Large-volume leukapheresis for collection of mononuclear cells for hematopoietic rescue in Hodgkin's disease

BACKGROUND: Peripheral blood mononuclear cells (MNCs) collected by leukapheresis contain hematopoietic stem and progenitor cells that provide autologous hematopoietic rescue after high-dose chemotherapy, an approach that offers a significant benefit to patients with recurrent Hodgkin's disease. However, patients with low MNC counts may require 10 or more standard leukapheresis procedures for the collection of sufficient cells for hematopoietic rescue. STUDY DESIGN AND METHODS: The effectiveness of steady-state large-volume leukapheresis (LVL; 15- 35 L blood processed) was evaluated as a method for collecting MNCs for hematopoietic rescue in seven patients with recurrent Hodgkin's disease. LVL was performed on 2 consecutive days per week to collect 7 × 10(8) MNCs per kg. The circulating MNC counts on the first day of LVL and the total numbers of LVL, of MNCs collected, and of liters of blood processed were determined per patient. After high-dose chemotherapy and MNC transfusion, days to granulocyte and platelet engraftment were recorded. RESULTS: On the first day of LVL, patients had median circulating MNCs of 1536 (range, 504–3950) × 10(6) per L. The median number of LVL procedures per patient was four (range, 1.25-6), and the median L per kg of blood processed was 1.57 (range, 0.38-4.03). Simple regression analysis plotting L per kg against initial MNCs gave a curve with the equation y = e(1.42-(6.31 × 10E-4)x) (correlation coefficient = -0.97, R2 = 0.95, exponential fit). Without posttransfusion growth- factor support, median days to granulocyte engraftment were 19 (range, 12–26) and those to platelet transfusion independence were 34.5 (range, 10–57). CONCLUSION: LVL provides a useful method of collecting MNCs for hematopoietic rescue in patients with Hodgkin's disease. The patient's baseline MNC count provides a useful estimate of the volume required for LVL.     

Comparison of CD34+ cell numbers and colony growth before and after cryopreservation of peripheral blood progenitor and stem cell harvests: influence of prior chemotherapy

BACKGROUND: Quantitative determination of hematopoietic progenitor cells is a major issue in peripheral blood progenitor and stem cell collection and transfusion, although the extent is still an object of discussion. STUDY DESIGN AND METHODS: In 116 leukapheresis collections from 42 patients, immunophenotyping for CD34+ cells, evaluation of in vitro proliferative capacity by a colony-forming unit-granulocyte- macrophage (CFU-GM) assay, and viability assessment by trypan blue exclusion were performed before and after storage in liquid nitrogen at -196 degrees C. RESULTS: Before storage, the median number of CD34+ cells was 1.46 × 10(6) (range, 0.01–54.05 × 10(6)) per kg of body weight (BW). There was no significant difference between precryopreservation and postcryopreservation numbers. The median number of CFU-GM was 2.25 × 10(5) (range, 0.02–157.49 × 10(5)) per kg of BW before cryopreservation and significantly (p < 0.001) lower, 0.83 × 10(5) (range, 0–220.36 × 10(5)) per kg of BW, after cryopreservation. The correlation coefficient of prestorage and poststorage values was 0.92. The median ratio of poststorage and prestorage values was 42.3 percent (0–304.8%). Male patients who underwent intense chemotherapy (> 5 cycles) showed a significantly lower ratio of postcryopreservation and precryopreservation CFU-GM values than other patients (p = 0.0047). A strong linear correlation was determined between the number of CD34+ cells per kg of BW and the number of CFU-GM per kg of BW before and after cryopreservation. A viability below 50 percent predicted a high loss of in vitro proliferative capacity, while a viability above 50 percent did not correlate with a high ratio of CFU-GM from after and before cryopreservation. CONCLUSION: A good correlation between the variables used for characterization of peripheral blood progenitor cells–the number of CD34+ cells and the number of CFU-GM–was observed. Viability assessment by trypan blue exclusion does not seem to be a substitute for assays evaluating in vitro proliferative capacity.     

