Peripheral blood progenitor cell (PBPC) transplantation with a single apheresis in patients with lymphoma,myeloma and solid tumors

Abstract: The aim of this study was to investigate if a single apheresis after peripheral blood progenitor cell (PBPC) mobilization can be used to rescue patients receiving high dose chemotherapy (HD.CHE) as treatment for an underlying malignancy. Eighteen consecutive patients who were admitted to the transplant unit for treatment were leukapheresed following mobilization with one of the following protocols: group I: rHuG–CSF alone, group II: conventional chemotherapy (C.CHE)+rHuG–CSF or rHuGM–CSF and group III: high dose Cytoxan (HD.CTX)+rHuG–CSF. The optimal day for leukapheresis was determined by following white blood cell counts (WBC), mononuclear cell counts (MNC) and CD34⁺ cell counts daily. Granulocyte – macrophage colony-forming cells (GM–CFC) assay was performed at the leukapheresis product and prior to reinfusion. All patients proceeded directly to ablative therapy according to their underlying malignancy. PBPC from single apheresis were reinfused to all patients and cytokines started 24 h after infusion. Hematologic recovery after HD.CHE was the parameter used to ensure successful engraftment. We have been able to recover adequate number of PBPC for transplantation with a single apheresis in all patients. The number of infused cells were for groups I, II and III: (1) median number of MNC 4.7, 3.58 and 2.79 × 10⁸/kg, respectively (2); median number of CD34⁺ cells 4.4, 2.8, 2.7 × 10⁶/kg, respectively. The median apheresis day was 6, 16 and 16, respectively. Recovery times to granulocyte count >0.5 × 10⁹/L was 9 d (range 9–12) and to platelets >20 × 10⁹/L was 12 d (range 1–135); 17/18 patients have engrafted successfully independent of the mobilization method used.These data suggest that sufficient PBPC can be harvested at a single leukapheresis for hemopoietic rescue after myeloablative therapy. Rapid hematologic recovery occurs when cytokines alone after conventional or HD.CHE are used for mobilization. Results of collection products and hematopoietic recovery are independent of the mobilization technique used.     

Phase II study of etoposide,ifosfamide, and mitoxantrone for the treatment of resistant adult acute lymphoblastic leukemia

Although combination chemotherapy induces complete remission in 60–90% of adults with acute lymphoblastic leukemia, only 20–45% of patients remain in continued remission 5 years from diagnosis. For patients with a short first remission, multiple relapses, or patients with disease refractory to initial induction chemotherapy, few salvage treatments are successful. To improve the results of salvage therapy we studied the efficacy and toxicity of a combination of etoposide (100 mg/m² IV qd × 5), ifosfamide (1.5 g/m²/d × 5), and mitoxantrone (8 mg/m²/d IV × 3) in 11 adult patients with relapsed or refractory ALL. The median follow-up of all patients completing therapy is 208 days (30–484+ days). Eight of 11 (73%; 95% confidence interval 45–92%) achieved a complete remission, two patients failed to enter remission, and one patient died of multiorgan system failure shortly after receiving therapy. Median DFS is 96 days and median survival from remission is 234 days. Five patients who achieved CR subsequently relapsed with a median time to relapse of 80 days (50–151 days). Median time to granulocyte > .5 × 10⁹/L was 28 days (21–46 days) and the median time to platelet recovery > 20 × 10⁹/L was 24 days (21–39 days). Although gastrointestinal toxicity was common, no patient developed severe cardiac, hepatic, pulmonary, or neurologic complications. These results demonstrate that the combination of etoposide, ifosfamide, and mitoxantrone can be used as an effective salvage therapy for patients with resistant ALL.     

Granulocyte colony-stimulating factor given in addition to interferon-α to mobilize peripheral blood stem cells for autologous transplantation in chronic myeloid leukaemia

In order to potentially mobilize and harvest the Ph^? cells observed in most patients with chronic myeloid leukaemia (CML) during interferon-α (IF-α) therapy, G-CSF (filgrastim), 5 μg/kg/d, was administered subcutaneously together with IF-α to 30 CML patients in haematological remission but with various degrees of cytogenetic remission, after IF-α therapy. Peripheral blood stem cells (PBSC ) were harvested using standard aphereses from day 5 of G-CSF. Patients underwent one to four (median three) aphereses. Median total yields/kg were 7.6 (range 3.8–25) × 10⁸ MNC, 3.4 (0–140) × 10⁶ CD34⁺ cells, and 17 (1.1–107) × 10⁴ CFU-GM. No patient had a significant increase in the percentage of Ph⁺ cells in the bone marrow under G-CSF therapy. The percentage of Ph⁺ cells in apheresis products tended to decrease between the first and the last apheresis (P = 0.05). 14 patients who were not responsive to IF-α were transplanted after conditioning with busulphan 16 mg/kg and melphalan 140 mg/m². Median time to neutrophils > 0.5 × 10⁹/l was 20 d (16–114 d) and to platelets > 50 × 10⁹/l 18 d (12–149 d). Nine patients had a major cytogenetic response post graft, which correlated with the amount of Ph⁺ cells reinfused with the graft (P = 0.02). We conclude that this procedure is feasible, allowing the harvest of enough PBSC, some of them Ph^? in patients who responded to IF-α, to allow autologous transplantation.     

