Meta-Analysis of the Efficacy and Adverse Reactions of Ibrutinib in the Treatment of Refractory/Relapsed Mantle Cell Lymphoma ()
1. Introduction
Mantle cell lymphoma (MCL) is a malignant tumor derived from B lymphocytes. It is an invasive and refractory disease that progresses rapidly, and the long-term survival rate is low [1]. The genetic basis of MCL pathogenesis is the abnormality of chromosome t (11; 14) (q13; q32), which elevates the expression of Cyclin D1 and the cell cycle disorder [2]. Although some patients with MCL responded to multi-drug combination chemotherapy, such as R-CHOP (rituximab, cyclophosphamide, Adriamycin, vincristine and prednisone) at the initial diagnosis, relapse was common, and the subsequent prognosis was poor. Currently, there is no standard effective treatment regimen, and the common chemotherapeutic regimens exhibit adverse reactions, which could lead to bone marrow suppression [3] [4]. Thus, study new drugs with low toxicity and improved efficacy.
Bruton’s tyrosine kinase (BTK) is a key enzyme in the B cell receptor (BCR) signaling pathway and plays a critical role in the occurrence and development of MCL [5]. Inhibiting BTK in B-cell malignancies could slow the growth and proliferation of tumor cells; thus, it is deemed as a unique therapeutic target [6]. The BTK inhibitor ibrutinib covalently binds to a cysteine residue (Cys-481) in the ATP binding domain of the BTK active site to inhibit the activity of this enzyme, thereby inhibiting the BCR signal transduction, and inhibiting the proliferation, survival, adhesion, and migration of tumor cells [7] [8]. Clinical studies have confirmed that ibrutinib is an effective drug for R/R MCL and was a major breakthrough in the history of MCL treatment. In 2013, the US FDA approved ibrutinib for the treatment of R/R MCL. Several clinical studies have shown the efficacy of the drug. For example, Dreyling et al. [9] conducted a phase 3 randomized controlled trial to compare the efficacy of ibrutinib and temsirolimus in the treatment of R/R MCL. The study included 280 patients with R/R MCL, including 139 patients in the ibrutinib group and 141 patients in the temsirolimus group. The results showed that the overall response rate (ORR) was 72%, and the complete remission rate (CR) was 19%, which was significantly higher than the ORR (40%) and CR (1%) of the temsirolimus group. Wang et al. [10] recruited 120 patients with R/R MCL in the study to evaluate the therapeutic effect of ibrutinib, and showed that the ORR was 62.7%, and CR was 20.9%. Although ibrutinib achieved a specific effect in the treatment of R/R MCL, adverse reactions, such as bleeding and atrial fibrillation, also occurred during the treatment. The study by Dreyling et al. [9] showed that the occurrence rate of atrial fibrillation ≥ grade 3 and bleeding ≥ grade 3 was 4% and 10%, respectively and the study by Wang et al. [10] showed that the occurrence rate of atrial fibrillation ≥ grade 3 and bleeding ≥ grade 3 was 10.8% and 2%, respectively.
However, the sample size of these individual clinical studies was relatively small, and the results of each clinical study differed due to the variety of definite or uncertain factors. Hence, some clinicians were concerned about the treatment of R/R MCL with ibrutinib, deeming it necessary to conduct a comprehensive systematic analysis of the existing clinical research results on larger sample size and evaluate the clinical efficacy and adverse reactions of ibrutinib in the treatment of R/R MCL, as well as provide guidance for clinical medication.
2. Materials and Methods
2.1. Materials
The literature of clinical studies on ibrutinib in the treatment of R/R MCL before December 1, 2019, was retrieved. The inclusion criteria were as follows: 1) The subjects were >18-year-old; 2) Patients with refractory or relapsed MCL; 3) The treatment regimen was ibrutinib alone or in combination with other drugs; 4) The observation indicators included ORR, CR, two-year progression-free survival (PFS) rate, two-year overall survival (OS) rate, and the occurrence rate of serious adverse reactions (≥grade 3 neutropenia, hemoglobin reduction, thrombocytopenia, infection, atrial fibrillation, and bleeding); 5) If several articles were in the same cohort study, only the results of the last update were included. The exclusion criteria were as follows: 1) MCL patients with initial treatment; 2) Patients with tumors other than MCL; 3) Patients with MCL who relapsed after prior hematopoietic stem cell transplantation treatment; 4) The sample size was small (n < 10); 5) The data were incomplete.
