Flow cytometric enumeration of CD34+ hematopoietic stem and progenitor cells in leukapheresis product and bone marrow for clinical transplantation: a comparison of three methods

Flow cytometric enumeration of CD34+ hematopoietic stem and progenitor cells (HSCs) is widely used for evaluation of graft adequacy of peripheral blood and bone marrow stem cell grafts. In the present study, we review and compare the major counting techniques of stem and progenitor cells. The methods are: the Milan/Mullhouse protocol, two-platform ISHAGE (International Society of Hematotherapy and Graft Engineering) and single-platform ISHAGE analysis system. According to the Milan/Mulhouse protocol, HSCs are identified by CD34 antibody staining and easy gating strategy. The ISHAGE guidelines for detection of CD34+ cells are based on a four-parameter flow cytometry method (CD34PE/CD45PerCP staining, side and forward angle light scatter) thus employing multiparameter gating strategy. With two-platform ISHAGE protocol, an absolute CD34+ count is generated by incorporating the leukocyte count from an automated hematology analyser. The single-platform ISHAGE method to determine the absolute CD34+ count directly from a flow cytometer includes the use of Trucount tubes (Becton Dickinson) with a known number of fluorescent beads. CD34+ cells were quantified in mobilized peripheral blood, collected by leukapheresis, and bone marrow from 42 samples from patients with hematological malignancies. The differences against the means display low disagreement between the Milan/Mulhouse and ISHAGE protocols, with discrepancies of up to 2.5% (two-platform ISHAGE)--2.6% (single-platform ISHAGE) in enumeration of CD34+ cells in leukapheresis product and 4.8% (two-platform ISHAGE)--4.9% (single-platform ISHAGE) in bone marrow. Our results show high correlation among all three methods. Since the three protocols are compatible, choosing the most convenient in terms of costs, simplicity and compliance with clinical results appears to be a logical consequence.     

Comparison of single and dual platform methodologies for the estimation of CD34+ hematopoietic progenitor cells: correlation with colony assay

In this study three assays for the enumeration of CD34+ progenitors were compared: 1) a modified version of the Milan protocol, used in the standard dual-platform format; 2) a dual-platform version of the ISHAGE protocol; 3) the ProCOUNT software version 2.0/ProCOUNT kit. The assays were compared to validate the accuracy of CD34+ cell counts in mobilized peripheral blood (PB), apheresis products (AP), and cord blood (CB). The ProCOUNT protocol uses reference beads for absolute CD34+ cell counting, whereas CD34 counts by other techniques are derived from a separate leukocyte count performed by a hematology analyzer. A good correlation between the ISHAGE and ProCOUNT methods was obtained for estimation of CD34+ counts in PB (n=42 samples analyzed) and AP (n=35)--except for samples having a leukocyte count >25 x 10(9)/L or a CD34 count <0.0025 x 10(9)/L)--while a suboptimal correlation between the methods was observed for CB (n=30). The ProCOUNT system proved to be effective in reducing the variability in CD34+ cell counting and appeared to be useful for intralaboratory methodology standardization. The main disadvantage of the ProCOUNT assay was its inability to calculate CD34 counts in leukopenic samples and in CB samples showing a high erythroblast count. As far as the correlation with hematopoietic colonies is concerned, data collected from apheresis samples showed a good correlation between the three flow cytometry methods and colony-forming unit granulocyte-macrophage (CFU-GM) counts, confirming the value of the flow cytometric test as a real-time, truly predictive test to measure the hematopoietic potential of the graft. In summary, all methods are suitable for enumeration of most PB samples, while the single-platform methodology should be preferred for the analysis of AP and CB. We also found the dual-platform format of the ISHAGE method precise and accurate for the estimation of CD34+ cells from CB samples. Based on these data it can be concluded that the single-platform flow cytometry assay format should be the preferred approach for CD34+ stem cell enumeration in different types of samples.     

