (59.5–70.8) | 110 | 66.4 (56.7–75.1) | |||||
Total | VPZ/AMPC/CAM | 290 | 79.0 (73.8–83.5) | 259 | 88.4 (83.9–92.0) | EPZ/AMPC/CAM | 288 | 65.6 (59.5–70.8) | 272 | 69.5 (63.6–74.9) | |||||
Suzuki (2020)29† | RCT | Sensitive | VPZ/AMPC/CAM | NA | NA | 122 | 95.1 (89.6–98.2) | NA | NA | NA | NA | NA | |||
Resistant | VPZ/AMPC/CAM | NA | NA | 42 | 76.2 (60.5–87.9) | NA | NA | NA | NA | NA | |||||
NA | VPZ/AMPC/CAM | 167 | 89.2 (83.5–93.5) | NA | NA | NA | NA | NA | NA | NA | |||||
Total | VPZ/AMPC/CAM | 167 | 89.2 (83.5–93.5) | 164 | 90.2 (84.6–94.3) | NA | NA | NA | NA | NA | |||||
Suzuki (2016)33† | RST | NA (total) | VPZ/AMPC/CAM | 175 | 89.1 (84.5–93.8) | 171 | 91.2 (87.0–95.5) | LPZ or RPZ/AMPC/CAM | 175 | 70.9 (64.1–77.6) | 173 | 71.7 (64.9–78.4) | |||
Shinozaki (2016)34† | RST | NA (Total) | VPZ/AMPC/CAM | 117 | 82.9 (74.8–89.2) | 114 | 85.0 (77.2–91.1) | LPZ or RPZ or EPZ/AMPC/CAM | 456 | 70.6 (66.0–74.6) | 435 | 74.0 (69.6–78.1) | |||
Shichijo (2016)35† | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 422 | 87.2 (83.6–90.2) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 2,293 | 72.4 (70.5–74.2) | |||
Yamada (2016)36† | RST | NA (total) | VPZ/AMPC/CAM | 335 | 85.7 (81.5–89.2) | 318 | 90.3 (86.4–93.3) | LPZ or RPZ or EPZ/AMPC/CAM | 1,720 | 73.2 (71.0–75.3) | 1,647 | 76.4 (74.3–78.4) | |||
Tsujimae (2016)37† | RST | NA (total) | VPZ/AMPC/CAM | 443 | 84.6 (81.4–88.3) | 439 | 86.3 (82.8–89.4) | EPZ/AMPC/CAM | 431 | 79.1 (75.0–82.9) | 427 | 79.9 (75.7–83.6) | |||
Katayama (2017)38 | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 258 | 90.6 (86.3–93.9) | NA | NA | NA | NA | NA | |||
Kajihara (2017)39† | RST | NA (total) | VPZ/AMPC/CAM | 111 | 94.6 (88.6–98.0) | 110 | 95.5 (89.7–98.5) | RPZ/AMPC/CAM | 98 | 86.7 (78.4–92.7) | 98 | 86.7 (78.4–92.7) | |||
Ono (2017)40† | RST | NA (total) | VPZ/MNZ/CAM | 14 | 92.9 (66.1–99.8) | 14 | 92.9 (66.1–99.8) | LPZ or RPZ/MNZ/CAM | 13 | 46.2 (19.2–74.9) | 11 | 54.6 (23.4–83.3) | |||
Sakurai (2017)41† | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 546 | 87.9 (84.9–90.5) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 807 | 66.9 (63.5–70.2) | |||
Maruyama (2017)42† | RCT | NA (total) | VPZ/AMPC/CAM | 72 | 95.8 (88.3–99.1) | 70 | 95.7 (88.0–99.1) | LPZ or RPZ/AMPC/CAM | 69 | 69.6 (57.3–80.1) | 63 | 71.4 (58.7–82.1) | |||
Nishizawa (2017)43† | RST | NA (total) | VPZ/AMPC/CAM | 353 | 62.3 (57.0–67.4) | 246 | 89.4 (84.9–93.0) | LPZ or RPZ/AMPC/CAM | 2,173 | 47.1 (45.0–49.2) | 1,532 | 66.8 (64.4–69.1) | |||
Tanabe (2017)44 | RST | NA (total) | VPZ/AMPC/CAM | 694 | 82.7 (84.7–89.7) | 641 | 94.4 (92.6–96.2) | NA | NA | NA | NA | NA | |||
Ozaki (2018)45 | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 1,688 | 90.8 (89.3–92.2) | RPZ or EPZ/AMPC/CAM | NA | NA | 147 | 72.8 (64.8–79.8) | |||