FLAG (Fludarabine,Cytarabine, G-CSF) as a second line therapy for acute lymphoblastic leukemia with myeloid antigen expression: in vitro and in vivo effects

Abstract: Thirteen consecutive adult patients with primary refractory (n = 5) or relapsed (n = 8) acute lymphoblastic leukemia (ALL) were treated by an induction schedule (FLAG) consisting of Fludarabine (30 mg/sqm/d) plus high dose Cytarabine (HD-ara-C: 2 g/sqm/d) (d 1–5) and G-CSF (from d 0 to polymorphonuclear recovery). Patients achieving complete remission (CR) were administered a second FLAG course as consolidation and were then submitted to an individualized program of post-remission therapy, depending on the patient's age and performance status. CR was achieved in 8/12 evaluable cases (67%). The median CR duration was 22.5 w. CR attainment was significantly related to the co-expression of lymphoid and myeloid antigens. ALL/My+ patients achieved CR in 6/6 evaluable cases vs. 2/6 for ALL/My^-. In vitro ³H ara-C incorporation into cellular DNA resulted significantly increased by Fludarabine (in 7/9 tested cases) and, furthermore, by the association of Fludarabine-G-CSF in 5 evaluable ALL/My+ cases; in contrast, no effect of G-CSF addition to Fludarabine was observed in 4 ALL/My^–. Myelosuppression was observed in all patients: the median time to neutrophils >0.5 × 10⁹/l was 16.3 d (range 13–22) and 16.2 d (range 9–29) to platelets>20 × 10⁹/l. Nonhematological toxicity was minimal. In conclusion, FLAG is an active and tolerable combination in refractory ALL, particularly in cases with myeloid antigen expression where G-CSF appears to improve efficacy, probably increasing ara-C incorporation into the DNA of leukemic cells.     

Peripheral blood progenitor cells mobilized by chemotherapy plus granulocyte-colony stimulating factor accelerate both neutrophil and platelet recovery after high-dose VP16, ifosfamide and cisplatin

Summary. We report on the chemotherapy plus granulocyte colony-stimulating factor (G-CSF) induced mobilization of peripheral blood progenitor cells (PBPCs) and their impact on haematopoietic recovery following high-dose chemotherapy. Twenty-four patients with advanced solid tumours or lymphomas received standard-dose chemotherapy with VP16, ifosfamide and cisplatin (VIP) followed by filgrastim (G-CSF; 5 μg/kg s.c. daily for 14 d) for the prevention of chemotherapy induced neutropenia and for the simultaneous mobilization of PBPCs. Maximal numbers of progenitors of different lineages were reached at day 11 (range 9–14) after VIP chemotherapy. A median of 0·415 × 10⁹/1 CD34⁺ cells (range 0·11–1·98), 9000 CFU-GM/ml (range 2800–17700). 3500 BFU-E/ml (range 400–10800) and 200 CFU-GEMM/ml (range 0–4400) were recruited. One single apheresis yielded a median of 1·6 × 10⁸ mononuclear cells/kg (range 0·2–5·4) or 5·4 × 10⁶ CD34⁺ cells/kg body weight (range 0·2–24·2). Fourteen patients who showed at least a partial remission after two cycles of the standard-dose chemotherapy regimen were subjected to high-dose VIP chemotherapy (cumulative doses of 1500 mg/m² VP16, 12 g/m² ifosfamide and 150 mg/m² cisplatin) with or without PBPC support. The first six patients were treated with growth factors only (IL-3/GM-CSF) and did not receive PBPCs, whereas the following eight patients were supported with PBPCs in addition to IL-3 and GM-CSF. Neutrophil recovery as well as platelet recovery were significantly faster in patients receiving PBPCs with a median of 6·5 d below 0·1 × 10⁹ neutrophils/1 and 3 d below 20 × 10⁹ platelets/1 as compared to 10·5 d and 8 d in control patients receiving growth factors only. The accelerated platelet recovery in patients supported with PBPCs might be explained—in the absence of detectable colony-forming units megakaryocyte—by the presence of glycoprotein IIb/IIIa⁺, non-proliferating endomitotic megakaryocytic precursor cells within G-CSF mobilized PBPCs. Our data demonstrate that chemotherapy plus G-CSF mobilized PBPCs accelerate both neutrophil and platelet recovery after high-dose VIP chemotherapy in patients with solid tumours or lymphomas.     

