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.     

Monitoring of peripheral blood CD34+ cell counts on the first day of apheresis is highly predictive for efficient CD34+ cell yield.

The purpose of this study was to evaluate the correlation of preleukapheresis circulating CD 34+ cells/micro L, white blood cells (WBC), and platelet counts on the first day of apheresis with the yield of collected CD 34+ cell counts in 40 patients with hematological malignancies (n = 29) and solid tumors (n = 11). The median numbers of apheresis cycles, numbers of CD 34+ cells, peripheral blood (PB) mononuclear cells, and total nucleated cells collected were 2 (range, 1-4), 5.5 x 106/kg (range, 0.05-33.78), 2.59 x 108/kg (range, 0.04-20.68), and 7.36 x 108/kg (range, 0.15-28.08), respectively. There was a strong correlation between the number of preleukapheresis circulating CD 34+ cells/micro L and the yield of collected CD 34+ cells per kilogram (r = 0.962, p < 0.001). The threshold levels of PB C 34+ cell/micro L to obtain > or =1 x 106/kg and > or =2.5 x 106/kg CD 34+ cell in one collection were 12/micro L and 34/ micro L, respectively. Fifteen of 17 (88%) patients who had > or =34 CD 34+ cells/ micro L in the PB before collection reached the level of > or =2.5 x 106/kg in a single apheresis. Despite a low r value, WBC and platelet counts on the first day of apheresis also correlated with the yield of collected daily CD 34+ cells per kilogram (r = 0.482, p < 0.01 and r = 0.496 p < 0.01, respectively). These data suggest that preleukapheresis circulating CD 34+ cells/ micro L correlated significantly better with the yield of collected CD 34+ cells than WBC and platelet counts on the first day of apheresis. Using a value of 34/micro L preleukapheresis circulating CD 34+ cells as a guide for the timing of peripheral blood stem cells collections can be time saving and cost-effective.     

The predictive value of white cell or CD34+ cell count in the peripheral blood for timing apheresis and maximizing yield

BACKGROUND: The collection of peripheral blood stem and progenitor cells (PBPCs) for transplantation can be time-consuming and expensive. Thus, the utility of counting CD34+ cells and white cells (WBCs) in the peripheral blood was evaluated as a predictor of CD34+ cell yield in the apheresis component. STUDY DESIGN AND METHODS: The WBC and CD34+ cell counts in the peripheral blood and the apheresis components from 216 collections were assessed. Sixty-three patients underwent mobilization with chemotherapy plus filgrastim, and 17 patients and 14 allogeneic PBPC donors did so with filgrastim alone. The relationship between the number of WBC and CD34+ cells in the peripheral blood and in the apheresis component was analyzed by using rank correlation and linear regression analysis. RESULTS: The correlation coefficient for CD34+ cells per liter of peripheral blood with CD34+ cell yield (x 10(6)/kg) was 0.87 (n = 216 collections). This correlation existed for many patient and collection variables. However, patients with acute myeloid leukemia had fewer CD34+ cells in the apheresis component at any level of peripheral blood CD34+ cell count. Components collected from patients with CD34+ cell counts below 10 x 10(6) per L in the peripheral blood contained a median of 0.75 x 10(6) CD34+ cells per kg. When the WBC count in the blood was below 5.0 x 10(9) per L, the median number of CD34+ cells in the peripheral blood was 5.6 x 10(6) per L (range, 1.0-15.5 x 10(6)/L). A very poor correlation was found between the WBC count in the blood and the CD34+ cell yield (p = 0.12, n = 158 collections). CONCLUSION: The number of CD34+ cells, but not WBCs, in the peripheral blood can be used as a predictor for timing of apheresis and estimating PBPC yield. This is a robust relationship not affected by a variety of patient and collection factors except the diagnosis of acute myeloid leukemia. Patients who undergo mobilization with chemotherapy and filgrastim also should undergo monitoring of peripheral blood CD34+ cell counts, beginning when the WBC count in the blood exceeds 1.0 to 5.0 x 10(9) per L.     