Mori (2018)46 | RST | NA (total) | VPZ/AMPC/CAM | 308 | NA | 275 | 91.0 (86.9–94.0) | LPZ/AMPC/CAM | 272 | NA | 249 | 84.7 (79.7–89.0) | |||
Shinozaki (2018)47 | RST | NA (total) | VPZ/AMPC/CAM | 174 | 83.3 (76.9–88.5) | 171 | 84.8 (78.5–89.8) | NA | NA | NA | NA | NA | |||
Kusunoki (2019)48† | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 415 | 92.5 (89.6–94.9) | LPZ or RPZ or EPZ/AMPC/CAM | NA | NA | 757 | 83.9 (81.1–86.5) | |||
Nishida (2019)49 | RST | NA (total) | VPZ/AMPC/CAM | NA | NA | 326 | 71.9 (68.3–75.2) | LPZ or RPZ/AMPC/CAM | NA | NA | 644 | 90.2 (86.5–93.0) | |||
Mori (2019)50† | RST | NA (total) | VPZ/AMPC/CAM | 1,676 | 81.4 (79.4–83.2) | NA | 89.1 (87.4–90.6) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | 2,043 | 62.7 (60.6–64.8) | NA | 69.4 (67.2–71.5) | |||
Furuta (2019)51 | RST | NA (total) | VPZ/AMPC/CAM | 56 | 91.9 (80.4–97.0) | 55 | 92.7 (82.4–98.0) | NA | NA | NA | NA | NA |
All papers that investigated the efficacy of first-line vonoprazan-containing eradication therapy until January 2020 were listed. A total of 4 RCTs and 26 RSTs investigated the efficacy of first-line VPZ-containing therapy. There were many RSTs but few RCTs (Murakami 2016, Maruyama 2017, Sue 2018, Suzuki 2020). Because CAM resistance is becoming a global clinical problem for
CAM, clarithromycin; VPZ, vonoprazan; PPI, proton pump inhibitor; ITT, intention-to-treat analysis; FAS, full analysis set; PP, per-protocol analysis; ER, eradication rate; CI, confidence interval; RCT, randomized controlled trial; PST, prospective interventional trial; RST, retrospective cohort trial; AMPC, amoxicillin; LPZ, lansoprazole; RPZ, rabeprazole; EPZ, esomeprazole; OPZ, omeprazole; MNZ, metronidazole; NA, not available.
*FAS; †Studies were used for meta-analyses.
Table 2 Second-Line Vonoprazan-Based Compared to PPI-Based Eradication Regimen
First author (year) | Method | MNZ susceptible | First-line | VPZ-based eradication regimen | PPI-based eradication regimen | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Regimen | ITT/FAS analysis | PP analysis | Regimen | ITT/FAS analysis | PP analysis | |||||||||||
No. | ER (95% CI), % | No. | ER (95% CI), % | No. | ER (95% CI), % | No | ER (95% CI), % | |||||||||
Murakami (2016)9 | PST | Sensitive | VPZ | VPZ/AMPC/MNZ | 45 | NA | NA | NA | NA | NA | NA | NA | NA | |||
Resistant | VPZ | VPZ/AMPC/MNZ | 4 | NA | NA | NA | NA | NA | NA | NA | NA | |||||
NA | VPZ | VPZ/AMPC/MNZ | 1 | NA | NA | NA | NA | NA | NA | NA | NA | |||||
Total | VPZ | VPZ/AMPC/MNZ | 50 | 98.0 (89.4–99.9)* | NA | NA | NA | NA | NA | NA | NA | |||||
Yamada (2016)36 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 66 | 89.4 (79.4–95.6) | 61 | 96.7 (88.7–99.6) | LPZ or RPZ or EPZ/AMPC/MNZ | 386 | 89.9 (86.4–92.7) | 374 | 92.8 (89.7–95.2) | |||
