ALBERT

Description: Background Diagnosis and prognosis of patients with established MDS/CMML is currently based on WHO criteria and the IPSS prognostic Index. High variation of survival in subgroups warrants the search for additional criteria. A comparison of CFU-C cultures with WHO criteria and IPSS score has not yet been done in a large patient group. Patients and methods We analyzed in a single center retrospective cohort study 93 untreated consecutive patients (55 male/ 38 female; median age: 66 years; range: 13 – 88 years) admitted between July 1992 and June 2002 and diagnosed as MDS/CMML (RA/RARS(4), MDS-U (2), RCMD (26), RAEB I/II (44) and CMML I/II (17). All patients had an unequivocal diagnosis of MDS or CMML according to WHO criteria. Simultaneous examinations of blood, bone marrow (cytology and biopsy), BM-cytogenetics and BM-and PB cultures for CFU-GM and BFU-E were done. Culture results were scored blindly and classified either as “Low risk CFU-C“ including normal growth (N=2), no colony growth (N=6) or reduced growth of normal colonies (N=19) or as „High risk CFU-C’s“ including excess normal growth in PB termed “MPS pattern” (N=5), discrete leukemic cluster growth (N=22), abundant leukemic cluster growth (N=14) or the „CMML pattern“ defined as giant“ pseudonormal“ CFU-GM and strongly reduced BFU-E (N=23). Culture score was compared with the WHO diagnosis and with the IPSS score in all 93 patients and survival was assesed in 82 patients treated with conventional therapy (12 allografted patients were excluded) after minimal observation time of 3 years in July 2005. Results Comparison of WHO diagnosis with culture score Low risk CFU-C score High risk CFU-C score RA/RARS/RCMD/MDS-U 15 16 RAEBI/II 12 30 CMML-I/II 0 17 The typical CMML pattern was observed in 13 of 17 patients with CMML (Specificity 94%). Comparison of IPSS Score with culture score low risk CFU-C score low risk CFU-C score High risk CFU-C score High risk CFU-C score IPSS Score alive/dead mean survival(d) alive/dead mean survival(d) Low and Int-1 4/4 2022+/−543 8/39 965+/−143 Int-2 and High 1/1 1024+/−701 1/26 565+/−92 Mean survival time for patients with a low/intermediate-1 IPSS score was less than half if they had a high risk CFU-score (p

Description: The 5q deletion syndrome is described as having a favourable outcome in MDS. However, little data is available concerning del(5q) and additional karyotype anomalies or taking into account bone marrow blast count. We screened the MDS registries of Düsseldorf, Germany and Lausanne, Switzerland in order to obtain data on patients with karyotype anomalies including del(5q). In both registries 1073 patients were karyotyped at diagnosis. 198 patients with del(5q) with or without other karyotype anomalies and 105 patients with complex karyotype anomalies without del(5q) were analysed. 106 patients showed del(5q) as single anomaly, 23 had 1 additional karyotype anomaly, 69 had 2 or more additional anomalies and were therefore classified as complex karyotype. In the group with del(5q) only, mean survival was 76 months as compared to 42 months in patients with a normal karyotype. In the group with 1 additional anomaly mean survival was 47 months (p=0.02), in the group with 2 or more additional anomalies 7 months (p=0.0005). Survival differed significantly in each subgroup when patients presenting less than 10% of bone marrow blasts where compared to patients with 10% or more. Patients with del(5q) only show a median survival of 12 months when presenting with more than 10% medullary blasts. Patients with a complex karyotype including del(5q) with less than 5% medullary blasts had a median survival of 12 months, but median survival was only 6 months in patients with elevated medullary blasts. By multivariate analyses, we found that additional karyotype anomalies, followed by an elevated medullary blast count above 10% are the most important independent prognostic parameters. Furthermore, we compared the subgroups with del(5q) and 2 or more additional karyotype anomalies (n=69) to patients with complex karyotype anomalies not including del(5q) (n=105). Median survival of the group with complex karyotype anomalies including del(5q) was 7 months as compared to 12 months in the group without del(5q) (p=0.02). 