In adults with standard-risk acute lymphoblastic leukemia, the greatest benefit is achieved from a matched sibling allogeneic transplantation in first complete remission, and an autologous transplantation is less effective than conventional consolidation/maintenance chemotherapy in all patients: final results of the International ALL Trial (MRC UKALL XII/ECOG E2993)

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Blood, 15 February 2008, Vol. 111, No. 4, pp. 1827-1833.
Prepublished online as a Blood First Edition Paper on November 29, 2007; DOI 10.1182/blood-2007-10-116582.

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CLINICAL TRIALS AND OBSERVATIONS
In adults with standard-risk acute lymphoblastic leukemia, the greatest benefit is achieved from a matched sibling allogeneic transplantation in first complete remission, and an autologous transplantation is less effective than conventional consolidation/maintenance chemotherapy in all patients: final results of the International ALL Trial (MRC UKALL XII/ECOG E2993)
Anthony H. Goldstone¹, Susan M. Richards², Hillard M. Lazarus³, Martin S. Tallman⁴, Georgina Buck², Adele K. Fielding⁵, Alan K. Burnett⁶, Raj Chopra⁷, Peter H. Wiernik⁸, Letizia Foroni⁵, Elisabeth Paietta⁸, Mark R. Litzow⁹, David I. Marks¹⁰, Jill Durrant², Andrew McMillan¹¹, Ian M. Franklin¹², Selina Luger¹³, Niculae Ciobanu¹⁴, and Jacob M. Rowe¹⁵
¹ University College London Hospitals, London, United Kingdom; ² Clinical Trial Service Unit, Oxford, United Kingdom; ³ Ireland Cancer Center, University Hospitals of Cleveland, Cleveland, OH; ⁴ Northwestern University Feinberg School of Medicine, Chicago, IL; ⁵ Royal Free & University College Medical School, London, United Kingdom; ⁶ University of Wales, Cardiff, United Kingdom; ⁷ Christie National Health Service Trust Hospital, Manchester, United Kingdom; ⁸ Our Lady of Mercy Cancer Center, New York Medical College, Bronx, NY; ⁹ Mayo Clinic College of Medicine, Rochester, MN; ¹⁰ Bristol Haematology & Oncology Centre, Bristol, United Kingdom; ¹¹ Nottingham University, Nottingham, United Kingdom; ¹² University of Glasgow, National Blood Transfusion Service, Glasgow, Scotland; ¹³ Department of Haematology/Oncology, University of Pennsylvania, Philadelphia; ¹⁴ Stem Cell Sciences, New York, NY; and ¹⁵ Rambam Medical Center and Technion, Israel Institute of Technology, Haifa

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An international collaboration was set up to prospectively evaluatethe role of allogeneic transplantation for adults with acutelymphoblastic leukemia (ALL) and compare autologous transplantationwith standard chemotherapy. Patients received 2 phases of inductionand, if in remission, were assigned to allogeneic transplantationif they had a compatible sibling donor. Other patients wererandomized to chemotherapy for 2.5 years versus an autologoustransplantation. A donor versus no-donor analysis showed thatPhiladelphia chromosome–negative patients with a donorhad a 5-year improved overall survival (OS), 53% versus 45%(P = .01), and the relapse rate was significantly lower (P $≤$ .001). The survival difference was significant in standard-riskpatients, but not in high-risk patients with a high nonrelapsemortality rate in the high-risk donor group. Patients randomizedto chemotherapy had a higher 5-year OS (46%) than those randomizedto autologous transplantation (37%; P = .03). Matched relatedallogeneic transplantations for ALL in first complete remissionprovide the most potent antileukemic therapy and considerablesurvival benefit for standard-risk patients. However, the transplantation-relatedmortality for high-risk older patients was unacceptably highand abrogated the reduction in relapse risk. There is no evidencethat a single autologous transplantation can replace consolidation/maintenancein any risk group. This study is registered at http://clinicaltrials.govas NCT00002514 [ClinicalTrials.gov] .