Hematopoietic progenitor cell count, but not immature platelet fraction value, predicts successful harvest of autologous peripheral blood stem cells

Mobilized stem cells in the peripheral blood (PB) must be efficiently harvested at the appropriate time before autologous PB stem cell (PBSC) transplantation. Enumeration of CD34+ cells in the PB before apheresis predicts the number of PBSCs that can be collected, but the cytometric techniques used are complex and expensive. Therefore, it is necessary to identify an alternative to the CD34+ cell count in PBSC harvest-time monitoring. Fully automated flow cytometry using blood cell counters now allows reliable quantification of immature myeloid cells in the PB, referred to as hematopoietic progenitor cells (HPC), and reticulated platelets, expressed as the immature platelet fraction (IPF). Immature or reticulated platelets are thought to correlate with thrombopoietic activity of the marrow. Following a chemotherapy nadir, the recovery of white blood cell and platelet counts has been used to determine the right time for apheresis. Therefore, we examined whether the HPC count and IPF value could be used to predict PBSC mobilization in 20 patients with hematological malignancies. The HPC count was found to be correlated with the CD34+ cell count (r = 0.84, P < 0.01), whereas the IPF value was not (r = 0.37, P = 0.44). Therefore, the HPC count, but not the IPF value, is a possible predictor of the timing of autologous stem cell transplantation.     

An alternative test for determining autologous stem cell transplantation cell harvesting outcome: Comparison between predictive values of two tests

Daily CD34+ cells enumeration as a success indicator of stem cell pheresis procedure using flow cytometry is costly, lengthy, and labor-intensive. Thus, finding a simpler method to achieve the optimum time for harvesting the minimum required stem cells for transplantation could be helpful. The aim of this study was to evaluate the predictive value of reticulocytes fractions and their sensesivity and specificity in guiding CD34+ cell harvesting by G-CSF mobilization strategy. In this study, 49 candidates for autologous peripheral blood stem cell transplantation were enrolled. Before leukapheresis, the immature reticulocytes fraction (IRF) and CD34+ cell count were measured. Moreover, patients were evaluated for leukapheresis outcomes in two MNC and cMNC groups. Here we demonstrated that IRF, LFR, and MFR with the associated criterion of >17.3, ≤82.5, and >15.9, respectively, earned 100 % specificity and 47.2 %, 47.22 %, and 41.46 % sensitivity to predict the minimum required CD34+ cell count. Furthermore, IRF-V (Value) and MFR-V with the associated criterion of >0.77 and >0.55, respectively, earned 58.33 %, 66.67 % sensitivity and 84.62 %, 69.23 % of specificity, separately. As only MFR-V was able to predict the platelet engraftment (P-value = 0.014), none of the other above mentioned factors were not able to predict the neutrophil engraftment. Likewise, it was shown that patients who underwent MNC leukapheresis had a statistically significantly higher total WBC, harvested CD34⁺ cells, MNCs/ kg, and lower apheresis durations (P-values<0.05). Taken together, using IRF and its maturity stages seems to be a compelling predictor of minimal required CD34+ cells in autologous peripheral blood stem cell transplantation.     

Preharvest hematopoietic progenitor cell counts predict CD34+ cell yields in granulocyte–colony‐stimulating factor–mobilized peripheral blood stem cell harvest in healthy donors