Successful autologous bone marrow rescue in patients who failed peripheral blood stem cell mobilization

 We assessed autologous bone marrow (BM) harvest and hematologic recovery after high-dose chemotherapy (HDCT) in patients who failed to achieve peripheral blood stem cell (PBSC) mobilization. One hundred and ninety-three patients with germ cell tumor, malignant lymphoma, sarcoma or medulloblastoma were scheduled for HDCT. In 123 patients, PBSC were mobilized by disease-specific chemotherapy plus granulocyte colony-stimulating factor (G-CSF). In 110/123 patients (89%) with circulating CD34+ cell counts ≥10/μl, sufficient hematopoietic autografts were collected (group A). In 13/123 patients (11%) with peripheral CD34+ cell counts <10/μl, PBSC harvesting was not performed (group B). These latter patients were classified as "poor mobilizers" and underwent second-line BM harvest at a median of 46 (range 10–99) days after mobilization failure. Seventy patients with first-line BM harvest (group C) acted as historical controls. Ten patients from group B proceeded to HDCT and nine were evaluable for hematopoietic reconstitution. Recovery to neutrophils >0.5×10⁹/l was comparable with group C patients: 16 (range 9–34) days vs 13 (range 8–98) days. However, platelet (PLT) reconstitution >20×10⁹/l was significantly slower, with a median of 35 (range 13–50) days as compared with 19 (range 9–148) days (P=0.0106) for control patients. Supportive care requirements, febrile days and length of hospital stay were not significantly different between the two groups of patients. We conclude that patients who fail to mobilize PBSC should be evaluated for second-line BM harvest. This approach may preserve the therapeutic option of HDCT for these patients. Received: 7 March 2000 / Accepted: 4 May 2000     

FLAG-IDA in the treatment of refractory/relapsed adult acute lymphoblastic leukemia

Relapsed or refractory adult acute lymphoblastic leukemias (ALL) have poor prognosis. The strategy for treating these patients is through reinduction chemotherapy followed by allogeneic stem cell transplantation, provided that the toxicity of the salvage regimen is acceptable. Twenty three patients with relapsed/refractory adult ALL were treated with fludarabine, cytarabine, granulocyte colony-stimulating factor, and idarubicin (FLAG-IDA). Five patients had primary refractory disease, and 18 were in first relapse. Nine (39.1%) patients achieved complete remission (CR) following salvage therapy, whereas 13 (56.5%) patients were refractory, and one patient died in aplasia due to infection. In patients achieving remission, the median time to reach absolute neutrophil count (ANC) more than 0.5×10⁹/l and 1×10⁹/l was 20 (range 16–25) and 24 (range 20–28) days from the start of chemotherapy, respectively. Platelet levels of more than 20×10⁹/l and 100×10⁹/l were achieved in a median time of 23 (range 19–25) and 33 (range 28–39) days, respectively. Fever more than 38.5°C was observed in 18 of 23 patients (78.2%), 13 had fever of unknown origin, and 5 had documented infections. Nonhematological side effects, consisting mainly of mucositis (18/23 or 78.2%) and transient liver toxicity increase (10/23 or 43.4%), were generally tolerated. All nine patients who achieved CR received a second course with FLAG-IDA, and seven patients underwent allogeneic stem cell transplantation (four from a matched donor, one from a mismatched donor, and two from an unrelated donor), while two did not reach that stage due to early relapse from CR. The median overall survival (OS) for all 23 patients was 4.5 (range 1–38) months; for the nine responders, the disease-free survival (DFS) and the OS were 6 (range 3–38) and 9 (7–38) months, respectively; the seven patients who received allogeneic stem cell transplantation had a DFS of 10 (range 7–38) months. In our experience, FLAG-IDA is a well-tolerated regimen in relapsed/refractory ALL patients; the toxicity is acceptable, enabling patients who have achieved CR to receive allogeneic transplantation.     

Transplantation of peripheral blood progenitor cells from HLA-identical sibling donors

Transplantation of peripheral blood progenitor cells (PBPCs) has largely replaced autologous bone marrow transplantation. The same might occur in the allogeneic setting if the favourable initial experience with allogeneic PBPCT is confirmed. We analysed all primary transplants utilizing unmodified PBPC from HLA-identical sibling donors reported to the European Group for Blood and Marrow Transplantation (EBMT) for 1994. 59 patients with a median age of 39 years received myeloablative therapy for acute myelogenous leukaemia (23 patients), acute lymphoblastic leukaemia (13), chronic myelogenous leukaemia (nine), lymphoma (seven), or other diagnoses (seven) mostly of advanced stages followed by transplantation of allogeneic PBPC. Three patients died soon after grafting, the others showed prompt haemopoietic recovery with median times to recover an absolute neutrophil count (ANC) above 0.5 and 1.0×10⁹/l of 15 (range 9–27) and 17 d (range 10–28) respectively. Time to platelet recovery above 20 or 50×10⁹/l was 16 (range 9–76) and 18 d (range 12–100) respectively. 27 patients (46%) developed no or mild acute graft-versus-host disease (GVHD). The incidence of moderate (grade II) disease was 27%; 24% of the patients developed severe acute GVHD (grades III or IV). 55% of patients who were alive 90 d after transplantation developed chronic GVHD, the probability to develop extensive chronic GVHD was 32% (95% confidence interval 22–42) with a median follow-up of 14 months. Overall and event-free survival (EFS) at 1 year were 54% (CI 48–60) and 50% (CI 43–57), respectively, the relapse incidence was 23% (CI 17–29). EFS was 67% (CI 55–79) in patients transplanted for acute leukaemias in first complete remission, chronic myelogenous leukaemia in first chronic phase, or severe aplastic anaemia. Transplantation of allogeneic PBPC resulted in prompt and durable engraftment. The incidence and severity of acute and chronic GVHD seemed comparable to that observed after allogeneic BMT. Overall and event-free survival in this cohort of patients, most of whom suffered from advanced leukaemia or lymphoma, is encouraging, suggesting that the high numbers of T lymphocytes and/or natural killer cells contained in a typical PBPC collection product exert a vigorous graft-versus-leukaemia effect. Further evaluation of allogeneic PBPCT is highly desirable.     

