Comparison of volumetric capillary cytometry with standard flow cytometry for routine enumeration of CD34+ cells

BACKGROUND: This study assesses the feasibility of a new volumetric cytometry system for the enumeration of CD34+ cells in apheresis components, peripheral blood, and cord blood samples in routine laboratory work. This system is compared with the following flow cytometry protocols: Milan, ISHAGE, ISHAGE with 7-AAD, and flow-count fluorospheres. STUDY DESIGN AND METHODS: Correlation, linearity, and reproducibility studies were performed for the various methods. Clonogenic cultures were performed, as an external control, to assess the correlation between the number of CD34+ cells per microL and the number of colony-forming units per microL. RESULTS: The linear regression analysis demonstrated that the five methods were comparable (R2 ranged from 0.86 to 0.96 and slopes were close to 1). The CD34+ assay and the flow-count methods showed poor linearity for CD34+ cell counts below 10 cells per microL (R2 = 0.46 and 0.47). The reproducibility assay for a CD34+ count of 10 cells per microL showed a CV of 12 percent and 25 percent for the Milan and CD34+ assay methods, respectively. The mean CV among all five methods for the 46 evaluated samples was 20 percent. There was a strong correlation between the number of CD34+ cells per microL and colony-forming units per microL in cord blood and apheresis samples (r = 0.71-0.81). CONCLUSION: The CD34+ assay is useful in CD34 enumeration in cord blood, leukapheresis samples, and peripheral blood samples and provides comparable results to the Milan, ISHAGE, ISHAGE with 7-AAD, and flow-count methods. Nevertheless, peripheral blood samples with low CD34 absolute counts (below 10 cells/microL) should be analyzed by alternative flow cytometry protocols. Even though the same operator performed the study in a single laboratory, the high inter-method CV suggests that differences in sample preparation and gating strategy are factors that increase variability. Protocols with fewer intermediate steps or fully automated protocols such as the CD34+ assay are expected to reduced intra- and inter-laboratory variability.     

Peripheral blood stem cell mobilization by chemotherapy with and without recombinant human granulocyte colony-stimulating factor.

Chemotherapy can serve as a stimulus for mobilizing hematopoietic progenitor cells to the peripheral blood for harvest via leukapheresis. Mobilized peripheral blood stem cells (PBSC) support rapid hematologic reconstitution after bone marrow aplasia induced by intensive myelosuppressive treatments. Our purpose was to develop effective mobilization regimens allowing collection of large quantities of PBSC. We administered high-dose cyclophosphamide (HDC, 4 gm/m2) or cyclophosphamide (4 gm/m2) plus etoposide (600 mg/m2) (HDCE) in a nonrandomized, sequential fashion to 94 patients with breast cancer, lymphoma, and other malignancies with collection of PBSC via leukapheresis during white blood cell (WBC) recovery from nadir counts. Each apheresis product was analyzed for total nucleated cell number, granulocyte-macrophage colony-forming units (CFU-GM) and CD34+ cells. Twenty-four additional patients with comparable pretreatment characteristics received HDCE plus recombinant human granulocyte colony-stimulating factor (HDCE+G) after chemotherapy through the end of apheresis. Patients receiving HDC were matched for age, sex, and disease but were more heavily pretreated. HDCE was superior to HDC in mean daily CFU-GM and CD34+ yield (p < 0.05), even when groups were adjusted for performance status and amount of prior therapy. HDCE+G led to 3.7 times more CFU-GM and 4.7 times more CD34+ cells than HDCE. Target PBSC yield, defined as > 20 x 10(4) CFU-GM/kg and >4 x 10(8) cells/kg, was achieved by 92% of HDCE+G patients after a median of three aphereses, 56% of HDCE patients after five aphereses, and 16% of HDC patients after six apheresis (p < 0.0001). Prior chemotherapy inversely correlated with the quantity of PBSC harvested regardless of regimen utilized. Our results demonstrate effective chemotherapy regimens for harvesting hematopoietic progenitors in a diverse patient population. HDCE+G produced the highest number of progenitors, suggesting that increasing dose intensity and adding rhG-CSF enhances mobilization. Correlation between cumulative CD34+ and CFU-GM allows real-time flow cytometric analysis of the number of aphereses required to harvest target numbers of PBSC.     