Pre-clinical development of cord blood-derived progenitor cell graft expanded ex vivo with cytokines and the polyamine copper chelator tetraethylenepentamine

BACKGROUND: We have previously demonstrated that the copper chelator tetraethylenepentamine (TEPA) enables preferential expansion of early hematopoietic progenitor cells (CD34+CD38-, CD34+CD38-Lin-) in human umbilical cord blood (CB)-derived CD34+ cell cultures. This study extends our previous findings that copper chelation can modulate the balance between self-renewal and differentiation of hematopoietic progenitor cells. METHODS: In the present study we established a clinically applicative protocol for large-scale ex vivo expansion of CB-derived progenitors. Briefly, CD133+ cells, purified from CB using Miltenyi Biotec's (Bergisch Gladbach, Germany) CliniMACS separation device and the anti-CD133 reagent, were cultured for 3 weeks in a clinical-grade closed culture bag system, using the chelator-based technology in combination with early-acting cytokines (SCF, thrombopoietin, IL-6 and FLT-3 ligand). This protocol was evaluated using frozen units derived from accredited cord blood banks. RESULTS: Following 3 weeks of expansion under large-scale culture conditions that were suitable for clinical manufacturing, the median output value of CD34+ cells increase by 89-fold, CD34+CD38- increase by 30-fold and CFU cells (CFUc) by 172-fold over the input value. Transplantation into sublethally irradiated non-obese diabetic (NOD/SCID) mice indicated that the engraftment potential of the ex vivo expanded CD133+ cells was significantly superior to that of unexpanded cells: 60+/-5.5% vs. 21+/-3.5% CD45+ cells, P=0.001, and 11+/-1.8% vs. 4+/-0.68% CD45+CD34+ cells, P=0.012, n=32, respectively. DISCUSSION: Based on these large-scale experiments, the chelator-based ex vivo expansion technology is currently being tested in a phase 1 clinical trial in patients undergoing CB transplantation for hematological malignancies.     

Enumeration of CD34+ cells in cord blood: a variation on a single-platform flow cytometric method based on the ISHAGE gating strategy

Single-platform flow cytometric absolute cell counting protocols provide increased robustness for CD34+ cell enumeration by limiting potential sources of imprecision. However, samples with any cellular fragmentation or debris, such as cord blood samples, provide challenges for these assays. We describe a simple, robust absolute CD34+ cell counting protocol, suitable for cord blood, using TRUCOUNT absolute count tubes (BD Biosciences, San Jose, CA) and a modified ISHAGE (International Society for Hematotherapy and Graft Engineering) gating strategy. An advantage of TRUCOUNT tubes is that each tube is supplied with a known number of lyophilized fluorescent beads. The method includes no-wash fixative-free ammonium chloride red blood cell lysis and the viability dye, 7-amino actinomycin D, to exclude dead cells. The threshold was set on CD45 expression in the FL1 channel and an exclusion gate in the forward scatter channel reduced debris. No manual adjustment of the gating regions was required, even for samples in less than optimal condition. Comparison of the TRUCOUNT-ISHAGE protocol with the original dual-platform ISHAGE assay (n = 30) and the single-platform ISHAGE protocol using Flow-Count Fluorospheres (Beckman Coulter, Fullerton, CA; n = 22) showed high correlation (R(2) = 0.949 and 0.989, respectively) and no significant difference or bias for samples ranging from 22 to 600 CD34+ cells per microliter. Results are presented that demonstrate the detrimental effect of a fixative-containing lysis reagent when used in a lyse-and-wash procedure. The TRUCOUNT-ISHAGE protocol combines the attributes of TRUCOUNT tubes and the ISHAGE gating strategy to provide a single-platform protocol capable of achieving readily standardization of CD34+ cell enumeration.     

