Collection of mobilized blood progenitor cells for hematopoietic rescue by large-volume leukapheresis

BACKGROUND: Mobilized blood progenitor cells rapidly reconstitute hematopoiesis in patients after dose-intensive chemotherapy. However, optimal timing and methods of mobilized blood progenitor cell collection have yet to be fully defined. STUDY DESIGN AND METHODS: The utility of large-volume leukapheresis (LVL; > 15 L blood processed) in collecting target doses of mononuclear cells (7 × 10(8)/kg) for use in autologous hematopoietic rescue was investigated. LVL was begun at a standardized interval (14 days) after a course of limited chemotherapy and subsequent daily recombinant human granulocyte-macrophage-colony- stimulating factor administration to mobilize blood progenitor cells into the circulation. With each LVL procedure, mononuclear cells, colony-forming units-granulocyte-macrophage (CFU-GM), burst-forming units-erythroid, mixed colonies, total clonogenic progenitor cells, and CD34+ cells collected per kg of patient weight were counted. After high- dose chemotherapy and infusion of cryopreserved mobilized blood progenitor cells, the days needed for neutrophils to reach levels of > 0.5 × 10(9) per L and for platelets to reach levels of > 20 × 10(9) per L were recorded. RESULTS: In 14 previously treated cancer patients, an average of 28.9 +/? 4.9 L of blood was processed per LVL (n = 35) to collect medians of 2.5 × 10(8) mononuclear cells per kg (range, 1.0- 7.4), 14 × 10(4) CFU-GM per kg (0-208), 27 × 10(4) clonogenic progenitor cells per kg (0-370), and 2.8 × 10(6) CD34+ cells per kg (0- 112.5). Fifty-seven percent of patients (8/14) required one or two LVL procedures to collect adequate blood progenitor cells (range, 1–4). After dose-intensive chemotherapy, 13 patients received medians of 6.8 × 10(8) mononuclear cells per kg (range, 5.1-9.9), 53 × 10(4) CFU-GM per kg (9-208), and 12 × 10(6) CD34+ cells per kg (3.6-112.5). Rapid hematopoietic reconstitution occurred with 10 days (range, 8–12) and 9 days (6-15), respectively, for neutrophil and platelet recoveries. CONCLUSION: Scheduled LVL, beginning on Day 14 after the administration of granulocyte-macrophage-colony-stimulating factor following chemotherapy, is a convenient and efficient method of collecting blood progenitor cells. The mononuclear cells so obtained effected consistent and rapid hematopoietic reconstitution in a highly reproducible manner in a group of heavily treated patients.     

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.     

Evaluation of a new protocol for peripheral blood stem cell collection with the Fresenius AS 104 cell separator

In this report we analyzed sixty leukapheresis procedures on 35 patients with a new protocol for the Fresenius AS 104. Yields and efficiencies for MNC, CD 34+ cells, and CFU-GM indicate that the new protocol is able to collect large quantities of hemopoietic progenitors. Procedures were performed processing 8.69 ± 2.8 liters of whole blood per apheresis and modifying 3 parameters: spillover-volume 7 ml, buffy-coat volume 11.5 ml, centrifuge speed 1,500 rpm; blood flow rate was 50 ml/min and the anticoagulant ratio was 1:12. No side effects were observed during apheresis procedures except for transient paresthesia episodes promptly resolved with the administration of calcium gluconate. Yields show a high capacity of the new program to collect on average MNC 17.28 ± 10.85 × 10⁹, CD 34+ 471 ± 553.5 × 10⁶ and CFU-GM 1278.7 ± 1346.3 × 10⁴ per procedure. Separator collection efficiency on average was 49.91 ± 23.28% for MNC, 55.1 ± 35.66% for CFU-GM, and 62.97 ± 23.09% for CD 34+ cells. Particularly interesting are results for MNC yields and CD 34+ efficiency; these results make the new program advantageous or similar to the most progressive blood cell separators and capable to collect a sufficient number of progenitor cells for a graft with a mean of 1.80 ± 0.98 procedures per patient. J. Clin. Apheresis 12:82–86, 1997. © 1997 Wiley-Liss, Inc.     