Large-volume leukapheresis for peripheral blood stem cell collection in patients with hematologic malignancies

Large-volume leukapheresis (LVL, 15-35 L) was performed in two groups of patients (n = 10) with hematologic malignancies to obtain peripheral blood stem cells for bone marrow rescue following high-dose chemotherapy. The target cell count was 7 x 10(8) mononuclear cells (MNCs = lymphocytes and monocytes) per kg of body weight. Group A patients (n = 4) were studied on Day 1 of LVL, and components were collected from them as four sequential samples. Total MNCs collected averaged 1.29 x 10(10), total colony-forming-units granulocyte-macrophage (CFU-GM) averaged 12.1 x 10(6), and a 1.8-fold mobilization of CFU-GM was observed (p < 0.05, Sample 1 vs. Sample 4). Group B patients (n = 6) were studied throughout the three consecutive planned days of 5-hour LVL. An average of three LVL procedures per patient was performed (range, 1.25-4), and an average of 27 L (range, 24-33) of blood per LVL was processed. The blood:ACD-A ratio was 24:1 with 3000 units of heparin per 500 mL of ACD-A; heparin was also added to the collection bags. The component had an average hematocrit (Hct) of 0.02 and MNC content of 93 percent. The patients' pre-LVL and post-LVL average Hct varied significantly (before Day 1, 0.36 +/- 0.08; after Day 3, 0.28 +/- 0.06; p < 0.05). Platelet counts also decreased, with post-Day 3 counts averaging 19 percent of the average pre-Day 1 counts (p < 0.05). A decrease in the average MNC count after LVL was significant on Day 1 only (p < 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)     

Hematopoietic recovery in cancer patients after transplantation of autologous peripheral blood CD34+ cells or unmanipulated peripheral blood stem and progenitor cells

BACKGROUND: A study of CD34+ cell selection and transplantation was carried out with particular emphasis on characteristics of short- and long-term hematopoietic recovery. STUDY DESIGN AND METHODS: Peripheral blood stem and progenitor cells (PBPCs) were collected from 32 patients, and 17 CD34+ cell-selection procedures were carried out in 15 of the 32. One patient in whom two procedures failed to provide 1 × 10(6) CD34+ cells per kg was excluded from further analysis. After conditioning, patients received CD34+ cells (n = 10, CD34 group) or unmanipulated (n = 17, PBPC group) PBPCs containing equivalent amounts of CD34+ cells or progenitors. RESULTS: The yield of CD34+ cells was 53 percent (18–100) with a purity of 63 percent (49–82). The CD34+ fraction contained 66 percent of colony-forming units-granulocyte- macrophage (CFU-GM) and 58 percent of CFU of mixed lineages, but only 33 percent of burst-forming units-erythroid (BFU-E) (p < 0.05). Early recovery of neutrophils and reticulocytes was identical in the two groups, although a slight delay in platelet recovery may be seen with CD34+ cell selection. Late hematopoietic reconstitution, up to 1.5 years after transplant, was also similar. The two groups were thus combined for analyses of dose effects. A dose of 40 × 10(4) CFU-GM per kg ensured recovery of neutrophils to a level of 1 × 10(9) per L within 11 days, 15 × 10(4) CFU of mixed lineages per kg was associated with platelet independence within 11 days, and 100 × 10(4) BFU-E per kg predicted red cell independence within 13 days. However, a continuous effect of cell dose well beyond these thresholds was apparent, at least for neutrophil recovery. CONCLUSION: CD34+ cell selection, despite lower efficiency in collecting BFU-E, provides a suitable graft with hematopoietic capacity comparable to that of unmanipulated PBPCs. In both groups, all patients will eventually show hematopoietic recovery of all three lineages with 1 × 10(6) CD34+ cells per kg or 5 × 10(4) CFU-GM per kg, but a dose of 5 × 10(6) CD34+ cells or 40 × 10(4) CFU-GM per kg is critical to ensure rapid recovery.     

Volume-dependent collection of peripheral blood progenitor cells during large-volume leukapheresis for patients with solid tumours and haematological malignancies

We investigated the efficacy of peripheral blood progenitor cell (PBPC) collection during large-volume leukapheresis (LVL) in patients with solid tumours and haematological malignancies (n = 18). The time- and volume-dependent harvest of leucocytes (WBC), mononuclear cells (MNC), CD34+ cells and colony-forming cells (CFU-GM) during LVL was analysed in six sequentially filled collection bags processing four times the patient's blood volumes. The amounts of leucocytes (WBC) and the purity of mononuclear cells (MNC%) did not show any significant changes during LVL. The percentage of CD34+ cells remained constant for the first three bags but consecutively decreased from initially 1.71% CD34+ cells in the beginning of LVL to finally 1.34% CD34+ cells (P = 0.02). The mean numbers of colony-forming cells (CFU-GM) decreased from 74 microL-1 to 59 microL-1 during LVL (P = 0.16). Furthermore, the comparison of volume-dependent PBPC collection for patients with high, medium and low total yields of CD34+ cells showed similar kinetics on different levels for the three groups. We concluded that - relative to the initial total amount of PBPC harvested - comparable numbers of progenitor cells can be collected during all stages of LVL with a slight decreasing trend processing four times the patient's blood volumes.     