Analysis of commercial CD34 control samples for quality assurance

The amount of CD34+ cells is important to predict the quality of stem cell transplants and ensure safe engraftment after high-dose chemotherapy. Further, daily controls of the patients' peripheral blood CD34+ cell counts are performed to optimize peripheral blood stem cell collection, especially in patients with low CD34+ cell numbers. Therefore, the use of reliable reference samples is mandatory for quality assurance, both in terms of patient safety and reproducibility of results from different laboratories. We report our first experience with CD-Chex CD34, containing stabilized placental cord blood cells in preservative medium with defined concentrations of CD34+ cells. Analysis was performed according to standard operating procedures. Three lots were tested sequentially on a day per day use. The expected CD34+ values were 28.6-, 36.7- and 28.1 microl(-1), respectively, and the mean measured values were 27.4 +/- 2.75 microl(-1) (n = 25, range 21 - 33 microl(-1), coefficient of variation [CV] 10.0%), 29.9 +/- 2.39 microl(-1) (n = 17, range 26 - 35 microl(-1), CV 8.0%), and 27.2 +/- 2.24 micro1(-1) (n = 18, range 24 - 34 microl(-1), CV 8.2%). Serial dilution (1:2 to 1:10) with normal peripheral blood or PBS w/o Ca++/Mg++ gave adequate results. We conclude that the control samples used in this setting are reliable and thus helpful to increase the accuracy in the analysis of CD34+ cells.     

动员外周血CD34阳性细胞流式细胞术测定中的策略探讨

探索用流式细胞术测定动员外周血中CD34^ 细胞的简便有效的方法，以便在干细胞动员中进行有效的动态监测，及时收取干细胞，把握最佳移植效果，将经药物动员的移植供的外周血用CD34和CD45荧光抗体标记，用红细胞裂解液将红细胞裂解后经流式细胞仪检测，运用恰当的分析窗口，有效的设门分析结合干细胞的生物学特性，确定CD34^ 细胞在窗口中的确切位置，统计CD34^ 细胞在有核细胞中的比例，结果表明，通过本方法可有效地测定0.05%-0.1%的CD34^ 细胞的相对含量，在药物动员的第5或6天，多数患外周血中CD34^ 细胞达到峰值，某些患外周血中CD34^ 细胞可超过1%，结论：通过标记中的有效阻断和多参数分析，本方法可对动员外周血中微量的CD34^ 细胞进行有效的动态监测，对适时采集干细胞进行移植提供了重要的参考。     

Positive selection of CD34+ cells by immunoadsorption: factors affecting the final yield and hematopoietic recovery in patients with hematological malignancies and solid tumors.

There is a progressive increase in the use of selected hematopoietic progenitor cells after myeloablative therapy in patients affected by malignancies. Our goal was to determine which blood parameters, in the starting cell population, influence the concentration of CD34+ progenitors and the removal of unwanted cells in the final product. Also, we evaluated the hematopoietic recovery and toxicity associated with peripheral blood stem cell infusion. We retrospectively reviewed 53 procedures of positive selection of CD34+ cells, performed with the Ceprate SC immunoadsorption system, in 47 paticnts affected by various hematologic malignancies and solid tumors. An increased percentage of CD34+ cells in the starting fraction was associated both with the final purity and enrichment of CD34+ cells and with a decreased percentage of CD3+ and CD19+ cells in the final product. A low platelet count before selection had a borderlinc influence on the recovery of CD34+ cells. Forty patients received a median of 5 x 10(6) CD34+ cells per kg; the absolute neutrophil count (ANC) reached 0.5 x 10(9)/l in a median of 10 days whereas a PLT count above 20 x 10(9)/l was observed in 14 days. The reinfusion of selected CD34+ cells, containing a very low amount of dymethylsulfoxide. was well tolerated and no adverse reactions were observed. Autologous transplantation with selected CD34+ cells is a safe and well-tolerated procedure in patients affected by hematologic malignancies and solid tumors. Positive selection of CD34+ cells seems to be related to the quality of the apheresis products, particularly to the initial CD34+ cell and PLT content.     

