Literature DB >> 28962635

Long-term survival in patients treated with ruxolitinib for myelofibrosis: COMFORT-I and -II pooled analyses.

Srdan Verstovsek¹, Jason Gotlib², Ruben A Mesa³, Alessandro M Vannucchi⁴, Jean-Jacques Kiladjian⁵, Francisco Cervantes⁶, Claire N Harrison⁷, Ronald Paquette⁸, William Sun⁹, Ahmad Naim⁹, Peter Langmuir⁹, Tuochuan Dong¹⁰, Prashanth Gopalakrishna¹¹, Vikas Gupta¹².

Abstract

BACKGROUND: Myelofibrosis (MF) is associated with a variety of burdensome symptoms and reduced survival compared with age-/sex-matched controls. This analysis evaluated the long-term survival benefit with ruxolitinib, a Janus kinase (JAK)1/JAK2 inhibitor, in patients with intermediate-2 (int-2) or high-risk MF.
METHODS: This was an exploratory analysis of 5-year data pooled from the phase 3 COMFORT-I and -II trials. In both trials, patients could cross over to ruxolitinib from the control group (COMFORT-I, placebo; COMFORT-II, best available therapy). All continuing patients in the control groups crossed over to ruxolitinib by the 3-year follow-up. Overall survival (OS; a secondary endpoint in both trials) was evaluated using pooled intent-to-treat data from patients randomized to ruxolitinib or the control groups. OS was also evaluated in subgroups stratified by baseline anemia and transfusion status at week 24.
RESULTS: A total of 528 patients were included in this analysis; 301 were originally randomized to ruxolitinib (COMFORT-I, n = 155; COMFORT-II, n = 146) and 227 to control (n = 154 and n = 73, respectively). The risk of death was reduced by 30% among patients randomized to ruxolitinib compared with patients in the control group (median OS, 5.3 vs 3.8 years, respectively; hazard ratio [HR], 0.70 [95% CI, 0.54-0.91]; P = 0.0065). After correcting for crossover using a rank-preserving structural failure time (RPSFT) method, the OS advantage was more pronounced for patients who were originally randomized to ruxolitinib compared with patients who crossed over from control to ruxolitinib (median OS, 5.3 vs 2.3 years; HR [ruxolitinib vs RPSFT], 0.35 [95% CI, 0.23-0.59]). An analysis of OS censoring patients at the time of crossover also demonstrated that ruxolitinib prolonged OS compared with control (median OS, 5.3 vs 2.4 years; HR [ruxolitinib vs censored at crossover], 0.53 [95% CI, 0.36-0.78]; P = 0.0013). The survival benefit with ruxolitinib was observed irrespective of baseline anemia status or transfusion requirements at week 24.
CONCLUSIONS: These findings support ruxolitinib treatment for patients with int-2 or high-risk MF, regardless of anemia or transfusion status. Further analyses will be important for exploring ruxolitinib earlier in the disease course to assess the effect on the natural history of MF. TRIAL REGISTRATION: ClinicalTrials.gov identifiers, NCT00952289 and NCT00934544 .

