Korean J Hematol 2010; 45(2):
Published online June 30, 2010
https://doi.org/10.5045/kjh.2010.45.2.95
© The Korean Society of Hematology
1Department of Internal Medicine, Asan Medical Center, University of Ulsan College of Medicine, Seoul, Korea.
2Department of Internal Medicine, Seoul National University Hospital, Seoul National University College of Medicine, Seoul, Korea.
3Department of Internal Medicine, Samsung Medical Center, Sungkyunkwan University School of Medicine, Seoul, Korea.
4Department of Preventive Medicine, University of Ulsan College of Medicine, Seoul, Korea.
Correspondence to : Correspondence to Sung-Soo Yoon, M.D. Department of Internal Medicine, Seoul National University College of Medicine, Clinical Research Institute, Seoul National University Hospital, 28, Yeongeon-dong, Jongno-gu, Seoul 110-744, Korea. Tel: +82-2-2072-3079, Fax: +82-2-762-9662, ssysmc@snu.ac.kr
This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
The role of pre-transplant salvage chemotherapy has been controversial in relapsed acute leukemia.
We investigated post-transplant outcomes in 65 patients with acute leukemia treated with allogeneic hematopoietic cell transplantation (HCT) during first relapse or second remission.
The 5-year cumulative incidence of relapse (CIR) was 52.3%. Multivariate analysis for CIR revealed that patients with unfavorable cytogenetics and those not in remission at the time of HCT had a significantly high CIR (
Our results do not support the role of salvage chemotherapy aimed at re-induction of remission before allogeneic HCT in patients with acute leukemia after first relapse. Patients with early relapse do not appear to benefit from salvage chemotherapy before HCT.
Keywords Allogeneic HCT, Acute leukemia, First relapse, Second remission
Treatment outcome in young acute leukemia patients has improved over the past 2 decades, with complete remission (CR) rates ranging from 60-80% [1, 2]. However, 50-70% of patients in the first CR eventually relapse, and these patients have poor prognosis. Although a number of chemotherapeutic agents alone and in combination with other drugs have been tested, the CR rate in relapsed patients is very low and any remission with chemotherapy alone is usually short-lived [3-7]. For these patients, allogeneic hematopoietic cell transplantation (HCT) may offer the only chance for cure. The probability of disease-free survival (DFS) 5 years after HCT is about 20% to 30% [8-11]. The timing of allogeneic HCT in patients who relapse after the first CR may be important. Moreover, it is difficult to determine whether reinduction therapy should be attempted or HCT should be directly performed in relapsed patients with histocompatible donors. Several studies have reported contradictory results, with some favoring HCT without reinduction therapy [8, 10, 12, 13], while others emphasized the importance of CR before HCT [11, 14, 15].
In this study, we retrospectively investigated the clinical outcomes of acute leukemia patients who underwent allogeneic HCT after first relapse and analyzed the role of salvage chemotherapy aimed at the reinduction of remission before allogeneic HCT.
We retrospectively reviewed the records of 65 consecutive adult patients who had received allogeneic HCT for acute leukemia at first relapse or second CR at 3 institutes in Seoul, Korea, between January 1995 and September 2004 (Table 1). Acute myeloid leukemia (AML) was the underlying disease in 43 patients (66.2%), acute lymphoblastic leukemia (ALL) in 20 (30.8%), and biphenotypic acute leukemia in 2 (3.1%). All patients had previously achieved CR and had relapsed after a median CR duration of 275 days (range, 28-1,405 days). The attending physician at each institute decided whether to attempt reinduction therapy or to proceed directly to HCT. Fourteen patients (21.5%) underwent allogeneic HCT after first relapse without salvage chemotherapy aimed at the reinduction of remission ("untreated relapse" group), 15 patients (23.1%) failed to achieve CR with intensive chemotherapy for re-induction of remission before HCT ("refractory relapse" group), and 36 patients (55.4%) attained second CR with salvage chemotherapy before HCT ("second remission" group). Salvage chemotherapy regimens varied: cytarabine plus anthracycline-based regimens were administered in most patients with AML and vincristine, prednisolone plus daunorubicin-based regimens were administered in most patients with ALL. Cytogenetic analyses were successfully performed in 55 patients at diagnosis. Of the 29 patients who were not in remission before HCT, 9 had ≤30% bone marrow (BM) blasts and 17 had >30% blasts; the blast percentage for the other 3 patients was not available.
