Ghobadi Armin, Fiala Mark A, Ramsingh Giridharan, Gao Feng, Abboud Camille N, Stockerl-Goldstein Keith, Uy Geoffrey L, Grossman Brenda J, Westervelt Peter, DiPersio John F
Division of Oncology, Department of Medicine, Washington University School of Medicine, St. Louis, Missouri.
Division of Oncology, Department of Medicine, Washington University School of Medicine, St. Louis, Missouri.
Biol Blood Marrow Transplant. 2017 Jul;23(7):1072-1077. doi: 10.1016/j.bbmt.2017.03.019. Epub 2017 Mar 18.
CD34-selected stem cell boost (SCB) without conditioning has recently been utilized for poor graft function (PGF) after allogeneic hematopoietic stem cell transplantation with promising results. Unfortunately, many patients have been unable to receive the boost infusion as their donors were unwilling or unable to undergo an additional stem cell collection. Therefore, we conducted this study utilizing either fresh or cryopreserved peripheral blood stem cell products to create CD34-selected boost infusions for the treatment of PGF. Additionally, to explore relationship of CD34 dose and response, we included a cohort of donors mobilized with plerixafor in addition to the standard granulocyte colony-stimulating factor (G-CSF). Twenty-six patients with PGF were included in this study. Seventeen donor-recipient pairs were enrolled onto the prospective study; an additional 9 patients treated off protocol were reviewed retrospectively. Three different donor products were used for CD34 selection: (1) fresh mobilized product using G-CSF only, (2) fresh mobilized products using G-CSF and plerixafor, and (3) cryopreserved cells mobilized with G-CSF. CD34 cell selection was performed using a CliniMACS. The infusion was not preceded by administration of any chemotherapy or conditioning regimen. The primary objective was hematologic response rate and secondary objectives included CD34 yields, incidence and severity of acute and chronic graft-versus-host disease (GVHD), overall survival (OS), and relapse-free survival (RFS). The median post-selection CD34 counts per kilogram of recipient weight were 3.1 × 10, 10.9 × 10, and 1 × 10 for G-CSF only, G-CSF plus plerixafor, and cryopreserved products, respectively. The median CD34 yields (defined as the number of CD34 cells after selection/CD34 cells before CD34 selection) were 69%, 66%, and 28% for G-CSF only, G-CSF plus plerixafor, and cryopreserved products, respectively. After SCB, 16 of the 26 recipients (62%) had a complete response, including 5 of 8 (63%) who received cryopreserved products. Five had a partial response (19%), resulting in an overall response rate of 81%. One-year RFS and OS were 50% and 65%, respectively. There was no treatment-related toxicity reported other than GVHD: 6 (23%) developed acute GVHD (2 grade I and 4 grade II) and 8 (31%) developed chronic GVHD (2 limited and 6 extensive). Cryopreserved products are viable alternatives to create SCB for the treatment of PGF. When collecting fresh products is an option, the addition of plerixafor increases CD34 yield over G-CSF alone; however, it is currently unclear if the CD34 cell dose impacts the efficacy of the SCB.
最近,未进行预处理的CD34选择的干细胞增强治疗(SCB)已被用于异基因造血干细胞移植后移植物功能不良(PGF)的治疗,并取得了有前景的结果。不幸的是,许多患者无法接受增强输注,因为他们的供体不愿意或无法进行额外的干细胞采集。因此,我们开展了这项研究,利用新鲜或冷冻保存的外周血干细胞产品来制备用于治疗PGF的CD34选择的增强输注物。此外,为了探索CD34剂量与反应的关系,除了标准的粒细胞集落刺激因子(G-CSF)外,我们还纳入了一组使用普乐沙福动员的供体。本研究纳入了26例PGF患者。17对供体-受体对纳入前瞻性研究;另外9例接受非方案治疗的患者进行回顾性分析。三种不同的供体产品用于CD34选择:(1)仅使用G-CSF的新鲜动员产品,(2)使用G-CSF和普乐沙福的新鲜动员产品,(3)用G-CSF动员的冷冻保存细胞。使用CliniMACS进行CD34细胞选择。输注前未给予任何化疗或预处理方案。主要目标是血液学反应率,次要目标包括CD34产量、急性和慢性移植物抗宿主病(GVHD)的发生率和严重程度、总生存期(OS)和无复发生存期(RFS)。每千克受体体重选择后的CD34计数中位数,仅使用G-CSF的产品为3.1×10,G-CSF加普乐沙福的产品为10.9×10,冷冻保存产品为1×10。CD34产量中位数(定义为选择后CD34细胞数/CD34选择前CD34细胞数),仅使用G-CSF的产品为69%,G-CSF加普乐沙福的产品为66%,冷冻保存产品为28%。SCB后,26例受体中有16例(62%)完全缓解,包括8例接受冷冻保存产品的患者中的5例(63%)。5例部分缓解(19%),总缓解率为81%。1年RFS和OS分别为50%和65%。除GVHD外,未报告与治疗相关的毒性:6例(23%)发生急性GVHD(2例I级和4例II级),8例(31%)发生慢性GVHD(2例局限性和6例广泛性)。冷冻保存产品是制备用于治疗PGF的SCB的可行替代方案。当可以选择采集新鲜产品时,添加普乐沙福比单独使用G-CSF可提高CD34产量;然而,目前尚不清楚CD34细胞剂量是否影响SCB的疗效。