12 months after diagnosis, 30% of the group with del(5q) in a complex karyotype was alive as compared to 45% of the group with a complex karyotype without del(5q). Disease related death was noted in 77% of patients with a complex karyotype and del(5q) and 73% without del(5q). Therefore, our data show that the prognosis of survival in patients with del(5q) is highly dependent on the number of additional karyotype anomalies as well as medullary blast count. The prognosis of MDS patients with del(5q) is associated with an extremely poor prognosis when diagnosed within a complex karyotype. Although there are no substantial differences in clinical, haematological and morphological data between patients with or without del(5q), the median survival differs significantly. Figure Figure

Description: The most frequent chromosomal aberrations in B-cell chronic lymphocytic leukemia (B-CLL) are deletions on 13q, 11q, and 17p, and trisomy 12, all of which are of prognostic significance. Conventional cytogenetic analysis and fluorescence in situ hybridization (FISH) are used for their detection, but cytogenetic analysis is hampered by the low mitotic index of B-CLL cells, and FISH depends on accurate information about candidate regions. We used a set of 400 highly informative microsatellite markers covering all chromosomal arms (allelotyping) and automated polymerase chain reaction (PCR) protocols to screen 46 patients with typical B-CLL for chromosomal aberrations. For validation, we compared data with our conventional karyotype results and fine mapping with conventional single-site PCR. All clonal cytogenetic abnormalities potentially detectable by our microsatellite PCR (eg, del13q14 and trisomy 12) were picked up. Allelotyping revealed additional complex aberrations in patients with both normal and abnormal B-CLL karyotypes. Aberrations detectable in the samples with our microsatellite panel were found on almost all chromosomal arms. We detected new aberrant loci in typical B-CLL, such as allelic losses on 1q, 9q, and 22q in up to 25% of our patients, and allelic imbalances mirroring chromosomal duplications, amplifications, or aneuploidies on 2q, 10p, and 22q in up to 27% of our patients. We conclude that allelotyping with our battery of informative microsatellites is suitable for molecular screening of B-CLL. The technique is well suited for analyses in clinical trials, it provides a comprehensive view of genetic alterations, and it may identify new loci with candidate genes relevant in the molecular biology of B-CLL.

Description: The prognostic relevance of additional cytogenetic findings at diagnosis of chronic myeloid leukemia (CML) is unclear. The impact of additional cytogenetic findings at diagnosis on time to complete cytogenetic (CCR) and major molecular remission (MMR) and progression-free (PFS) and overall survival (OS) was analyzed using data from 1151 Philadelphia chromosome–positive (Ph+) CML patients randomized to the German CML Study IV. At diagnosis, 1003 of 1151 patients (87%) had standard t(9;22)(q34;q11) only, 69 patients (6.0%) had variant t(v;22), and 79 (6.9%) additional cytogenetic aberrations (ACAs). Of these, 38 patients (3.3%) lacked the Y chromosome (−Y) and 41 patients (3.6%) had ACAs except −Y; 16 of these (1.4%) were major route (second Philadelphia [Ph] chromosome, trisomy 8, isochromosome 17q, or trisomy 19) and 25 minor route (all other) ACAs. After a median observation time of 5.3 years for patients with t(9;22), t(v;22), −Y, minor- and major-route ACAs, the 5-year PFS was 90%, 81%, 88%, 96%, and 50%, and the 5-year OS was 92%, 87%, 91%, 96%, and 53%, respectively. In patients with major-route ACAs, the times to CCR and MMR were longer and PFS and OS were shorter (P 〈 .001) than in patients with standard t(9;22). We conclude that major-route ACAs at diagnosis are associated with a negative impact on survival and signify progression to the accelerated phase and blast crisis.