Activity of acetyl-Ser-Asp-Lys-Pro (AcSDKP) on human hematopoietic progenitor cells in short-term and long-term bone marrow cultures

The tetrapeptide acetyl-Ser-Asp-Lys-Pro (AcSDKP) is a potent inhibitor of hematopoietic stem cell proliferation. We examined the effects of AcSDKP on the production of granulocyte-macrophage colony-forming cells (CFU-GM) and high proliferative potential colony-forming cells (HPP-CFC) in human long-term bone marrow (LTBM) cultures and CFU-GM and erythroid burst-forming cells (BFU-e) in short-term liquid cultures. The addition of AcSDKP in short-term bone marrow cultures resulted in a maximum depression of the total number of progenitor cells as well as the number of progenitor cells entering cell cycle following culture with 10(-12) to 10(-14) M AcSDKP and 10(-14) M AcSDKP when exogenous cytokines (GM-CSF, IL-3, or SCF) were added. AcSDKP was added daily to LTBM cultures at various concentrations (10(-8) M to 10(-16) M) for up to 5 weeks. In these LTBM culture studies, AcSDKP inhibited the entry of nonadherent progenitor cells into S phase and decreased the number of nonadherent progenitor cells with peak activity at 10(-12) M. In contrast, AcSDKP had no effect on the number of adherent CFU-GM, HPP-CFC, or cellularity per culture or percent of adherent progenitor cells in S phase. These studies indicate that the concentration of the tetrapeptide is critical to the activity of AcSDKP on human hematopoietic progenitor cells. Furthermore, we report that the presence of cytokines or stromal cells also affects the response of progenitor cells to AcSDKP. These results will aid in determining kinetic properties of AcSDKP for the development of clinical protocols to protect normal human hematopoietic stem and progenitor cells following cycle-specific chemotherapy agents.     

Safety of large-volume leukapheresis for collection of peripheral blood progenitor cells

Large volume leukapheresis (LVL) reduces the number of procedures required to obtain adequate peripheral blood progenitor cells (PBPCs) for autologous hematopoietic reconstitution. LVL involves the processing of >15 L or 5 patient blood volumes using high flow rates. We report our experience with LVL evaluating its efficiency and adverse effects in 71 adult patients with hematologic or solid organ malignancies. All were mobilized with chemotherapy and granulocyte colony-stimulating factor (G-CSF). All collections used a double lumen apheresis catheter. Means values per LVL were as follows: blood processed, 24.6 L; patient blood volumes processed, 5.9; ACD-A used. 1.048 ml; heparin used, 6,148 units; collect time, 290 min; blood flow rate, 89 ml/min. Eighty percent of the collections were completed in one or two procedures to obtain ≥6.0 × 10⁸ MNCs/kg body weight. The most frequent side effect (39%) was parasthesia due to citrate-related hypocalcemia. This was managed with oral calcium supplements and or slower flow rates. Post-LVL electrolyte changes were generally asymptomatic. Prophylactic oral potassium supplements were administered in 57% of cases. Other reactions included hypotension (4%), prolonged parasthesia (1.4%), and headache (1.4%). Catheter problems in 9 (13%) of the procedures were attributed to clot formation (37%) or positional effects (63%). No bleeding occurred. Post-LVL decreases in hematocrit and platelet count averaged 3.5% and 46%, respectively. Six (4%) of the procedures required red blood cell transfusions. Platelet transfusions were given in 19 (13%) of the procedures. We conclude that adverse reactions with LVL are similar to those reported for conventional PBPC collections, making it safe and efficacious as an outpatient procedure. J. Clin Apheresis 12:10–13, 1997. © 1997 Wiley-Liss, Inc.     