Successful collection of peripheral blood progenitor cells in patients with acute myeloid leukaemia following early consolidation therapy with granulocyte colony-stimulating factor-supported high-dose cytarabine and mitoxantrone

We evaluated the feasibility of collecting peripheral blood progenitor cells (PBPC) in patients with acute myeloid leukaemia (AML) following two cycles of induction chemotherapy with idarubicin, cytarabine and etoposide (ICE), and one cycle of consolidation therapy with high-dose cytarabine and mitoxantrone (HAM). Thirty-six patients of the multicentre treatment trial AML HD93 were enrolled in this study, and a sufficient number of PBPC was harvested in 30 (83%). Individual peak concentrations of CD34⁺ cells in the blood varied (range 13.1–291.5/μl; median 20.0/μl). To reach the target quantity of 2.5 × 10⁶ CD34⁺ cells/kg, between one and six (median two) leukaphereses (LP) were performed. The LP products contained between 0.2 × 10⁶ and 18.9 × 10⁶ CD34⁺cells/kg (median 1.2 × 10⁶/kg). Multivariate analysis showed that the white blood cell count prior to HAM and the time interval from the start of HAM therapy to reach an unsupported platelet count > 20 × 10⁹/l were predictive for the peak value of CD34⁺ cells in the blood during the G-CSF stimulated haematological recovery. In 16 patients an intraindividual comparison was made between bone marrow (BM) and PBPC grafts. Compared to BM grafts, PBPC grafts contained 14-fold more MNC, 5-fold more CD34⁺ cells and 36-fold more CFU-GM. A CD34⁺ subset analysis showed that blood-derived CD34⁺ cells had a more immature phenotype as indicated by a lower mean fluorescence intensity for HLA-DR and CD38. In addition, the proportion of CD34⁺/Thy-1⁺ cells tended to be greater in the PBPC grafts. The data indicate that sufficient PBPC can be collected in the majority of patients with AML following intensive double induction and first consolidation therapy with high-dose cytarabine and mitoxantrone.     

Kinetics of T-cell subset reconstitution following treatment with bendamustine and rituximab for low-grade lymphoproliferative disease: a population-based analysis

Delayed lymphocyte and T-cell immune reconstitution following bendamustine-rituximab (BR) for indolent non-Hodgkin lymphoma (iNHL) has been described, but no information is available for chronic lymphocytic leukaemia (CLL). We present a population-based retrospective analysis of immune reconstitution and risk of infection following BR. Outcomes included timing/correlates of CD4+ recovery and risk of ≥grade 3 infections. Consecutively treated patients (1 April 2014 to 31 January 2017) were included (n = 295),with a median age of 65 years (range 33–92); 57% were 1st line treatments. Median cumulative bendamustine dose was 1080 mg/m² (range 140–1440 mg/m²). CD4/CD8/CD19/NK subsets were available for 148 patients. Median follow-up was 24 months. Median times to lymphocyte count (ALC) recovery (≥1 × 10⁹/l) and CD4+ recovery (≥0·2 × 10⁹/l) were 26 and 24 months, respectively. Bendamustine total dose >1080 mg/m² (hazard ratio [HR] 0·4; 95% confidence interval [CI]: 0·2–0·8), end-of-treatment ALC ≤0·4 × 10⁹/l (HR 0·53; 95% CI: 0·3–0·9) and CD4+ <0·1 × 10⁹/l 1-year post-BR (HR 0·03; 95% CI: 0·008–0·15) were covariables for delayed CD4+ recovery. ALC-recovery ≥1 × 10⁹/l was an unreliable predictor of CD4+ recovery (negative predictive vale 74%, positive predictive value 86%, likelihood ratio 3·3). CD4+ lymphopenia >3 years was a significant risk factor for ≥grade 3 infections (Odds ratio 3·4; 95% CI: 1·4–6·9). CD4+ recovery after BR is unexpectedly delayed and late recovery is associated with risk of serious infections. Monitoring CD4+ following BR could identify patients at high risk of delayed infections.     

