Tailored Therapy in Hodgkin Lymphoma, Based on Predefined Risk Factors and Early Interim PET/CT: Israeli H2 Study

Introduction: The aim of therapy in Hodgkin lymphoma (HL) is to maximize response and minimize long-term toxicity. Methods: This multicenter study prospectively evaluated outcomes of HL patients (pts) recruited between 9/2006-8/2013, whose therapy was chosen according to baseline prognostic factors...

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Published in:Blood 2014-12, Vol.124 (21), p.4409-4409
Main Authors: Dann, Eldad J, Bairey, Osnat, Bar-Shalom, Rachel, Sabbag, Elinor, Izak, Marina, Korenberg, Abraham, Akria, Luiza, Attias, Dina, Filanovsky, Kalman, Abadi, Uri, Ruchlemer, Rosa, Abdah-Bortnyak, Roxolyana, Goldschmidt, Neta, Epelbaum, Ron, Horowitz, Netanel, Lavie, David, Ben Yehuda, Dina, Shpilberg, Ofer, Paltiel, Ora B.
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Language:English
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Summary:Introduction: The aim of therapy in Hodgkin lymphoma (HL) is to maximize response and minimize long-term toxicity. Methods: This multicenter study prospectively evaluated outcomes of HL patients (pts) recruited between 9/2006-8/2013, whose therapy was chosen according to baseline prognostic factors and tailored based on PET/CT results performed after 2 cycles of chemotherapy (PET-2). Pts with classic HL aged 18-60 years, stages I-IV were eligible. Those with early HL were categorized into early favorable (EFD) and unfavorable (EUD) disease groups. After 2 ABVD cycles, EFD pts with negative PET-2 underwent involved nodal radiation therapy (INRT) and EUD pts received 2 more ABVD cycles (total 4) followed by INRT. At physician’s discretion, young pts requiring large-field irradiation could be given a total of 6 ABVD cycles with no RT. Pts with positive PET-2 received 2 additional ABVD cycles (total 4) in EFD and 4 additional cycles (total 6) in EUD followed by RT in both groups. Thus, differences in treatment modality between early disease pts with positive and negative PET-2 included addition of 2 ABVD cycles and mandatory RT for pts with positive PET-2. Pts with advanced HL (B symptoms or stages III/IV) were assigned to therapy based on the International Prognostic Score (IPS). Standard-risk pts (IPS 0-2) initially received 2 ABVD cycles and those with IPS of ≥ 3 received 2 cycles of escalated BEACOPP (EB). If PET-2 was negative or showed minimal residual uptake in a single site, further therapy with 4 ABVD cycles was given and RT to bulky mediastinal masses was omitted. If PET-2 was positive with no evidence of HL progression, therapy was escalated to EB with RT given to bulky mediastinal masses. Results: Data on 356 pts are presented in Table 1. At a median follow-up of 36 months (4-92), 3-y PFS for pts with early disease, overall, and for those with negative and positive PET-2, was 89, 91 and 74%, respectively (p=0.004). For pts with advanced HL, 3-y PFS overall and among those with negative and positive PET-2 was 85, 86 and 75%, respectively (p=0.012). No difference in PFS was observed according to IPS score. RT was given to 45% of pts with early and 12.5% of pts with advanced disease. Three pts died: one during autologous stem cell transplant (SCT), one after allogeneic SCT and one from acute myocardial ischemia. Conclusions: Tailored therapy based on PET-2 is feasible both in early and advanced HL. A positive PET-2 is a marker of inferior prognosis bo
ISSN:0006-4971
1528-0020
DOI:10.1182/blood.V124.21.4409.4409