Description: Introduction The impact of the type of therapy on cytogenetic evolution in chronic myeloid leukemia (CML) regarding the occurrence of additional cytogenetic aberrations (ACA) at the time point of blast crisis (BC) may be critical. The aim of this analysis was to elucidate whether patients (pts) treated with imatinib (IM) had ACA less frequently than pts treated with BU and other therapies used prior to IM as hydroxyurea (HU) and interferon alpha (IFN). We comparatively analyze the BC karyotype of CML pts treated in consecutive trials of the German CML Study Group (Studies I, II and IV) to answer the following question: Does CML therapy influence the occurrence or even induce ACA or do these alterations rather reflect the natural history and the biology of the disease and are independent of therapy? Materials and methods Cytogenetic data of 157 pts with Philadelphia chromosome and BCR-ABL positive CML in BC were analyzed from a total of 2,380 pts randomized to CML study I (BU vs. HU vs. IFN, recruitment 1983 – 1991), CML study II (IFN + HU vs. HU, recruitment 1991 – 1994), and CML study IV (IM 400 mg vs. IM 800 mg vs. IM 400 mg +IFN vs. IM 400 mg + AraC vs. IM 400 mg after IFN failure recruitment 2002 – 2012). Cytogenetic analysis was reported according to ISCN 2005. ACA were divided into major route (+8, i(17)(q10), +19, +der(22)t(9;22)(q34;q11)) and minor route alterations (reciprocal translocations other than the t(9;22)(q34;q11), e.g. t(1;21), t(2;16), t(3;12), t(4;6), t(5;8), t(15;20) (Fabarius et al., Blood 2011). Confirmatory testing of pairwise comparisons of therapies with regard to their frequency of major ACAs was performed using two-sided chi-square test. To keep the level of significance at 0.05 despite multiple testing, a priori hypotheses were hierarchically ordered: First, frequency of major route ACA of pts on IM was compared with that on BU, then, with HU and with IFN. Next, the comparisons of IFN vs. BU and IFN vs. HU were planned. Cumulative incidences were estimated under consideration of death before BC as a competing risk. Results 115 of 188 pts randomized to BU (CML study I), 117 of 194 pts randomized to HU (CML study I only) and 159 of 360 randomized to IFN-based therapy (CML studies I+II) progressed to BC. Eight-year cumulative incidence probability of BC was 0.63 [95%-confidence interval (CI): 0.56; 0.69], 0.60 [95%-CI: 0.53; 0.66], and 0.49 [95%-CI: 0.43; 0.54] in pts randomized to BU, HU, and IFN-based therapy, respectively and 0.06 [95%-CI: 0.04; 0.07] in pts on IM (CML-study IV). Three-year survival probabilities after BC were 0.009 [95%-CI: 0.001; 0.043] with BU, 0.017 [95%-CI: 0.003; 0.055] with HU, 0.013 [95%-CI: 0.003; 0.042] with IFN, and 0.252 [95%-CI: 0.157; 0.368] with IM. Cytogenetic data at BC with banding analysis were available from 21 pts on BU, 31 on HU, 56 on IFN and 49 on IM. 81% of pts treated with BU, 52% with HU, 38% with IFN and 55% with IM showed major route ACA. All other pts had minor route ACA or translocation t(9;22)(q34;q11) and variant translocation (t(v;22)) without ACA (Table 1). The difference in major route ACA between BU and IM was significant (p = 0.04, two-sided chi-square test). There was no statistically significant difference in ACA between pts on HU and IFN in comparison to IM. According to the testing order, further comparative testing was not possible. However, the differences of induction of major route ACA between HU and BU and IFN and BU were even more pronounced than the difference between IM and BU. The most frequently observed major route ACA was trisomy 8 in all studies and therapy arms. Conclusions The type of cytogenetic aberrations in CML BC after different therapies is comparable. The characteristic major route ACA after various therapies points to a CML BC-related chromosomal pattern rather than a therapy-induced effect. Pts treated with IM showed a significantly lower rate of major route ACA than BU. IM not only reduces the frequency of BC and increases survival probabilities but appears to moderately change the biology of BC as compared to BU Disclosures: Haferlach: MLL Munich Leukemia Laboratory: Employment, Equity Ownership. Hehlmann:BMS: Consultancy, Research Funding; Novartis: Research Funding. Hochhaus:Pfizer: Consultancy, Honoraria; BMS: Consultancy, Honoraria, Research Funding; Ariad: Consultancy, Honoraria; Novartis: Consultancy, Honoraria, Research Funding, Travel Other. Müller:Novartis: Honoraria, Research Funding, Speakers Bureau; BMS: Honoraria, Research Funding; Ariad: Honoraria. Kolb:Pierre Fabre, Therakos: Honoraria; Kolb Consulting UG: Consultancy, Equity Ownership. Saussele:BMS: Honoraria, Research Funding, Travel, Travel Other; Pfizer: Honoraria; Novartis: Honoraria, Research Funding, Travel Other.