RCT Entities: Population Interventions Outcomes

Entities: Chemical Disease Gene Species

Keywords: Anemia; Myelofibrosis; Overall survival; Ruxolitinib; Transfusion

Mesh：

Substances：
INCB018424
Pyrazoles

Year: 2017 PMID： 28962635 PMCID： PMC5622445 DOI： 10.1186/s13045-017-0527-7

Source DB: PubMed Journal: J Hematol Oncol ISSN： 1756-8722 Impact factor: 17.388

Background

Myelofibrosis (MF) is associated with progressive bone marrow fibrosis, splenomegaly [1], burdensome symptoms [2], and reduced survival compared with age- and sex-matched controls [3]. Anemia [4] and transfusion dependence [5] are associated with shortened overall survival (OS) in patients with MF. However, the effects of transfusion status on OS have not been evaluated in patients receiving ruxolitinib. Ruxolitinib is a Janus kinase (JAK)1/JAK2 inhibitor approved by the European Medicines Agency for the treatment of disease-related splenomegaly or symptoms in adult patients with primary MF (PMF), post–polycythemia vera MF (PPV-MF), and post–essential thrombocythemia MF (PET-MF) [6], and by the US Food and Drug Administration for intermediate or high-risk MF, including PMF, PPV-MF, and PET-MF [7]. Primary results from two long-term, pivotal phase 3 clinical trials (COMFORT-I and COMFORT-II) demonstrated that ruxolitinib reduced spleen volume, improved MF-related symptoms and quality-of-life measures, and was associated with prolonged OS in patients with intermediate-2 (int-2) or high-risk MF compared with controls [8-10]. Exploratory analyses of pooled 3-year data from the COMFORT trials showed that OS favored ruxolitinib regardless of baseline anemia status or development of new or worsening anemia post baseline [11]. Here, we report the findings from exploratory analyses of long-term OS benefit with ruxolitinib using pooled 5-year data from the COMFORT trials. In addition, OS was also evaluated in subgroups stratified by baseline anemia and week 24 transfusion status.

Methods

The double-blind COMFORT-I and open-label COMFORT-II trials (ClinicalTrials.gov identifiers, NCT00952289, NCT00934544) were randomized phase 3 studies described previously [8, 10]. Briefly, all patients were ≥ 18 years of age with int-2 or high-risk PMF, PPV-MF, or PET-MF. The ruxolitinib starting dose was 15 or 20 mg twice daily based on baseline platelet counts (100–200 or > 200 × 109/L, respectively). Dose modifications were permitted for safety and efficacy. Patients could cross over to ruxolitinib from the control group for progressive splenomegaly (COMFORT-I, ≥ 25% increase in spleen volume from baseline; COMFORT-II, study nadir) or for select protocol-defined progression events; crossover was mandatory following treatment unblinding in COMFORT-I. The control group in COMFORT-I received placebo. The control group in COMFORT-II received best available therapy; the three most common were hydroxyurea (47%), no medication (33%), and prednisone/prednisolone (12%). All continuing patients in the control groups crossed over to ruxolitinib by the 3-year follow-up [9, 12]. This report includes exploratory analyses of OS (a secondary endpoint in both studies) using pooled intent-to-treat (ITT) data from patients randomized to ruxolitinib and the control groups. OS was also evaluated in subgroups stratified by baseline anemia and transfusion status at week 24, defined as follows: Baseline anemia: receiving any units of red blood cells (RBCs) within 12 weeks before baseline measurement or having baseline hemoglobin < 10 g/dL. Baseline nonanemic: not meeting criteria for anemia. Transfusion independence at week 24: absence of RBC transfusions and hemoglobin levels ≥ 8 g/dL during weeks 13 to 24. Not transfusion independent at week 24: requiring RBC transfusions or hemoglobin levels < 8 g/dL during weeks 13 to 24. Transfusion dependence at week 24: requiring ≥ 4 units of RBCs or hemoglobin levels < 8 g/dL during weeks 17 to 24. Not transfusion dependent at week 24: requiring < 4 units of RBCs and hemoglobin levels ≥ 8 g/dL during weeks 17 to 24. Transfusion independence/dependence subgroup status was defined separately from baseline transfusion status (e.g., patients who were transfusion independent at week 24 did not necessarily require RBC transfusions before baseline). Two analyses were performed based on the definitions of independence and dependence, comparing patients who were (1) transfusion independent at week 24 versus not independent and (2) transfusion dependent at week 24 versus not dependent. Overall survival was evaluated using a stratified log-rank test and Cox proportional hazards model that estimated the treatment effect stratified by clinical trial and International Prognostic Scoring System (IPSS) risk [4]. The crossover-corrected treatment effect was estimated using a rank-preserving structural failure time (RPSFT) method and through censorship of survival time at the time of crossover. The effect of transfusion status on OS was evaluated using the Landmark approach, which included patients completing ≥ 24 weeks of study treatment, and the stratified log-rank test, which included study, IPSS risk, and baseline anemia status as stratification variables.