2.2. Methods
2.2.1. Literature Search Methods
The databases in English were searched using the terms, mantle cell lymphoma, MCL, and ibrutinib. The Chinese databases were searched using the Chinese search terms, mantle cell lymphoma and ibrutinib. Also, the subject term and free word search were conducted, and all relevant literature was retrieved to avoid errors caused by excluding any literature.
2.2.2. Data Extraction and Quality Evaluation of Literature
Two investigators searched the Chinese and English databases using the above search terms and read the titles and abstracts of the literature according to the inclusion and exclusion criteria listed above; the full-text of the articles was read for screening if necessary. Finally, the data of the included literature were extracted, and the quality was evaluated. All the above steps were completed independently. In case of any disagreement, a consensus was reached through discussion, and a third-party judgment was approached if necessary. The extracted data included the author of the literature, the number of patients, the time of publication, intervention measures, age, and some indicators to evaluate the efficacy and adverse reactions.
2.2.3. Statistical Methods
R software was used for meta-analysis of the extracted data. The χ2 test was used to evaluate the heterogeneity of the included literature. P < 0.1 indicated heterogeneity between the included literature results, which was assessed by the random effect model. If there was no heterogeneity or if heterogeneity was relatively small, the fixed-effect model was used, and I2 was an indicator that reflected the degree of heterogeneity between multiple research results. Typically, heterogeneity was considered when I2 > 50%, no heterogeneity when I2 < 25%, the heterogeneity was low when I2 was 25% - 0%, greater heterogeneity when I2 was 50% - 75%, and significant heterogeneity when I2 > 75%. Combining P-value and I2 value, it could be considered that if I2 ≥ 50% or P ≤ 0.10 and I2 > 25%, it could be inferred that there was statistical heterogeneity; if I2 ≤ 25% or P > 0.10 and I2 < 50%, it could be inferred that the heterogeneity was small and could be ignored. Each effect size was expressed as a 95% confidence interval (CI, the statistical significance level was set at α = 0.05, and sensitivity analysis was performed if necessary [11].
2.2.4. Publishing Bias
The reliability of meta-analysis results was affected by publication bias, and hence, publication bias analysis was carried out on the included studies. Funnel chart was an intuitive method to evaluate the publication bias. If the included studies had publication bias, the funnel chart was asymmetric, and the more obvious the asymmetry, the greater the publication bias. However, no publication bias was reported if the funnel chart was symmetric.
3. Results
3.1. Literature Search Results
A total of 1800 articles were retrieved from the database, including 1564 in English and 236 in Chinese; 1366 articles were remaining after 434 duplicate documents were excluded. After reading the titles and abstracts, 1289 articles irrelevant to the research topic were removed, and the remaining 77 were retained. Then, 65 articles were removed after reading the full text, including 14 due to incomplete data, 1 was a case report, 8 were reviews, 15 articles as they were same source of a cohort study, next, 7 articles were excluded as they follow an unqualified therapeutic regimen, 3 due to small sample size (n < 10), 6 due to unqualified research model (cell lines research), 6 were retrospective analyses, 4 described unqualified outcome indicators, and 1 study was at the recruitment stage. Finally, 12 articles, in English, were recruited. The study selection process is shown in Figure 1.
Figure 1. Flow chart of studies selection process.
3.2. Baseline Information and Methodological Quality Evaluation of the Included Literature
The 12 articles were cohort studies of refractory or relapsed MCL treated with ibrutinib alone or in combination with other drugs. The basic information was extracted from the included studies, including author, publication date, number of patients, age, treatment regimen, and outcome indicators (Table 1). The baseline data of the 12 studies were similar, and the literature quality was >5 points, which was deemed as satisfactory.
3.3. Meta-Analysis Results
3.3.1. Publication Bias Assessment
R software was used to test the publication bias of the 12 included articles. The funnel chart (Figure 2) indicated basic symmetry but no publication bias.