Composition of peripheral blood progenitor cell components collected from healthy donors

BACKGROUND: Peripheral blood progenitor cell (PBPC) components are being collected from healthy donors for allogeneic transplantation, but the quantity, quality, composition, and variability of PBPCs collected from healthy people given granulocyte-colony-stimulating factor (G-CSF) have not been evaluated. STUDY DESIGN AND METHODS: PBPC components were collected from 150 healthy people who were given G-CSF (5, 7.5, or 10 microg/kg/day) for 5 days. The components were evaluated for white cell (WBC), mononuclear cell, CD34+ cell, neutrophil, platelet, and red cell (RBC) composition. RESULTS: The quantities collected were: WBCs, 35.0 +/? 16.4 × 10(9) (range, 11.9–163.3 × 10(9)); mononuclear cells, 33.3 +/? 14.4 × 10(9) (range, 11.9–139.6 × 10(9)); CD34+ cells, 412 +/? 287 × 10(6) (range, 70–1658 × 10(6)); neutrophils, 1.71 +/? 3.59 × 10(9) (range, 0–27.6 × 10(9)); RBCs, 7.2 +/? 4.0 mL (range, 0–22.1 mL); and platelets, 480 +/? 110 × 10(9) (range, 250–920 × 10(9)). PBPC components collected from people given G-CSF at 7.5 or 10 microg per kg per day contained significantly more CD34+ cells (respectively, 428 +/? 300 × 10(6); range, 70–1658 × 10(6) and 452 +/? 294 × 10(6); range, 78- 1380 × 10(6)) than those from people given G-CSF at 5 microg per kg per day (276 +/? 186 × 10(6); range, 91–767 × 10(6)) (p = 0.007 and p = 0.002). When 10 microg per kg per day of G-CSF was given, 50 percent of the components contained enough CD34+ cells for transplantation to a 75- kg recipient (375 × 10(6) CD34+ cells), but 10.6 percent of the components contained less than 150 × 10(6) CD34+ cells and thus would provide a transplantable dose only for a 30-kg patient. CONCLUSION: One PBPC component collected from a healthy donor given 7.5 or 10 microg per kg per day of G-CSF should contain 70 to 1660 × 10(6) CD34+ cells, with 0 to 22 mL of RBCs. Because of the great variability in the number of CD34+ cells collected, the quantity of CD34+ cells in each component should be measured after each procedure to ensure that sufficient quantities of cells are present for a successful transplant.     

Prediction of engraftment after autologous peripheral blood progenitor cell transplantation: CD34, colony‐forming unit–granulocyte‐macrophage,or both?

BACKGROUND: The rate of hematologic recovery after peripheral blood progenitor cell (PBPC) transplantation is influenced by the dose of progenitor cells. Enumeration of cells that express CD34+ on their surface is the most frequently used method to determine progenitor cell dose. In vitro growth of myeloid progenitor cells (colony-forming unit-granulocyte-macrophage [CFU-GM]) requires more time and resources, but may add predictive information. STUDY DESIGN AND METHODS: A series of 323 patients, who underwent autologous PBPC transplantation for multiple myeloma, malignant lymphoma, or locally advanced breast cancer, were studied for the effect of CD34+ dose and CFU-GM dose on hematologic recovery. Measures for engraftment were days to absolute granulocyte and platelet (PLT) counts to greater than 500 per muL and than 20 x 10(9) per L, respectively, and number of PLT transfusions and red cell units required. RESULTS: The CD34+ dose had a median of 8.4 x 10(6) per kg, and the CFU-GM dose a median of 84.9 x 10(4) per kg. The CD34+ and CFU-GM doses showed significant correlation (R = 0.63; p < 0.0001) but a wide variation in the ratio of CD34+ and CFU-GM. Both CD34+ and CFU-GM doses had significant correlation with the measures of engraftment, but for all measures the relationship of CD34+ was stronger. Multivariate analysis and subgroup analysis of patients receiving CD34+ doses of less than 5 x 10(6) per kg also did not reveal an independent predictive value for CFU-GM. CONCLUSION: For prediction of hematologic recovery after autologous PBPC transplantation, determination of CFU-GM dose does not add to the predictive value of the CD34+ dose.     