Quality comparison of umbilical cord blood cryopreserved with conventional versus automated systems

Umbilical cord blood (CB) banks usually freeze and store CB for clinical transplantation using conventional controlled-rate freezer or the automated BioArchive system. The aim of this study is to compare the quality of CB cryopreserved with conventional and automated methods and to make clear the cause of the quality difference between the two methods. The experiment used 80 CB units: 40 were conventionally cryopreserved and the remainder were cryopreserved with a BioArchive. After thawing, the following measures of CB quality were compared: recovery rates of cell count, cell viability of total nucleated cells (TNCs), mononuclear cells (MNCs), and CD34+ cells, as well as colony-forming unit-granulocyte/macrophage (CFU-GM) content. Additionally, processing and storage records were reviewed to quantify the number of exposures of CB units at room temperature (transient warming event, TWE), which was analyzed in relation to CB quality. MNC and CD34+ cell viability were as follows: MNC, 78.2% ± 6.8% (conventional), 81.7% ± 7.2% (automated); CD34+ cell, 90.6% ± 6.9% (conventional), 94.7% ± 3.5% (automated). The absolute CFU-GM content per CB unit was 7.1 × 10⁵ ± 5.9 × 10⁵ with conventional cryopreservation and 12.3 × 10⁵ ± 12.0 × 10⁵ with automated cryopreservation. CBs cryopreserved with BioArchive showed significantly higher MNC and CD34+ cell viability, and CFU-GM content than those conventionally cryopreserved. The CB quality comparison depending on the amount of TWEs showed no significant quality difference between groups that were more exposed to TWEs and groups that were less exposed. CBs cryopreserved with BioArchive were of higher quality than conventionally cryopreserved CBs, and the cause of quality difference might be due to the difference of freezing conditions rather than the TWE effect.     

Ex vivo expansion of cord blood mononuclear cells on mesenchymal stem cells

BACKGROUND: Cord blood (CB) cells are being used increasingly as a source of hematopoietic cells to support high dose chemotherapy. However, CB units contain low numbers of cells, including CD34+ cells, and thus their use is associated with significant delays in engraftment of neutrophils and platelets. Exvivo expansion of CB has been proposed to increase the numbers of cells available. We and others have reported the requirement of CD34 selection for optimal expansion of CB products'; however, the selection of frozen CB products in clinical trials results in significant loss of CD34+ cells, with a median recovery of 50, but less than 40% recovery in more than one-third of products. In the present studies we evaluated the potential of mesenchymal stem cells (MSC) to support ex vivo expansion of unselected CB products. METHODS: Mononuclear cells (MNC) from CB products were isolated and cultured on preformed MSC layers in T150 flasks containing 50 mL Stemline II media plus hematopoietic growth factors. Various culture conditions were compared for optimal expansion of the CB MNC. RESULTS: Ex vivo expansion of CB MNC on MSC resulted in 10- to 20-fold expansion of total nucleated cells, seven- to 18-fold expansion of committed progenitor cells, two- to five-fold expansion of primitive progenitor cells and 16- to 37-fold expansion of CD34+ cells. DISCUSSION: These studies demonstrated significant expansion of CB products without CD34 cell selection using culture conditions that are clinically applicable. Our current focus is to initiate clinical trials to evaluate the in vivo potential of CB cells expanded with these conditions.     

Effect of dimethyl sulfoxide on post-thaw viability assessment of CD45+ and CD34+ cells of umbilical cord blood and mobilized peripheral blood

BACKGROUND: The effect of dimethyl sulfoxide (Me2SO) on enumeration of post-thaw CD45+ and CD34+ cells of umbilical cord blood (HPC-C) and mobilized peripheral blood (HPC-A) has not been systematically studied. METHODS: Cells from leukapheresis products from multiple myeloma patients and umbilical cord blood cells were suspended in 1, 2, 5, or 10% Me2SO for 20 min at 22 degrees C. Cells suspended in Me2SO were then immediately assessed or assessed following removal of Me2SO. In other samples, cells were suspended in 10% Me2SO, cooled slowly to -60 degrees C, stored at -150 degrees C for 48 h, then thawed. The thawed cells in 10% Me2SO were diluted to 1, 2, 5, or 10% Me2SO, held for 20 min at 22 degrees C and then immediately assessed or assessed after the removal of Me2SO. CD34+ cell viability was determined using a single platform flow cytometric absolute CD34+ cell count technique incorporating 7-AAD. RESULTS: The results indicate that after cryopreservation neither recovery of CD34+ cells nor viability of CD45+ and CD34+ cells from both post-thaw HPC-A and HPC-C were a function of the concentration of Me2SO. Without cryopreservation, when Me2SO is present recovery and viability of HPC-C CD34+ cells exposed to 10% Me2SO but not CD45+ cells were significantly decreased. Removing Me2SO by centrifugation significantly decreased the viability and recovery of CD34+ cells in both HPC-A and HPC-C before and after cryopreservation. DISCUSSION: To reflect the actual number of CD45+ cells and CD34+ cells infused into a patient, these results indicate that removal of Me2SO for assessment of CD34+ cell viability should only be performed if the HPC are infused after washing to remove Me2SO.     