BACKGROUND: The hematopoietic progenitor cell (HPC) count measured by the Sysmex hematology analyzer can determine the timing for leukapheresis in autologous peripheral blood stem cell (PBSC) harvest. We evaluated whether a HPC count could predict CD34+ cell yield in healthy, unrelated donors after granulocyte–colony‐stimulating factor mobilization. STUDY DESIGN AND METHODS: A total of 117 healthy donors underwent 161 PBSC leukapheresis procedures in our institution. The HPCs and CD34+ cells were identified by an automated hematology analyzer and flow cytometry, respectively. Using Spearman's rank test, we evaluated the relationships between preharvest HPCs, CD34+ cell counts, and CD34+ cell yields in the apheresis product. A receiver operating characteristic (ROC) curve analysis was used to identify the cutoff value of HPC for adequate mobilization and harvest yield. RESULTS: The HPC count had a moderate correlation with the preharvest CD34+ cell count (r = 0.502, p < 0.001), and an HPC count of more than 21.3 × 10⁶/L could exclude poor mobilization (<20 × 10⁶ CD34+ cells/L) with sensitivity and specificity of 89.2 and 83.3%. However, the relationship between HPC count and CD34+ cell yield was not marked (r = 0.321, p < 0.001). The area under the curve for HPCs was significantly smaller than the preharvest CD34+ cell count on the ROC curve for predicting adequate harvest yield (>10 × 10⁶ CD34+ cells/L of processed blood volume, 0.678 vs. 0.850, p = 0.001). CONCLUSION: Although the preapheresis HPC count could predict mobilization in healthy donors before leukapheresis, it may not be a superior index for predicting CD34+ cell yield compared with the preharvest CD34+ cell count.     

Dynamics of monocyte count: a good predictor for timing of peripheral blood stem cell collection

To investigate potential predictive parameters for successful collection of autologous peripheral blood stem cells (PBSC), 60 consecutive first mobilization attempts and 145 leukapheresis procedures for patients with hematologic malignancies (multiple myeloma: n = 20; acute leukemia: n = 27; lymphoma: n = 13) were analyzed. All patients underwent chemotherapy and granulocyte-colony stimulating factor combined mobilization protocols. PBSC collection began when white blood cell (WBC) count rebounded to >1.0 × 10(9)/L. Poor mobilization (PM) was defined as <2.0 × 10(6)/kg of ideal body weight CD34+ cells were collected from at least three leukapheresis procedures. PM incidence was 15% (9/60). On the first apheresis day, CD34+ cell yield was closely associated with the final yield. Failure to reach the first-day target of 0.7 × 10(6) CD34+ cells/kg was perfectly matched with PM. Circulating WBC and monocyte (MO) counts preleukapheresis had a positive correlation with final CD34+ cell yield. For the first-day apheresis target, receiver operator characteristic (ROC) curve analysis showed that MO count had an area under the curve (AUC) of 0.806 (P = 0.004). An optimal predictive cutoff value for MO count was 1.455 × 10(9)/L with both high sensitivity and specificity of 0.739 and 0.899, respectively. Patients who began leukapheresis with an MO count of ≥1.455 × 10(9)/L accomplished more successful first-day collections than those of their counterparts (P = 0.021). ROC analysis also showed preapheresis WBC count had a high AUC of 0.768 (P = 0.012). However, we could not find a WBC indicator to initiate leukapheresis. In conclusion, circulating MO count after mobilization is a helpful parameter to determine the optimal time point for starting a PBSC collection.     

The number of CD34(+) cells in peripheral blood as a predictor of the CD34(+) yield in patients going to autologous stem cell transplantation

The number of CD34(+) cells in peripheral blood (PB) is a guide to the optimal timing to harvest peripheral blood progenitor cells (PBPC). The objective was to determine the number of CD34(+) cells in PB that allows achieving a final apheresis product containing > or =1.5 x 10(6) CD34(+) cells/kg, performing up to three aphereses. Between March 1999 and August 2003, patients with hematological and solid malignancies who underwent leukapheresis for autologous bone marrow transplantation were prospectively evaluated. Seventy-two aphereses in 48 patients were performed (mean 1.45 per patient; range 1-3). PBPC were mobilized with cyclophosphamide plus recombinant human granulocyte-colony stimulating factor (G-CSF) (n = 40), other chemotherapy drugs plus G-CSF (n = 7), or G-CSF alone (n = 1). We found a strong correlation between the CD34(+) cells count in peripheral blood and the CD34(+) cells yielded (r = 0.903; P < 0.0001). Using receiver-operating characteristic (ROC) curves, the minimum number of CD34(+) cells in PB to obtain > or =1.5 x 10(6)/kg in the first apheresis was 16.48 cells/microL (sensitivity 100%; specificity 95%). The best cut-off point necessary to obtain the same target in the final harvest was 15.48 cells/microL, performing up to three aphereses (sensitivity 89%; specificity 100%). In our experience, > or =15 CD34(+) cells/microL is the best predictor to begin the apheresis procedure. Based on this threshold level, it is possible to achieve at least 1.5 x 10(6)/kg CD34(+) cells in the graft with < or =3 collections.     