Preparative regimens for allogeneic HCT were dependent on the treatment strategy at each institute and the attending physician's discretion (Table 1). Regimens included cyclophosphamide (120 mg/kg) plus oral busulfan (16 mg/kg) or intravenous busulfan (12.8 mg/kg), 12.0 Gy of total body irradiation (TBI) plus cyclophosphamide (120 mg/kg), 10.0-2.0 Gy of TBI plus combinations with other chemotherapeutic agents, and various reduced-intensity conditioning regimens, which fulfilled one of the following criteria: (1) 500 cGy or less of TBI, (2) 9 mg/kg or less of total busulfan dose, (3) 140 mg/m2 or less of total melphalan dose, and (4) regimen included the purine analog fludarabine [16]. Fifty-six donors were HLA-ABDR-matched and 6 donors were mismatched with their respective recipients.
The probabilities of overall survival (OS) and event-free survival (EFS) were calculated by the Kaplan-Meier method [17] and compared by a log-rank test [18]. For the calculation of EFS, only surviving patients without relapse were censored at the last follow-up date. The effects of variables that changed with time after HCT, such as graft-versus-host disease (GVHD), on survival were analyzed in a time-dependent fashion using Cox regression models [19].
For the analysis of the cumulative incidence of relapse (CIR), patients who were alive without relapse were censored, whereas those who died without relapse were counted as competing cause of failure [20]. For the analysis of the cumulative incidence of non-relapse mortality (NRM), patients who relapsed were counted as competing cause of failure. The cumulative incidence was calculated and compared by Gray's method [21].
Statistically or marginally significant prognostic factors identified by univariate analysis were entered into an appropriate multivariate model (Cox proportional hazards regression model for OS and EFS [22] and Gray's method for CIR and NRM).
Acute graft-versus-host disease (GVHD) occurred in 17 (26.6%) of 64 evaluable patients on median day 26 and chronic GVHD occurred in 15 (27.8%) of 54 evaluable patients on median day 150.
A median follow-up for 673 days (range, 151-3,010 days) among surviving patients indicated that 34 had relapsed and 49 had died. We observed 56 events (deaths or relapses). Of the 49 deaths, 22 were not related to leukemia relapse. These 22 non-relapse deaths were caused by infection (N=10), GVHD (N=4), hepatic venoocclusive disease (N=4), bleeding (N=2), thrombotic thrombocytopenic purpura (N=1), and suicide (N=1). The 5-year probabilities of OS and EFS were 20.6% and 14.0%, respectively (Fig. 1), and the 5-year CIR and NRM were 51.3% and 34.7%, respectively (Fig. 2).
After univariate analyses, TBI (no vs. yes; OS at 5-year, 25.0% vs. 7.7%;
Patients in the second CR before HCT showed a significantly lower relapse rate than those who did not show remission before HCT. However, the latter group was divided into patients in the untreated relapse and refractory relapse groups, depending on whether they received salvage chemotherapy aimed at reinduction of CR before HCT. The 5-year CIR rate in the untreated relapse group (57.1%) was higher than that of the second remission group (42.3%), but it was lower than that for the refractory relapse group (66.7%) (Fig. 3). The median age of patients in second remission group was lower (31.0 vs. 40.5 vs. 43.0 years) and the median duration of the first CR was longer (367 vs. 168 vs. 131 days) than that of patients in the untreated relapse or refractory relapse groups. Among patients who underwent allogeneic HCT in relapse, those with ≤30% BM blasts had a lower 3-year CIR than those in florid relapse (BM blasts >30%) (57.7% vs. 70.6%; Fig. 4). Table 3 shows 5-year estimates of OS, EFS, CIR, and NRM in patients in untreated first relapse, refractory relapse, and second CR groups.