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Treatment of acute lymphoblastic leukemia (ALL) has improvedenormously in the last 40 years particularly in children inwhom a long-term survival of 80% is now achieved.^1–4 Adultshave fared much worse; the survival in the best series may noteven reach 35% to 40% for those younger than 60 years and lessthan 10% for those older than 60 years.^5–9
For adults, 2 separate approaches have been constructed, transplantation-basedstudies^10–15 and attempts to optimize chemotherapy, reservingtransplantation only for patients with the Philadelphia chromosome.¹⁴
The putative factors defining individual patients as "high risk"in adult ALL are numerous and include age, particularly olderthan 35 years,^{3,7,9,10,16,17} elevated white blood cell count(WBC), which may well differ in relation to a "high-risk" thresholdbetween B- and T-cell ALL,^7,11 cytogenetics,^18–22 andthe presence or absence of minimal residual disease (MRD) atparticular points in the early phases of treatment.^23,24 Molecularcomplete remission (CR) rates currently achieved may be as lowas 60%.²⁵
The low incidence of the adult disease has meant that to studyadequate numbers of patients, collaboration by large cooperativegroups is required.
In 1993 collaboration from the UK Medical Research Council (MRC)and the Eastern Cooperative Oncology Group (ECOG) of the UnitedStates developed a large study to ask 2 fundamental questionsregarding this disease.

(1)Given that the graft versus leukemia effect (GVL) was firstdescribed in adult ALL²⁶ and given published data supportingallogeneic transplantation in first complete remission (CRI)for Ph⁺ and other high-risk patients,¹⁴ could the allogeneiceffect improve the outcome for all suitable adult patients?

(2)Given the fact that protracted consolidation/maintenancetherapy has been the mainstay of treatment for ALL, based ondata mostly extrapolated from pediatric experience, could asingle autologous transplantation be at least as effective?

The design of the study was that all adult patients with a matchedsibling donor would receive an allogeneic transplant, whilethose without would be randomized to an autologous transplantationversus consolidation maintenance/chemotherapy. The study designhas been previously described in detail,²⁷ and the simplifiedoutline is shown in Figure 1A.