Tsujimae (2016)37 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 46 | 89.1 (76.4–96.4) | 45 | 91.1 (78.8–97.5) | EPZ/AMPC/MNZ | 54 | 83.3 (70.7–92.1) | 51 | 88.2 (76.1–95.6) | |||
Katayama (2017)38 | RST | NA (total) | VPZ | VPZ/AMPC/MNZ | NA | NA | 23 | 87.0 (66.4–97.2) | NA | NA | NA | NA | NA | |||
Sakurai (2017)41 | RST | NA (total) | NA | VPZ/AMPC/MNZ | NA | NA | 76 | 96.1 (88.9–99.2) | LPZ or RPZ or EPZ/AMPC/MNZ | NA | NA | 185 | 91.6 (86.3–95.0) | |||
Nishizawa (2017)43 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 85 | 71.8 (61.0–81.0) | 63 | 96.8 (89.0–99.6) | LPZ or RPZ/AMPC/MNZ | 650 | 73.7 (70.1–77.0) | 529 | 90.5 (87.7–92.9) | |||
Sue (2017)24 | PST | NA (total) | NA | VPZ/AMPC/MNZ | 216 | 80.5 (74.6–85.6) | 211 | 82.4 (76.6–87.9) | LPZ or RPZ or EPZ/AMPC/MNZ | 146 | 81.5 (74.2–87.4) | 145 | 82.1 (74.8–87.9) | |||
Tanabe (2017)44 | RST | NA (total) | NA | VPZ/AMPC/MNZ | 73 | 90.4 (83.7–97.2) | 68 | 97.1 (93.0–101.1) | NA | NA | NA | NA | NA | |||
Ozaki (2017)45 | RST | NA (total) | VPZ | VPZ/AMPC/MNZ | NA | NA | 94 | 86.3 (77.5–92.4) | NA | NA | NA | NA | NA | |||
Mori (2018)46 | RST | NA (total) | VPZ | VPZ/AMPC/MNZ | NA | NA | 23 | 87.0 (66.4–97.2) | NA | NA | NA | NA | NA | |||
PPI | NA | NA | NA | NA | NA | RPZ/AMPC/MNZ | NA | NA | 33 | 87.9 (71.8–96.6) | ||||||
Kusunoki (2019)48 | RST | NA (total) | NA | VPZ/AMPC/MNZ | NA | NA | 48 | 93.8 (82.8–98.7) | LPZ or RPZ or EPZ/AMPC/MNZ | NA | NA | 108 | 90.7 (83.6–95.5) | |||
Mori (2019)50 | RST | NA (total) | NA | VPZ/AMPC/MNZ | NA | 80.0 | 1,292 | 90.1 (88.3–91.7) | LPZ or RPZ or OPZ or EPZ/AMPC/CAM | NA | 77.6 | 2,280 | 86.6 (85.1–88.0) | |||
Saito (2019)32 | RST | NA (total) | NA | VPZ/AMPC/MMZ | 60 | 81.7 (69.6–90.5) | 54 | 90.7 (79.7–96.9) | EPZ/AMPC/MNZ | 74 | 89.2 (79.8–95.2) | 73 | 90.4 (81.2–96.1) |
All papers that investigated the efficacy of second-line vonoprazan-containing eradication therapy up until March 2019 were listed. A total of 1 PST and 12 RSTs investigated the efficacy of second-line VPZ-containing therapy. There were many RSTs but no RCTs. In 8 studies (Yamada 2016, Tsujimae 2016, Sakurai 2017, Nishizawa 2017, Sue 2017, Kusunoki 2019, Mori 2019, Saito 2019), statistical significance was not found between the VPZ and PPI regimens. This may be because although CAM and AMPC are acid-sensitive antimicrobial agents, MNZ is not an acid-sensitive antimicrobial agent. However, there were no RCTs containing susceptibility information. The first-line regimen is important for the
MNZ, metronidazole; VPZ, vonoprazan; PPI, proton pump inhibitor; ITT, intention-to-treat analysis; FAS, full analysis set; PP, per-protocol analysis; ER, eradication rate; CI, confidence interval; PST, prospective interventional trial; RST, retrospective cohort trial; AMPC, amoxicillin; LPZ, lansoprazole; RPZ, rabeprazole; EPZ, esomeprazole; OPZ, omeprazole; CAM, clarithromycin; NA, not available.
*FAS.