Although many patients with acute leukemia do not undergo allogeneic HCT during their first CR, it may be the only option for cure after relapse, and allogeneic HCT is performed depending on the disease characteristics and the discretion of the patients of their physicians. Because a small but significant proportion of patients with refractory acute leukemia can be cured by allogeneic HCT [23-27], a clinically important issue in relapsed patients is not whether to perform allogeneic HCT but when this treatment should be performed. Although allogeneic HCT in untreated first relapse has proven to be feasible, with a 23-29% 5-year DFS rate, a 44-57% 5-year relapse rate, and a 44-47% 5-year NRM rate [8, 10], only a few studies have addressed the issue regarding the optimal time for allogeneic HCT in acute leukemia patients who relapse after non-transplantation treatment and who had a suitable hematopoietic cell donor, and different results have been reported in these studies [12, 13, 15]. According to the Société Fançaise de Greffe de Möelle (SFGM) registry data on allogeneic HCT for advanced AML, the survival of patients receiving HCT in untreated relapse or refractory relapse was significantly lower than that of patients undergoing HCT in second or third CR (untreated relapse vs. refractory relapse vs. CR; OS, 14% vs. 11% vs. 35%; DSF, 13% vs. 11% vs. 32%) [15]. However, others have reported that clinical outcomes in AML patients receiving allogeneic HCT during untreated first relapse were similar to or better than those for patients receiving allogeneic HCT in second or subsequent CR (untreated relapse vs. CR; OS, 29% vs. 22%; relapse incidence 23% vs. 47%) [12]. In a study of pediatric patients with advanced AML, allogeneic HCT during second CR resulted in significantly better outcomes than in patients with refractory disease, but the outcomes did not differ significantly between patients in second CR and those in untreated first relapse (untreated relapse vs. refractory relapse vs. CR; DFS, 36% vs. 9% vs. 58%; relapse incidence, 36% vs. 74% vs. 42%) [13]. While the SFGM registry data suggested the importance of CR reinduction before HCT in patients with relapsed acute leukemia, two other studies found that attainment of second CR before HCT did not significantly improve clinical outcomes. Similarly, our results, showing that clinical outcomes of patients in untreated first relapse were between those of patients in refractory relapse and patients in second CR, suggest that salvage chemotherapy aimed at reinduction of CR is not beneficial in patients with relapsed acute leukemia who have suitable HCT donors. Reinduction chemotherapy may serve to select chemosensitive patients with better prognosis rather than improving clinical outcomes. Furthermore, reinduction chemotherapy can result in mortality or serious morbidity before HCT. All of the above cited studies, including ours, however, were retrospective in design, emphasizing the necessity for randomized prospective studies to determine the optimal time for allogeneic HCT in relapsed acute leukemia patients. Moreover, our findings, that patients in early relapse (BM blasts ≤30%) had lower CIR rates than those in florid relapse (BM blasts >30%), were similar one study [12] but different from another [8].