A combination of low-dose cyclophosphamide and colony-stimulating factors is more cost-effective than granulocyte-colony-stimulating factors alone in mobilizing peripheral blood stem and progenitor cells

BACKGROUND: The use of peripheral blood progenitor cells (PBPCs) instead of autologous bone marrow leads to more rapid engraftment following high-dose chemotherapy. Mobilization regimens differ with respect to toxicity, efficiency, and cost. STUDY DESIGN AND METHODS: Two cohorts of patients with breast cancer received one of two mobilization regimens: granulocyte-colony-stimulating factor (G-CSF) at 10 micrograms per kg was given subcutaneously for 5 days, with leukapheresis begun on Day 6, or low-dose cyclophosphamide followed by sequential granulocyte-macrophage-CSF (GM-CSF) at 5 micrograms per kg for 5 days and by G-CSF at 10 micrograms per kg, with leukapheresis begun on Day 11. Results of CD34+ cell collection, engraftment, and costs of mobilization were determined. RESULTS: The combination chemotherapy and growth factor regimen was more efficient in mobilizing CD34+ cells. Sixty-six percent of patients reached a target 4 × 10(6) CD34+ cells per kg in a single leukapheresis session with the combination regimen, compared to 14 percent who received G-CSF alone (p < 0.01). The mean number of leukapheresis sessions required to reach a target of 4 × 10(6) CD34+ cells per kg was 1.3 for the combination regimen and 2.7 for the regimen of G-CSF alone (p < 0.01). One patient in the chemotherapy and growth factor group developed febrile neutropenia. Engraftment was similar in both cohorts of patients. The cost of mobilization, including all supplies and cryopreservation, was $7381 for the G-CSF regimen and $5508 for the chemotherapy regimen (p < 0.05). This reduction was attributed to the lower number of leukapheresis and cryopreservation sessions, which outweighed the slight increase in expense for chemotherapy and growth factor in the combination regimen. CONCLUSION: This combination mobilization regimen allowed the predictable and efficient collection of CD34+ cells from the peripheral blood in a limited number of leukapheresis sessions, which reduced the cost of mobilization by approximately 25 percent.     

Evaluation of hematological reconstitution potential of autologous peripheral blood progenitor cells cryopreserved by a simple controlled-rate freezing method

A novel and simple procedure for the controlled-rate cryopreservation of peripheral blood progenitor cells (PBPCs) was introduced. A freezing bag housed in a protective aluminum canister was placed on top of a styrene foam box in the -85 degrees C electric freezer. A second set of samples was kept in cryotubes placed in a double styrene foam box in the same electric freezer. Measurement of the freezing rate in the PB bags and cryotubes demonstrated that this simple method for PBPC cryopreservation provided optimal conditions for both large-scale and small-scale cryopreservation. Within several days after autologous peripheral blood stem cell transplantation, we thawed the cells in the small sample tubes and evaluated the cell viability, the cell recovery, and the recovery rates of hematopoietic progenitor cells (HPCs), such as CD34+ cells and colony-forming unit-granulocyte/macrophage (CFU-GM) colonies. The median duration of cryopreservation was 59 days (range, 14-365 days). According to our analysis, infusions of more than 2 x 10(6) CD34+ cells/kg body weight and 0.5 x 10(6) CFU-GM colonies/kg body weight after thawing had favorable influences on the neutrophil engraftment. We have therefore established a simple freezing method for cryopreservation of human PBPCs, which ensures the transplantability of hematopoietic progenitors even after thawing. In vitro HPC assay after thawing is important to evaluate the quality of cryopreservation procedures.     