3.3.2. Evaluation of Efficacy
1) ORR (CR + Partial Remission (PR))
Table 1. Baseline characteristics of the included literature.
The ORR of ibrutinib in the treatment of R/R MCL was assessed in 11 studies. The total number of patients was 724, the number of patients treated with ibrutinib alone was 558, and the number of patients treated with ibrutinib combined with other drugs (palbociclib/rituximab/lenalidomide + rituximab/venetoclax/ublituximab) was 166. The included studies showed large heterogeneity; hence, the random effect model was used. The results of 11 studies showed that the ORR of ibrutinib was 76% (95% CI: 70% - 82%, I2 = 70%, P < 0.01), the ORR of ibrutinib alone was 74% (95% CI: 67% - 82%, I2 = 77%, P < 0.01), and the ORR of ibrutinib combined with other drugs was 81% (95% CI: 75% - 87%, I2 = 44%, P = 0.13). The effect of combination therapy was better than that of monotherapy. The specific results are shown in Figure 3.
2) Complete Remission (CR) Rate
The CR of ibrutinib was 34% (95% CI: 26% - 45%, I2 = 84%, P < 0.01), the CR of ibrutinib monotherapy was 26% (95% CI: 20% - 34%, I2 = 70%, P < 0.01), and the CR of ibrutinib combination therapy was 50% (95% CI: 40% - 63%, I2 = 48%, P = 0.1). The effect of combination therapy was better than that of monotherapy. The specific results were as follows (Figure 4).
Figure 3. ORR of ibrutinib in the treatment of R/R MCL patients. The ORR of ibrutinib in the treatment of R/R MCL was 76% (95% CI: 70% - 82%, I2 = 70%, P < 0.01), the ORR of ibrutinib alone was 74% (95% CI: 67% - 82%, I2 = 77%, P < 0.01), and the ORR of ibrutinib combined with other drugs was 81% (95% CI: 75% - 87%, I2 = 44%, P = 0.13).
Figure 4. CR of ibrutinib in the treatment of R/R MCL patients. The CR of ibrutinib in the treatment of R/R MCL was 34% (95% CI: 26% - 45%, I2 = 84%, P < 0.01), the CR of ibrutinib monotherapy was 26% (95% CI: 20% - 34%, I2 = 70%, P < 0.01), and the CR of ibrutinib combination therapy was 50% (95% CI: 40% - 63%, I2 = 48%, P = 0.1).
3) Two-Year PFS Rate
The two-year PFS rate of R/R MCL patients treated with ibrutinib was evaluated in 4 studies, including 1 of combination therapy in 27 patients and 3 of monotherapy in 266 patients; since, heterogeneity was detected among the groups (I2 = 69%, P = 0.02), random effect model was used. The results showed that the two-year PFS rate of ibrutinib in the treatment of R/R MCL patients was 41% (95% CI: 31% - 54%), and the two-year PFS rate of combination therapy group was 59% (95% CI: 43% - 81%), which was significantly higher than 37% of the monotherapy group 37% (95% CI: 32% - 44%, I2 = 28%, P = 0.25), indicating that the combination therapy could achieve a higher two-year PFS rate than the monotherapy (Figure 5).
4) Two-Year OS Rate
The two-year OS rate of R/R MCL patients treated with ibrutinib was evaluated in 3 studies: 1 study of combination therapy with 27 patients, and 2 studies of monotherapy with 127 patients. The heterogeneity among the groups was small (I2 = 0%, P = 0.81), and hence, the random effect model was used. The results showed that the two-year OS rate of ibrutinib in the treatment of R/R MCL patients was 49% (95% CI: 41% - 57%), and the two-year OS rate of combination therapy group was 59% (95% CI: 40% - 77%), which was significantly higher than 47% (95% CI: 38% - 56%, I2 = 0%, P = 0.81) of the monotherapy group, indicating that the combination therapy had a higher two-year OS rate than monotherapy (Figure 6).