Peripheral blood stem cell collection with a blood cell separator

Forty-three patients with malignant nonmyeloid diseases underwent peripheral blood stem cell collections on an apheresis system (Spectra, COBE BCT, Lakewood, CO). Collections took place during the white cell (WBC) recovery phase following conditioning chemotherapy. One hundred two procedures were done after chemotherapy alone, and 72 procedures after chemotherapy plus granulocyte-colony-stimulating factor (G-CSF). Four centrifugal separation factors were tested. One and one-half patient blood volumes were processed in each procedure. The mean volume of the collected component was 158 +/− 16 mL. After chemotherapy alone, the procedures provided a mean of 0.8 × 10(8) WBCs per kg and 2.3 × 10(4) colony-forming units-granulocyte macrophage (CFU-GM) per kg of recipient body weight. The mononuclear cell percentage in the components increased with the centrifugal separation factor from 85 to 96 percent. In parallel, platelet contamination increased from 2.1 to 3.8 × 10(11). The collect hematocrit ranged from 1.0 to 2.5 percent (0.01-0.025). The collection efficiency for mononuclear cells and CFU- GM also increased with the centrifugal separation factors from 52 to 70 percent for mononuclear cells and from 55 to 68 percent for CFU-GM. Collections performed after G-CSF-stimulated mobilization were characterized by a higher neutrophil contamination independent of centrifugal separation factor, which gave a mean mononuclear cell percentage of 64 percent in the collected component. The average yield for these procedures was 2 × 10(8) WBCs per kg and 28 × 10(4) CFU-GM per kg.(ABSTRACT TRUNCATED AT 250 WORDS)     

Large-volume leukapheresis for peripheral blood progenitor cell collection in low body weight pediatric patients: a single center experience.

Peripheral blood progenitor cells (PBPC) have became the preferred source of stem cells for autologous transplantation because of easier accessibility, rapid engraftment, and lower tumor cell contamination. In pediatric patients is very important to optimize peripheral blood stem cells (PBSC) harvesting to obtain a sufficient number of cells with a reduced number of leukapheresis. In this study we prospectively analyzed data on 43 large volume leukapheresis (LVL) from 20 consecutive low body weight pediatric patients with various malignancies. Patients' mean body weight was 16.6 kg (range, 8.9-32.0 kg), and the median age was 4 years (range, 1-10 y ears). Instead of saline, it was used irradiated and leukoreduced red blood cell (RBC) units to prime the machine in 15 patients weighting 25 kg or less. The median number of LVL was 2 (range, 1-4) and a mean of 5.2 patient's blood volume was processed per session lasting 165 min (range, 118-239). The mean number of CD34+ cells, one day before leukapheresis was 49 mm(-3) (range, 9-219). The PBPC collection yielded 24.7 x 10(8) total nucleated cells/kg (range, 6.2-74.0), 10.7 x 10(6) kg(-1) CD34+ cells (range, 3.6-53.7); 49.8 x 10(4) CFU-GM/kg (range, 6.4-198.1), and 65.6 x 10(4) BFU-E/kg (range, 7.6-198.1). The platelet count decreased significantly after each procedure 39.8 +/- 9.1 x 10(9) mm(-3) (range, 18.000-76.000) (p < 0.001). In conclusion, our data show that LVL for collection of PBPC in low weight pediatric patients is a safe and efficient procedure, but it may expose the patient to the risk of thrombocytopenia.     

短程大剂量粒细胞集落刺激因子动员外周血造血干细胞的研究

研究短程大剂量粒细胞集落刺激因子对外周血造血干细胞的动员作用。方法采用短程大剂量Ｇ－ＣＳＦ对１１例患者进行外周血造血干细胞动员，Ｇ－ＣＳＦ５μｇ／ｋｇ皮下注射，每日２次，共３天，动员当天及第４天，分别取骨髓及外周血增生明显活跃，外周血白细胞计数明显升高。     

Preparation of autologous bone marrow grafts for cryopreservation using the AS104 cell separator