Minimal number of circulating CD34+ cells to ensure successful leukapheresis and engraftment in autologous peripheral blood progenitor cell transplantation

BACKGROUND: The number of peripheral blood (PB) CD34+ cells has been widely used to monitor the timing of leukapheresis for autologous transplantation. However, no cutoff value for CD34+ cells in PB has been defined as a guideline for the identification of patients in whom the harvest would be effective and those in whom there was a high probability of failure. STUDY DESIGN AND METHODS: The present study investigated the best threshold of CD34+ cells in PB for successful harvesting and engraftment, using 263 PB samples with their corresponding leukapheresis components. In addition, that measure has been compared to other commonly used criteria such as the white cell count, the number of mononuclear cells, and the number of colony- forming units-granulocyte macrophage in PB. RESULTS : Time to engraftment of both granulocytes and platelets was significantly influenced by the number of CD34+ cells transfused, but all patients receiving > or = 0.75 × 10(6) CD34+ cells per kg achieved engraftment within a reasonable number of days (> 0.5 × 10(9)/L granulocytes by Day 11 and > 20 × 10(9)/L platelets by Day 13). A clear correlation between the number of CD34+ cells per microL in PB and of CD34+ cells per kg collected was found at each apheresis (r = 0.9, p < 0.0001). Moreover, the number of CD34+ cells per microL measured in PB the day the first leukapheresis was initiated displayed an excellent correlation with the total amount of CD34+ cells per kg finally collected (r = 0.81, p < 0.0001). On the basis of the regression curve obtained and the clinical engraftment results, it was found that the presence of > 5 CD34+ cells per microL in PB ensured a good yield from the harvest in 95 percent of patients and would avoid an unsuccessful harvest in 81 percent of cases. CONCLUSION: A dose of only 0.75 × 10(6) CD34+ cells per kg guarantees hematopoietic recovery within a reasonable number of days. To initiate a leukapheresis from which enough progenitor cells may confidently be obtained, a minimum of 5 CD34+ cells per microL in PB is required.     

Large-volume apheresis for the harvest of peripheral blood progenitor cells for autologous transplantation

BACKGROUND: The mobilization and harvest of a sufficient number of peripheral blood stem and progenitor cells for autologous transplantation is an important aspect of treatment in patients with certain hematologic and solid tumor disease. The level of CD34+ cells in peripheral blood is often used as a predictor of successful harvest. STUDY DESIGN AND METHODS: A total of 129 apheresis procedures in 38 patients have been investigated retrospectively to evaluate the possibility to predict the outcome by other measures, such as total treated blood volume (TBV) during the apheresis. RESULTS: No significant correlation was observed between the level of CD34+ cells per kg of body weight in collected apheresis components and the TBV in all 129 apheresis procedures. However, analysis of results from 22 apheresis procedures with TBV > 16 L (large-volume apheresis) and with < 10 × 10(3) CD34+ cells per mL in the peripheral blood found a correlation between TBV and the number of CD34+ cells per kg of body weight in the collected component (R2 = 0.585, p = 0.005). In patients who underwent large-volume apheresis (> 16 L) and who had < 10 × 10(3) CD34+ cells per mL in their peripheral blood, the number of CD34+ cells in the apheresis component was not correlated with that in the peripheral blood prior to harvest (R2 = 0.262, p = 0.1569). In the patients who underwent apheresis procedures with TBV < 16 L and who had > 20 × 10(3) CD34+ cells per mL in their peripheral blood, there was a correlation between the number of CD34+ cells in the component and the number of CD34+ cells in the peripheral blood (R2 = 0.800, p = 0.0000). However, there was not a correlation in this group between the number of CD34+ cells in the component and the TBV. There were no significant differences in the content of CD34+/CD33+ and CD34+/ HLA-DR+ cells in the collected component in the two groups. CONCLUSION: TBV appears to be critical for the collection of a sufficient number of progenitor cells in patients with < 10 × 10(3) CD34+ cells per mL in peripheral blood.     

Blood counts in healthy donors 1 year after the collection of granulocyte-colony-stimulating factor-mobilized progenitor cells and the results of a second mobilization and collection