Autografting with blood progenitor cells: predictive value of preapheresis blood cell counts on progenitor cell harvest and correlation of the reinfused cell dose with hematopoietic reconstitution

One hundred and nine patients suffering from various malignancies underwent 285 apheresis procedures for PBPC collection. A median of two leukaphereses (range: 2–5) resulted in median numbers of 4.6×10 ⁸ MNC/kg, 14.1×10 ⁴ CFU-GM/kg, and 6.0×10 ⁶ CD34+ cells/kg. Preleukapheresis peripheral blood CD34+ cells correlated significantly with collected CD34+ cells/kg ( r=0.94; p<0.0001) and with CFU-GM/kg ( r=0.52; p<0.0001). A value >4×10 ⁴ CD34+ cells/ml was highly predictive for a collection yield >2.5×10 ⁶ CD34+ cells/kg harvested by a single leukapheresis. Sixty patients were evaluated for hematologic reconstitution and engrafted in a median time of 10 days for WBC >1.0×10 ⁹/l (range: 7–21 days), 10 days for ANC >0.5×10 ⁹/l (7–20) and 11 days for PLT >20×10 ⁹/l (7–62). Reinfused CD34+ cells/kg correlated significantly with hematologic engraftment ( r=0.44–0.52 and p<0.006–0.001) as well as CFU-GM/kg ( r=0.36–0.44 and p<0.007–0.001). A progenitor cell dose >2.5×10 ⁶ CD34+ cells/kg or >8.0×10 ⁴ CFUGM/kg led to a significantly faster recovery for WBC, ANC, and PLT when compared with patients receiving <2.5×10 ⁶ CD34+ cells/kg or <8.0×10 ⁴ CFU-GM/kg. We conclude that rapid hematopoietic engraftment after high-dose therapy and PBPC reinfusion correlates well with a progenitor cell dose >2.5×10 ⁶ CD34+ cells/kg or >8.0×10 ⁴ CFU-GM/kg, and that above a preleukapheresis threshold of 4×10 ⁴ CD34+ cells/ml a PBPC autograft containing >2.5×10 ⁶ CD34+ cells/kg can be collected by a single leukapheresis. We suggest that patients recovering from myelosuppression should be monitored for CD34+ cells in serial blood samples to determine the course of circulating hematopoietic progenitor cells. This issue will help to define the optimal time point to start apheresis and to predict a PBPC autograft harvested by a single leukapheresis, which will lead to rapid and stable hematopoietic reconstitution following transplantation.     

White blood cell count and mortality in patients with acute pulmonary embolism

Although associated with adverse outcomes in other cardiovascular diseases, the prognostic value of an elevated white blood cell (WBC) count, a marker of inflammation and hypercoagulability, is uncertain in patients with pulmonary embolism (PE). We therefore sought to assess the prognostic impact of the WBC in a large, state‐wide retrospective cohort of patients with PE. We evaluated 14,228 patient discharges with a primary diagnosis of PE from 186 hospitals in Pennsylvania. We used random‐intercept logistic regression to assess the independent association between WBC count levels at the time of presentation and mortality and hospital readmission within 30 days, adjusting for patient and hospital characteristics. Patients with an admission WBC count <5.0, 5.0–7.8, 7.9–9.8, 9.9–12.6, and >12.6 × 10⁹/L had a cumulative 30‐day mortality of 10.9%, 6.2%, 5.4%, 8.3%, and 16.3% (P < 0.001), and a readmission rate of 17.6%, 11.9%, 10.9%, 11.5%, and 15.0%, respectively (P < 0.001). Compared with patients with a WBC count 7.9–9.8 × 10⁹/L, adjusted odds of 30‐day mortality were significantly greater for patients with a WBC count <5.0 × 10⁹/L (odds ratio [OR] 1.52, 95% confidence interval [CI] 1.14–2.03), 9.9–12.6 × 10⁹/L (OR 1.55, 95% CI 1.26–1.91), or >12.6 × 10⁹/L (OR 2.22, 95% CI 1.83–2.69), respectively. The adjusted odds of readmission were also significantly increased for patients with a WBC count <5.0 × 10⁹/L (OR 1.34, 95% CI 1.07–1.68) or >12.6 × 10⁹/L (OR 1.29, 95% CI 1.10–1.51). In patients presenting with PE, WBC count is an independent predictor of short‐term mortality and hospital readmission. Am. J. Hematol. 88:677–681, 2013. © 2013 Wiley Periodicals, Inc.     