The duration of the first CR is an important prognostic factor in relapsed acute leukemia patients [28]. We analyzed the effects of the duration of the first CR on post-transplant outcomes, and univariate analysis indicated that it was a significant risk factor for CIR, although the significance was not confirmed by multivariate analysis. Cytogenetic results at diagnosis have been shown to predict the outcomes of pre- and post-remission therapy for acute leukemia patients [29-31], as well as being associated with outcomes after allogeneic HCT in adults with AML in the first CR [32-34] or primary refractory AML [24] and in pediatric patients with advanced AML [13]. Multivariate analysis showed that the presence of unfavorable cytogenetic abnormalities (Philadelphia chromosome or complex karyotype) was associated with high CIR after HCT, indicating that unfavorable cytogenetics is a risk factor favoring allogeneic HCT for adult patients with advanced acute leukemia and suggesting that allogeneic HCT should be performed prior to relapse. Leukemia relapse is a common cause of treatment failure after allogeneic HCT for advanced acute leukemia. One approach to reduce the risk of relapse is intensification of the preparative regimen. This approach showed promising results in some studies [8, 35], probably due to an increase in drug toxicities [14, 36]. In our study, the use of TBI-containing preparative regimens resulted in lower OS, mainly due to an increase in NRM. Although the results cannot be generalized to other populations because of the limitations of a retrospective study, this finding suggests that a more refined approach, rather than merely intensifying the preparative regimen, can reduce the risk of relapse without increasing NRM. Our study showed that patients receiving methotrexate-containing regimens (usually cyclosporine or tacrolimus plus methotrexate) showed a significantly lower NRM and a tendency toward higher EFS than patients not receiving methotrexate (i.e., cyclosporine or tacrolimus alone) (Table 3). Our results were similar to those of other studies [11, 27], suggesting that optimal GVHD prophylaxis is essential even in patients with advanced acute leukemia. Furthermore, we failed to show antileukemic effects of GVHD (acute or chronic)(data not shown). However, some studies showed the importance of graft-versus-leukemia effects in advanced acute leukemia [10, 15, 36] and efforts are being focused on post-HCT immune modulation to increase graft-versus-leukemia effects without worsening GVHD.
Our study has several limitations, primarily due to its retrospective design. The study population included both AML and ALL, and the heterogeneity may mislead the conclusion because graft-versus-leukemia effects are different between AML and ALL. We included, however, both disease entities because the treatment strategy and issue of salvage chemotherapy in relapsed patients before HCT are similar. We could not perform subgroup analyses due to limited number of patients. The transplantation procedures were variable in their conditioning regimens, GVHD prophylaxis, T-cell depletion of hematopoietic cells before infusion, and source of hematopoietic cells. Moreover, the 3 participating institutes differed in their treatment policy after first relapse. A prospective randomized trial is required to determine the optimal time for allogeneic HCT in relapsed acute leukemia patients. In addition, the role of novel therapeutic agents such as hypomethylating agents, tipifarnib, or clofarabine before HCT in relapsed acute leukemia should be investigated in future trials.
In summary, our results do not support the role of salvage chemotherapy aimed at reinduction of remission before allogeneic HCT in patients with acute leukemia after first relapse and suggest that at least the patients with early relapse do not appear to benefit from salvage chemotherapy before HCT.
Cumulative incidence of relapse relative to salvage chemotherapy aimed at reinduction of complete remission (CR) before hematopoietic cell transplantation: second CR vs. untreated relapse vs. refractory relapse.
Cumulative incidence of relapse relative to bone marrow blast percentage before hematopoietic cell transplantation.
Table 1 Patient and transplantation characteristics.
Abbreviations: M, male; F, female; AML, acute myeloid leukemia; ALL, acute lymphoblastic leukemia; BAL, biphenotypic acute leukemia; HCT, hematopoietic cell transplantation; CR, complete remission; BuCy, busulfan-cyclophosphamide; TBI, total body irradiation; RIC, reduced-intensity conditioning; CSA, cyclosporine; MTX, methotrexate; CS, corticosteroid; BM, bone marrow; PB, peripheral blood; CB, cord blood.
Table 2 Multivariate analysis of prognostic factors for survival probabilities and cumulative incidences.
Abbreviations: a)Cox proportional hazards regression model; b)Gray's method.
MTX, methotrexate; HCT, hematopoietic cell transplantation; CR2, second complete remission; GVHD, graft-versus-host disease.
Table 3 Clinical outcomes after allogeneic hematopoietic cell transplantation according to disease status.
Abbreviation: CR: complete remission.
Korean J Hematol 2010; 45(2): 95-101
Published online June 30, 2010 https://doi.org/10.5045/kjh.2010.45.2.95
Copyright © The Korean Society of Hematology.
Je-Hwan Lee1, Sung-Soo Yoon2*, Chul Won Jung3, Jung-Hee Lee1, Dae-Young Kim1, Young-Shin Lee1, Sung Cheol Yun4, Inho Kim2, Seonyang Park2, Byoung Kook Kim2, Kihyun Kim3, Jin Seok Ahn3, and Kyoo-Hyung Lee1
1Department of Internal Medicine, Asan Medical Center, University of Ulsan College of Medicine, Seoul, Korea.