Description: During the course of chronic myeloid leukemia (CML) progression to blast crisis (BC) is thought to be caused by genetic instability such as cytogenetic aberrations in addition to the translocation t(9;22)(q34;q11). We have shown previously that major route ACA indicate an unfavorable outcome (Fabarius et al., Blood 2011). We now investigate whether there is a correlation in time between appearance of major route ACA and increase in blast count. Methods: Cytogenetic data and blast count in the peripheral blood were available from 1,290 CML patients recruited to the German CML-studies III (621 patients) and IIIa (669 patients) from January 1995 to January 2004. Treatments were interferon-alpha-based or related allogeneic stem cell transplantation (HSCT). Presence of ACA and major route ACA was considered as a time-dependent covariate. Multivariate proportional hazards models were estimated taking Euro CML score, study III vs. IIIa and stem cell transplantability into account. Cumulative incidences of blast increases were calculated starting at the date of the first ACA or major route ACA, respectively, regarding death as a competing risk. Patients were censored at the date of HSCT with an unrelated donor. Results: 1,287 patients were evaluable with median observation times of 13 and 12 years and a 10-year survival of 48% and 61% in CML studies III and IIIa, respectively. 258 patients progressed to BC with a cumulative 10-year incidence of 20%. 195 patients displayed ACA during the course of disease. 45 patients (15.7%) showed ACA already at diagnosis. 44 patients showed unbalanced minor route, 29 balanced minor route aberrations, 23 -Y. 109 patients showed major route aberrations including 10 with other prior ACA. In a multivariate analysis on 1,257 patients, patients with ACA had a hazard ratio (HR) for a blast increase of between 2.0-2.2 (p

Description: Introduction Current evidence indicates that acquired genetic instability in chronic myeloid leukemia (CML) as a consequence of the balanced reciprocal translocation t(9;22)(q34;q11) or the variant translocation t(v;22) and the resulting BCR-ABL fusion causes the continuous acquisition of additional chromosomal aberrations (ACA) and mutations and thereby progression to accelerated phase and blast crisis (BC). At least 10% of patients in chronic phase (CP) CML show ACA already at diagnosis and more than 80% of patients acquire ACA during the transformation process into BC. Therefore, alterations at diagnosis as well as acquisition of chromosomal changes during treatment are considered as a poor prognostic factor. Differences in progression-free survival (PFS) and overall survival (OS) have been detected depending on the type of ACA. Patients with major route ACA (+8, i(17)(q10), +19, +der(22)t(9;22)(q34;q11)) and with other alterations like -X, del(1)(q21), del(5)(q11q14), +10, -21 at diagnosis resulting in an unbalanced karyotype have a worse outcome. Patients with minor route ACA (for example reciprocal translocations other than the t(9;22)(q34;q11) (e.g. t(1;21), t(2;16), t(3;12), t(4;6), t(5;8), t(15;20)) resulting in a balanced karyotype show no differences in OS and PFS compared to patients with the standard translocation, a variant translocation or the loss of the Y chromosome (Fabarius et al., Blood 2011). Here we compare the type of chromosomal changes (i.e. balanced vs. unbalanced karyotypes) during the course of the disease from CP to BC aiming to provide a valid parameter for future risk stratification. Patients and Methods Clinical and cytogenetic data available from 1,346 out of 1,524 patients at diagnosis (40% females vs. 60% males; median age 53 years (range, 16-88)) with Philadelphia and BCR-ABL positive CP CML included until March 2012 in the German CML-Study IV (a randomized 5-arm trial to optimize imatinib therapy) were investigated. ACA were comparatively analyzed in CP and in BC. Results At diagnosis 1,174/1,346 patients (87%) had the standard t(9;22)(q34;q11) only and 75 patients (6%) had a variant t(v;22). Ninety-seven patients (7%) had additional cytogenetic aberrations. Of these, 44 patients (3%) lacked the Y chromosome (-Y) and 53 patients (4%) had ACA. Regarding the patients with ACA thirty-six of the 53 patients (68%) had an unbalanced karyotype and 17/53 patients (32%) a balanced karyotype. During the course of the disease 73 patients (out of 1,524 patients) developed a BC during the observation time (5%). Cytogenetic data were available in 52 patients with BC (21 patients with BC had no cytogenetic analysis). Three patients had a normal male or female karyotype after stem cell transplantation. Nine patients showed the translocation t(9;22)(q34;q11) or a variant translocation t(v;22) (six and three patients, respectively) only and in 40 patients ACA could be observed in BC (40/49 (82%)). Out of these 40 patients with ACA, 90% showed an unbalanced karyotype whereas only 10% of patients had a balanced karyotype. No male patient in BC showed the loss of the Y chromosome pointing to a minor effect of this numerical alteration on disease progression. Conclusion We conclude that patients with CML and unbalanced karyotype at diagnosis are under higher risk to develop CML BC compared to patients with balanced karyotypes or compared to patients without ACA. In BC, 90% of CML patients showed unbalanced karyotypes (only 68% of CML patients at diagnosis have unbalanced karyotypes) supporting the hypothesis that the imbalance of chromosomal material is a hallmark of disease progression, representing the natural history of the disease from CP to BC and indicating therefore a strong prognostic impact. Consequently, different therapeutic options (such as intensive therapy or stem cell transplantation) should be considered for patients with unbalanced karyotypes in CP CML at diagnosis. Disclosures: Haferlach: MLL Munich Leukemia Laboratory: Employment, Equity Ownership. Hehlmann:BMS: Consultancy, Research Funding; Novartis: Research Funding. Hochhaus:Novartis: Consultancy, Honoraria, Research Funding, travel Other; BMS: Consultancy, Honoraria, Research Funding; Pfizer : Consultancy, Honoraria; Ariad : Consultancy, Honoraria. Müller:Ariad: Honoraria; BMS: Honoraria, Research Funding; Novartis: Honoraria, Research Funding, Speakers Bureau. Saussele:Pfizer: Honoraria; BMS: Honoraria, Research Funding, Travel, Travel Other; Novartis: Honoraria, Research Funding, Travel Other.