Successful mobilization of peripheral blood stem cells in heavily pretreated myeloma patients with G-CSF alone

 We investigated the feasibility of mobilizing peripheral blood stem cells (PBSC) with G-CSF alone in 24 patients with multiple myeloma. The median age was 53 years (range 33–62). All patients had stage II/III disease and responded to standard first-line (n=6) or salvage chemotherapy (n=18). The median number of previous chemotherapy cycles was 7 (4–18) and the median number of prior melphalan-cycles was 6 (0–14). Nine (35%) patients had experienced prior radiation therapy. The patients received either 10 μg/kg G-CSF (n=18) or 24 μg/kg G-CSF (n=7, including one patient with previous 10 μg/kg G-CSF stimulation) daily s.c. for 5 or more consecutive days until completion of harvesting, starting apheresis on the fifth day. G-CSF treatment was well tolerated, with only slight bone pain in half of the patients (51%). After a median of three (range 1–7) apheresis procedures, medians of 3.8 (0.3–17)×10⁶ CD34+ cells/kg, 8.5 (4.5–24)×10⁸ MNC/kg, 2.9 (0.6–39.4)×10⁴ CFU-GM/kg, and 5.6 (0.9–49)×10⁴ BFU-E/kg were harvested. Three patients (12%) with extensive melphalan pretreatment failed the target collection of at least 2.0×10⁶ CD34+ cell/kg. Pretreatment with six or more cycles of melphalan yielded a smaller number of CD34+ cells than pretreatment with fewer than six cycles (2.5 vs 5.3×10⁶/kg;p=0.001). Nineteen patients underwent high-dose chemotherapy consisting of either total marrow irradiation (9 Gy)/busulfan (12 mg/kg) and cyclophosphamide (120 mg/kg) (n=10), or busulfan (14 mg/kg)/cyclophosphamide (120 mg/kg) (n=5), or tandem melphalan (200 mg/m²). The median time for granulocyte (>1.0/nl) and platelet (>50/nl) recovery was 10 and 14 days (ranges 7–12 and 8–40), respectively. G-CSF alone is a safe, alternative approach to mobilizing sufficient PBSC in patients with multiple myeloma and allows an exact prediction of harvest time. G-CSF-mobilized PBSCs ensure rapid engraftment after myeloablative therapy. Melphalan treatment should be avoided in patients who are candidates for high-dose chemotherapy. Received: February 5, 1998 / Accepted: April 14, 1998     

Peripheral Blood Progenitor Cell Collection during Hematopoietic Recovery following Autologous Blood Progenitor Cell Transplantation

Background and objectives: Peripheral blood progenitor cells (PBPC) are increasingly used for autologous transplantation after high-dose radio/chemotherapy in patients suffering from cancer. PBPC are usually collected after mobilization with conventional-dose chemotherapy plus growth factor. However, it is conceivable to perform leukapheresis for the second autograft during recovery of hematopoiesis after the first course of HDCT/ABPCT. Materials and methods: We treated two patients this way. In the first, with germ cell cancer, six 12-liter leukaphereses yielded 1.8×10⁶ CD34+ cells/kg after mobilization with cis-platinum, etoposide and ifosfamide (PEI) plus granulocyte colony-stimulating factor (G-CSF). The second patient, with relapsed Hodgkin's disease, underwent PBPC collection after treatment with dexamethasone, carmustine, etoposide, cytarabine and melphalan (DexaBEAM) plus G-CSF. Due to excellent mobilization, 8.5×10⁶ CD34+ cells/kg were collected by one 12-liter leukapheresis. Both patients then underwent PBPC collection during hematopoietic recovery following HDCT and ABPCT. Results: In patient 1, following HDCT and ABPCT, three 12-liter aphereses resulted in 0.7×10⁶ CD34+ cells/kg. In patient 2, also after HDCT and ABPCT, a second autograft with 3.2×10⁶ CD34+ cells/kg was harvested by a single 10-liter apheresis. No adverse effects were seen in either patient during apheresis following ABPCT. To our knowledge this is the first report dealing with PBCT collection during hematopoietic recovery following HDCT and ABPCT. Conclusions: (1) PBPC harvesting is feasible and well tolerated in this setting. (2) In appropriate patients with efficient PBPC mobilization after conventional-dose chemotherapy, a further PBPC autograft can be collected during recovery of hematopoiesis after ABPCT, serving as a rescue for a second course of HDCT.     

The utility of ADAMTS13 in differentiating TTP from other acute thrombotic microangiopathies: results from the UK TTP Registry

Thrombotic microangiopathies (TMAs) are frequently difficult to differentiate clinically, and measurement of ADAMTS13 (a disintegrin and metalloproteinase with a thrombospondin type 1 motif, member 13) remains vital in thrombotic thrombocytopenic purpura (TTP) diagnosis. We retrospectively reviewed cases referred for ADAMTS13 testing, using UK TTP Registry screening data. Of a total 810 cases, 350 were confirmed as TTP. The 460 non‐TTP cases comprised secondary TMAs (24·57%) and haemolytic uraemic syndrome (HUS) (27·17% aHUS, 2·83% Shiga‐like toxin‐producing E. coli [STEC]‐HUS); the remainder were TMAs with no clear association, not TMAs, or had no confirmed diagnosis. ADAMTS13 levels were significantly lower in TTP than STEC‐HUS, aHUS and other TMAs. TTP patients had significantly lower platelet count (15 × 10⁹/l; range 0–96) than aHUS (57 × 10⁹/l; range 13–145, P < 0·0001) or STEC‐HUS (35 × 10⁹/l; range 14–106, P < 0·0001); they also had lower creatinine levels (92 μmol/l; range 43–374) than aHUS (255 μmol/l; range 23–941, P < 0·0001) and STEC‐HUS (324 μmol/l; range 117–639, P < 0·0001). However, 12/34 (35·3%) aHUS patients had a platelet count <30 × 10⁹/l and 26/150 (17·3%) of TTP patients had a platelet count >30 × 10⁹/l; 23/150 (15·3%) of TTP patients had a creatinine level >150 μmol/l. This study highlights the wide variety of TMA presentations, and confirms the utility of ADAMTS13 testing in TTP diagnosis.     