2Department of Internal Medicine, Seoul National University Hospital, Seoul National University College of Medicine, Seoul, Korea.
3Department of Internal Medicine, Samsung Medical Center, Sungkyunkwan University School of Medicine, Seoul, Korea.
4Department of Preventive Medicine, University of Ulsan College of Medicine, Seoul, Korea.
Correspondence to: Correspondence to Sung-Soo Yoon, M.D. Department of Internal Medicine, Seoul National University College of Medicine, Clinical Research Institute, Seoul National University Hospital, 28, Yeongeon-dong, Jongno-gu, Seoul 110-744, Korea. Tel: +82-2-2072-3079, Fax: +82-2-762-9662, ssysmc@snu.ac.kr
This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
The role of pre-transplant salvage chemotherapy has been controversial in relapsed acute leukemia.
We investigated post-transplant outcomes in 65 patients with acute leukemia treated with allogeneic hematopoietic cell transplantation (HCT) during first relapse or second remission.
The 5-year cumulative incidence of relapse (CIR) was 52.3%. Multivariate analysis for CIR revealed that patients with unfavorable cytogenetics and those not in remission at the time of HCT had a significantly high CIR (
Our results do not support the role of salvage chemotherapy aimed at re-induction of remission before allogeneic HCT in patients with acute leukemia after first relapse. Patients with early relapse do not appear to benefit from salvage chemotherapy before HCT.
Keywords: Allogeneic HCT, Acute leukemia, First relapse, Second remission
Treatment outcome in young acute leukemia patients has improved over the past 2 decades, with complete remission (CR) rates ranging from 60-80% [1, 2]. However, 50-70% of patients in the first CR eventually relapse, and these patients have poor prognosis. Although a number of chemotherapeutic agents alone and in combination with other drugs have been tested, the CR rate in relapsed patients is very low and any remission with chemotherapy alone is usually short-lived [3-7]. For these patients, allogeneic hematopoietic cell transplantation (HCT) may offer the only chance for cure. The probability of disease-free survival (DFS) 5 years after HCT is about 20% to 30% [8-11]. The timing of allogeneic HCT in patients who relapse after the first CR may be important. Moreover, it is difficult to determine whether reinduction therapy should be attempted or HCT should be directly performed in relapsed patients with histocompatible donors. Several studies have reported contradictory results, with some favoring HCT without reinduction therapy [8, 10, 12, 13], while others emphasized the importance of CR before HCT [11, 14, 15].
In this study, we retrospectively investigated the clinical outcomes of acute leukemia patients who underwent allogeneic HCT after first relapse and analyzed the role of salvage chemotherapy aimed at the reinduction of remission before allogeneic HCT.
We retrospectively reviewed the records of 65 consecutive adult patients who had received allogeneic HCT for acute leukemia at first relapse or second CR at 3 institutes in Seoul, Korea, between January 1995 and September 2004 (Table 1). Acute myeloid leukemia (AML) was the underlying disease in 43 patients (66.2%), acute lymphoblastic leukemia (ALL) in 20 (30.8%), and biphenotypic acute leukemia in 2 (3.1%). All patients had previously achieved CR and had relapsed after a median CR duration of 275 days (range, 28-1,405 days). The attending physician at each institute decided whether to attempt reinduction therapy or to proceed directly to HCT. Fourteen patients (21.5%) underwent allogeneic HCT after first relapse without salvage chemotherapy aimed at the reinduction of remission ("untreated relapse" group), 15 patients (23.1%) failed to achieve CR with intensive chemotherapy for re-induction of remission before HCT ("refractory relapse" group), and 36 patients (55.4%) attained second CR with salvage chemotherapy before HCT ("second remission" group). Salvage chemotherapy regimens varied: cytarabine plus anthracycline-based regimens were administered in most patients with AML and vincristine, prednisolone plus daunorubicin-based regimens were administered in most patients with ALL. Cytogenetic analyses were successfully performed in 55 patients at diagnosis. Of the 29 patients who were not in remission before HCT, 9 had ≤30% bone marrow (BM) blasts and 17 had >30% blasts; the blast percentage for the other 3 patients was not available.
