Chlortetracycline, the first tetracycline compound, was introduced in the 1950s. Shortly thereafter, Duggar et al[15] analyzed the mutant of chlortetracycline in Staphylococcus aureus and revealed demeclocycline, a precursor, which was further reduced and transformed into minocycline. Minocycline is a tetracycline derivative with a similar mechanism of action to that of tetracycline. It enters the bacteria mainly through the outer membrane protein channel and specifically binds to A site of the 30S subunit aminoacyl group of bacterial ribosomes, thereby blocking the aminoacyl-tRNA binding at this site, preventing peptide chain extension and bacterial protein synthesis, and playing the bactericidal role[16] (Figure 1). The affinity between minocycline and ribosome is 20 times higher and the in vitro translational suppression efficiency is 2-7 times higher than that of tetracycline. Therefore, minocycline demonstrated better and more potent bactericidal effects[17,18]. Minocycline contains a broad antimicrobial spectrum covering Gram-positive cocci, Gram-negative bacilli, and cocci, as well as atypical pathogens[16].

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Figure 1 Scheme of the minocyclines’ mechanism of action. Amino acids and tRNAs are linked together by aminoacyl-tRNA synthetase to produce specific Aminoacyl-tRNAs. ribosomes on the ribosomal complex then read the code along the 5’-3’ direction of the mRNAs while linking various aminoacyl-tRNA-transported amino acids according to the instructions of the mRNA coding sequences for the process of protein synthesis. When minocycline enters into bacteria, it specifically binds to the A site of bacterial ribosomal 30S subunit aminoacyl group, thus blocking the aminoacyl-tRNA binding at this site, preventing peptide chain elongation and bacterial protein synthesis, and exerting bactericidal effects. AA: Amino acids.

Minocycline has a longer serum half-life than tetracycline of up to 12-18 h and can reach the peak plasma concentration within 2-3 h after oral administration. Minocycline is only taken once or twice daily and is not taken as frequently as tetracycline, which helps improve treatment compliance[12,19]. Compared with tetracycline, minocycline is not susceptible to food impact and has a high absorption rate, which is conducive to obtaining better bioavailability[19]. Minocycline demonstrated better lipid solubility and tissue permeability than other tetracyclines, which are beneficial to improving drug distribution and concentration in tissues[20]. Minocycline is almost completely absorbed in the duodenum and jejunum (95%-100%), widely distributed in body fluids, bile, and tissues, and mainly excreted through feces (20%-34%) and kidneys (5%-15%)[19].

In 2009, Horiki et al[21] discussed the antibiotic resistance rate of the H. pylori strain (n = 3521) in an investigation in Japan from 1996 to 2008, and they revealed a very low primary drug resistance rate of minocycline [0.06% (2/3, 521)]. Five studies from China, including drug resistance testing, clinical cohort, and randomized controlled trials (RCTs), discussed the drug resistance of minocycline in the Chinese mainland. The results indicated a low drug resistance rate of minocycline (approximately 0.7%-8.2%), which was similar to that of tetracycline in the same period[11,22-25]. A study in Japan evaluated the antibacterial activity, i.e., the minimum inhibitory concentration (MIC) of minocycline against clarithromycin-resistant H. pylori strain, and revealed MIC50 and MIC90 of 0.5 μg/mL, which were similar to those of tetracycline (1 μg/mL), indicating that minocycline, similar to tetracycline, had significantly sensitive antibacterial activity against H. pylori strain[21]. Further, Murakami et al[26] concluded similar results. The in-depth study of antibiotic resistance revealed that tetracycline resistance mutation has been discovered in the stem-loop of the 31^st helix of 16S rRNA of H. pylori strain, with the triple mutation A965U/G966U/A967C, conferring high-level resistance against tetracycline as well as an increased MIC for minocycline[27].

We conducted a comprehensive literature retrieval and meta-analysis, which was described in detail below, to explore the eradication rates, adverse reaction incidences, and minocycline-containing regimens compliance.

Literature retrieval: PRISMA statement guidelines were followed for conducting and reporting the meta-analysis data. We have conducted a comprehensive and systematic retrieval in PubMed, Web of Science, EMBASE, China National Knowledge Infrastructure, SinoMed and Wanfang database. The retrieval cut-off date was October 30, 2023. The retrieval keywords included (Minocycline) AND (Helicobacter pylori OR Helicobacter nemestrinae OR Campylobacter pylori OR Campylobacter pylori subsp. pylori OR Campylobacter pyloridis OR H. pylori OR Hp) AND (Eradication OR Therapeutics OR Therapeutic OR Therapy * OR Treatment * OR Eradicate * OR Regimen *).

Literature inclusion criteria were minocycline contained in H. pylori infection eradication regimen; adult patients over 18 years old; specific information of eradication regimens obtained, including drug types, dosages, frequencies, and treatment durations; reported numbers of successful and unsuccessful eradication in patients. Literature exclusion criteria were treatment duration of < 7 d; repeated studies; and loss to follow-up rate of > 20%.

