Hui Wei1, Chunlin Zhou2, Dong Lin2, Bingcheng Liu2, Yan Li2, Xingli Zhao2, Shuning Wei2, Benfa Gong2, Kaiqi Liu2, Xiaoyuan Gong2, Yuntao Liu2, Guangji Zhang2, Jiayuan Chen3, Junping Zhang2, Jingjing Jin2, Shaowei Qiu2, Runxia Gu2, Ying Wang4, Yingchang Mi1, Jianxiang Wang5. 1. State Key Laboratory of Experimental Hematolog; National Clinical Research Center for Blood Disease; Leukemia center, Institute of Hematology and Blood Diseases Hospital, Chinese Academy of Medical Sciences. 2. Leukemia center, Institute of Hematology and Blood Diseases Hospital, Chinese Academy of Medical Sciences. 3. State Key Laboratory of Experimental Hematolog. 4. National Clinical Research Center for Blood Disease; Leukemia center, Institute of Hematology and Blood Diseases Hospital, Chinese Academy of Medical Sciences. 5. State Key Laboratory of Experimental Hematolog; National Clinical Research Center for Blood Disease; Leukemia center, Institute of Hematology and Blood Diseases Hospital, Chinese Academy of Medical Sciences. wangjx@ihcams.ac.cn.
The outcome of acute myeloid leukemia (AML) is affected by disease characteristics as well as treatment regimens.[1-3] In the CALGB8525 trial, patients with core binding factor (CBF)-positive leukemia benefited from consolidation with a high dose of cytarabine.[4] More recently, high-dose daunorubicin (60-90 mg/m[2]) has become widely used.[5,6] High-dose daunorubicin confers a favorable prognosis for patients with NPM1 mutations. [1,7,8]Higher-dose cytarabine was also introduced into AML induction therapy.[3,9] Recently, we investigated the role of intermediate-dose cytarabine in induction therapy of AML and found that the introduction of intermediatedose cytarabine, combined with daunorubicin and omacetaxine mepesuccinate, improved outcomes in patients with new-diagnosed AML.[2] Overall, 591 patients aged 15 to <55 years with de novo newly-diagnosed AML were enrolled in our study, registered at (trial identifier: ChiCTR-TRC-10001202), as described in detail in our previous report.[2] The characteristics of the patients at study entry were included in that report.[2] The distribution of the cytogenetic and mutation subgroups is shown in Online Supplementary Table S1. Eligible patients were randomly-assigned to conventional-dose cytarabine (100 mg/m[2]/day on days 1-7 as a 12-h intravenous infusion) or intermediate-dose cytarabine (100 mg/m[2]/day on days 1-4 as a 12-h intravenous infusion and 1 g/m[2] every 12 h as a 3-h intravenous infusion on days 5-7). Patients also received daunorubicin (40 mg/m[2]/day on days 1-3) and omacetaxine mepesuccinate (2 mg/m[2]/day on days 1-7) (see the Online Supplementary Materials and Methods for details). Here we updated results with longer follow-up and focused on the benefit of intermediate-dose cytarabine induction in molecular subgroups of AML. The median follow-up time of survivors in the current report was 70 months (range, 5-115 months).In total, 107 of 591 patients underwent allogeneic transplantation in first complete remission (CR1). With longer follow-up, the induction regimen with intermediate- dose cytarabine improved relapse-free survival (RFS), event-free survival (EFS), and overall survival (OS) in the entire cohort compared with outcomes achieved with conventional-dose cytarabine (Online Supplementary Figure S1), as before.[2] The intermediate-dose cytarabine still improved RFS, EFS, and OS in patients with intermediate- risk cytogenetics (Online Supplementary Table S2). Intermediate-dose cytarabine produced better RFS and EFS in patients with favorable cytogenetics in univariate and multivariable analyses, as shown in Online Supplementary Table S2 and Online Supplementary Figure S2. However, intermediate-dose cytarabine was not associated with better OS, despite the longer follow-up, in patients with favorable cytogenetics. We were unable to determine the benefit of intermediate-dose cytarabine in the adverse cytogenetic cohorts due to small sample sizes.Overall, there were 75 patients with CEBPA double mutations (CEBPAdm) in our cohort, including 32 in the conventional-dose group and 43 in the intermediate-dose group. Intermediate-dose cytarabine did not increase the complete remission rate in patients with CEBPAdm (95% and 100% in the intermediate-dose and conventionaldose cytarabine groups, respectively; P=0.504). Intermediate-dose cytarabine