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Statistics
The target recruitment was based on 550 patients randomized,giving 95% power to detect an absolute difference of 15% inevent-free survival (EFS) between autologous transplantationand chemotherapy. The randomization rate was lower than anticipated,and in 2006 the coordinators asked for disclosure of the resultsto plan the next trial. As the recruitment period had alreadybeen extended, the Steering Committee, in ignorance of the results,agreed to close the trial.
All patients were centrally registered at the Clinical TrialService Unit in Oxford, for MRC patients, or at the ECOG operationsoffice for ECOG patients. Randomization between autograft andchemotherapy was done at these 2 centers, with minimization(MRC) used to balance over sex, age (< 20, 20–29, 40–49,50 + years), WBC count (< 10 x 10⁹/L, 10–49 x 10⁹/L, $≥$ 50 x 10⁹/L), and Ph status, or balanced blocks (ECOG) withinstrata by age (< 50, 50+ years), time to remission (<4 weeks, > 4 weeks), and Ph status.
The primary outcome measure was overall survival (OS). Otheroutcomes analyzed were (1) EFS, defined as the time to relapseor death, (2) relapse rate, and (3) nonrelapse mortality, definedas time to death censored at relapse. Kaplan-Meier curves wereused and all treatment comparisons were by intention to treat.Comparisons between autologous transplantation and chemotherapywere made by the log-rank method. All event times were measuredfrom the diagnosis, or from randomization for the randomizedcomparison of autologous transplantation and chemotherapy.
The comparison between those with versus those without a matchedrelated donor was used as an unbiased assessment of the effectof matched related donor transplantation. This comparison includedonly patients younger than 50 or 55 years, commensurate withthe upper age limit for related donor transplantation. Differencesbetween the Kaplan-Meier curves at 5 years were tested witha chi-square test. All P values are 2-sided. Subgroup analysishas been performed for risk groups based on reports from othertrials and interim prognostic factor analyses from this trial.²⁷
Patients
The trial recruited patients between 1993 and 2006. All patientsfrom 15 to 59 years of age with newly diagnosed ALL, includingPh positive, received identical induction therapy, irrespectiveof risk assessment, including central nervous system (CNS) prophylaxisand treatment of CNS disease, if present at diagnosis. In 2003,the upper age limit of the study was raised to 64 years andfor an allogeneic transplantation was raised to 54 from 49 years.All patients who had an HLA-matched sibling donor were assignedto receive an allogeneic transplant. Patients with the Philadelphiachromosome could also receive a matched unrelated donor transplant.Those who did not have an HLA-matched sibling donor, or wereolder than 50 years or (later) 55 years, were randomized toreceive a single autologous transplant or consolidation/maintenancetherapy. Prior to receiving the assigned or randomized therapy,all patients received intensification with high-dose methotrexate.In this study, patients older than 35 years or those with ahigh WBC count at presentation ( $≥$ 100 x 10⁹/L for B lineage and $≥$ 30 x 10⁹/L for T lineage) along with all patients with thePhiladelphia chromosome were deemed to be high risk. All theothers were classified as standard risk. Time to remission wasnot an independent risk factor in this study.²⁷ The study wasapproved by the relevant Institutional Review Boards of eachcenter (Document S1, available on the Bloodwebsite; see theSupplemental Materials link at the top of the online article)and informed consent was obtained in accordance with the Declarationof Helsinki. The precise details of the study regimen have beenpreviously reported.²⁷

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A total of 1929 patients were registered to this study of whom16 were excluded as misdiagnoses (Figure 1B). The median follow-upis 4 years 11 months (range, 1 month to 13 years 11 months).

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Figure 1. Outline of study and treatment demographics. (A) Simplified overall schema of the study. MUD indicates matched unrelated donor transplantation; HD MTX, high-dose methotrexate. (B) Patient flow diagram. All randomized patients with the exception of 2 misdiagnoses were included in the comparison of autologous transplantation and chemotherapy. A large number of patients were lost, as in all transplantation studies, in the period from initial accrual to randomization. Only Ph-negative patients were eligible for the intent-to-treat donor versus no-donor analysis as Ph-positive patients without a donor were to have unrelated donor transplantation if possible.

Overall survival
The OS of all 1913 patients at 5 years was 39% (Figure 2A);it was 43% for patients who were Ph negative (Figure 2B), andthere was no difference in survival between patients enteredthrough MRC or ECOG (Figure 2C). Details of the Ph-positivepatients have been presented²⁸ and are being published separately.

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Figure 2. Survival of patients and donor versus no-donor analysis. Overall survival from diagnosis for (A) all patients entered on the study, including Ph-positive; (B) Ph-negative and Ph-positive patients; (C) patients entered via MRC or ECOG; (D) donor versus no-donor for all Ph-negative patients; (E) donor versus no-donor for Ph-negative patients with high risk; and (F) donor versus no-donor for Ph-negative patients with standard risk.

Donor versus no-donor analysis for Philadelphia chromosome–negative patients
Figure 1B is a flowchart of patients in the study. Of the 1646Ph-negative patients, there were 1351 patients who were youngerthan 50 years or younger than 55 years and achieved a completeremission on protocol. In 1031 patients, HLA-typing informationwas available. Figure 2D demonstrates the overall survival benefitwhen all patients on study are included in this analysis witha 5-year survival of 53% (95% CI = 48%-58%) for patients witha donor versus 45% (95% CI = 40%-49%) for patients without adonor (P = .01). Patients at high risk had an OS of 41% versus35% for donor versus no donor, respectively, which was not significantlydifferent (P = .2; Figure 2E); however, the OS was significantlyimproved among patients at standard risk—62% versus 52%for donor versus no donor, respectively (P = .02), for survivalat 5 years (Figure 2F), although an interaction test was notsignificant (P = .4). The relapse rate was significantly reducedin both risk groups, demonstrating the potent graft-versus-leukemiaeffect in an allogeneic transplantation (Figure 3A,B).