3.3.3. Analysis of Adverse Reactions
Hematological toxicity (neutropenia, hemoglobin reduction, and thrombocytopenia) was a common adverse effect during the treatment of ibrutinib. The hematological toxicity statistics were performed on the included studies. Consequently, the occurrence rate of neutropenia ≥ grade 3 was 17% (95% CI: 12% - 25%, I2 = 82%, P < 0.01), while the occurrence rate of thrombocytopenia ≥ grade
Figure 5. Two-year PFS rate of ibrutinib in the treatment of R/R MCL patients. The two-year PFS rate of ibrutinib in the treatment of R/R MCL patients was 41% (95% CI: 31% - 54%), and the two-year PFS rate of combination therapy group was 59% (95% CI: 43% - 81%), which was significantly higher than 37% of the monotherapy group 37% (95% CI: 32% - 44%, I2 = 28%, P = 0.25).
Figure 6. Two-year OS rate of ibrutinib in the treatment of R/R MCL patients. The two-year OS rate of ibrutinib in the treatment of R/R MCL patients was 49% (95% CI: 41% - 57%), and the two-year OS rate of combination therapy group was 59% (95% CI: 40% - 77%), which was significantly higher than 47% (95% CI: 38% - 56%, I2 = 0%, P = 0.81) of the monotherapy group.
3 (12% (95% CI: 7% - 17%, I2 = 75%, P < 0.01)) and anemia ≥ grade 3 (6% (95% CI: 3% - 9%, I2 = 80%, P < 0.01) was lower than that of neutropenia, respectively. Previous studies reported that ibrutinib treatment increases the occurrence rate of infection, atrial fibrillation, and bleeding. Because the occurrence rate of such adverse reactions was not clear and that of the individual study event was relatively small, the statistical analysis of the included studies was performed. The results showed that the occurrence rate of infection ≥ grade 3 was 18% (95% CI: 12% - 27%, I2 = 63%, P = 0.03), the occurrence rate of atrial fibrillation ≥ grade 3 was 6% (95% CI: 4% - 9%, I2 = 49%, P = 0.05), and the occurrence rate of bleeding ≥ grade 3 was 4% (95% CI: 2% - 6%, I2 = 52%, P = 0.04). The specific results are shown in Figure 7.
4. Discussion
Although some treated MCL responded to first-line combined chemotherapy, relapse was common, and the prognosis of patients with relapse was very poor [20]. However, currently, no uniform standard effective treatment regimen is available for R/R MCL patients. New drugs available for R/R MCL include ibrutinib, temsirolimus, lenalidomide, and bortezomib [21]. Some studies have reported that the ORR and CR rates of ibrutinib in the treatment of R/R MCL were higher than those of any other single drug, which is a major breakthrough in the treatment of R/R MCL [21] [22]. Although ibrutinib has been reported to be efficacious in the treatment of R/R MCL, some differences are noted in the results due to various factors. Therefore, this study systematically analyzed 12 articles to evaluate the efficacy and safety of ibrutinib in the treatment of MCL. The results showed that the ORR (CR + PR) was 76% (95% CI: 70% - 82%), and the heterogeneity (I2 = 70%, P < 0.01) was high. Based on the comprehensive analysis, the heterogeneity might be high due to different drug regimens, and hence,
Figure 7. Occurrence rate of adverse reactions ≥ grade 3 in patients with R/R MCL treated with ibrutinib. Occurrence rate of neutropenia ≥ grade 3 was 17% (95% CI: 12% - 25%, I2 = 82%, P < 0.01), occurrence rate of thrombocytopenia ≥ grade 3 was 12% (95% CI: 7% - 17%, I2 = 75%, P < 0.01)), anemia ≥ grade 3 was (6% (95% CI: 3% - 9%, I2 = 80%, P < 0.01), infection ≥ grade 3 was 18% (95% CI: 12% - 27%, I2 = 63%, P = 0.03), atrial fibrillation ≥ grade 3 was 6% (95% CI: 4% - 9%, I2 = 49%, P = 0.05), bleeding ≥ grade 3 was 4% (95% CI: 2% - 6%, I2 = 52%, P = 0.04).