Preparative regimens for allogeneic HCT were dependent on the treatment strategy at each institute and the attending physician's discretion (Table 1). Regimens included cyclophosphamide (120 mg/kg) plus oral busulfan (16 mg/kg) or intravenous busulfan (12.8 mg/kg), 12.0 Gy of total body irradiation (TBI) plus cyclophosphamide (120 mg/kg), 10.0-2.0 Gy of TBI plus combinations with other chemotherapeutic agents, and various reduced-intensity conditioning regimens, which fulfilled one of the following criteria: (1) 500 cGy or less of TBI, (2) 9 mg/kg or less of total busulfan dose, (3) 140 mg/m2 or less of total melphalan dose, and (4) regimen included the purine analog fludarabine [16]. Fifty-six donors were HLA-ABDR-matched and 6 donors were mismatched with their respective recipients.
The probabilities of overall survival (OS) and event-free survival (EFS) were calculated by the Kaplan-Meier method [17] and compared by a log-rank test [18]. For the calculation of EFS, only surviving patients without relapse were censored at the last follow-up date. The effects of variables that changed with time after HCT, such as graft-versus-host disease (GVHD), on survival were analyzed in a time-dependent fashion using Cox regression models [19].
For the analysis of the cumulative incidence of relapse (CIR), patients who were alive without relapse were censored, whereas those who died without relapse were counted as competing cause of failure [20]. For the analysis of the cumulative incidence of non-relapse mortality (NRM), patients who relapsed were counted as competing cause of failure. The cumulative incidence was calculated and compared by Gray's method [21].
Statistically or marginally significant prognostic factors identified by univariate analysis were entered into an appropriate multivariate model (Cox proportional hazards regression model for OS and EFS [22] and Gray's method for CIR and NRM).
Acute graft-versus-host disease (GVHD) occurred in 17 (26.6%) of 64 evaluable patients on median day 26 and chronic GVHD occurred in 15 (27.8%) of 54 evaluable patients on median day 150.
A median follow-up for 673 days (range, 151-3,010 days) among surviving patients indicated that 34 had relapsed and 49 had died. We observed 56 events (deaths or relapses). Of the 49 deaths, 22 were not related to leukemia relapse. These 22 non-relapse deaths were caused by infection (N=10), GVHD (N=4), hepatic venoocclusive disease (N=4), bleeding (N=2), thrombotic thrombocytopenic purpura (N=1), and suicide (N=1). The 5-year probabilities of OS and EFS were 20.6% and 14.0%, respectively (Fig. 1), and the 5-year CIR and NRM were 51.3% and 34.7%, respectively (Fig. 2).
After univariate analyses, TBI (no vs. yes; OS at 5-year, 25.0% vs. 7.7%;
Patients in the second CR before HCT showed a significantly lower relapse rate than those who did not show remission before HCT. However, the latter group was divided into patients in the untreated relapse and refractory relapse groups, depending on whether they received salvage chemotherapy aimed at reinduction of CR before HCT. The 5-year CIR rate in the untreated relapse group (57.1%) was higher than that of the second remission group (42.3%), but it was lower than that for the refractory relapse group (66.7%) (Fig. 3). The median age of patients in second remission group was lower (31.0 vs. 40.5 vs. 43.0 years) and the median duration of the first CR was longer (367 vs. 168 vs. 131 days) than that of patients in the untreated relapse or refractory relapse groups. Among patients who underwent allogeneic HCT in relapse, those with ≤30% BM blasts had a lower 3-year CIR than those in florid relapse (BM blasts >30%) (57.7% vs. 70.6%; Fig. 4). Table 3 shows 5-year estimates of OS, EFS, CIR, and NRM in patients in untreated first relapse, refractory relapse, and second CR groups.