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Figure 3. Relapse on study and mortality not associated with relapse. Relapse rate for (A) Ph-negative patients at standard risk; (B) Ph-negative patients at high risk; and (C) nonrelapse mortality for high-risk and standard-risk patients. Note the underlying mortality at 1 and 2 years among the no-donor group.

Nonrelapse mortality
Figure 3C illustrates the high mortality rate after transplantationamong high-risk patients at 1 and 2 years, mostly due to graft-versus-hostdisease and infection. At 2 years, 36% of high-risk patientswith a donor had died from nonrelapse causes compared with 14%of patients who did not have a donor. Among standard-risk patients,the nonrelapse mortality at 2 years was 20%, bearing in mindthat among patients who did not have a donor there was alsoa significant nonrelapse mortality of 7% at 2 years. Surprisinglythe nonrelapse mortality did not change over the 13 years ofthis study.
Chemotherapy versus autologous transplantation randomization for all patients, including Ph-positive patients
Among the 456 patients randomized to chemotherapy vs autologoustransplantation, 16 were Ph positive. Patients randomized tochemotherapy had significantly improved 5-year EFS (41% vs 32%;P = .02); and OS (46% [95% CI = 39%-53%] vs 37% [95% CI = 31%-44%];P = .03; Figure 4A,B).

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Figure 4. Randomized chemotherapy versus autologous transplantation, measured from time of randomization. (A) Event-free survival for all patients. (B) Overall survival for all (C) high-risk patients and (D) standard-risk patients. (E) Nonrelapse mortality for all patients undergoing chemotherapy or autologous transplantation.

Among patients at high risk, the 5-year survival for chemotherapyversus autologous transplantation was 37% versus 31%, respectively,and for patients at standard risk this was 56% versus 46%, respectively(interaction P = .8; Figure 4C,D).
In contrast to the donor versus no-donor analysis, there wasno difference in the nonrelapse mortality between autologoustransplantation and chemotherapy (Figure 4E), irrespective ofthe risk group (data not shown).
Effect of allogeneic transplantation versus chemotherapy: donor versus no-donor analysis for Ph-negative patients censoring at autologous transplantation
As patients randomized to chemotherapy had a better outcomethan those undergoing autologous transplantation, an analysiswas made comparing patients with a donor versus those withouta donor, censoring at autologous transplantation, to assessthe effect of sibling donor transplantation versus chemotherapyonly.
Figure 5A demonstrates the superior OS for patients with a donor.As with the primary donor versus no-donor analysis, this superioritycould not be demonstrated among patients at high risk, but wassignificant for patients at standard risk with a 5-year survivalof 63% for those with a donor versus 52% for those without adonor (interaction P = .6; Figure 5B,C).

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Figure 5. Overall survival from diagnosis for donor versus no-donor for Ph-negative patients censoring at first remission autologous transplantation. Estimation of the effect of sibling donor transplant versus chemotherapy in (A) all patients; (B) high-risk patients; and (C) standard-risk patients.