Description: Introduction In acute leukemias, specific cytogenetic aberrations frequently correlate with myeloid or lymphoid phenotype of blasts and influence risk stratification. In chronic myeloid leukemia (CML) blast crisis (BC) it is not clear whether myeloid or lymphoid phenotype of blasts could be distinguished by specific chromosomal aberrations and have prognostic value. At diagnosis of CML, major route additional cytogenetic aberrations (ACA) like +8, i(17)(q10), +19, +der(22)t(9;22)(q34;q11) and minor route ACA like -X, del(1)(q21), del(5)(q11q14), +10,-21, resulting in an unbalanced karyotype have been described to adversely affect outcome. Patients with minor route ACA (for example reciprocal translocations other than the t(9;22)(q34;q11) (e.g. t(1;21), t(2;16), t(3;12), t(4;6), t(5;8), t(15;20)) resulting in a balanced karyotype did not show differences in overall survival and progression free survival compared to patients with the standard translocation, a variant translocation or the loss of the Y chromosome. Aim of this study was to analyze the impact of the phenotype (myeloid or lymphoid) on time to BC and on cytogenetic pattern. Methods 73 out of 1524 evaluable patients (4.8%) randomized until March 2012 to the German CML-Study IV (a 5-arm trial to optimize imatinib therapy) progressed to BC. Cytogenetic data of 23 out of 32 patients with myeloid BC and 14 out of 21 patients with lymphoid BC were available. In 15 patients, cytogenetic analysis were missing whereas 2 and 3 patients had megakaryoblastic and mixed phenotype, respectively and were not considered in this analysis. Karyotypes of lymphoid and myeloid BC were divided in major route and minor route ACA and balanced and unbalanced karyotypes. Categorical covariates were compared with Fisher’s exact test, while continuous covariates were compared with the Mann-Whitney-Wilcoxon test. Survival probabilities after BC were compared using the log-rank test. Results Out of 23 patients with myeloid BC, 14 (61%) had major route unbalanced ACA (n=10) or minor route unbalanced ACA (n=4), 4 had minor route balanced ACA and 5 patients had the translocation t(9;22)(q34;q11) or a variant translocation t(v;22) without ACA.13 out of 14 (93%) patients with lymphoid BC had major route unbalanced (n=10) or minor route unbalanced ACA (n=3) and 1 had the standard translocation t(9;22)(q34;q11) only. Between myeloid and lymphoid BC, the difference in the distribution of unbalanced ACA was apparent, but not statistically significant (p=0.06). The most frequently observed major route ACA was trisomy 8 in both groups (7 vs. 6), +der (22)t(9;22)(q34;q11) was more frequently found in myeloid than lymphoid BC (6 vs. 2), +19 was found in both phenotypes (3 vs. 3) whereas an isochromosome i(17)(q10) and an isoderivative chromosome ider(22)t(9;22)(q34;q11) were less frequent and found only in myeloid BC (1 for each vs 0 for each aberration). In lymphoid BC, 5 of 14 patients (36%) had ACA which involved chromosome 7 (del(7)(q22) and -7) whereas in myeloid BC only 2 patients (9%) had -7 (p=0.08). The balanced karyotype with a translocation t(3;21)(q26;q22) and the translocation t(9;11)(p22;q23) described in acute myeloid leukemia was observed in 3 patients with myeloid CML (2 and 1, respectively) and in none with lymphoid phenotype. No differences were observed in time to BC for patients with lymphoid vs. myeloid BC (p=0.31, median time: 409 vs. 453 days) and survival after onset of BC (p=0.9, median time: 544 vs. 284 days). Conclusions The proportion of unbalanced karyotypes was higher