We evaluated the AS104 cell separator (Fresenius AG, Bad Homburg, Germany) for ex vivo processing of bone marrow (BM) grafts of 43 patients suffering from germ cell cancer (GCC, n = 22), acute lymphocytic leukemia (ALL, n = 13) and malignant lymphoma (ML, n = 8). Recoveries of total nucleated cells (TNC), mononuclear cells (MNC) and colony-forming units granulocyte-macrophage (CFU-GM) were determined in the BM concentrates prepared for cryopreservation. Hematopoietic reconstitution was analyzed in patients who underwent autologous transplantation following high-dose radio-/chemotherapy (HDRCT). Processing of the BM suspension with a median volume of 1,013 ml (range: 422–1,574) resulted in 156 ml (80–186) within 50–120 min (median: 90). In the BM concentrates, medians of 28.6% TNC (10.6–69.6), 37.9% MNC (22.3–86.4), and 52.4% CFU-GM (20.8–96.4) were recovered. Twenty-six patients underwent HDRCT with reinfusion of autologous BM and were evaluable for engraftment. They received a median of 0.8 × 10⁸ MNC/kg (0.3–1.6 × 10⁸) and 2.2 × 10⁴ CFU-GM/kg (0.6–12.8 × 10⁴) for hematopoietic rescue. Engraftment with neutrophils >500/μl occurred in a median time of 12 days (8–33) in all patients. We conclude that ex vivo processing of autologous BM with median recovery rates of 37.9% for MNC, and 52.4% for CFU-GM, results in a cell population that can rescue patients from HDRCT. The described technique is convenient, time-efficient, and provides reliable results in preparing BM autografts for cryopreservation. J. Clin. Apheresis 12:179–182, 1997. © 1997 Wiley-Liss, Inc.     

化疗对造血微环境的影响及化疗后回输自体骨髓基质细胞对造血功能恢复的作用

目的观察化疗对造血祖细胞、造血微环境的影响,化疗后回输体外扩增的自体骨髓基质细胞(ABMSC)对造血功能恢复的作用.方法对化疗患者进行骨髓CFU-GM、CFU-E、BFU-E及基质细胞集落(CFU-F)培养、长期骨髓培养,观察基质层融合情况,计算基质层覆盖率及完全融合时间.长期化疗的10例患者进行自身前后对照,在同一化疗方案下,单纯化疗与化疗后回输体外扩增的ABMSC[(1.1～8.7)×103/次]作对比,观察两者造血恢复情况.结果①长期化疗组的CFU-GM、BFU-E、CFU-E、CFU-F显著低于正常对照组及短期化疗组,后两组差异无显著性;②三组基质层覆盖率及完全融合时间差异无显著性;③长期化疗组ABMSC输注后的CFU-GM、CFU-E、BFU-E、CFU-F显著高于未输注组;④输注ABMSC后白细胞计数及血小板计数降至最低点的值显著高于未输注组,前者白细胞计数及血小板计数恢复正常时间较后者明显缩短;⑤基质细胞回输过程及输后临床观察无不良反应.结论长期化疗明显损伤造血祖细胞、基质祖细胞,但对骨髓基质细胞融合功能无明显影响,化疗后给予ABMSC可加速造血功能的恢复.     

Application of whole blood and peripheral blood progenitor cells (PBPC) and new strategies for rescue after intensive cyclic chemotherapy in high-risk breast cancer