Large-volume leukapheresis using femoral venous access for harvesting peripheral blood stem cells with the Fenwal CS 3000 Plus from normal healthy donors: predictors of CD34+ cell yield and collection efficiency

The current paper reports on the predicting factors associated with satisfactory peripheral blood stem cell collection and the efficacy of large-volume leukapheresis (LVL) using femoral vein catheterization to harvest PBSCs with Fenwal CS 3000 Plus from normal healthy donors for allogeneic transplantation. A total of 113 apheresis procedures in 57 patients were performed. The median number of MNCs, CD3+ cells, and CD34+ cells harvested per apheresis was 5.3 x 10(8)/kg (range, 0.3-11.0 x 10(8)/kg), 3.0 x 10(8)/kg (range, 0.2-6.6 x 10(8)/kg), and 7.9 x 10(6)/kg (range, 0.1-188.9 x 10(6)/kg), respectively. The median collection efficiency of MNCs and CD34+ cells was 49.8% and 49.7%, respectively. A highly significant correlation was found between the collected CD34+ cell counts and the pre-apheresis WBC counts in the donors (P = 0.013), and between the collected CD34+ cell counts and the pre-apheresis peripheral blood (PB) CD34+ cell counts (P<0.001). Harvesting at least >4 x 10(6)/kg CD34+ cells from the 1st LVL was achieved in 44 (77.2%) out of 57 donors and in 19 (90.5%) out of 21 donors with a PB-CD34+ cell count of >40/microl. There was no significant difference in the harvested MNC and CD34+ cell counts between the 1st and 2nd apheresis. The catheter-related complications included catheter obstruction (n = 2) and hematoma at the insertion site (n = 3). Accordingly, LVL using femoral venous access for allogeneic PBSC collection from normal healthy donors would appear to be safe and effective.     

Predictive value of circulating immature cell counts in peripheral blood for timing of peripheral blood progenitor cell collection after G-CSF plus chemotherapy-induced mobilization

BACKGROUND: Enumeration of CD34+ cells in peripheral blood (PB) before apheresis predicts the number of CD34+ cells collected, although flow cytometric techniques used are complex and expensive. In an attempt to determine the optimal timing for peripheral blood progenitor cell (PBPC) collection, the usefulness of circulating immature cell (CIC) counts in PB was evaluated. STUDY DESIGN AND METHODS: CIC counts in PB and CD34+ cell counts in the apheresis product from 249 collections were assessed, and the relationship between these two parameters was evaluated by with the Pearson rank correlation analysis, the Fisher exact test, and the U-test. RESULTS: CIC counts were correlated significantly with the number of CD34+ cells per kg of patient's body weight in the apheresis product (Pearson rank correlation analysis: r = 0.635, p < 0.0001). When a level of 1 x 10(9) CICs per L was selected as a cutoff value, the sensitivity and specificity for collecting more than 1 x 10(6) CD34+ cells per kg of body weight were 75.7 and 85.5 percent, respectively. CONCLUSION: The present study strongly suggests that the number of CICs in PB may estimate the number of CD34+ cells collected. The data indicate that CIC counts above 1 x 10(9) per L can be used as a good predictor for PBPC collections containing more than 1 x 10(6) CD34+ cells per kg of body weight in a single apheresis procedure.     