Results

Disposition and baseline anemia

This pooled analysis included 528 patients; 301 were originally randomized to ruxolitinib (COMFORT-I, n = 155; COMFORT-II, n = 146) and 227 were randomized to control (n = 154 and n = 73, respectively). Most patients in the control group crossed over to ruxolitinib during the study (69.6%). At data cutoff, 27.2% of patients in the ruxolitinib group versus 0 in the control group remained on treatment. Similar proportions of patients in each pooled treatment group had anemia at baseline (ruxolitinib, 45.8%; control, 49.8%); 39.3 and 67.5% of patients in the ruxolitinib and control groups, respectively, had ≥ 1 transfusion in the 28 days before baseline.

Overall survival: ITT analysis and subgroups by IPSS risk status

At the 5-year ITT analysis, 128 patients (42.5%) in the ruxolitinib group had died compared with 117 (51.5%) in the control group. The risk of death was reduced by 30% among patients randomized to ruxolitinib compared with patients in the control group (median OS, 5.3 vs 3.8 years, respectively; hazard ratio [HR; ruxolitinib vs control], 0.70 [95% CI, 0.54–0.91]; P = 0.0065; Fig. 1a [13]). After correcting for crossover using RPSFT, the OS advantage was more pronounced in patients who were originally randomized to ruxolitinib compared with patients who crossed over from control to ruxolitinib (median OS, 5.3 vs 2.3 years; HR [ruxolitinib vs RPSFT], 0.35 [95% CI, 0.23–0.59]; Fig. 1b). An analysis of OS censoring patients at the time of crossover also demonstrated that ruxolitinib prolonged survival compared with control (median OS, 5.3 vs 2.4 years; HR [ruxolitinib vs censored at crossover], 0.53 [95% CI, 0.36–0.78]; P = 0.0013; Fig. 1c).

Fig. 1

Overall survival: 5-year pooled data. OS analysis of 5-year pooled data from the COMFORT-I and -II trials. Data are presented a for the ITT population, b corrected for crossover with the RPSFT model, c censored at crossover, and d stratified by IPSS risk status. Originally presented at the American Society of Hematology 58th Annual Meeting [13]. HR, hazard ratio; int-2, intermediate-2; IPSS, International Prognostic Scoring System; ITT, intent-to-treat; NE, not evaluable; OS, overall survival; RPSFT, rank-preserving structural failure time Among patients randomized to ruxolitinib, those with int-2 MF had longer median OS than those with high-risk MF (median OS, int-2 not reached, estimated, 8.5 years; high-risk, 4.2 years; HR [high vs int-2], 2.86 [95% CI, 1.95–4.20]; P < 0.0001; Fig. 1d).

Overall survival: subgroups by baseline anemia status and week 24 transfusion status

Overall survival was not significantly different between ruxolitinib-treated patients who were transfusion independent and not independent at week 24 (P = 0.1322; Fig. 2a, e [13]), whereas there was a statistically significant difference in the control-treated subgroups (P = 0.0004; Fig. 2b, f). Among patients who were not transfusion independent at week 24, median OS favored ruxolitinib versus control in those with baseline anemia (200 vs 137 weeks) and those without baseline anemia (271 vs 166 weeks; overall P = 0.002).

Fig. 2

Overall survival: 5-year pooled data stratified by baseline anemia status and week 24 transfusion status. OS analysis of 5-year pooled data from the COMFORT-I and -II trials stratified by baseline anemia status and week 24 transfusion status. Patients in the ruxolitinib and control groups were stratified by anemia status at baseline and (a, b, e, f) transfusion independence status at week 24 or (c, d, g, h) transfusion dependence status at week 24. OS probability in the ruxolitinib group was not significantly affected by transfusion status at week 24 (transfusion independent vs not independent, P = 0.1322*; transfusion dependent vs not dependent, P = 0.4547*), but was significantly affected in the control group (transfusion independent vs not independent, P = 0.0004*; transfusion dependent vs not dependent, P = 0.0323*). Baseline anemia was defined as receiving any units of RBCs within 12 weeks before baseline measurement or having baseline hemoglobin < 10 g/dL; nonanemic was defined as not meeting criteria for anemia. Transfusion independence at week 24 was defined as the absence of RBC transfusions and hemoglobin levels ≥ 8 g/dL during weeks 13 to 24; not transfusion independent at week 24 was defined as requiring RBC transfusions or hemoglobin levels < 8 g/dL during weeks 13 to 24. Transfusion dependence at week 24 was defined as requiring ≥ 4 units of RBCs or hemoglobin levels < 8 g/dL during weeks 17 to 24; not transfusion dependent at week 24 was defined as requiring < 4 units of RBCs and hemoglobin levels ≥ 8 g/dL during weeks 17 to 24. Originally presented at the American Society of Hematology 58th Annual Meeting [13]. IPSS, International Prognostic Scoring System; OS, overall survival; RBC, red blood cell. *Stratified by study, IPSS risk, and baseline anemia status