Although many patients with acute leukemia do not undergo allogeneic HCT during their first CR, it may be the only option for cure after relapse, and allogeneic HCT is performed depending on the disease characteristics and the discretion of the patients of their physicians. Because a small but significant proportion of patients with refractory acute leukemia can be cured by allogeneic HCT [23-27], a clinically important issue in relapsed patients is not whether to perform allogeneic HCT but when this treatment should be performed. Although allogeneic HCT in untreated first relapse has proven to be feasible, with a 23-29% 5-year DFS rate, a 44-57% 5-year relapse rate, and a 44-47% 5-year NRM rate [8, 10], only a few studies have addressed the issue regarding the optimal time for allogeneic HCT in acute leukemia patients who relapse after non-transplantation treatment and who had a suitable hematopoietic cell donor, and different results have been reported in these studies [12, 13, 15]. According to the Société Fançaise de Greffe de Möelle (SFGM) registry data on allogeneic HCT for advanced AML, the survival of patients receiving HCT in untreated relapse or refractory relapse was significantly lower than that of patients undergoing HCT in second or third CR (untreated relapse vs. refractory relapse vs. CR; OS, 14% vs. 11% vs. 35%; DSF, 13% vs. 11% vs. 32%) [15]. However, others have reported that clinical outcomes in AML patients receiving allogeneic HCT during untreated first relapse were similar to or better than those for patients receiving allogeneic HCT in second or subsequent CR (untreated relapse vs. CR; OS, 29% vs. 22%; relapse incidence 23% vs. 47%) [12]. In a study of pediatric patients with advanced AML, allogeneic HCT during second CR resulted in significantly better outcomes than in patients with refractory disease, but the outcomes did not differ significantly between patients in second CR and those in untreated first relapse (untreated relapse vs. refractory relapse vs. CR; DFS, 36% vs. 9% vs. 58%; relapse incidence, 36% vs. 74% vs. 42%) [13]. While the SFGM registry data suggested the importance of CR reinduction before HCT in patients with relapsed acute leukemia, two other studies found that attainment of second CR before HCT did not significantly improve clinical outcomes. Similarly, our results, showing that clinical outcomes of patients in untreated first relapse were between those of patients in refractory relapse and patients in second CR, suggest that salvage chemotherapy aimed at reinduction of CR is not beneficial in patients with relapsed acute leukemia who have suitable HCT donors. Reinduction chemotherapy may serve to select chemosensitive patients with better prognosis rather than improving clinical outcomes. Furthermore, reinduction chemotherapy can result in mortality or serious morbidity before HCT. All of the above cited studies, including ours, however, were retrospective in design, emphasizing the necessity for randomized prospective studies to determine the optimal time for allogeneic HCT in relapsed acute leukemia patients. Moreover, our findings, that patients in early relapse (BM blasts ≤30%) had lower CIR rates than those in florid relapse (BM blasts >30%), were similar one study [12] but different from another [8].
The duration of the first CR is an important prognostic factor in relapsed acute leukemia patients [28]. We analyzed the effects of the duration of the first CR on post-transplant outcomes, and univariate analysis indicated that it was a significant risk factor for CIR, although the significance was not confirmed by multivariate analysis. Cytogenetic results at diagnosis have been shown to predict the outcomes of pre- and post-remission therapy for acute leukemia patients [29-31], as well as being associated with outcomes after allogeneic HCT in adults with AML in the first CR [32-34] or primary refractory AML [24] and in pediatric patients with advanced AML [13]. Multivariate analysis showed that the presence of unfavorable cytogenetic abnormalities (Philadelphia chromosome or complex karyotype) was associated with high CIR after HCT, indicating that unfavorable cytogenetics is a risk factor favoring allogeneic HCT for adult patients with advanced acute leukemia and suggesting that allogeneic HCT should be performed prior to relapse. Leukemia relapse is a common cause of treatment failure after allogeneic HCT for advanced acute leukemia. One approach to reduce the risk of relapse is intensification of the preparative regimen. This approach showed promising results in some studies [8, 35], probably due to an increase in drug toxicities [14, 36]. In our study, the use of TBI-containing preparative regimens resulted in lower OS, mainly due to an increase in NRM. Although the results cannot be generalized to other populations because of the limitations of a retrospective study, this finding suggests that a more refined approach, rather than merely intensifying the preparative regimen, can reduce the risk of relapse without increasing NRM. Our study showed that patients receiving methotrexate-containing regimens (usually cyclosporine or tacrolimus plus methotrexate) showed a significantly lower NRM and a tendency toward higher EFS than patients not receiving methotrexate (i.e., cyclosporine or tacrolimus alone) (Table 3). Our results were similar to those of other studies [11, 27], suggesting that optimal GVHD prophylaxis is essential even in patients with advanced acute leukemia. Furthermore, we failed to show antileukemic effects of GVHD (acute or chronic)(data not shown). However, some studies showed the importance of graft-versus-leukemia effects in advanced acute leukemia [10, 15, 36] and efforts are being focused on post-HCT immune modulation to increase graft-versus-leukemia effects without worsening GVHD.
