Abstract
Abstract 1539
Standard AML therapy with cytarabine and an anthracycline produces a complete remission (CR) rate of 60%–70% but cure rates of only 15%–25%. AI (ara-C 1.5g/m2x3d and idarubicin 12mg/m2x3d), the standard induction chemotherapeutic backbone used at M.D. Anderson Cancer Center for AML, consists of idarubicin 12 mg/m2/day on days 1–3 and cytarabine 1.5 g/m2 IV over 24 hours daily on days 1–4 (days 1–3 only if age >60 years). In recent years several targeted agents have been combined with IA in an attempt to improve outcomes.
We reviewed all the AI-based protocols used at our institution over the last decade to identify combinations that may improve outcomes over standard AI. Only trials that enrolled >20 pts (age 15–70 years) were analyzed, including AI alone (n=486) and in combination with sorafenib (BAY; n=56), interleukin-11 (IL-11; n=37), lisofylline (Liso; n=24), vorinostat (SAHA; n=58), tipifarnib (Zarn; n=84), G-CSF+/−ATRA (G+/−ATRA; n=115). Patients with core-binding factor AML or acute promyelocytic leukemia were excluded.
The combination of AI with BAY (84%), lisofylline (67%), SAHA (76%) and G+/−ATRA (76%; no difference regardless of the addition of ATRA) produced higher CR rates than IA alone (61%; p=0.0001), which for BAY and SAHA was also accompanied by improved early death (ED; 8-wk mortality) rate and median overall survival (OS) (5%/not reached [NR] & 5%/68wks) compared to AI alone (15%/48wks) (Table 1, Figure 1). AI+Zarn produced similar CR (61%) but improved ED rate & OS (8%/54wks) while AI+G+/−ATRA also rendered a better OS (83wks) than AI. Of note, both BAY (80%) and SAHA (79%) but not G+/−ATRA (57%) included a higher number of pts younger than 60 yrs compared to AI (55%). However, when only pts <60 years were considered, the CR/OS rates were still superior for BAY (87%/NR), SAHA (76%/68wks), and G+/−ATRA (86%/115wks) compared with AI (71%/67wks). A similar trend was observed for pts ≥60 years (73%/64wks for BAY, 67%/32wks for SAHA, 61%/34wks for G+/−ATRA, and 49%/29 for AI) but the low number of pts in the BAY (n=11), and SAHA (n=12), albeit not in the G+/−ATRA group (n=49), limits the value of this comparison.
Regimens . | AI . | AI+BAY . | AI+IL11 . | AI+LISO . | AI+SAHA . | AI+ZARN . | AIG+/-ATRA . | p value . | |||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
. | N . | % . | N . | % . | N . | % . | N . | % . | N . | % . | N . | % . | N . | % . | |
Response Rate | |||||||||||||||
CR | 296 | 61% | 47 | 84% | 19 | 51% | 16 | 67% | 43 | 74% | 51 | 61% | 87 | 76% | 0.001 |
CRp | 21 | 4% | 2 | 4% | 1 | 3% | 0 | 0% | 6 | 10% | 8 | 10% | 0 | 0% | |
ED | 74 | 15% | 1 | 2% | 7 | 19% | 6 | 25% | 3 | 5% | 7 | 8% | 20 | 17% | |
NR | 95 | 20% | 6 | 11% | 10 | 27% | 2 | 8% | 6 | 10% | 18 | 21% | 8 | 7% | |
Total | 486 | 56 | 37 | 24 | 58 | 84 | 115 | ||||||||
Pts age 0–59 | 266 | 55% | 45 | 80% | 9 | 24% | 12 | 50% | 46 | 79% | 80 | 95% | 66 | 57% | 0.00001 |
Pts age ≥60 | 220 | 45% | 11 | 20% | 28 | 76% | 12 | 50% | 12 | 21% | 4 | 5% | 49 | 43% | 0.0001 |
Median CRD (Weeks) | 63 | 58 | 39 | 26 | 42 | 72 | 82 | 0.085 | |||||||
2-year | 39% | 34% | 29% | 13% | 50% | 46% | 42% | ||||||||
5-year | 28% | 0% | 44% | 31% | |||||||||||
Median OS (Weeks) | 48 | NR | 20 | 33 | 68 | 54 | 83 | <0.001 | |||||||
2-year | 32% | 63% | 12% | 21% | 32% | 39% | 42% | ||||||||
5-year | 18% | 8% | 31% | 20% |
Regimens . | AI . | AI+BAY . | AI+IL11 . | AI+LISO . | AI+SAHA . | AI+ZARN . | AIG+/-ATRA . | p value . | |||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
. | N . | % . | N . | % . | N . | % . | N . | % . | N . | % . | N . | % . | N . | % . | |
Response Rate | |||||||||||||||
CR | 296 | 61% | 47 | 84% | 19 | 51% | 16 | 67% | 43 | 74% | 51 | 61% | 87 | 76% | 0.001 |
CRp | 21 | 4% | 2 | 4% | 1 | 3% | 0 | 0% | 6 | 10% | 8 | 10% | 0 | 0% | |
ED | 74 | 15% | 1 | 2% | 7 | 19% | 6 | 25% | 3 | 5% | 7 | 8% | 20 | 17% | |
NR | 95 | 20% | 6 | 11% | 10 | 27% | 2 | 8% | 6 | 10% | 18 | 21% | 8 | 7% | |
Total | 486 | 56 | 37 | 24 | 58 | 84 | 115 | ||||||||
Pts age 0–59 | 266 | 55% | 45 | 80% | 9 | 24% | 12 | 50% | 46 | 79% | 80 | 95% | 66 | 57% | 0.00001 |
Pts age ≥60 | 220 | 45% | 11 | 20% | 28 | 76% | 12 | 50% | 12 | 21% | 4 | 5% | 49 | 43% | 0.0001 |
Median CRD (Weeks) | 63 | 58 | 39 | 26 | 42 | 72 | 82 | 0.085 | |||||||
2-year | 39% | 34% | 29% | 13% | 50% | 46% | 42% | ||||||||
5-year | 28% | 0% | 44% | 31% | |||||||||||
Median OS (Weeks) | 48 | NR | 20 | 33 | 68 | 54 | 83 | <0.001 | |||||||
2-year | 32% | 63% | 12% | 21% | 32% | 39% | 42% | ||||||||
5-year | 18% | 8% | 31% | 20% |
When the analysis was limited to pts with unfavorable cytogenetics (−5, −7, complex) BAY (75%/NR), SAHA (69%/43wks), G+/−ATRA (80%/23wks) also improved the outcomes produced by AI (50%/21wks) with better ED rates (0%, 5%, 12.5% and 19%, respectively).
Of the latter targeted agents, sorafenib and SAHA showed remarkable activity in FLT3-mutated AML. CR/OS rates for pts with FLT3-ITD were 94%/67wks for BAY, 91%/77wks for SAHA (no FLT3 mutational data for G+/−ATRA) and 64%/48wks for AI (AI vs BAY or SAHA, p=0.001 for CR and p=0.001 for OS).
Long-term follow-up suggests that IA combined with sorafenib, SAHA, or G+/−ATRA may improve outcomes in pts with AML, including those with adverse karyotypes and those older than 60 years, compared with AI alone. AI+Sorafenib and (surprisingly) AI+SAHA showed remarkable activity against FLT3-mutated AML. Randomized studies are warranted to confirm these observations.
No relevant conflicts of interest to declare.
Author notes
Asterisk with author names denotes non-ASH members.
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