BACKGROUND : Granulocyte–colony-stimulating factor (G–CSF)-mobilized blood cells are being used for allogeneic transplants, but the long-term effects of G–CSF on healthy individuals are not known. Furthermore, it is not certain how many CD34+ cells can be collected in a second mobilization and collection procedure. STUDY DESIGN AND METHODS : Nineteen people were given 2, 5, 7.5, or 10 μg of G–CSF per kg per day for 5 days, and blood progenitor cells were collected by apheresis on the sixth day; this was done on two occasions separated by at least 12 months. Blood counts obtained before and after each course of G–CSF and the quantity of cells collected were compared. RESULTS : There were no differences in white cell (WBC), platelet, red cell, and WBC differential counts measured before each course of G–CSF, and all the values were in the normal range. In a subset of 12 people who received 7.5 or 10 μg of G–CSF per kg per day for both courses, the numbers of neutrophils, mononuclear cells, and CD34+ cells in the blood after each course were similar (34.1 ± 7.31 × 10⁹/L vs. 36.4 ± 12.3 × 10⁹/L, p = 0.24; 6.59 ± 2.28 × 10⁹/L vs. 5.63 ± 2.11 × 10⁹/L, p = 0.24; and 92.0 ± 55.6 × 10⁶/L vs. 119.2 ± 104.6 × 10⁸/L; p = 0.48, respectively), as were the quantities of mononuclear cells (31.0 ± 8.4 × 10⁹ vs. 31.0 ± 6.1 × 10⁹; p = 0.64) and CD34+ cells (417 ± 353 × 10⁶ vs. 449 ± 286 × 10⁶; p = 0.53) collected in the two apheresis procedures. Furthermore, there was a positive correlation between the quantity of CD34+ cells collected from each of the 12 people per liter of whole blood processed in the two procedures (r² = 0.86, p<0.001). CONCLUSION : One year after the administration of G–CSF to healthy people, their blood counts were normal and unchanged from pretreatment counts. If healthy people donate blood progenitor cells after a second G–CSF course, the quantity of CD34+ cells collected will be similar to that obtained in the first collection.     

CD41+ and CD42+ hematopoietic progenitor cells may predict platelet engraftment after allogeneic peripheral blood stem cell transplantation

The objective of this study was to quantify subpopulations of CD34+ cells such as CD41+ and CD42+ cells that might represent megakaryocyte (MK) precursors in peripheral blood stem cell (PBSC) collections of normal, recombinant human granulocyte‐colony stimulating factor (rhG‐CSF) primed donors and to determine whether there is a statistical association between the dose infused megakaryocytic precursors and the time course of the platelet recovery following an allogeneic PBSC transplantation. Twenty‐six patients with various hematologic malignancies transplanted from their HLA identical siblings between July 1997 and December 1999 were used. All patients except one with severe aplastic anemia who had cyclophosphamide (CY) alone received busulfan‐CY as preparative regimen and cyclosporine‐methotrexate for GVHD prophylaxis. Normal healthy donors were given rhG‐CSF 10 μg/kg/day subcutaneously twice daily and PBSCs were collected on days 5 and 6. The median number of infused CD34+, CD41+ and CD42+ cells were 6.61 × 10⁶/kg (range 1.47–21.41), 54.85 × 10⁴/kg (5.38–204.19), and 49.86 × 10⁴/kg (6.82–430.10), respectively. Median days of ANC 0.5 × 10⁹/L and platelet 20 × 10⁹/L were 11.5 (range 9–15) and 13 (8–33), respectively. In this study, the number of CD41+ and CD42+ cells infused much better correlated than the number of CD34+ cells infused with the time to platelet recovery of 20 × 10⁹/L in 26 patients receiving an allogeneic match sibling PBSC transplantation (r = ?0.727 and P < 0.001 for CD41+ cells, r = ?0.806 and P < 0.001 for CD42+ cells, r = ?0.336 and P > 0.05 for CD34+ cells). There was an inverse correlation between the number of infused CD41+ and CD42+ cells and duration of platelet engraftment. Therefore, as the number of CD41+ and CD42+ cells increased, duration of platelet engraftment (time to reach platelet count of ≥ 20 × 10⁹/L) shortened significantly. Based on this data we may conclude that flow cytometric measurement of CD41+ and CD42+ progenitor cells may provide an accurate indication of platelet reconstitutive capacity of the allogeneic PBSC transplant. J. Clin. Apheresis. 16:67–73, 2001. © 2001 Wiley‐Liss, Inc.     