Hematopoietic progenitor cells (HPC) and immature reticulocytes evaluations in mobilization process: new parameters measured by conventional blood cell counter

Monitoring the timing of leukapheresis in peripheral blood stem cells (PBSC) mobilization is an important clinical decision that requires an accurate analytical tool. The present study assessed hematopoietic progenitor cells (HPC) and immature reticulocyte fraction (IRF) counts provided by a routine automated blood counter as potential parameters for predicting the appropriate time for harvesting. The HPC and IRF values were compared with white blood cell (WBC) and CD34+ cell counts obtained by flow cytometry in 30 adult patients with hematological malignancies undergoing PBSC mobilization. It was observed that there was a significant correlation between HPC counts and CD34(+) cells in peripheral blood counts (r=0.61, P=0.0003) and between the number of HPC and CD34+cells collected by leukapheresis (r=0.5733, P=0.0009). Comparing HPC, IRF, WBC, and CD34+ cells parameters as a sign of hematological recovery showed that the raise in immature reticulocytes counts preceded the increase of WBC (P=0.0002), HPC (P=0.0001), and CD34(+) (P=0.0001) cells in peripheral blood counts. According to our results, HPC and IRF parameters may be integrated into clinical protocols to evaluate the timing of leukapheresis. IRF, as previously demonstrated in bone marrow transplantation, is the earliest sign of hematopoietic recovery in mobilization process.     

Peripheral blood circulating immature cell counts predict CD34+ cell yields in G-CSF-induced PBPC mobilization in healthy donors

BACKGROUND: It has been previously reported that the number of circulating immature cells (CIC) in peripheral blood (PB) estimates the number of CD34+ cells collected in G-CSF plus chemotherapy-induced PBPC mobilization. The correlation of CIC counts in PB with CD34+ cell yield and its usefulness was evaluated in G-CSF-induced PBPC mobilization for healthy donors. STUDY DESIGN AND METHODS: CIC counts in PB and CD34+ cell counts in the apheresis product from 122 collections were assessed, and the relationship between these two variables was evaluated with the Pearson rank correlation analysis, the chi-squared test, and the U-test. RESULTS: CIC counts were correlated weakly with the number of CD34+ cells per L of blood processed in the apheresis product (Pearson rank correlation analysis; r=0.357, p<0.0001). When a level of 1.7 x 10(9) CICs per L was selected as a cutoff value, the sensitivity and specificity for collecting more than 20 x 10(6) CD34+ cells per L of blood processed were 63.6 and 77.5 percent, respectively. CONCLUSION: The present study suggests that the number of CICs in PB may estimate the number of CD34+ cells collected. The data indicate that CIC counts above 1.7 x 10(9) per L can be used as a good predictor for PBPC collections containing more than 20 x 10(6) CD34+ cells per L of blood processed in a single apheresis procedure.     

Tempo of hematologic recovery correlates with peripheral blood CD34+ cell level in patients undergoing stem cell mobilization