Proficiency testing experience for viable CD34+ stem cell analysis

BACKGROUND: Successful hematopoietic engraftment depends on the number of viable CD34+ stem cells. Therefore, accurate quantification of viable CD34+ stem cells is required. STUDY DESIGN AND METHODS: To evaluate clinical laboratory performance, the New York State Department of Health initiated proficiency testing (PT) for viable CD34+ stem cells. Preserved adult peripheral blood was spiked with preserved cord blood CD34+ stem cells and was shipped to the participating laboratories. Three educational and two graded PTs were performed by participating laboratories, and their results were analyzed for consistency. Comparative analysis of viability with 7-aminoactinomycin D (7-AAD) and ToPro-3 dyes also was performed. RESULTS: Laboratories had to adapt their standard operating procedures to include a viability dye to quantify the number of viable CD34+ stem cells. The majority of laboratories chose 7-AAD as their preferred viability dye, but propidium iodide (PI) and ToPro-3 were used by two laboratories. Once all laboratories started to simultaneously analyze viability and staining for CD34, graded PTs started. Lower numbers of viable CD34+ stem cells were obtained for ToPro-3 when the dye was compared with 7-AAD. CONCLUSION: It is concluded that ToPro-3 stains more cells than 7-AAD and likely includes compromised cells. The use of new vital dyes, like ToPro-3, that may stain preapoptotic cells could represent an important advance to improve the quantification of viable CD34+ stem cells, for engraftment purposes. Further studies are needed to document the benefits of switching to a method that excludes not only dead cells, but apoptotic cells as well.     

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.     

Gene transfer into fetal baboon hematopoietic progenitor cells

We studied hematopoietic progenitors from fetal baboon blood, marrow, and liver at four time points (125, 140, 160, and 175 days) during the third trimester (gestation approximately 180 days) to determine if fetal baboons might be an appropriate model for in utero gene therapy of hematopoietic stem cells (HSCs). Cells were studied for expression of CD34, CD33, CD38, and HLA-DR, for progenitor content in colony-forming cell assays, and for susceptibility of CD34+ progenitors to retrovirus-mediated gene transfer. Throughout the third trimester, the frequency of CD34+ progenitors in blood and marrow appears to remain unchanged at approximately 0.6 and 5.0%, respectively. In liver, progenitors progressively decrease to undetectable levels by day 175. The proportion of fetal baboon bone marrow and liver CD34+ cells expressing CD38 and HLA-DR appears to increase with increasing fetal age, similar to changes reported for human cord blood CD34+ cells. In fetal baboon blood the proportion of CD34+ cells expressing CD33 appears to decrease with increasing gestational age, also similar to changes reported for human cord blood cells. Progenitors from human cord blood and baboon fetal tissues were similarly susceptible to transduction by the gibbon ape leukemia pseudotyped retroviral vector LAPSN(PG13) containing the genes for human placental alkaline phosphatase (AP) and the bacterial neomycin phosphotransferase (neo). Fetal baboon and human hematopoietic progenitor cells undergo similar phenotypic changes during the third trimester of fetal development and are similarly susceptible to retrovirus-mediated gene transfer. The fetal baboon may be a model in which approaches to mobilization and gene transfer into fetal HSCs can be studied.     