in lymphoid than in myeloid BC. In lymphoid BC alterations of chromosome 7 were more often present whereas +der(22)t(9;22)(q34;q11) was observed more frequently in myeloid BC. The reciprocal translocations t(3;21)(q26;q22) and t(9;11)(p22;q23) described in acute myeloid leukemias were only observed in myeloid BC. However these cytogenetic differences do not seem to alter the course of BC. Disclosures: Haferlach: MLL Munich Leukemia Laboratory: Employment, Equity Ownership. Hehlmann:Novartis: Research Funding; BMS: Consultancy, Research Funding. Hochhaus:Ariad: Consultancy, Honoraria; Pfizer: Consultancy, Honoraria; BMS: Consultancy, Honoraria, Research Funding; Novartis: Consultancy, Honoraria, Research Funding, Travel Other. Müller:Novartis: Honoraria, Research Funding, Speakers Bureau; BMS: Honoraria, Research Funding; Ariad: Honoraria. Saussele:Pfizer: Honoraria; BMS: Honoraria, Research Funding, Travel, Travel Other; Novartis: Honoraria, Research Funding, Travel Other.

Description: Abstract 782 Introduction: Current evidence indicates that acquired genetic instability in chronic myeloid leukemia (CML) as a consequence of the t(9;22)(q34;q11) and the resulting BCR-ABL fusion causes the continuous acquisition of additional chromosomal aberrations (ACA) and mutations and thereby progression to accelerated phase and blast crisis (BC). Around 10 –12% of patients in chronic phase (CP) CML have ACA already at diagnosis. During the course of the disease this number rises to 80% in BC. Acquisition of ACA during treatment is considered as a poor prognostic indicator, whereas the impact of ACA at diagnosis is controversial. Patients and methods: Clinical and cytogenetic data of 1151 out of 1311 patients with Philadelphia and BCR-ABL positive CP CML randomized until 2009 to the German CML-Study IV were investigated in a prospective study. There were 459 females (40%) and 692 males (60%). Median age was 53 years (range, 16–88). All patients were treated with imatinib alone or in combination with interferon alpha or araC. The impact of ACA at diagnosis on time to complete cytogenetic and major molecular remission (CCR, MMR) and progression-free and overall survival (PFS, OS) was investigated. Written informed consent was obtained from all patients prior to entering the study. Results: At diagnosis 1003/1151 patients (87%) had the standard t(9;22)(q34;q11) only and 69 patients (6.0%) had a variant t(v;22). In 60 of 69 patients with t(v;22), only one further chromosome was involved in the translocation, in 7 patients two, and in 2 patients three further chromosomes were involved. Seventy-nine patients (6.9%) had ACA. Of these, 38 patients (3.3%) lacked the Y chromosome (-Y) and 41 patients (3.6%) had ACA except -Y. Sixteen of the 41 patients had major-route ACA (+8, i(17)(q10), +der(22)t(9;22)(q34;q11), ider(22)(q10)t(9;22)(q34;q11)) and 25 minor-route ACA [e.g. t(3;12), t(4;6), t(2;16), t(1;21)]. In patients with major-route ACA, trisomy 8 was the most frequent additional alteration (n=9). +der(22)t(9;22)(q34;q11) was observed in six patients, isochromosome (17)(q10) in five patients and ider(22)(q10)t(9;22)(q34;11) in three patients. After a median observation time of 5.3 years for patients with t(9;22), t(v;22), -Y, minor- and major-route ACA median times to CCR were 1.01, 0.95, 0.98, 1.49 and 1.51 years, to MMR 1.40, 1.58, 1.65, 2.49 and 〉 7 years, 5-year PFS 90%, 81%, 88%, 96% and 50% and 5-year OS 92%, 87%, 91%, 96% and 53%, respectively. In patients with major-route ACA times to CCR and MMR were longer. PFS and OS were shorter (p