did, however, produce better RFS and EFS rates and showed a marked tendency to improve the OS of patients with CEBPAdm in both univariate and multivariable analyses, as shown in Online Supplementary Table S2. Five-year RFS, EFS, and OS rates were 85%, 81%, and 88% in the intermediate-dose compared with 56%, 56%, and 68% in the conventionaldose group, respectively (Figure 1). In total, 13 of 75 (17%) patients with CEBPAdm AML underwent allogeneic transplantation in CR1, including five of 32 (16%) in the conventional-dose group and eight of 43 (19%) in the intermediate-dose group. To analyze results in the absence of any possible contributory effect of transplantation, patients were censored at the time of transplantation in CR1. Patients with CEBPAdm AML exposed to intermediate-dose cytarabine achieved an increase in 5- year RFS, censored at the date of transplantation, from 56% to 83% (hazard ratio [HR], 0.313; 95% confidence interval [95% CI]: 0.119-0.824; Wald P=0.019) (Online Supplementary Figure S3). Intermediate-dose cytarabine showed a tendency to increase EFS and OS rates, censored at the date of transplantation, from 58% to 79% (HR, 0.420; 95% CI: 0.174-1.013; Wald P=0.053), and from 74% to 89% (HR, 0.398; 95% CI: 0.133-1.187; Wald P=0.099), respectively (Online Supplementary Figure S3). We found a significant interaction between treatment assignment and CEBPAdm status in RFS (P=0.042), but not EFS (P=0.184) or OS (P=0.119). The hazard ratios for relapse or death of CEBPAdm AML compared with other types of AML were 0.298 (95% CI: 0.130-0.682; Wald P=0.004) in the intermediate-dose cytarabine group and 0.829 (95% CI: 0.473-1.453; Wald P=0.513) in the conventional-dose cytarabine group (Figure 1). The data indicated that the favorable RFS of patients with CEBPAdm AML depended on treatment assignment. After adjusting for the presence of FLT3-ITD and transplantation in CR1, the interaction between treatment assignment and CEBPAdm status still existed for RFS (P=0.042), but not for EFS (P=0.215) or OS (P=0.148).
Figure 1.
Patients with acute myeloid leukemia with (A) Relapse-free survival, (B) eventfree survival, and (C) overall survival are shown for patients with CEBPA double mutations and other types of acute myeloid leukemia by receipt of intermediate- dose or conventional-dose cytarabine induction. AML: acute myeloid leukemia: HR: hazard ratio; 95%CI: 95% confidence interval.
The OS and RFS rates of AMLpatients with CEBPAdm are approximately 54%-63% and 44-48%, respectively.[10-13] However, relapsed patients with CEBPAdm have a favorable outcome after reinduction followed by allogeneic transplantation. Schlenk et al. proposed both strategies, allogeneic or autologous transplantation in CR1 versus intensive chemotherapy in CR1, and reinduction followed by allogeneic transplantation in the case of relapse.[13] We demonstrated that CEBPAdm AMLpatients receiving intermediate-dose cytarabine had a remarkable increase in RFS as well as in RFS rates censored at the date of allogeneic transplantation. This indicated that more patients would not relapse and did not need transplantation after intermediate-dose cytarabine induction therapy.Overall, there were 131 patients with RUNX1- RUNX1T1 in our cohort, including 60 in the conventional- dose group and 71 in the intermediate-dose group. Intermediate-dose cytarabine did not increase the complete remission rate in patients with RUNX1-RUNX1T1 compared to that in patients treated with conventionaldose cytarabine (97% and 93%; P=0.528). However, intermediate-dose cytarabine produced better RFS and EFS and showed a marked tendency to improve OS in patients with RUNX1-RUNX1T1 in both univariate and multivariable analyses, as shown in Online Supplementary Table S2. The 5-year RFS, EFS, and OS rates in patients with RUNX1-RUNX1T1AML were 72%, 70%, and 74% in the intermediate-dose cytarabine group compared to 56%, 52%, and 58% in the conventional-dose group, respectively (Figure 2). There was no interaction between the treatment assignment and RUNX1-RUNX1T1 status (RFS: P=0.300; EFS: P=0.383; OS: P=0.391). All patients with CBFB-MYH11AML achieved complete remission after both intermediate-dose and conventional-dose cytarabine. We were unable to determine the impact of intermediate-dose cytarabine in patients with CBFBMYH11AML since there were only 33 patients with CBFB-MYH11 in our cohort.