外周血造血干/祖细胞动员与采集时动态快速监测造血祖细胞的意义

为了获得高效的外周血干/祖细胞采集,探索一种简便、快速的外周血干/祖细胞监测方法，采用Sysmex XE-2100血细胞分析仪的幼稚细胞信号（IMI）检测通道识别和计数外周血造血祖细胞（HPC）。对25例行异基因外周血造血干细胞移植动员的供和11例自体外周血干细胞动员的患的外周血造血干/祖细胞进行了动态观察。于动员过程中取外周血进行HPC，CD34^ 细胞和CFU-GM的检测，对采集物也进行上述检测。结果表明：在外周血标本中HPC与CD34^ 细胞和CFU-GM二间均呈良好的正相关性。所有检测病例外周血CD34^ 细胞与HPC同时上升，同时达高峰。供的峰值出现在动员的第5天，快速升高晚于白细胞。而患外周血干/祖细胞的快速升高早于白细胞。采集物中HPC与CD34^ 细胞和CFU-GM呈正相关性。采集当日外周血中HPC和CD34^ 细胞计数与采集所得CD34^ 细胞数量亦具有良好的线性相关。结论：造血祖细胞的监测是一种快速、简便又经济的监测外周血干细胞采集时机和预测成功采集的可靠指标。     

CFU-Mk content of immunoselected CD34+ peripheral blood progenitor cells, evaluated with an adapted serum-free methylcellulose assay, is predictive of platelet lineage reconstitution in children with solid tumors

Immunoselected CD34+ peripheral blood progenitor cell (PBPC) transplantation is now frequently used to support autologous hematopoiesis after myeloablative therapy, its feasability having been proved by several groups. However, we and others observed delayed platelet recovery. We hypothesized that immunoselection processing might induce selective loss of megakaryocyte progenitors, or a decrease in their proliferation. We used a colony-forming units megakaryocyte (CFU-Mk) assay to evaluate these consequences and predict platelet recovery in patients. In CD34+ PBPCs from 10 children with solid tumors, we observed no selective loss in CFU-Mk numbers during immunoselection processing and no impairment of clonogenicity. The CFU-Mk yield (59.2 +/- 11.3%) was at least similar to the CD34+ yield (44.2 +/- 3.8%). We assessed the predictive value of CFU-Mk numbers infused for recovery of platelet lineage. We found an inverse correlation between the time taken to reach a platelet count greater than 50 x 10(9)/L and only the CFU-Mk dose (r = -0.71; p = 0.022) among the different type of progenitors, including colony-forming units granulocyte-macrophage (CFU-GM), burst-forming units erythrocyte (BFU-E) and colony-forming units-mixed (CFU-Mix). These findings suggest that CFU-Mk number could be used as sole predictive functional parameter for platelet reconstitution in children after immunoselection of CD34+ cells, in particular for low CD34+ cell dose, and thus as an indicator for initial quality of hematopoietic cells before in vitro expansion.     

T lymphocyte differentiation in vitro from adult human prethymic CD34+ bone marrow cells

Pluripotent lymphohematopoietic stem cells are probably confined to bone marrow cells expressing CD34 surface molecules. To investigate the capacity of adult human CD34+ bone marrow cells to differentiate along the T lymphoid lineage, we plated purified CD34+ cells from healthy adults in liquid culture on adherent thymic stromal cells prepared from HLA- or blood group-mismatched postnatal thymic tissue. We show that purified CD34+CD3-CD4-CD8- bone marrow cells contained progenitors with the ability to differentiate into CD4+ and CD8+ T lymphocytes expressing surface (s)CD3 and T cell receptor alpha/beta in vitro. These progenitors were found in the CD34+CD2+sCD3-CD4-CD8-, CD34+CD7+sCD3-CD4-CD8-, and CD34+CD2+CD7+sCD3-CD4-CD8-, as well as in the CD34+CD2-sCD3-CD4-CD8-, CD34+CD7-sCD3-CD4-CD8-, and CD34+CD2-CD7- sCD3-CD4-CD8- subsets, indicating that T lymphocyte progenitors sensitive to signals mediated by thymic stroma in vitro are not restricted to CD34+ cells already coexpressing early T lymphocyte- associated markers. Finally, we show that T lymphopoiesis was enhanced by c-kit ligand.     

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.     