This study was undertaken to evaluate the relationship between the time to recovery of peripheral blood counts and CD34+ cells in the peripheral blood (PB) and apheresis collections of patients undergoing intensive chemotherapy followed by rhG-CSF. Twenty-three patients with a median age of 42 years (range 17–64) with malignancies underwent peripheral blood stem cell (PBSC) collection after cyclophosphamide (CY) 4 g/m² and etoposide (600 mg/m²) followed by rhG-CSF (10 μg/kg/day). The WBC, platelet counts, CD34+ cell counts per ml of PB, and CD34+ cells in apheresis products were followed in all patients. The relationship of the time to recovery of WBC >1,000/μl, >3,000/μl, >10,000/μl and platelets >20,000/μl and 50,000/μl was compared to the average daily CD34+ cells/ml in each patient using the Spearman Correlation test. The tempo of recovery of WBC and platelets were highly correlated with the average CD34+ cell count in blood. In order to derive some useful guidelines for the timing of apheresis, the patients were divided into two groups, early recover (ER) and late recover (LR) based on the median time (day 10) to reach WBC count greater than 1,000/μl. ER patients had an average daily PB CD34+ cell count of 9.04 × 10⁴/ml (range 0.44–17.5) and a median yield of CD34+ cells of 10.43 × 10⁶/kg (range 0.60–25.95) compared to LR patients, who had 1.87 × 10⁴/ml (range 0.32–5.44) in the PB (P = .001) and a yield 3.20 × 10⁶/kg CD34+ cells (range 0.037–9.39) (P = .001). Patients recovering their WBC to 1,000/ml within 10 days of completing this regimen may undergo PBSC collection and achieve minimum-target cell doses of >2.5 × 10⁶ CD34+ cells/kg—100% of the time. J. Clin. Apheresis 13:1–6, 1998. © 1998 Wiley-Liss, Inc.     

Factors influencing engraftment in autologous peripheral hematopoetic stem cell transplantation (PBSCT).

Autologous peripheral blood stem cells transplantation (PBSCT) is a therapeutic option which can be used in various hematological neoplastic disorders; and it can prolong disease free survival and total survival and at times it may be curative. In this study, we investigated variables influencing PBSCT in 91 patients who had undergone PBSCT between 1998 and 2002 in our center, retrospectively. PBSC collection was performed after mobilization with G-CSF or chemotherapy plus growth factor. Only high dose chemotherapy was used for conditioning regimes. The median number of CD34+ was 11.5 x 10(6)/kg. Posttransplant neutrophil engraftment (>500/microL) was requiring a median of 10 days, it was 13 days for platelet engraftment (>20,000/microL). For neutrophil and platelet engraftment, we investigated; sex, age, diagnosis and CD34+ cells, the time interval between diagnosis and transplantation, number of apheresis, conditioning regime, growth factor initiation day as independent variables. In univariate analysis CD34+ cell number (>10 x 10(6)/kg), time interval more than one year between diagnosis and transplantation and BEAM conditioning was found to be significant for neutrophil engraftment. But in multivariate analysis none of them was found to be significant. For platelet engraftment in univariate analysis CD34+ cell number (>7 x 10(6)/kg), primary diagnosis of multiple myeloma initiation day of growth factor (>2 day) was found to be significant. In multivariate analyses only CD34+ cell count was found to be significant (p=0.005). In conclusion, as in previous studies we found that the only predictor of engraftment kinetics was CD34+ cell count.     

Determining factors predictive of CD34+ cell collection efficiency in an effort to avoid extended and repeated apheresis sessions

Introduction: Collection efficiency (CE) is a reflection of the proportion of cells passing through a cell separator that is harvested. The aim of our study was to evaluate which factors influence CE independently in order to find ways to improve CE and therefore minimize the costs and risks of leukapheresis and graft processing. Materials and Methods: A total of 206 consecutive apheresis procedures performed on 128 donors/patients were studied retrospectively. We explored the association between CE and the following factors: age, sex, weight, mobilization (granulocyte‐colony‐stimulating factor with or without chemotherapy), collection type (autologous versus allogeneic), venous access (peripheral versus central), total processed blood volume (TPV), hematocrit, white blood cell (WBC) count, thrombocyte count, and peripheral blood CD34+ cell concentration (PBCD34+). Results: Stepwise multiple regression analysis showed WBC count to be the single best predictor of CE, accompanied by TPV. When performing subgroup analysis for autologous apheresis procedures, the inverse correlation of WBC count and TPV with CE becomes stronger (r = ?0.563 with P < 0.001 and r = ?0.198 with P = 0.020 respectively), whereas those correlations disappear when analyzing only allogeneic apheresis procedures. Conclusion: The negative correlation between TPV and CE present only in autologous collection procedures can be explained by the limited intra‐apheresis recruitment of CD34+ cells into the blood which is negatively influenced by extensive pre‐treatment. As a result of this study we decided to limit TPV to a maximum of three times the patient's blood volume in autologous apheresis procedures at our center. J. Clin. Apheresis, 28:404–410, 2013. © 2013 Wiley Periodicals, Inc.     