Figure 2.
Outcomes of patients with (A) Relapse-free survival, (B) event-free survival, and (C) overall survival. HR: hazard ratio; 95%CI: 95% confidence interval.
Patients with acute myeloid leukemia with (A) Relapse-free survival, (B) eventfree survival, and (C) overall survival are shown for patients with CEBPA double mutations and other types of acute myeloid leukemia by receipt of intermediate- dose or conventional-dose cytarabine induction. AML: acute myeloid leukemia: HR: hazard ratio; 95%CI: 95% confidence interval.Outcomes of patients with (A) Relapse-free survival, (B) event-free survival, and (C) overall survival. HR: hazard ratio; 95%CI: 95% confidence interval.In this subgroup analysis of our trial, our data suggested that AMLpatients with RUNX1-RUNX1T1 benefited from intermediate-dose cytarabine induction. Previous reports also indicated that a higher dose of cytarabine improved the outcome in patients with RUNX1-RUNX1T1AML.[14,15] Hence, all these data suggest that an induction regimen with an intensified dose of cytarabine benefits patients with RUNX1-RUNX1T1AML.There were a total of 89 patients with NPM1 mutations, regardless of FLT3-ITD mutation status, in our cohort, including 51 in the conventional-dose group and 38 in the intermediate-dose group. There were 66 patients with FLT3-ITD mutations, regardless of NPM1 mutations, including 35 in the conventional-dose group and 31 in the intermediate-dose group. Intermediate-dose cytarabine did not increase the complete remission rate or improve RFS, EFS, or OS compared to conventional-dose cytarabine in patients with NPM1 or FLT3-ITD mutations, as shown in Online Supplementary Table S2. In patients with NPM1 mutations, the 5-year RFS, EFS, and OS rates were 68%, 63%, and 70% in the intermediate-dose cytarabine group compared to 61%, 53%, and 65% (Figure 3A-C), respectively, in the conventional-dose group. In patients with FLT3-ITD mutations, the 5-year RFS, EFS, and OS rates were 68%, 48%, and 58% in the intermediate-dose cytarabine group compared to 50%, 34%, and 45% (Figure 3DF), respectively, in the conventional-dose group. We then investigated the impact of intermediate-dose cytarabine in NPM1+/FLT3-ITD–, NPM1+/FLT3–ITD+, and NPM1–/FLT3- ITD+ subgroups. Intermediate-dose cytarabine did not increase complete remission rate or improve RFS, EFS, or OS compared to conventional-dose cytarabine in all these subgroups, as shown in Online Supplementary Table S3.
Figure 3.
Outcomes of (A) Relapse-free survival, (B) event-free survival, and (C) overall survival of patients with NPM1 mutations. (D) Relapse-free survival, (E) event-free survival, and (F) overall survival of patients with FLT3-ITD mutation. HR: hazard ratio; 95%CI: 95% confidence interval.
Outcomes of (A) Relapse-free survival, (B) event-free survival, and (C) overall survival of patients with NPM1 mutations. (D) Relapse-free survival, (E) event-free survival, and (F) overall survival of patients with FLT3-ITD mutation. HR: hazard ratio; 95%CI: 95% confidence interval.Death rates within 30 days were similar in the intermediate- and conventional-dose cytarabine induction cohorts.[2] There were no significant differences in RFS, OS, cumulative incidence of relapse or cumulative incidence of death in complete remission between the consolidation regimens even with longer follow-up (data not shown). With inclusion of the second randomization in multivariable analyses, the conclusions regarding outcomes depending on induction treatment were not modified by the second randomization, as shown in Online Supplementary Table S4, except that the OS in the intermediate cytogenetic-risk group was not significantly different, but with a trend, and no difference in EFS in the poor cytogenetic-risk group.In this subgroup analysis with updated follow-up, we demonstrated that AMLpatients with CEBPAdm and RUNX1-RUNX1T1 might benefit from intermediate-dose cytarabine induction. AMLpatients with CEBPAdm had a more favorable RFS than others only when treated with intermediate-dose cytarabine induction. Intermediate-dose cytarabine did not, however, improve outcomes in AMLpatients with NPM1 or FLT3-ITD mutations. Luskin et al. suggested that anthracycline dose intensification induction conferred a favorable prognosis for AMLpatients with NPM1 mutations.[7] These data indicate that AMLpatients with different mutations might benefit from intensified doses of different drugs. Recently, novel drugs, such as gemtuzumabozogamicin, FLT3 inhibitors and so on, are being used in clinical practice. Prospective trials would be needed to confirm the benefit of induction with intermediate- dose cytarabine, especially when novel drugs are used.