The collection and evaluation of peripheral blood progenitor cells sufficient for repetitive cycles of high-dose chemotherapy support

BACKGROUND: The development of an optimized peripheral blood progenitor cell (PBPC) harvest protocol to provide support for repetitive chemotherapy cycles is described. STUDY DESIGN AND METHODS: PBPCs mobilized by cyclophosphamide plus granulocyte-colony-stimulating factor (G-CSF) were studied in 163 leukapheresis harvests from 26 lymphoma patients. Harvested cells were transfused with two chemotherapy cycles and with an autologous bone marrow transplant. Progenitor cell content was examined in the context of hematopoietic engraftment. RESULTS: Mobilization allowed the harvest of large numbers of PBPCs. Peak harvests tended to occur after the recovering white cell count exceeded 10 × 10(9) per L. CD34+ lymphomononuclear cell (MNC) and colony-forming units-granulocyte-macrophage (CFU-GM) counts correlated poorly, but both measures peaked within 24 hours of each other in 21 of 26 patients, which demonstrated PBPC mobilization. Engraftment of platelets (> 50×10(9)/L) and granulocytes (> 500×10(6)/L) was achieved in a median of 20.5 and 16 days, respectively. A minimum number of progenitors necessary to ensure engraftment could be derived. CONCLUSION: Cyclophosphamide and G-CSF allowed the harvest of sufficient PBPCs to support multiple rounds of chemotherapy. Harvest should commence when the recovery white cell count exceeds 10×10(9) per L. PBPC harvest CD34+MNC counts are as useful as CFU-GM results in the assessment of PBPC content, and they may allow harvest protocols to be tailored to individual patients.     

Evaluation of the Sysmex XN automated hematopoietic progenitor cell enumeration for timing of peripheral blood stem cell harvest

BackgroundEnumeration of stem cells is essential in the management of peripheral blood stem cell (PBSC) harvest. An alternative to the gold standard flow cytometric CD34+ stem cell count is the fully automated hematopoietic stem cell (HPC) count on the Sysmex XN hematology analyzer.Materials and methodsEighty-nine patients and healthy stem cell donors who underwent PBSC harvest were included in the study. Stem cells were enumerated in pre-harvest peripheral blood and the apheresis yield by both flow cytometric CD34+ stem cell enumeration and by the Sysmex XN HPC count.ResultsThe Sysmex HPC concentration overestimated the CD34+ stem cell concentration by a ratio of 1.3 in average. The agreement between the two methods was poor at concentration <40 stem cells/μL (Bias: 45 %, 95 % limits of agreement: -71 - 160 %). CD34+ stem cell concentration and HPC concentration correlated well in pre-harvest peripheral blood (R=0.73, slope=0.96). We established a positive cut off >43.5 HPC/μL, where PBSC harvest can be initiated. And a negative cut off <16.5 HPC/μL, where harvest should be postponed or other mobilizing regimens or bone marrow harvest should be considered. 33 % of measurements were in between the negative and positive cut-off and would require a supplementary CD34+ cell count.ConclusionAlthough Sysmex HPC count correlates well with CD34+ cell count in peripheral blood, the agreement between the two methods is poor, especially at low concentrations, namely in the clinical decision range. Sysmex HPC count as a surrogate for CD34+ cell count should, therefore, be used with caution.     

Correlation of CD34+ cell counts with volume of bone marrow collected for allogeneic bone marrow harvests

The quantity of bone marrow collected for allogeneic bone marrow transplantation is based on collecting 10 to 15 cc of bone marrow/kg of recipient weight. We hypothesized that the percentage of CD34+ cells collected during a bone marrow harvest decreased at the end of the harvest because of increasing amounts of peripheral blood contamination. We performed a prospective, blinded study in which we measured CD34+ percentages and cell counts at 200-cc intervals during bone marrow harvests from 11 consecutive human leukocyte antigen (HLA)-matched sibling bone marrow donors. We observed that the percentage of CD34+ cells in aspirated bone marrow did not vary significantly from the start to the end of the bone marrow harvest, and the total number of CD34+ cells/kg increased in a linear fashion, thus disproving our original hypothesis. In conclusion, the percentage of CD34+ cells in aspirated bone marrow will remain constant throughout a bone marrow harvest.     