Autologous progenitor cell transplantation: prior exposure to stem cell- toxic drugs determines yield and engraftment of peripheral blood progenitor cell but not of bone marrow grafts

Agents with stem cell-toxic potential are frequently used for salvage therapy of Hodgkin's disease (HD) and high-grade non-Hodgkin's lymphoma (NHL). Because many patients with relapsed or refractory lymphoma are candidates for autologous progenitor cell transplantation, possible toxic effects of salvage chemotherapy on progenitor cells must be taken into account. In a retrospective study, we have analyzed the influence of a salvage regimen containing the stem cell-toxic drugs BCNU and melphalan (Dexa-BEAM) on subsequently harvested bone marrow (BM)- and peripheral blood-derived progenitor cell grafts (PBPC) and compared it with other factors. Progenitor cells were collected from 96 patients with HD or high-grade NHL. Seventy-nine grafts were reinfused (35 PBPC and 44 BM) after high-dose chemotherapy. Compared with patients autografted with BM, hematopoietic recovery was significantly accelerated in recipients of PBPC. For PBPC, the number of Dexa-BEAM cycles ( > or = v > 1) was the predominate prognostic factor affecting colony-forming unit-granulocyte-macrophage (CFU-GM) yield (66 v 6.8 x 10(4)/kg, P = .0001), CD34+ cell yield (6.6 v 1.6 x 10(6)/kg, P = .0001), neutrophil recovery to > 0.5 x 10(9)/L (9 v. 11 days, P = .0086), platelet recovery to > 20 x 10(9)/L (10 v 15.5 days, P = .0002), and platelet count on day +100 after transplantation (190 v 107 x 10(9)/L, P = .031) using univariate analysis. Previous radiotherapy was associated with significantly lower CFU-GM and CD34+ cell yields but had no influence on engraftment. Patient age, patient sex, disease activity, or chemotherapy other than Dexa-BEAM did not have any prognostic impact. Multivariate analysis confirmed that Dexa-BEAM chemotherapy was the overriding factor adversely influencing CFU-GM yield (P < .0001), CD34+ cell yield (P < .0001), and platelet engraftment (P < .0001). BM grafts were not significantly affected by previous Dexa-BEAM chemotherapy or any other variable tested. However, prognostic factors favoring the use of BM instead of PBPC were not identified using joint regression models involving interaction terms between the graft type (PBPC or BM) and the explanatory variables investigated. We conclude that, in contrast to previous radiotherapy or other chemotherapy, exposure to salvage regimens containing stem cell- toxic drugs, such as BCNU and melphalan, is a critical factor adversely affecting yields and performance of PBPC grafts. Marrow progenitor cells appear to be less sensitive to stem cell-toxic chemotherapy. PBPC should be harvested before repeated courses of salvage chemotherapy involving stem cell-toxic drugs to preserve the favorable repopulation kinetics of PBPC in comparison with BM.     

Factors influencing G-CSF-mediated mobilization of hematopoietic progenitor cells during steady-state hematopoiesis in patients with malignant lymphoma and multiple myeloma

 We retrospectively analyzed factors influencing PBPC mobilization during steady-state hematopoiesis in 52 patients with malignant lymphoma (n=35) or multiple myeloma (n=17) who received 77 cycles of G-CSF (12.5–50 μg G-CSF/kg/day). For 15 of these patients, the first mobilization cycle (12.5 μg G-CSF/kg/day) was followed by a second course with an increased dose of G-CSF (25 or 50 μg/kg/day). Leukapheresis was started on day 4, about 2 h after s.c. G-CSF administration, and repeated on 2–5 consecutive days. CD34+ cells were determined by flow cytometry in each apheresis product and in the peripheral blood prior to G-CSF administration, beginning on day 4. Colony assays were performed on cryopreserved samples prior to autografting. In the 15 patients receiving two mobilization cycles the higher G-CSF dose was associated with higher levels of CD34+ cells, a higher mean yield of CD34+ cells per apheresis (p<0.05), and a higher percentage of successful (>2×10⁶ CD34+ cells/kg) collections (p=0.058). Patients with limited previous cytotoxic therapy (n=19, up to six cycles of a standard regimen such as CHOP and/or less than 20% marrow irradiation) who received a daily dose of 12.5 μg G-CSF/kg had higher levels of circulating CD34+ cells, a higher mean yield of CD34+ cells per apheresis (p<0.05), and a higher percentage of successful collections (p<0.05) compared with patients previously treated with more intensive radiochemotherapy (n=15). Ten of 20 patients (50%) who failed during the first cycle were successful during subsequent cycles with escalated doses of G-CSF. Trough levels of circulating CD34+ cells on day 4 were predictive for success or failure to achieve >2×10⁶ CD34+ cells/kg, especially in heavily pretreated patients. In conclusion, a daily dose of 12.5 μg G-CSF/kg seems sufficient to mobilize PBPC during steady-state hematopoiesis in the majority of patients who have received limited previous radiochemotherapy. Higher doses of G-CSF, up to 50 μg/kg/day, mobilize more PBPC and should be considered for patients previously treated with intensive radiochemotherapy or those failing to mobilize sufficient numbers of CD34+ cells with lower doses of G-CSF. Received: December 15, 1998 / Accepted: April 28, 1999     