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The overall CR rate of 90% (Figure 1B) is very high and confirmsthe efficacy of the induction regimen, with relatively low toxicityallowing a very high percentage of patients to proceed to receivepostremission therapy.²⁷ The rate of randomization was higherin ECOG at 60% than in the MRC at 36% (Figure 1B), possiblyreflecting somewhat different cultural practices in the trialgroups regarding adherence to randomization rules and potentialpenalties. There was no difference in survival between the MRCversus the ECOG patients (Figure 2C), indicating that the studywas well balanced in all aspects on each side of the Atlantic.
The study originally included patients between 15 and 55 yearsalthough the age threshold, if there is one, at which "adult"ALL begins and "childhood" ALL ceases is a matter of currentcontroversy. Indeed there may be evidence that patients up tothe age of 20 to 25 years or beyond might in 2007 achieve betteroutcomes on pediatric protocols.^28–30
Hitherto, allogeneic stem-cell transplantation has been acceptedas being of value in second remission and for high-risk patientsin first remission.^9,10,12–14 In this study, outcome ofallogeneic transplantation for all patients should best be estimatedfrom a donor versus no-donor analysis for patients between 15and 50 years. This eliminates selection bias that would operateif only those who underwent transplantation were compared withthose who did not. We regarded 50 years as the upper age limitinitially for allogeneic transplantation, at the beginning ofthe study in 1993. This may not be the case 14 years on. Survivalat 5 years of 53% for those Ph-negative patients with a donor,versus 45% for those without, (P = .02) indicates the superiorityof allogeneic transplantation overall while eliminating thebiases of selection of transplantation or not for those whohave a donor.
Surprising though it might appear, the high-risk patients benefitless from having a donor than the standard-risk patients interms of overall survival. For high-risk patients, the donorversus no-donor comparison shows a 5-year 41% versus 35% OS,which is not significantly superior (P = .2; Figure 2E). Thisis an important finding since there is often a view that high-riskpatients should proceed immediately to allogeneic transplantation.In fact, the relapse rate for high-risk patients is much reducedby the availability of a donor (Figure 3B), 63% versus 37% at5 years (P $≤$ .001), so it is the toxicity of the transplant thatis largely responsible for the lack of significantly improvedsurvival for those patients who have a donor.
Somewhat unexpectedly, the significant overall benefits of havinga donor are better for the standard-risk Ph-negative patientwho has a significantly superior survival at 5 years if he/shehas a donor (62% vs 52%; P = .02; Figure 2D). Relapse ratesfor these patients with a donor are also reduced as for high-riskpatients (49% vs 24%; P $≤$ .001; Figure 3A). With a donor, thenonrelapse mortality is far greater for high-risk than for standard-riskpatients (Figure 3C). The nonrelapse mortality was also higherfor high-risk patients compared with standard-risk among thosenot undergoing a transplantation (14% vs 7%; Figure 3C). Thereforea not insignificant number of patients were lost from treatment-relatedcauses other than transplantation.
In the randomized group comparing chemotherapy and autologoustransplantation, the EFS and OS were superior for chemotherapy(P = .02 and P = .03, respectively). Differences were not statisticallysignificant within subgroups, but these comparisons lack statisticalpower.
When comparing patients with a donor to the best no-donor groups(ie, by removing the effect of autologous transplantation bycensoring), the OS is once again significantly superior forstandard-risk patients with a donor but not for high-risk patients(Figure 5A-C).
This study shows that the most potent antileukemia effect foradults with ALL derives from an allogeneic transplantation asdemonstrated by the significantly reduced relapse rate. Thisconfirms the original hypothesis of a potential allogeneic effectand survival benefit therefrom. However, the transplantation-relatedmortality for high-risk patients—due to the older agegroup—was unacceptably high. Although the size of theimprovement in survival for the donor group was not statisticallysignificantly different between the standard- and high-riskgroups, this much higher mortality rate suggests that the differenceis real. Thus benefit was confined to patients with standard-riskdisease for whom undergoing an allogeneic transplantation demonstratessignificant survival advantages over those undergoing conventionaltherapy.
For the younger patients with poor risk features, a matchedunrelated donor (MUD) allogeneic transplantation may becomea real option for the future,^30–35 ahead of conventionalconsolidation/maintenance chemotherapy
Several relatively small, variously designed studies of autologoustransplantation in ALL have been reported.^10–13,36 Theoverall data suggest that autologous transplantation offerslittle, if any, antileukemia benefit over conventional chemotherapy.However, as in no study was there a worse outcome for autologoustransplantation; its short duration offers a potentially significantbenefit. In this large study, the outcome for autologous transplantationwas not equivalent and therefore it cannot be suggested as thepreferred modality.
Adult ALL is a relatively uncommon disorder with perhaps feweradvances made in the last 2 decades than for other major hematologicmalignancies. It has taken a very large collaborative studylasting many years to demonstrate the value of a sibling allograftin this disease and the lack of additional value of an autograftover conventional consolidation/maintenance chemotherapy forthose without a donor.
It is not easy to consider how to go forward. The very highremission rate on the present protocol makes the achievementof a higher "conventional" remission rate very difficult, andit may be that interventions that attempt to reduce the amountof MRD are the way forward. This might potentially be achieved,as in so many other hematologic disorders, by the addition ofmonoclonal antibody to chemotherapy given that both the CD20and CD22 antigens are variably expressed in a considerable numberof adult ALL patients³⁷
Despite the high transplant-related mortality in older high-riskpatients, the GVL remains the single most potent strategy, andefforts must be made to reduce the toxicity. There are onlyrare data regarding the use of reduced-intensity transplantationconditioning in ALL.³⁸ Nevertheless, some form of less toxictransplantation must be studied in this high-risk group of patients.
The toxicity of the induction phases for many adults might bereduced using pegylated asparaginase³⁹ and perhaps with theinduction of hyper-CVAD (fractionated cyclophosphamide, vincristine,doxorubicin, and dexamethasone)⁴⁰ or other alternative chemotherapyand studying whether delays in treatment that sometimes occurin the early phases on this protocol can be reduced or abrogated.
Because of the paucity of significant new agents for this disease,it seems likely that the MUD transplantation as a potentialcurative option will be offered to more patients in any newstudy with a risk-adapted approach; perhaps an ablative transplantationfor those younger than 40 years without a sibling and a nonablativeapproach for those 40 years or older.
Sibling donor allogeneic transplantation is the treatment ofchoice for adults with standard-risk ALL in remission providingthe greatest chance for a long-term survival. Autologous transplantationhas a less favorable outcome than consolidation/maintenancechemotherapy for those without a donor.