CXCR-4 expression on bone marrow CD34+ cells prior to mobilization can predict mobilization adequacy in patients with hematologic malignancies

To investigate the mechanisms of mobilization and of the factors implicated in the homing of progenitors and possibly understand the reasons for unpredicted mobilization failure, we analyzed CXCR-4 (CD184) expression on bone marrow (BM) CD34+ cells prior to peripheral blood stem cell (PBSC) mobilization in 24 patients affected by hematologic malignancies (non-Hodgkin lymphoma, multiple myeloma, and acute myeloid leukemia). We wanted to determine whether the level of CXCR-4 expressed by hematopoietic stem cells could influence mobilization process and therefore could be considered a predictive factor for mobilization adequacy. These data were also compared with stromal cell function as assessed by colony forming unit-fibroblast (CFU-F) and CFU endothelial cells (CFU-En) assays and stromal layer confluence capacity exhibited by patients' BM cells. In this study, we also compared CXCR-4 expression on CD34+ cells from different sources and at different migration stages specifically bone marrow (BM), steady state peripheral blood (SSPB), fetal cord blood (FCB), cord blood (CB), and mobilized PBSC. Seven (29%) of the 24 patients undergoing mobilization failed to achieve an adequate number of CD34+ stem cells (5 x 10(6)/kg CD34+ cells) and showed a very high expression frequency of CXCR-4 on BM CD34(+) stem cells (mean number of positive cells, 97%) investigated before the mobilization regimen. We also found that high expression intensity per cell for CXCR-4 was associated with lower amounts of mobilized CD34+ cells whereas those patients (17 out of 24 patients, 71%) with lower expression intensity per cell of CD184 on BM CD34+ cells prior to mobilization harvested at least 5 x 10(6)/kg CD34+ cells. Setting a cut off of 5 x 10(6)/kg CD34+ cells harvested, patients mobilizing less had a mean value of 97% CD34+ cells expressing CXCR-4 with a relative mean channel fluorescence of 458 whereas patients mobilizing more than 5 x 10(6)/kg CD34+ progenitors showed a mean value of 59.8% CD34+/CXCR4+ cells with a relative mean channel fluorescence value of 305. Interestingly, in the poor mobilizers group, the marrow stromal microenvironment was found to be more severely damaged in comparison with that of good mobilizers. The comparative analysis of CXCR-4 expression showed no difference in percentage values between steady-state PB (87.4%) and BM (85.1%) stem cells whereas mobilized CD34+ stem cells have a lower expression frequency of CXCR-4 (71.6%) compared to that of progenitors from other sources. Fetal blood CD34+ stem cells had the lowest mean expression frequency of CD184 antigen (36.3%), while CB cells had the highest (94.8%). In conclusion, this study provides evidence that monitoring CXCR-4 CD34 double positive cells before mobilization can be regarded as a predictive factor for mobilization outcome, giving us directional cues for the choice of the best stem cell mobilization regimens.     

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.     

无血清脐血巨核系祖细胞体外扩增的研究

脐血造血干细胞移植后血小板恢复延迟是一大难题,目前认为这主要与脐血中巨核系祖细胞数量不足及脐血巨核细胞分化成熟延迟有关,而将部分脐血进行巨核系祖细胞体外扩增后输注受者体内是有望解决这一难题的重要途径。但适用于临床应用的扩增条件至今仍未确立。本课题采用人脐血单个核细胞(MNC)在无血清培养体系中使用TPO,IL-3,SCF,IL-6等细胞因子进行不同的组合,在培养的0,6,10,14天进行MNC、CD41^ 细胞及CFU-MK数的检测。以寻找最佳的细胞因子组合及最佳的收获时机。结果表明：无血清条件下TPO与IL-3,SCF,IL-6等细胞因子联用可实现脐血巨核系祖细胞有效的体外扩增,各因子组中以TPO IL-3 SCF IL-6组扩增效果为最佳。其CFU-MK数于第10天最多,扩增达6．8倍,CD41^ 细胞扩增达8．8倍。结论：在人脐血MNC无血清培养条件下。TPO IL-3 SCF IL-6组为巨核系祖细胞体外扩增较佳的因子组合。由于TPO IL-3 SCF IL-6组的CFU-MK数于第10天最多,CD41^ 细胞数亦为同期最高,故培养后收获时间宜控制在其体外培养的第10天。     