Consolidation treatment with autologous peripheral blood progenitor cell transplantation in acute myeloid leukemia: a single center experience

Several trials have suggested that intensive post-remission therapy may prolong the duration of complete remission (CR) in acute myeloid leukemia (AML). The purpose of this study was to evaluate the feasibility and the efficacy of high-dose cytarabine (HiDAC) consolidation chemotherapy followed by high-dose therapy and autologous infusion of peripheral blood progenitor cells (PBPC) mobilized by G-CSF in adult patients with AML in first CR. Fifteen consecutive AML patients underwent HiDAC consolidation chemotherapy, used as a method of in vivo purging, followed by G-CSF for the purpose of autologous PBPC collection. Eleven patients collected a median of 6.9x10(8)/kg peripheral blood mononuclear cells (MNC) (range 2.9-23) and a median of 6.67x10(6)/kg CD34+ cells (range 1.8-33.5) with a median of two aphereses (range 1-3). Two patients did not mobilize and two obtained an inadequate number of progenitor cells. The 11 patients with adequate collections received myeloablative chemotherapy followed by the infusion of PBPC. The median number of days to recover neutrophils and platelets was 12 and 13, respectively. After a median follow-up of 28.7 months (range 17.2-43.4), five out of 11 patients who underwent PBPC transplantation are still in CR, five have died in first relapse and one is alive in CR after relapse treated with salvage therapy and second PBPC infusion. These results demonstrate that HiDAC consolidation chemotherapy followed by autologous PBPC transplantation is a feasible procedure with minimal toxicity. Randomized studies should be performed to evaluate whether this form of consolidation may produce a significant improvement in leukemia-free survival.     

Bortezomib, Dexamethasone, and High-Dose Melphalan as Conditioning for Stem Cell Transplantation in Young Japanese Multiple Myeloma Patients: A Pilot Study

Autologous stem cell transplantation is recommended for younger patients with newly diagnosed multiple myeloma because of a high complete response rate and better survival. Bortezomib shows a synergistic effect with melphalan and has no prolonged hematologic toxicity, and the complete response rate after autologous stem cell transplantation is improved by combining bortezomib with melphalan for conditioning. Twelve patients were enrolled in a phase 2 study between February and November 2010, receiving bortezomib (1 mg/m² × 4), dexamethasone (20 mg/body × 8), and melphalan (200 mg/m²) for conditioning. No toxic deaths occurred. Neutrophils (absolute neutrophil count ≥0.5 × 10⁹/L) and platelets (≥20 × 10⁹/L without transfusion) recovered after a median of 5 days (range: 4–6 days) and 7 days (range: 4–8 days), respectively. No patient was admitted for exacerbation of peripheral neuropathy. Four patients obtained a stringent complete response, three patients obtained a complete response, and three patients showed a very good partial response. These results suggest that this conditioning regimen is safe and promising for young Japanese multiple myeloma patients. A prospective multicenter trial of this regimen combined with suitable induction and consolidation therapy should be performed.     

Combining thrombopoietin receptor agonists with immunosuppressive drugs in adult patients with multirefractory immune thrombocytopenia,an update on the French experience

Combining drugs could be an effective option for treating multirefractory ITP, that is, patients not responding to rituximab, thrombopoietin receptor agonists (TPO-RA) and splenectomy. We conducted a retrospective, multicenter, observational study including multirefractory ITP patients who received a combination of a TPO-RA and an immunosuppressive drug. We included 39 patients (67% women, median age 59 years [range 21–96]), with a median ITP duration of 57 months [3–393] and a median platelet count at initiation of 10 × 10⁹/L [1–35]. The combination regimen was given for a median duration of 12 months [1–103] and included eltrombopag (51%) or romiplostim (49%), associated with mycophenolate mofetil (54%), azathioprine (36%), cyclophosphamide (5%), cyclosporin (3%) or everolimus (3%). Overall, 30 patients (77%) achieved at least a response (platelet count ≥30 × 10⁹/L and at least doubling baseline during at least 3 months), including 24 complete responses (platelet count >100 × 10⁹/L during at least 3 months) with a median time to response of 30 days [7–270] and a median duration of response of 15 months [4–63]. Severe adverse event related to ITP treatment was observed in 31%. In conclusion, this study confirms that some patients with multirefractory ITP can achieve long lasting response with this combination.