Our study has several limitations, primarily due to its retrospective design. The study population included both AML and ALL, and the heterogeneity may mislead the conclusion because graft-versus-leukemia effects are different between AML and ALL. We included, however, both disease entities because the treatment strategy and issue of salvage chemotherapy in relapsed patients before HCT are similar. We could not perform subgroup analyses due to limited number of patients. The transplantation procedures were variable in their conditioning regimens, GVHD prophylaxis, T-cell depletion of hematopoietic cells before infusion, and source of hematopoietic cells. Moreover, the 3 participating institutes differed in their treatment policy after first relapse. A prospective randomized trial is required to determine the optimal time for allogeneic HCT in relapsed acute leukemia patients. In addition, the role of novel therapeutic agents such as hypomethylating agents, tipifarnib, or clofarabine before HCT in relapsed acute leukemia should be investigated in future trials.
In summary, our results do not support the role of salvage chemotherapy aimed at reinduction of remission before allogeneic HCT in patients with acute leukemia after first relapse and suggest that at least the patients with early relapse do not appear to benefit from salvage chemotherapy before HCT.
Overall survival and event-free survival curves.
Cumulative incidences of relapse and non-relapse mortality.
Cumulative incidence of relapse relative to salvage chemotherapy aimed at reinduction of complete remission (CR) before hematopoietic cell transplantation: second CR vs. untreated relapse vs. refractory relapse.
Cumulative incidence of relapse relative to bone marrow blast percentage before hematopoietic cell transplantation.
Table 1 . Patient and transplantation characteristics..
Abbreviations: M, male; F, female; AML, acute myeloid leukemia; ALL, acute lymphoblastic leukemia; BAL, biphenotypic acute leukemia; HCT, hematopoietic cell transplantation; CR, complete remission; BuCy, busulfan-cyclophosphamide; TBI, total body irradiation; RIC, reduced-intensity conditioning; CSA, cyclosporine; MTX, methotrexate; CS, corticosteroid; BM, bone marrow; PB, peripheral blood; CB, cord blood..
Table 2 . Multivariate analysis of prognostic factors for survival probabilities and cumulative incidences..
Abbreviations: a)Cox proportional hazards regression model; b)Gray's method..
MTX, methotrexate; HCT, hematopoietic cell transplantation; CR2, second complete remission; GVHD, graft-versus-host disease..
Table 3 . Clinical outcomes after allogeneic hematopoietic cell transplantation according to disease status..
Abbreviation: CR: complete remission..
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Overall survival and event-free survival curves.
|@|~(^,^)~|@|Cumulative incidences of relapse and non-relapse mortality.
|@|~(^,^)~|@|Cumulative incidence of relapse relative to salvage chemotherapy aimed at reinduction of complete remission (CR) before hematopoietic cell transplantation: second CR vs. untreated relapse vs. refractory relapse.
|@|~(^,^)~|@|Cumulative incidence of relapse relative to bone marrow blast percentage before hematopoietic cell transplantation.