A functional hierarchy among the CD34+ hematopoietic cells based on in vitro proliferative and differentiative potential of AC133+CD34(bright) and AC133(dim/)-CD34+ human cord blood cells

The 5-transmembrane receptor AC133 is expressed on a subpopulation of human hematopoietic cells that includes the CD34(bright) cells. We evaluated the developmental potential of AC133+CD34(bright) and AC133(dim/-)CD34+ cells isolated from 5 cord blood (CB) samples by studying the in vitro proliferative and differentiative potential of each population in both progenitor and mature cell expansion cultures. Seven-day culture of AC133+CD34(bright) cells with a cytokine combination favoring primitive progenitor cells causes a significant increase in CD34+, CFU-C and noncycling stem/progenitor cells HPP-Q (High Proliferative Potential-Quiescent), whereas culture of AC133(dim/-)CD34+ cells shows a limited increase in committed progenitor cells only. HPP-Q cells were not found in freshly isolated AC133(dim/-)CD34+ nor in expanded CD34+ cells derived from AC133(dim/-)CD34+ cells. No statistically significant difference was observed between the 1-week expanded AC133+ and the initial AC133+CD34(bright) cells regarding their clonogenic efficiency (CE), while expanded CD34+ cells derived from AC133(dim/-)CD34+ cells exhibited a decreased CE. Subexpansion of the reselected AC133+ derived from AC133+CD34(bright) cells reveals a further increase of stem/progenitor cells and the 14-day expanded AC133+ cells reveal an unchanged CE. Subexpansion of reselected 7-day CD34+ cells derived from AC133(dim/-)CD34+ cells was not possible. Culture of AC133+CD34(bright) cells in cytokines that favor megakaryopoiesis or erythropoiesis resulted in a significant expansion of CD41+ and CD71+ cells, respectively; AC133(dim/-)CD34+, in comparison, showed a limited potential to megakaryocytic differentiation and a decreased production of erythroid cells. Our data indicate that early high proliferating stem/progenitor cells and early committed progenitors are present in AC133+CD34(bright) cells, but not in AC133(dim/-)CD34+ cells; the latter represent late committed progenitors with limited proliferative potential.     

Nonobese diabetic-severe combined immunodeficient mice transplantation of volume-reduced and thawed umbilical cord blood transplants following closed-system immunomagnetic cell selection

BACKGROUND: Protocols for the expansion of human umbilical cord blood (UCB) progenitors begin with the selection of CD34+ cells from stored frozen and thawed units. Use of an immunomagnetic selection procedure within a closed blood bag system for volume-reduced UCB transplants was evaluated, and the influence of CD34 cell selection on in vivo engraftment potential was studied. STUDY DESIGN AND METHODS: Eleven thawed buffy coat-processed UCB units were processed within a standard blood bag with a washing solution. In six independent experiments, the same dosage of 2 x 104 CD34+ cells from paired selected and nonselected samples was transplanted into NOD-SCID mice. In two experiments, cells from the negative fraction were also transplanted. RESULTS: The purity of CD34+ cells after selection was correlated with the removal of supernatant after the first washing step and therefore with adequate removal of damaged or dead cells (r=0.86, p < 0.01). Mice transplanted with unselected UCB cells had more human cells within their marrow than animals transplanted with selected cells (8.6 +/- 5.9% selected group vs. 19.8 +/- 14.2% unselected group; p=0.04), whereas no engraftment could be observed transplanting cells from the two negative fractions. A higher percentage of human CD45+ cells in the unselected group were found to be positive for CD38, CD14, CD33, and CD19, indicating a higher potential for these unselected progenitors to differentiate into myeloid cells and B cells. CONCLUSIONS: Processing of volume-reduced and thawed UCB transplants within a closed-bag system before immunomagnetic CD34+ cell selection allows for the preparation of CD34+ cells of significant purity at technically useful cell recoveries. However, these experiments indicate a potential impairment of engraftment capacity for the CD34+ cell-enriched fraction.