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。     

Efficacious and save use of biosimilar filgrastim for hematopoietic progenitor cell chemo‐mobilization with vinorelbine in multiple myeloma patients

Biosimilars are increasingly being licensed as equipotent drugs, although efficacy and safety data are not available for all clinical indications. Accordingly, the efficacy of the biosimilar filgrastim Zarzio® combined with vinorelbine for chemo‐mobilization of CD34+ hematopoietic progenitor cells (HPC) in patients with multiple myeloma has not been evaluated yet. We compared the efficacy of vinorelbine combined with this biosimilar filgrastim for HPC mobilization to vinorelbine plus original filgrastim (Neupogen®). Overall, 105 multiple myeloma patients received vinorelbine 35 mg/m² intravenously on day 1 and either original filgrastim (n = 61;58%) or biosimilar filgrastim (n = 44;42%) at a dose of 5 µg per kg body weight (BW) twice daily subcutaneously starting day 4 until the end of the collection procedure. Leukapheresis was scheduled to start on day 8 and performed for a maximum of three consecutive days until at least 4 × 10⁶ HPC/kg BW were collected. All patients proceeded to leukapheresis. In 102 (97%) patients the leukapheresis sessions were started as planned at day 8. The median number of collected HPC was 7.3 × 10⁶/kg BW (0.2–18.3) with original filgrastim compared to 9 × 10⁶/kg BW (4.2‐23.8) with the biosimilar filgrastim (P = 0.16). HPC collection was successful in 57 (93%) of 61 patients of the original group and in all 44 (100%) patients of the biosimilar group (P = 0.14). No differences were observed regarding side effects. Duration of neutrophil engraftment after autologous HPC transplantation was similar between the two groups (P = 0.17). Biosimilar and original filgrastim achieve comparable results in combination with vinorelbine regarding HPC mobilization and transplantation outcome in multiple myeloma patients. J. Clin. Apheresis 32:21–26, 2017. © 2016 Wiley Periodicals, Inc.     

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.     

Cryopreservation of peripheral blood stem cell: the influence of cell concentration on cellular and hematopoietic recovery

BACKGROUND: The optimal cryopreservation cell concentration during the peripheral blood stem cell (PBSC) collection is a controversial topic. We evaluated the influence of cryopreservation concentration on the recovery of hematopoietic progenitor cells and the kinetics of hematopoietic recovery of autologous stem cell transplant patients. STUDY DESIGN AND METHODS: In this retrospective study, we compared two different cryopreservation protocols: 1 × 10⁸ cells/mL (Protocol A) and 2 × 10⁸ cells/mL (Protocol B). A total of 419 PBSCs were analyzed with regard to the number of viable cells and colony‐forming units–granulocytes‐monocytes (CFU‐GM) progenitors. The hematopoietic recovery of 275 patients who received PBSCs cryopreserved at a dose of 1 × 10⁸ cells/mL (Group A) and 2 × 10⁸ cells/mL (Group B) were compared. RESULTS: There were no significant differences in recovery of viable cells between Protocol A and Protocol B. The median of recovery of CFU‐GM progenitors was significantly higher in Protocol B (41.2 vs. 57.3, p < 0.01). The median times to neutrophil recovery (≥500 × 10⁶/L) and platelet (PLT) recovery (≥20 × 10⁹/L) in Groups A and B were 11 days versus 11 days and 12 days versus 12 days, respectively. However, by Kaplan and Meier analyses, Group B recovered neutrophils with a little delay (p = 0.01). No difference was observed with regard to time to PLT recovery. On multivariate analysis, we found that the number of CD34+ cells and CFU‐GM progenitors had a significant influence on hematopoietic recovery. CONCLUSION: Cryopreservation of PBSCs at a dose of 2 × 10⁸ cells/mL did not affect the recovery rate of viable cells or the hematopoietic recovery of autologous stem cell transplant patients.     