A new model for predicting the timing of leukapheresis on the basis of CD34+ cell and hematopoietic progenitor cell levels

We developed a model (depending on peripheral CD34(+) cell count and hematopoietic progenitor cell count) to determine the optimal timing of 3-day leukapheresis in patients pretreated with chemotherapy and G-CSF. Marrow potentials were identified on the basis of three patterns of leukapheretic yield. Pattern 1 predicted good marrow potential. The positive predictive value of a first-day leukapheretic yield of >1 x 10(6) CD34(+) cells/kg (mean 3-day yield = 8.18 x 10(6) CD34(+) cells/kg, n = 11) was 100%. Pattern 2 predicted poor marrow potential. The negative predictive value of a 3-day leukapheretic yield of >1 x 10(6) CD34(+) cells/kg (3-day yield = 0.26 x 10(6) CD34(+) cells/kg, n = 1) was 100%. Pattern 3 met neither of the above criteria (mean 3-day yield = 1.37 x 10(6) CD34(+) cells/kg, n = 19). The marrow potential was borderline and patients could be further divided into two subgroups according to peripheral CD34(+) cell counts when WBC reached >10,000/microl. The mean yield differed significantly between pattern 1 and 3 (P < 0.001). For patients with good marrow potential, leukapheresis should begin as soon as the WBC count is >5,000/microl. Patients with borderline marrow potential may benefit from delaying leukapheresis until the WBC level is >10,000/microl and leukapheresis extended more than 3 days.     

Mobilization kinetics of CD133+ hematoprogenitor cells for hematopoietic grafting

BACKGROUND: Quantification of CD34+ mononuclear cells is the most important quality control measure for hematopoietic stem cell (HSC) transplantation. A fraction of CD34+ cells also express the CD133 antigen. These cells constitute a group of earlier, less-differentiated HSCs with a potentially higher capacity for engraftment. The correlation between total CD34+ peripheral HSCs and the fraction of these cells that coexpress CD133 was determined before and after automated collection by leukapheresis, as well as the effect of HSC CD133+ dose on hematopoiesis recovery.
STUDY DESIGN AND METHODS: Granulocyte–colony-stimulating factor mobilization of HSCs from the marrow to the peripheral blood (PB) of allogeneic and autologous donors was followed by automated collection through leukapheresis on the fifth day. Quantification of CD34+ and CD133+ cells was performed on PB before collection and in the hematopoietic graft (HG) by flow cytometry.
RESULTS: There was a significant correlation between CD133+ and CD34+ HSCs in the PB before collection and in the final product for grafting (r = 0.62 and 0.64; p < 0.01). CD34+ HSCs per µL in PB and the HG was the only variable that did not correlate (r = 0.18). CD34+/CD133+ correlation increased from 0.33 on PB to 0.94 on the leukapheresis product (p < 0.01). Time to recovery was not related to CD133+ HSCs infused.
CONCLUSION: There was a significant correlation of both number per µL and percentage of CD34+/CD133+ HSCs before and after collection for transplantation; number of CD133+ cells had no apparent clinical impact on time to hematopoiesis regeneration.     

Viable CD34+ stem cell content of a cord blood graft: which measurement performed before transplantation is most representative?