Authors: Hartmut Döhner; Elihu Estey; David Grimwade; Sergio Amadori; Frederick R Appelbaum; Thomas Büchner; Hervé Dombret; Benjamin L Ebert; Pierre Fenaux; Richard A Larson; Ross L Levine; Francesco Lo-Coco; Tomoki Naoe; Dietger Niederwieser; Gert J Ossenkoppele; Miguel Sanz; Jorge Sierra; Martin S Tallman; Hwei-Fang Tien; Andrew H Wei; Bob Löwenberg; Clara D Bloomfield Journal: Blood Date: 2016-11-28 Impact factor: 22.113
Authors: Erdogan Taskesen; Lars Bullinger; Andrea Corbacioglu; Mathijs A Sanders; Claudia A J Erpelinck; Bas J Wouters; Sonja C van der Poel-van de Luytgaarde; Frederik Damm; Jürgen Krauter; Arnold Ganser; Richard F Schlenk; Bob Löwenberg; Ruud Delwel; Hartmut Döhner; Peter J M Valk; Konstanze Döhner Journal: Blood Date: 2010-12-21 Impact factor: 22.113
Authors: Bas J Wouters; Bob Löwenberg; Claudia A J Erpelinck-Verschueren; Wim L J van Putten; Peter J M Valk; Ruud Delwel Journal: Blood Date: 2009-01-26 Impact factor: 22.113
Authors: Roelof Willemze; Stefan Suciu; Giovanna Meloni; Boris Labar; Jean-Pierre Marie; Constantijn J M Halkes; Petra Muus; Martin Mistrik; Sergio Amadori; Giorgina Specchia; Francesco Fabbiano; Francesco Nobile; Marco Sborgia; Andrea Camera; Dominik L D Selleslag; Francois Lefrère; Domenico Magro; Simona Sica; Nicola Cantore; Meral Beksac; Zwi Berneman; Xavier Thomas; Lorella Melillo; Jose E Guimaraes; Pietro Leoni; Mario Luppi; Maria E Mitra; Dominique Bron; Georges Fillet; Erik W A Marijt; Adriano Venditti; Anne Hagemeijer; Marco Mancini; Joop Jansen; Daniela Cilloni; Liv Meert; Paola Fazi; Marco Vignetti; Silvia M Trisolini; Franco Mandelli; Theo de Witte Journal: J Clin Oncol Date: 2013-12-02 Impact factor: 44.544
Authors: Richard F Schlenk; Erdogan Taskesen; Yvette van Norden; Jürgen Krauter; Arnold Ganser; Lars Bullinger; Verena I Gaidzik; Peter Paschka; Andrea Corbacioglu; Gudrun Göhring; Andrea Kündgen; Gerhard Held; Katharina Götze; Edo Vellenga; Juergen Kuball; Urs Schanz; Jakob Passweg; Thomas Pabst; Johan Maertens; Gert J Ossenkoppele; Ruud Delwel; Hartmut Döhner; Jan J Cornelissen; Konstanze Döhner; Bob Löwenberg Journal: Blood Date: 2013-07-17 Impact factor: 22.113
Authors: J F Bishop; J P Matthews; G A Young; J Szer; A Gillett; D Joshua; K Bradstock; A Enno; M M Wolf; R Fox; R Cobcroft; R Herrmann; M Van Der Weyden; R M Lowenthal; F Page; O M Garson; S Juneja Journal: Blood Date: 1996-03-01 Impact factor: 22.113
Authors: R J Mayer; R B Davis; C A Schiffer; D T Berg; B L Powell; P Schulman; G A Omura; J O Moore; O R McIntyre; E Frei Journal: N Engl J Med Date: 1994-10-06 Impact factor: 91.245
Authors: C H Li; S N Wei; S W Qiu; B F Gong; X Y Gong; Y Li; Y T Liu; Q Y Fang; G J Zhang; K Q Liu; C L Zhou; D Lin; B C Liu; Y Wang; Y C Mi; H Wei; J X Wang Journal: Zhonghua Xue Ye Xue Za Zhi Date: 2022-04-14
Figure 1.
Figure 2.
Figure 3.