Discussion

This exploratory pooled analysis of the COMFORT trials demonstrated that long-term treatment with ruxolitinib prolonged survival compared with best available treatment or placebo in patients with int-2 or high-risk MF. Importantly, ruxolitinib treatment was associated with statistically significant improvements in OS irrespective of baseline anemia status or transfusion requirements at week 24. These findings agree with previous reports from the COMFORT trials [8, 9, 11]. Anemia and the resulting dependence on RBC transfusions have been associated with reduced OS in patients with MF [4, 5, 11, 14, 15]. Ruxolitinib treatment may cause an initial reduction in hemoglobin levels in some patients with MF; however, the levels typically stabilize within 24 to 36 weeks [9, 12]. Furthermore, a previous report demonstrated that ruxolitinib was associated with prolonged survival regardless of baseline anemia status [11]. The current analysis expanded on these findings by demonstrating that patients’ week 24 transfusion status did not significantly affect OS in the ruxolitinib group but was associated with reduced OS in the control group. Although the survival benefit associated with ruxolitinib treatment in patients with int-2 or high-risk MF is well established, further improvements in patient outcomes may be achieved by limiting the cytopenias experienced by some patients during treatment initiation. A recent phase 2 study of patients with int-2 or high-risk MF assessed combination treatment with ruxolitinib and danazol to obviate ruxolitinib-related anemia and thrombocytopenia [16]. Hematologic stabilization was achieved in most patients; however, the trial was halted due to modest efficacy per International Working Group-Myeloproliferative Neoplasms Research and Treatment criteria, and results from only 14 patients were reported. Further research is necessary to identify strategies that may be able to limit the initial cytopenias associated with ruxolitinib treatment in some patients.

Conclusions

Taken together, these findings indicate that anemia and transfusion status at week 24 do not affect the survival advantage of patients with int-2 or high-risk MF treated with ruxolitinib. Moreover, they underscore the importance of monitoring for cytopenias, which are generally manageable with ruxolitinib dose modifications [8, 10] and adjuvant therapy. Given these data, there is a rationale for exploring ruxolitinib earlier in the disease course to assess the effect on the natural history of MF.

13 in total

1. Three-year efficacy, safety, and survival findings from COMFORT-II, a phase 3 study comparing ruxolitinib with best available therapy for myelofibrosis.

Authors: Francisco Cervantes; Alessandro M Vannucchi; Jean-Jacques Kiladjian; Haifa Kathrin Al-Ali; Andres Sirulnik; Viktoriya Stalbovskaya; Mari McQuitty; Deborah S Hunter; Richard S Levy; Francesco Passamonti; Tiziano Barbui; Giovanni Barosi; Claire N Harrison; Laurent Knoops; Heinz Gisslinger
Journal: Blood Date: 2013-10-30 Impact factor: 22.113

2. A double-blind, placebo-controlled trial of ruxolitinib for myelofibrosis.

Authors: Srdan Verstovsek; Ruben A Mesa; Jason Gotlib; Richard S Levy; Vikas Gupta; John F DiPersio; John V Catalano; Michael Deininger; Carole Miller; Richard T Silver; Moshe Talpaz; Elliott F Winton; Jimmie H Harvey; Murat O Arcasoy; Elizabeth Hexner; Roger M Lyons; Ronald Paquette; Azra Raza; Kris Vaddi; Susan Erickson-Viitanen; Iphigenia L Koumenis; William Sun; Victor Sandor; Hagop M Kantarjian
Journal: N Engl J Med Date: 2012-03-01 Impact factor: 91.245

3. JAK inhibition with ruxolitinib versus best available therapy for myelofibrosis.

Authors: Claire Harrison; Jean-Jacques Kiladjian; Haifa Kathrin Al-Ali; Heinz Gisslinger; Roger Waltzman; Viktoriya Stalbovskaya; Mari McQuitty; Deborah S Hunter; Richard Levy; Laurent Knoops; Francisco Cervantes; Alessandro M Vannucchi; Tiziano Barbui; Giovanni Barosi
Journal: N Engl J Med Date: 2012-03-01 Impact factor: 91.245

4. Patterns of survival among patients with myeloproliferative neoplasms diagnosed in Sweden from 1973 to 2008: a population-based study.