BACKGROUND: Patient survival in allogeneic cord blood transplantation is critically dependent on total nucleated cell (TNC) count or total CD34+ cell count per kg of body weight. Theoretically, viable CD34+ cell measurement at the time of infusion should give a better indication of the suitability of a certain transplant. The relation between measurements on different samples and viable CD34+ cell count on the graft itself was analyzed. STUDY DESIGN AND METHODS: Viable CD34+ cells were measured with a no-wash, single-platform technique with 7-aminoactinomycin D. Analysis was performed before freezing on the cord blood, after freezing and thawing on the cord blood unit itself, and on various samples. RESULTS: Cord blood volume correlated poorly with viable CD34+ cell content (r=0.24) as did initial TNC count and WBC count (r=0.57 and r=0.48, respectively). In contrast, viable CD34 cell content determined before freezing correlated well with viable CD34 cell content of the graft (r=0.91) but was on average 25 percent higher than after freezing and thawing. The best correlations with the CD34+ cell content of the cord blood unit were obtained with CD34 cell measurements on a separate cryovial (r=0.95). These CD34 cell measurements on frozen samples were found to be very reproducible (r=0.96). CONCLUSION: Viable CD34 cell count of the graft is both accurate and precise when measured on a separate sample frozen together with the cord blood unit. This measurement can be performed by the transplant center to exclude between-laboratory variability.     

rhG-CSF动员健康供者CD34^＋细胞产率的影响因素分析

为探讨rhG—CSF动员健康供者年龄、性别等因素对采集物CD34^＋细胞产率的影响,分析61例健康供者外周血采集物CD34^＋细胞数量与自身特点的相关性,并进行多因素回归分析。以供者性别、年龄、身高、体重、体重指数（BMI）和采集时间作为研究参数,外周血采集物单核细胞计数、CD34^＋细胞占有核细胞百分比、CD34^＋细胞计数、CD34^＋细胞每公斤体重（供者）计数的均值作为研究变量。结果表明,供者年龄是影响CD34^＋细胞产率主要因素,呈中等负相关（-0．60〈r〈-0．45,P〈0．005）。偏相关分析排除身高、体重、BMI的影响,年龄仍和CD34^＋细胞产率呈中等负相关（-0．50〈r〈-0．35,P〈0．02）。BMI仅与CD34^＋细胞每公斤体重计数呈微弱负相关（r=-0．297,P〈0．05）,性别对CD34^＋细胞产率无明显影响,CD34^＋细胞计数的差别仅出现在男性和女性低龄组（年龄〈35岁）间,男性身高、体重、BMI为CD34^＋细胞计数增加的有利因素。供者采集时间为给药后第4天采集,70％供者CD34^＋细胞产率达峰值。结论：年龄应作为供者选择的首要因素,性别、身高、体重和BMI对CD34^＋细胞产率的影响是次要的。     

Preterm birth and the availability of cord blood for HPC transplantation

BACKGROUND: Cord blood from deliveries at term can be used for HPC transplantation. The objective of this study was to determine the amounts of cord blood nucleated cells (NCs) and HPCs that were collectable from preterm deliveries. STUDY DESIGN AND METHODS: Cord blood collected from preterm deliveries between 22 and 36 weeks of gestation was compared with regard to volume, NC count (/mL), CD34+ cell count (/mL), and the NC and CD34+ cell counts per cord blood sample and at different gestational ages. RESULTS: A correlation was found between gestational age and NC count (r = 0.52, p<0.001), and an inverse relation was found between gestational age and CD34+ cell count (r = - 0.68, p<0.001). The CD34+ cell count per cord blood sample was independent of gestational age (r = - 0.13, p = NS), and no significant difference between early (22-32 week) and late (33-36 week) preterm deliveries was found (p = 0.870). Comparison with published data from cord blood transplantations revealed that up to one-third of preterm samples contained at least as many NCs (or CD34+ cells) as the median cell dose transplanted (calculated for the median recipient weight) in the respective study. Furthermore, 77 percent of all preterm samples contained at least 1 x 10(7) NCs (and 42% at least 1 x 10(5) CD34+ cells) per kg for transplantation in a recipient of 20-kg body weight, which corresponds to the lower threshold of cells per kg in the graft recommended by Eurocord. CONCLUSION: Preterm delivery should not be a reason to exclude cord blood collection if allogeneic cord blood transplantation in a sibling is planned.