The efficacy of autologous peripheral stem cells given as mobilized whole blood or leukapheresis product for hematopoietic rescue after intensive chemotherapy was studied in 34 consecutive female patients with high-risk breast cancer. All patients received six cycles of chemotherapy regimen EC (epirubicin 150 mg/m2 and cyclophosphamide 1250 mg/m2) at 14-day intervals. In the first cycle, chemotherapy was given on day 1, and 24 h later mobilization of PBPC was started with G-CSF at a dose of 5 microg/kg/day for 13 days. In all other cycles, G-CSF was given at the same dose from day 7. On days 11, 12, and 13, leukaphereses were performed, and whole blood was collected on day 14 (the peak incidence of colony-forming units-granulocyte-macrophage [CFU-GM] burst-forming units-erythrocyte [BFU-E], and colony-forming unit-granulocyte-erythrocyte-macrophage-megakaryocyte [CFU-GEMM]). The second cycle of chemotherapy was started on day 15, and 24 h later, whole blood (collected in the first cycle) was reinfused, and the same was done in the third cycle. In the fourth to sixth chemotherapy cycles, leukapheresis product was used for hematopoietic rescue. The median increment of absolute values in both whole blood and leukapheresis product was as follows: CD34+ cells over baseline was approximately 17.4-fold, CFU-GM was 85.3-fold, BFU-E was 95.9-fold, and CFU-GEMM was 44.2-fold. In the cycles with whole blood support, the mean values of applied progenitors per cycle were CD34+ cells 1.52 x 10(6)/kg, CFU-GM, 1.18 x 10(5)/kg, BFU-E 2.54 x 10(5)/kg, CFU-GEMM 0.31 x 10(5)/kg. In the courses with PBPC support, the mean values of progenitors were CD34+ 2.04 x 10(6)/kg, CFU-GM 1.59 x 10(5)/kg, BFU-E 2.87 x 10(5)/kg, and CFU-GEMM 0.34 x 10(5)/kg. Leukopenia in patients supported with whole blood versus leukapheresed PBPC was as follows: grade 4, 13/6 (38.2%/17.6%), grade 3, 19/23 (55.9%/70.6%), and grade 2, 1/4 (2.9%/11.8%), respectively. Thrombocytopenia was grade 4, 11/6 (32.4%/17.6%), grade 3, 10/7 (29.4%/20.6%), grade 2, 7/13 (20.6%/38.2%), and grade 1, 6/6 (17.6%/17.6%), respectively. The median follow-up analysis was at 24.6 (7-36) months. High-risk patients previously treated with surgery and adjuvant chemotherapy (n = 5) were not evaluated for response. In 21 patients with locally advanced or inflammatory breast carcinoma the response rate (RR) was 94%, CR was 90%, and PR was 15%. No response to therapy was observed in 1 patient. In 8 patients with metastatic disease, RR was 75%, there was no CR, and PR was 75%. Two patients died during therapy. Relapse-free survival (RFS) in the adjuvant group was 23.7 (range 12-36) months and in the group with locally advanced disease was 18.2 (range 7-27) months. In the group with metastatic disease, time to tumor progression (TTP) was 12.1 (range 1-16) months. Mean duration of hospital stay for whole blood reinfusion in the second and third chemotherapy cycles was 6.7 (range 5-8) days and for PBPC in the fourth to sixth cycles was 6.2 (range 4-8) days, which at p < 0.001 was not statistically significant.     

1963份脐血造血干细胞的处理与保存

本研究目的是建立脐血造血干细胞库的标准工作程序。采用自然沉降法加离心法制备脐血的造血干细胞 ,经CD34 细胞计数、集落培养、微生物检测、传染病指标检测、HLA分型后 ,将造血干细胞贮存在液氮中保存。结果表明 :贮存脐带血造血干细胞有核细胞数平均值为 (10 .94± 2 .74 )× 10 8,回收率为 (79.82± 17.76 ) % ,CD34 细胞数平均值为 (5 1.6 2± 30 .5 3)× 10 5。 8份脐带血造血干细胞冰冻 2年后复苏 ,其有核细胞、CD34 细胞、CFU GM回收率分别为 (91.4± 6 .0 ) %、(84 .6± 2 0 .0 ) %、(85 .8± 14 .9) %。结论 :本方法和程序能有效地保存脐带血造血干细胞。     

A prospective, randomized, sequential, crossover trial of large-volume versus normal-volume leukapheresis procedures: effect on progenitor cells and engraftment

BACKGROUND: The influence of leukapheresis size on the number of harvested peripheral blood progenitor cells is still unclear. A prospective randomized crossover trial was thus performed, to evaluate the effect of large-volume leukapheresis (LVL) versus normal-volume leukapheresis (NVL) on progenitor cells and engraftment in 26 patients with breast cancer and 15 patients with non-Hodgkin's lymphoma who were eligible for peripheral blood progenitor cell transplantation. STUDY DESIGN AND METHODS: Patients were randomly assigned to undergo either LVL on Day 1 and on Day 2 or vice versa. The number of progenitor cells was evaluated in the harvest and before and after leukapheresis in the peripheral blood. RESULTS: The number of harvested CD34+ cells (4.8 x 10(6) vs. 3.4 x 10(6)/kg body weight, p < 0.001) and colony-forming units-granulocyte-macrophage (3.1 x 10(5) vs. 2.4 x 10(5)/kg body weight, p = 0.0026) was significantly higher for LVL procedures than for NVL procedures. The median extraction efficacy, defined as the difference between the yield in the harvest and the decrease in the total number of CD34+ cells in peripheral blood during leukapheresis, was significantly (p < 0.0001) higher for LVL than for NVL (2.6 x 10(8) and 8 x 10(7), respectively). In patients with breast cancer, the median amount of CD34+ cells in the harvest and the median extraction efficacy were higher for LVL than for NVL (p < 0.0001). This was not found for patients with non-Hodgkin's lymphoma. CONCLUSION: LVL results in a higher yield of CD34+ cells and colony-forming units-granulocyte-macrophage than NVL, but only in patients with breast cancer and with high numbers of CD34+ cells in the peripheral blood before leukapheresis.     