Authors: Malin Hultcrantz; Sigurdur Yngvi Kristinsson; Therese M-L Andersson; Ola Landgren; Sandra Eloranta; Asa Rangert Derolf; Paul W Dickman; Magnus Björkholm
Journal: J Clin Oncol Date: 2012-07-16 Impact factor: 44.544

5. Impact of ruxolitinib treatment on the hemoglobin dynamics and the negative prognosis of anemia in patients with myelofibrosis.

Authors: Haifa Kathrin Al-Ali; Viktoriya Stalbovskaya; Prashanth Gopalakrishna; Julian Perez-Ronco; Lynda Foltz
Journal: Leuk Lymphoma Date: 2016-02-25

6. DIPSS plus: a refined Dynamic International Prognostic Scoring System for primary myelofibrosis that incorporates prognostic information from karyotype, platelet count, and transfusion status.

Authors: Naseema Gangat; Domenica Caramazza; Rakhee Vaidya; Geeta George; Kebede Begna; Susan Schwager; Daniel Van Dyke; Curtis Hanson; Wenting Wu; Animesh Pardanani; Francisco Cervantes; Francesco Passamonti; Ayalew Tefferi
Journal: J Clin Oncol Date: 2010-12-13 Impact factor: 44.544

7. Efficacy, safety, and survival with ruxolitinib in patients with myelofibrosis: results of a median 3-year follow-up of COMFORT-I.

Authors: Srdan Verstovsek; Ruben A Mesa; Jason Gotlib; Richard S Levy; Vikas Gupta; John F DiPersio; John V Catalano; Michael W N Deininger; Carole B Miller; Richard T Silver; Moshe Talpaz; Elliott F Winton; Jimmie H Harvey; Murat O Arcasoy; Elizabeth O Hexner; Roger M Lyons; Azra Raza; Kris Vaddi; William Sun; Wei Peng; Victor Sandor; Hagop Kantarjian
Journal: Haematologica Date: 2015-01-23 Impact factor: 9.941

8. A dynamic prognostic model to predict survival in primary myelofibrosis: a study by the IWG-MRT (International Working Group for Myeloproliferative Neoplasms Research and Treatment).

Authors: Francesco Passamonti; Francisco Cervantes; Alessandro Maria Vannucchi; Enrica Morra; Elisa Rumi; Arturo Pereira; Paola Guglielmelli; Ester Pungolino; Marianna Caramella; Margherita Maffioli; Cristiana Pascutto; Mario Lazzarino; Mario Cazzola; Ayalew Tefferi
Journal: Blood Date: 2009-12-14 Impact factor: 22.113

9. New prognostic scoring system for primary myelofibrosis based on a study of the International Working Group for Myelofibrosis Research and Treatment.

Authors: Francisco Cervantes; Brigitte Dupriez; Arturo Pereira; Francesco Passamonti; John T Reilly; Enrica Morra; Alessandro M Vannucchi; Ruben A Mesa; Jean-Loup Demory; Giovanni Barosi; Elisa Rumi; Ayalew Tefferi
Journal: Blood Date: 2008-11-06 Impact factor: 22.113

Review 10. The 2016 revision to the World Health Organization classification of myeloid neoplasms and acute leukemia.

Authors: Daniel A Arber; Attilio Orazi; Robert Hasserjian; Jürgen Thiele; Michael J Borowitz; Michelle M Le Beau; Clara D Bloomfield; Mario Cazzola; James W Vardiman
Journal: Blood Date: 2016-04-11 Impact factor: 22.113

80 in total

Review 1. Managing myelofibrosis (MF) that "blasts" through: advancements in the treatment of relapsed/refractory and blast-phase MF.