subgroup analysis was conducted according to the treatment regimen. The results showed that the heterogeneity of the combination therapy group was significantly reduced (I2 = 44%, P = 0.13) and the ORR was 81% (95% CI: 75% - 87%), while the ORR of monotherapy group was 74% (95% CI: 67% - 82%), and the heterogeneity was high (I2 = 77%, P < 0.01), which might be correlated to different previous treatment regiments, different simplified MCL international prognostic index, and various treatment courses. Due to the lack of clinical research data, sub-group stratification analysis could not be repeated. However, the ORR results showed that the therapeutic effect of ibrutinib combined with other drugs was better than that of monotherapy. Therefore, the combination of other drugs for R/R MCL should be considered for patients with poor efficacy of ibrutinib alone or relapse after treatment. In addition to the efficiency, the survival data (PFS, OS) of the patient after treatment was also a critical indicator to evaluate the efficiency of the drug. Hence, statistical analysis was carried out, and the results showed that the two-year PFS rate of ibrutinib in the treatment of R/R MCL patients was 41% (95% CI: 31% - 54%), while the two-year OS rate was 49% (95% CI: 41% - 57%). Because only 3 - 4 included studies observed the survival data, and the sample size was small, more clinical data were needed for a comprehensive evaluation of the disease.
According to research reports, ibrutinib was well tolerated during treatment. The majority of the adverse reactions were grades 1 and 2; however, there were reports of adverse reactions of grade 3 and above. The most frequently reported adverse reactions were hematological toxic reactions (including neutropenia, hemoglobin reduction, thrombocytopenia) and atrial fibrillation, bleeding, infection). The analysis revealed that the occurrence rate of neutropenia was higher than other hematological toxicities, and ibrutinib treatment increased the occurrence rate of infection, atrial fibrillation, and bleeding.
In conclusion, ibrutinib shows a satisfactory efficacy in the treatment of R/R MCL with tolerable adverse reactions. Therefore, it could be recommended as an effective therapeutic regimen for R/R MCL in clinical practice. Nevertheless, the present study had some limitations: 1) There was only one randomized controlled trial (RCT) on this new drug in the treatment of R/R MCL, and the remaining were cohort studies. Hence, the findings are not as reliable as the conclusions obtained by RCT; 2) Presently, only a few studies have studies this new drug for R/R MCL, but the sample size was small. Thus, expand the sample size to conduct a subgroup analysis of the influence of Ki-67 index, MIPI score, and age on the efficacy, is an urgent requirement to obtain accurate results; 3) The drug resistance, the durability of the drug effect, and the safety of long-term adherence to the drug during the ibrutinib treatment for MCL need to be evaluated for long-term follow-up. Therefore, a large number of clinical studies are essential for a comprehensive assessment of ibrutinib treatment of R/R MCL and to guide the selection of clinical medication.
Acknowledgements
We would like to express gratitude to the staff of the Jiangxi Key Laboratory of Molecular Medicine and those of Department of Hematology, the Second Affiliated Hospital of Nanchang University.
Authors’ Contributions
M. Cao and J. Li participated in the design and conception of the study.
M. Cao, X. Y. Zhang, Y. Z. Yang and X. Y. Jiang collected data. M. Cao and Y. S. Tu analyzed and interpreted the data (e.g., statistical analysis, biostatistics, computational analysis). Y. S. Tu and M. Cao wrote the manuscript, which was reviewed and edited by J. Li. M. Cao, X. K. Wang, J. Li and H. J. Tu developed the methodology. Y. Z. Yang, X. K. Wang and X. Y. Jiang provided administrative, technical, or material support (i.e., reporting or organizing data, constructing databases). J. Li and H. J. Tu supervised the study. All authors read and approved the final manuscript.
Funding Sources
This study is supported by Grants from Natural Science Foundation of Jiangxi Province (20171BAB205045), National Natural Science Foundation of China (81760033).
Ethics Approval
All procedures followed were in accordance with the ethical standards of the responsible committee on human experimentation (institutional and national) and with the Helsinki Declaration of 1975, as revised in 2008.
Consent to Participate
Informed consent was obtained from all patients for being included in the study.
Consent for Publication
All authors approved the manuscript and gave their consent for publication.
NOTES
*M. Cao and Y.S. Tu contribute equally to this study and share first authorship.
#Corresponding author.