Kinetics of peripheral blood mononuclear cell mobilization with chemotherapy and/or granulocyte-colony-stimulating factor: implications for yield of hematopoietic progenitor cell collections

BACKGROUND: Peripheral blood progenitor cells (PBPCs) are commonly collected and used to reconstitute hematopoiesis after high-dose chemotherapy. However, strategies for optimal collection and assessment of leukapheresis components are not standardized. STUDY DESIGN and METHODS: Hematopoietic progenitor cell assays were performed on 369 leukapheresis components collected from 95 patients who had received doxorubicin-based chemotherapy and/or granulocyte-colony-stimulating factor (G-CSF). Precollection patient hematologic values, leukapheresis collection values, component hematopoietic progenitor cell assays, and patient outcome measures were summarized. The kinetics of mononuclear cell (MNC) and PBPC mobilization were assessed among four patient groups. RESULTS: Patient group was a significant predictor of the peripheral blood MNC count on the day of collection (p<0.0001), and that value was a significant predictor of granulocyte-macrophage– colony-forming unit (CFU-GM) yield (p<0.0001). This relationship between the peripheral blood MNC count on the day of collection and CFU- GM yield differed according to patient group (p<0.0001). CFU-GM made up a larger fraction of peripheral blood MNCs collected from patients who received chemotherapy plus G-CSF than collected from those who received G-CSF alone. Moreover, the peripheral blood MNC count and the corresponding CFU-GM yield increased significantly on consecutive days of collection in patient groups receiving chemotherapy and G-CSF but were unchanged or decreased in patients receiving G-CSF alone. CONCLUSION: The relationship between peripheral blood MNC count and leukapheresis component CFU-GM yield differed significantly between patients who received chemotherapy and G-CSF and those who received G- CSF alone for the mobilization of PBPCs. Patient peripheral blood MNC count and component CFU-GM yield are useful for both assessing and suggesting revisions to PBPC mobilization and collection strategies.     

rhIL-11联合rhG-CSF动员小鼠外周血造血干/祖细胞的研究

目的　研究rhIL 11对小鼠巨核系造血干 /祖细胞的动员作用。方法　rhIL 112 5 0μg·kg-1·d-1或联合rhG CSF 2 5 0 μg·kg-1·d-1给C5 7BL/ 6小鼠皮下注射 1～ 7d ,观察用药前和用药第 3,5 ,7,9天小鼠外周血白细胞、血小板计数 ,CD34 +细胞比例 ,CFU GM、CFU MK、CFU E的数量变化。结果　单用rhIL 11或与rhG CSF联合使用时 ,外周血白细胞、血小板、CD34 +细胞比例及各种造血细胞集落数明显高于对照组 (P <0 .0 1)。在含有IL 11的实验组中 ,CFU MK明显高于rhG CSF组 (P <0 .0 1)。结论　rhIL 11可升高外周血白细胞、血小板 ,同时增加外周血CD34 +细胞的比例 ,提高粒、红、巨核系造血细胞集落形成单位的数量 ,特别是对CFU MK作用较强 ;与rhG CSF联合使用对动员骨髓造血干 /祖细胞进入外周血有明显的协同作用。     

Allogeneic transplantation combining mobilized blood and bone marrow in patients with refractory hematologic malignancies