Authors: Robyn M Scherber; Ruben A Mesa
Journal: Hematology Am Soc Hematol Educ Program Date: 2018-11-30

Review 2. Novel and combination therapies for polycythemia vera and essential thrombocythemia: the dawn of a new era.

Authors: Jan Philipp Bewersdorf; Amer M Zeidan
Journal: Expert Rev Hematol Date: 2020-11-01 Impact factor: 2.929

3. Interferon Therapy in Myelofibrosis: Systematic Review and Meta-analysis.

Authors: Jan Philipp Bewersdorf; Smith Giri; Rong Wang; Nikolai Podoltsev; Robert T Williams; Raajit K Rampal; Martin S Tallman; Amer M Zeidan; Maximilian Stahl
Journal: Clin Lymphoma Myeloma Leuk Date: 2020-05-28

4. Targeting compensatory MEK/ERK activation increases JAK inhibitor efficacy in myeloproliferative neoplasms.

Authors: Simona Stivala; Tamara Codilupi; Sime Brkic; Anne Baerenwaldt; Nilabh Ghosh; Hui Hao-Shen; Stephan Dirnhofer; Matthias S Dettmer; Cedric Simillion; Beat A Kaufmann; Sophia Chiu; Matthew Keller; Maria Kleppe; Morgane Hilpert; Andreas S Buser; Jakob R Passweg; Thomas Radimerski; Radek C Skoda; Ross L Levine; Sara C Meyer
Journal: J Clin Invest Date: 2019-03-04 Impact factor: 14.808

Review 5. Philadelphia-Negative Myeloproliferative Neoplasms: Laboratory Workup in the Era of Next-Generation Sequencing.

Authors: Zhuang Zuo; Shaoying Li; Jie Xu; M James You; Joseph D Khoury; C Cameron Yin
Journal: Curr Hematol Malig Rep Date: 2019-10 Impact factor: 3.952

6. Low-dose ruxolitinib shows effective in treating myelofibrosis.

Authors: Yunfan Yang; Hongmei Luo; Yuhuan Zheng; Zhongqing Zou; Ting Niu; Yongqian Jia; Huanling Zhu; Ting Liu; Yu Wu; Hong Chang; Jie Ji; Jian Li; Ling Pan
Journal: Ann Hematol Date: 2020-10-20 Impact factor: 3.673

7. Phase 1/2 trial of glasdegib in patients with primary or secondary myelofibrosis previously treated with ruxolitinib.

Authors: Aaron T Gerds; Tetsuzo Tauchi; Ellen Ritchie; Michael Deininger; Catriona Jamieson; Ruben Mesa; Mark Heaney; Norio Komatsu; Hironobu Minami; Yun Su; Naveed Shaik; Xiaoxi Zhang; Christine DiRienzo; Mirjana Zeremski; Geoffrey Chan; Moshe Talpaz
Journal: Leuk Res Date: 2019-02-28 Impact factor: 3.156

Review 8. Progress in elucidation of molecular pathophysiology of myeloproliferative neoplasms and its application to therapeutic decisions.

Authors: Ruochen Jia; Robert Kralovics
Journal: Int J Hematol Date: 2019-11-18 Impact factor: 2.490

9. Guidance on changing therapy choice in myelofibrosis.

Authors: Donal P McLornan; Claire N Harrison
Journal: Blood Adv Date: 2020-02-25

10. Ruxolitinib and interferon-α2 combination therapy for patients with polycythemia vera or myelofibrosis: a phase II study.

Authors: Anders Lindholm Sørensen; Stine Ulrik Mikkelsen; Trine Alma Knudsen; Mads Emil Bjørn; Christen Lykkegaard Andersen; Ole Weis Bjerrum; Nana Brochmann; Dustin Andersen Patel; Lise Mette Rahbek Gjerdrum; Daniel El Fassi; Torben A Kruse; Thomas Stauffer Larsen; Hans Torben Mourits-Andersen; Claus Henrik Nielsen; Christina Ellervik; Niels Pallisgaard; Mads Thomassen; Lasse Kjær; Vibe Skov; Hans Carl Hasselbalch
Journal: Haematologica Date: 2019-12-26 Impact factor: 9.941