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Contribution: A.H.G. and J.M.R. designed and performed researchand wrote the paper; S.M.R., G.B., and J.D. analyzed data; H.M.L.,M.S.T., A.K.F., A.K.B., R.C., P.H.W., M.R.L., A.M., I.M.F.,S.L., N.C., and D.I.M. performed research; L.F. and E.P. contributedvital data.
A list of the participating centers of the United Kingdom MedicalResearch Council Adult Leukemia Working Party and Eastern CooperativeOncology Group can be found in Document S1, available on theBloodwebsite; see the Supplemental Materials link at the topof the online article.
Conflict-of-interest disclosure: The authors declare no competingfinancial interests.
Correspondence: Anthony H. Goldstone, Director of Services,North London Cancer Network, UCLH, 6th Floor Rosenheim Wing,25 Grafton Way, London WC1 E 6DB, United Kingdom; e-mail: anthony.goldstone{at}uclh.nhs.uk.

   Acknowledgments

The authors wish to acknowledge with thanks the assistance ofAlli Lewis and Sonia Kamenetsky in the preparation of the manuscript.

   Footnotes

Submitted October 11, 2007; accepted November 15, 2007.
Prepublished online as Blood First Edition Paper, November 28, 2007 DOI: 10.1182/blood-2007-10-116582

The online version of this article contains a data supplement.

The publication costs of this article were defrayed in partby page charge payment. Therefore, and solely to indicate thisfact, this article is hereby marked "advertisement" in accordancewith 18 USC section 1734.

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  Copyright © 2008 by American Society of Hematology         Online ISSN: 1528-0020





	Copyright © 2008 by American Society of Hematology Online ISSN: 1528-0020