BACKGROUND: Mobilized blood stem cells have been used successfully in autologous transplant recipients to reduce the complications of pancytopenia due to dose-intensive chemotherapy. Reports of cytokine- mobilized blood progenitor cells in allogeneic transplant recipients are rare. STUDY DESIGN AND METHODS: This is a pilot trial of six patients. Patients with advanced hematologic malignancy received bone marrow (median total 2.6 × 10(8) mononuclear cells/kg) followed by four daily transfusions of blood (median total 9.5 × 10(8) mononuclear cells/kg) from HLA-matched sibling donors who were mobilized with recombinant human granulocyte-colony-stimulating factor (5 micrograms/kg/day subcutaneously for 5 days). All patients received cyclosporine and prednisone for graft-versus-host disease (GVHD) prophylaxis. RESULTS: An absolute neutrophil count greater than 500 per mm3 was achieved on Day 12, and platelet transfusion independence was achieved on Day 16. The median day of hospital discharge was Day 23 after transplant. All patients achieved 100-percent donor cell engraftment. Acute > or = Grade III GVHD did not develop in any patients, but all patients developed Grade I (n = 4) or Grade II (n = 2) acute GVHD. Chronic extensive GVHD developed in four of six patients. One patient died of pneumonia 263 days after transplant while undergoing immune-suppressive therapy for chronic GVHD. CONCLUSION: The transfusion of blood stem cells in patients undergoing allogeneic bone marrow transplant is well tolerated soon after transplant, but the development of chronic GVHD may limit the general usage of unmanipulated blood stem cells.     

Determining factors for the outcome of peripheral blood progenitor cells harvests

This is a pilot retrospective study to investigate the factors that may affect the collection of peripheral blood progenitor cells (PBPC). Sixty-nine PBPC harvests in 18 cancer patients (median age 39.5:8 males and 10 females) were performed during marrow recovery after chemotherapy and hematopoietic growth factors. Median number of nucleated cells (MNC) collected were 13.3 (range 2.3–44.5) × 10⁹ per session. Median CFU-GM was 362 colonies (range 63–1,720) per 500,000 MNC. Neither sex, body weight, diagnosis, nor the number of days into leukapheresis was significantly associated with MNC and CFU-GM. Older patients tend to have higher CFU-GM in the PBPC harvests (P = .0437). Higher WBC on the day of harvest is significantly associated with higher yield of MNC after leukapheresis (P < .0001). Patients without any evidence of disease have significantly higher yield of MNC than those having local/distant metastases with or without marrow involvement (P = .0302 and .0446). For patients with metastatic disease, those with bone marrow involvement tend to have higher CFU-GM than those without bone marrow involvement although the difference is not statistically significant (P = .0559). Those patients who have received only one, or three and more chemotherapy regimens have a higher yield of MNC than those who have only two previous chemotherapy regimens (P = .036 and .0324). The mechanism of PBPC mobilization is also discussed. In view of the limited patient number in this study, the results should be confirmed by larger studies. © 1996 Wiley-Liss, Inc.     

Large-volume leukapheresis yields more viable CD34+ cells and colony-forming units than normal-volume leukapheresis, especially in patients who mobilize low numbers of CD34+ cells

BACKGROUND: Large-volume leukapheresis (LVL) differs from normal-volume leukapheresis (NVL) by increased blood flow and altered anticoagulation regimen. LVL is now regarded as a safe procedure for collection of peripheral blood progenitor cells (PBPCs), but it is not known whether the procedure will alter CD34+ cell quality or will be useful for patients who mobilize few CD34+ cells into peripheral blood. STUDY DESIGN AND METHODS: The results from 82 LVL and 125 NVL (4.0-5.3 and 2.7-3.5 times the patients' blood volumes processed, respectively) were retrospectively analyzed in altogether 112 consecutive patients with malignant diseases. RESULTS: The LVL yielded significantly more CD34+ cells (4.2 x 10(6) vs. 3.1 x 10(6)/kg, p = 0.006, all patients; and 1.8 x 10(6) vs. 1.3 x 10(6)/kg, p = 0.004, bad mobilizers) and significantly higher colony-forming units (77 x 10(4) vs. 33 x 10(4)/kg; all patients and 33 x 10(4) vs. 20 x 10(4)/kg, p < 0.001, both groups). Significantly fewer leukapheresis procedures were required to obtain 2 x 10(6) CD34+ cells per kg (one vs. two, p = 0.001, all patients; and two vs. three, p = 0.009, bad mobilizers). No significant differences in CD34+ cell viability and time to hematologic recovery were observed between the patients who received PBPCs harvested by NVL and LVL. CONCLUSION: Although a median platelet loss of 36 percent can be expected, LVL can be recommended as the standard apheresis method for PBPC collections in patients with malignant diseases. LVL is particularly useful in patients who mobilize a low number of CD34+ cells into the peripheral blood.