Uncontrolled-rate freezing and storage at -80 degrees C, with only 3.5-percent DMSO in cryoprotective solution for 109 autologous peripheral blood progenitor cell transplantations

BACKGROUND: Although controlled-rate freezing and storage in liquid nitrogen are the standard procedure for peripheral blood progenitor cell (PBPC) cryopreservation, uncontrolled-rate freezing and storage at -80 degrees C have been reported. STUDY DESIGN AND METHODS: The prospective evaluation of 109 autologous PBPC transplantations after uncontrolled-rate freezing and storage at -80 degrees C of apheresis products is reported. The cryoprotectant solution contained final concentrations of 1-percent human serum albumin, 2.5-percent hydroxyethyl starch, and 3.5-percent DMSO. RESULTS: With in vitro assays, the median recoveries of nucleated cells (NCs), CD34+ cells, CFU-GM, and BFU-E were 60.8 percent (range, 11.2-107.1%), 79.6 percent (6.3-158.1%), 35.6 percent (0.3-149.5%), and 32.6 percent (1.7-151.1%), respectively. The median length of storage was 7 weeks (range, 1-98). The median cell dose, per kg of body weight, given to patients after the preparative regimen was 6.34 x 10(8) NCs (range, 0.02-38.3), 3.77 x 10(6) CD34+ cells (0.23-58.5), and 66.04 x 10(4) CFU-GM (1.38-405.7). The median time to reach 0.5 x 10(9) granulocytes per L, 20 x 10(9) platelets per L, and 50 x 10(9) reticulocytes per L was 11 (range, 0-37), 11 (0-129), and 17 (0-200) days, respectively. Hematopoietic reconstitution did not differ in patients undergoing myeloablative or nonmyeloablative conditioning regimens before transplantation. CONCLUSION: This simple and less expensive cryopreservation procedure can produce successful engraftment, comparable to that obtained with the standard storage procedure.     

紫外线波段B对脐血免疫活性和造血活性抑制的体外研究

目的：探讨紫外线波段Ｂ（ＵＶＢ）对脐血淋巴细胞和造血细胞的作用差别。方法：选择０，５，１０，２０，５０ｍＪ／ｃｍ２等不同剂量ＵＶＢ照射脐血单个核细胞（ＭＮＣ），分别进行活力检测，混合淋巴细胞培养（ＭＬＣ），粒－单系祖细胞集落（ＣＦＵ－ＧＭ）培养和ＣＤ３４＋细胞比率检测。结果：脐血细胞ＭＬＣ的免疫增殖反应活性、免疫激活能力及ＣＦＵ－ＧＭ数均呈照射剂量依赖性下降（Ｐ＜０．０１），但在１０ｍＪ／ｃｍ２照射范围内脐血免疫活性下降幅度显著高于ＣＦＵ－ＧＭ。在脐血ＭＮＣ悬液内加入２０％小牛血清后不仅使ＵＶＢ的作用减弱，还加大了ＵＶＢ对脐血淋巴细胞和造血细胞失活作用的差别。ＵＶＢ照射前后ＣＤ３４＋细胞比率无明显变化。结论：小剂量ＵＶＢ照射可选择性降低脐血淋巴细胞的增殖反应活性，而对造血细胞活性影响少，提示运用ＵＶＢ预防脐血移植引起的移植物抗宿主病是可能的。     

Cryopreservation of hematopoietic progenitor cells with 5-percent dimethyl sulfoxide at −80 degrees C without rate-controlled freezing

BACKGROUND: Cryopreservation of hematopoietic cells with the rate- controlled method is used in the majority of centers. In recent years, there has been a trend toward the simplification of the process. STUDY DESIGN AND METHODS: A simplified method for cryopreservation was developed with 5-percent dimethyl sulfoxide (DMSO) as the sole cryoprotectant without rate-controlled freezing. Experiments were done with progressive concentrations of DMSO, ranging from 0 to 10 percent. With DMSO concentrations from 5- to 10-percent, the best recovery and viability for hematopoietic progenitor cells were observed. Hematopoietic progenitor cells with plasma and 5-percent DMSO were frozen and stored in a -80 degrees C mechanical freezer. Ten patients with solid and hematologic malignancies underwent transplantation with autologous hematopoietic progenitor cells. RESULTS: The median number of transfused mononuclear cells and CD34+ cells was 3.70 (3.1-8.2) × 10(8) per kg and 1.70 (0.8-6.5) × 10(6) per kg, respectively. The median number of transfused colony-forming units-granulocyte-macrophage was 12.45 (3.4-55.3) × 10(4) per kg. All patients showed rapid and sustained engraftment. The mean times to reach a neutrophil count of 0.5 × 10(9) per L and a platelet count of 50 × 10(9) per L were 11.50 +/− 1.70 and 13.90 +/− 3.98 days, respectively. All patients are alive and without transfusion requirements in complete remission 2 to 8 months after transplantation. CONCLUSION: This simplified cryopreservation technique will be useful for institutions without rate- controlled freezing facilities. Moreover, this method diminishes the amount of DMSO infused to patients, as well as its toxicity.     