First, preliminary screening was conducted on the included articles by titles, abstracts, and keywords. The remaining study reports passing the preliminary screening were then subjected to further review as per inclusion and exclusion criteria. Finally, the full text was thoroughly and carefully reviewed. We did not limit the minimum sample size in the analysis to reduce the bias. Figure 2 shows the process for article retrieval, screening, and inclusion.

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Figure 2 Literature identification process.

Literature quality evaluation: Both authors (Zhou K and Li CL) used the Cochrane bias risk tool to assess bias risk in a single study across five domains, i.e., selection bias, performance bias, detection bias, reporting bias, and other biases. Any disagreements were resolved through discussions with the expert (Song ZQ). The standard answers included: (1) Yes, indicating a high bias risk; (2) No, indicating a low bias risk; and (3) Unclear, indicating an uncertain bias risk.

Data extraction: All retrieved studies were loaded into the Endnote X9, which is a reference management software. Two authors (Zhou K and Li CL) extracted and recorded the following study data in pre-designed information extraction tables, including author, publication year, study country, study type, patient type, drug dose and frequency, sample size, treatment course, eradication rate, compliance, safety, and drug resistance rate. The two authors extracted the data independently and cross-checked them. Pre-extraction was performed before formal data extraction to assess the rationality of the data extraction table design and the consistent degree of understanding of the same issue. The two authors first communicated and resolved disagreements that arose during the extraction process. If disagreements persist, consensus is reached through discussions with the expert (Song ZQ).

Data analysis: The meta package of the R program (version 4.2.2) was used for the combined analysis of the single-arm eradication rates. The heterogeneity was investigated using I². I² of > 50% is considered a heterogeneity, and the random effect model was adopted to assess the effect size of included studies; otherwise, the fixed effect model was utilized. A relatively large heterogeneity was observed in the single-arm eradication rates. Therefore, the eradication rates in intention-to-treat (ITT) and per-protocol (PP) analyses and the corresponding 95% confidence interval (CI) were respectively summarized by the random effect model. Funnel plot, Egger’s test, and Begg’s test were used to evaluate the publication bias, and publication bias was considered if P values were < 0.05. Sensitivity analysis was conducted by assessing the stability of the results by deleting each study in turn.

Table 1 shows the specific information of the included studies (n = 22)[11,12,23-26,28-43]. A total of 36 minocycline-containing treatment groups were found in 22 studies, including 19 treatment-naive and 17 retreatment groups. Regarding the eradication regimen type, 5 treatment groups in 2 studies received triplet minocycline-containing regimens, 30 treatment groups in 21 studies received quadruplet minocycline-containing regimens, and 1 treatment group received quadruple therapy combined with probiotics. Of the included studies, 20 originated from China, 1 from Japan, and 1 from Italy. Regarding treatment course, 4 treatment groups (n = 177) in 2 studies adopted a 7-d course, 7 treatment groups (n = 332) in 5 studies adopted a 10-d course, and 16 studies (n = 2588) adopted a 14-d course. Regarding study design type, 1 study used a randomized grouping approach in treatment-naive patients, and patients in the salvage treatment group were assigned to different treatment regimen subgroups according to metronidazole-resistance status. Among the remaining 21 studies, 11 were RCTs and 10 were cohort studies.

Regarding antibiotic combinations in the minocycline-containing eradication regimens, nitroimidazole antibiotics (metronidazole, tinidazole, or ornidazole) were combined in 14 treatment groups from 12 studies[12,23-26,28,32,36-40], amoxicillin was combined in 17 treatment groups from 11 studies[11,26,29-31,33,34,36,41-43], and faropenem, levofloxacin, cefuroxime, furazolidone, and rifabutin were respectively combined in 1 treatment group[25,26,28,35,37]. Overall eradication rates of minocycline-containing eradication regimens were 82.3% (95%CI: 79.7%-85.1%, I² = 70%, P < 0.01) in ITT analysis and 90.0% (95%CI: 87.7%-92.4%, I² = 80%, P < 0.01) in PP analysis. The included studies demonstrated a high degree of heterogeneity. The pooled analysis included the overall eradication rates of the minocycline-containing regimens, the combination regimen of minocycline-containing and nitroimidazole antibiotics, the combination regimen of minocycline-containing and amoxicillin, the eradication rates in treatment-naive patients, and the eradication rates in retreated patients. Table 2 shows the results (see the appendix for details of the corresponding forest plots). Additionally, the overall incidence of adverse reactions in minocycline-containing eradication regimens was 36.5% (95%CI: 31.5%-42.2%)[9,11,12,23-25,31-33,36-38] (Supplementary Figures 1-10).