TRANSPLANTATION AND CELLULAR ENGINEERING: Increasing the economic efficacy of peripheral blood progenitor cell collections by monitoring peripheral blood CD34+ concentrations

BACKGROUND: After mobilization, the collection of peripheral blood progenitor cells (PBPCs) can either be started a fixed number of days after having passed the white blood cell nadir (fixed‐day scheme) or be based on monitoring of CD34+ cells. This study was conducted to compare both approaches and to assess possible financial consequences. STUDY DESIGN AND METHODS: For 29 patients daily enumeration of CD34+ cells was used to guide leukapheresis timing. In a retrospective analysis for the same group of patients, application of a fixed‐day scheme was assumed. For scenarios of beginning apheresis 2, 3, 4, or 5 days after WBC nadir, the number of apheresis days and granulocyte–colony‐stimulating factor (G‐CSF) application days that could be saved was calculated. RESULTS: A total of 44 apheresis procedures were performed resulting in a mean CD34+ cell content per apheresis product of 10.4 × 10⁶ (range, 0.1 × 10⁶‐49.5 × 10⁶)/kg of body weight. The smallest number of deviation days compared to a fixed‐day scheme was found for beginning an apheresis on Day 3. In comparison to this, CD34+ monitoring reduced the number of G‐CSF days by 9 and the number of apheresis procedures by 11 overall, resulting in savings of €19,965 (US$28,788) in comparison to expenses of €826 (US$1191) for CD34+ monitoring. CONCLUSIONS: Measurement of CD34+ cells has reached a precision enabling a prediction of the harvest success. In comparison to a fixed‐day scheme, daily CD34+ monitoring reduces the donor's exposition to G‐CSF, enables collection of a sufficient number of PBPCs in the least possible number of apheresis sessions, and improves the economic efficacy of the institution.     

CD133+ cell content does not influence recovery time after hematopoietic stem cell transplantation

BACKGROUND: Infusion of an adequate dose of CD34+ mononuclear hematopoietic stem cells (HSCs) is the single most important variable to assure success in hematopoietic grafting. CD133+ HSCs constitute the CD34+ subgroup with higher differentiation potential. The number of granulocyte–colony‐stimulating factor (G‐CSF)‐mobilized CD133+ HSCs administered during hematopoietic grafting and its relationship with the number of days needed to regain hematopoiesis was determined. STUDY DESIGN AND METHODS: Thirty‐eight patients with malignant hematologic diseases who received an autologous (n = 15) or allogeneic (n = 23) HSC transplant were prospectively evaluated. G‐CSF was administered for 5 days at 10 µg/kg/day. Hematopoietic progenitors were recovered from peripheral blood on day 5 by leukopheresis. CD34+ and CD133+/CD34+ cell populations were quantified by flow cytometry; the number of days to hematologic recovery was documented. RESULTS: A median dose of 4.56 × 10⁶/kg CD34+ HSCs (range, 1.35 × 10⁶‐14.6 × 10⁶) was recovered and transplanted; of these grafted cells, a median 3.25 × 10⁶ were also CD133+ (range, 1.25 × 10⁶‐14.3 × 10⁶). In the autologous group, the median number of days to reach a platelet (PLT) count of 20 × 10⁹/L or greater was 12, and 15 days to obtain a neutrophil count of 0.5 × 10⁹/L or greater; in the allogeneic group 13 and 16 days, respectively, were required (p > 0.05). A median 76.5% of G‐CSF–mobilized CD34+ HSCs coexpressed the CD133+ antigen (range, 23.1‐97.9). CONCLUSIONS: A higher number of CD133+/CD34+ HSCs in the graft was not clearly associated with a shorter neutrophil or PLT recovery time in either allogeneic or autologous recipients.