Comparison of efficacy of quadruplet eradication regimens with and without minocycline: The analysis included five RCTs that adopted minocycline-containing quadruple regimens[23-25,32,36]. Combinations of antibiotics in the minocycline-containing groups included metronidazole (n = 5), amoxicillin (n = 1), and cefuroxime (n = 1) and that in the control group included a tetracycline with metronidazole (n = 2), amoxicillin with clarithromycin (n = 2), and cefuroxime with metronidazole (n = 1). The figure shows no obvious heterogeneity in the ITT analysis using the fixed effect model (χ² = 3.51, P = 0.48, I² = 0), and the eradication efficacy between the quadruple regimens with and without minocycline was not statistically significantly different [risk ratio (RR) = 1.03, 95%CI: 0.98-1.07, P = 0.22]. The PP analysis revealed similar results to the ITT analysis. The two groups demonstrated no significant heterogeneity (χ² = 6.17, P = 0.19, I² = 35%) and no statistically significant difference in efficacy (RR = 1.03, 95%CI: 1.00-1.07, P = 0.07). ITT and PP analyses revealed the eradication rates of quadruple regimens with and without minocycline of 83.8% vs 82.4% and 91.1% vs 89.3%, respectively (Figure 3).

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Figure 3 Forest plots comparing eradication rates for intention-to-treat and per-protocol analyses of quadruple regimens with and without minocycline. CI: Confidence interval.

Comparison of eradication efficacy between quadruple regimens with or without minocycline and nitroimidazole antibiotics: The analysis included five RCTs that adopted minocycline-containing quadruple regimens with nitroimidazole antibiotics[23-25,32,36]. The combination of antibiotics in the control groups included tetracycline and metronidazole (n = 2), amoxicillin and clarithromycin (n = 2), cefuroxime and metronidazole (n = 1), minocycline and amoxicillin (n = 1), and minocycline and cefuroxime (n = 1). ITT analysis using a fixed effect model indicated no obvious heterogeneity (χ² = 0.36, P = 0.99, I² = 0) or statistically significant difference in the eradication efficacy between quadruple regimens with or without minocycline and nitroimidazole antibiotics (RR = 1.00, 95%CI: 0.96-1.05, P = 0.91). The PP analysis revealed similar results to those of the ITT analysis. The two groups demonstrated no obvious heterogeneity (χ² = 0.44, P = 0.98, I² = 0) and no statistically significant difference in efficacy (RR = 1.01, 95%CI: 0.98-1.04, P = 0.56). ITT and PP analyses revealed that the eradication rates of quadruple regimens with or without minocycline and nitroimidazole antibiotics were 83.7% vs 82.8% and 91.4% vs 89.6%, respectively (Figure 4).

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Figure 4 Forest plots comparing eradication rates for intention-to-treat and per-protocol analyses of quadruple regimens with and without minocycline-metronidazole. CI: Confidence interval.

The overall incidences of adverse reactions to minocycline-containing eradication regimens in the five studies were 22.6%-55.4%[23-25,32,36]. Most of the adverse reactions, mainly including inappetence, asthenia, abdominal discomfort, abdominal pain, diarrhea, headache, dizziness, nausea, vomiting, dysgeusia, rash, etc., were mild to moderate and well-tolerated. Figure 5A shows no statistically significant difference in the incidences of adverse reactions between the quadruple regimens with and without minocycline (RR = 0.94, 95%CI: 0.84-1.06, I² = 0, P = 0.63). Among them, 16% of patients treated with the minocycline-containing eradication regimens developed dizziness symptoms. Further comparative analysis (Figure 5B) revealed that significantly more patients adopting eradication regimens with minocycline developed dizziness than those adopting eradication regimens without minocycline (23.4% vs 10.4%, P < 0.001). Additionally, minocycline-containing eradication regimens demonstrated better compliance (≥ 90%) in treatment-naive and retreated patients.

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Figure 5 Comparison of the incidence of adverse reactions of quadruple therapy and dizziness in quadruple therapy with and without minocycline. A: Comparison of the incidence of adverse reactions of quadruple therapy with and without minocycline; B: Comparison of the incidence of dizziness in quadruple therapy with and without minocycline. CI: Confidence interval.

Funnel plots of all included studies were plotted through ITT and PP analyses[11,12,23-26,28-43]. The funnel plots were all asymmetric, and the P values of Begg’s test and Egger’s test were < 0.05, indicating a risk of publication bias. Sensitivity analysis was conducted on the comprehensive results of the included studies by deleting each study in turn. The results were stable and the combination results fluctuated within a small range (Figures 6 and 7). We used the Cochrane Bias Risk Tool to evaluate the risk of bias in the study[23-25,32,36] and revealed that these five RCTs were mostly low risk in terms of selection, follow-up, and reporting biases, while high and unclear risks in terms of performance, measurement, and other biases (the bias risk plot was detailed in the Supplementary Figure 11).

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Figure 6 Funnel plots of all included studies through intention-to-treat and per-protocol analyses. A: Intention-to-treat analyses; B: Per-protocol analyses.

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Figure 7 Sensitivity analysis of all included studies by sequentially removing each study with intention-to-treat and per-protocol analyses. A: Intention-to-treat analyses; B: Per-protocol analyses. CI: Confidence interval.