Quantification of circulating endothelial progenitor cells using the modified ISHAGE protocol

Aims

Circulating endothelial progenitor cells (EPC), involved in endothelial regeneration, neovascularisation, and determination of prognosis in cardiovascular disease can be characterised with functional assays or using immunofluorescence and flow cytometry. Combinations of markers, including CD34+KDR+ or CD133+KDR+, are used. This approach, however may not consider all characteristics of EPC. The lack of a standardised protocol with regards to reagents and gating strategies may account for the widespread inter-laboratory variations in quantification of EPC. We, therefore developed a novel protocol adapted from the standardised so-called ISHAGE protocol for enumeration of haematopoietic stem cells to enable comparison of clinical and laboratory data.

Methods and Results

In 25 control subjects, 65 patients with coronary artery disease (CAD; 40 stable CAD, 25 acute coronary syndrome/acute myocardial infarction (ACS)), EPC were quantified using the following approach: Whole blood was incubated with CD45, KDR, and CD34. The ISHAGE sequential strategy was used, and finally, CD45^dimCD34⁺ cells were quantified for KDR. A minimum of 100 CD34⁺ events were collected. For comparison, CD45⁺CD34⁺ and CD45⁻CD34⁺ were analysed simultaneously. The number of CD45^dimCD34⁺KDR⁺ cells only were significantly higher in healthy controls compared to patients with CAD or ACS (p = 0.005 each, p<0.001 for trend). An inverse correlation of CD45^dimCD34⁺KDR⁺ with disease activity (r = −0.475, p<0.001) was confirmed. Only CD45^dimCD34⁺KDR⁺ correlated inversely with the number of diseased coronaries (r = −0.344; p<0.005). In a second study, a 4-week de-novo treatment of atorvastatin in stable CAD evoked an increase only of CD45^dimCD34⁺KDR⁺ EPC (p<0.05). CD45⁺CD34⁺KDR⁺ and CD45⁻CD34⁺KDR⁺ were indifferent between the three groups.

Conclusion

Our newly established protocol adopted from the standardised ISHAGE protocol achieved higher accuracy in EPC enumeration confirming previous findings with respect to the correlation of EPC with disease activity and the increase of EPC during statin therapy. The data of this study show the CD45^dim fraction to harbour EPC.     

Unrelated and related cord blood banking and hematopoietic graft engineering

The first successful transplantation of umbilical-cord blood (CB) was performed in 1988 to treat a boy with Fanconi's anemia, using CB from his HLA full-matched sister. A few years later, CB transplantation (CBT) was also performed in an adult recipient, however major obstacles still prevent a wider application of CBT in this age group. The principle limiting-factor is the low numbers of nucleated (NC) and CD34+ cells available for transplantation compared to a typical bone marrow (BM)/peripheral blood (PB) allograft, resulting in a lower engraftment success as well as delayed hematopoietic recovery with its characteristic complications, including infections and transplant related mortality (TRM). Other problems include uncertainty regarding potency and efficacy of graft versus leukemia (GvL)/tumor effects in this kind of transplant, considering the reduced graft versus host disease (GvHD) manifestations and immunologic prematurity. These subjects are reviewed with orientation to technical methods directed to improve CB grafts and graft engineering.     

Peripheral blood and BM CD34+ CD38- cells show better resistance to cryopreservation than CD34+ CD38+ cells in autologous stem cell transplantation

BACKGROUND: We and others have shown a critical role for CD34+ CD38- cells in hematopoietic recovery after autologous stem cell transplantation (ASCT), in particular for platelet reconstitution. Thus a routine assessment of CD34+ CD38- cells in freezing-thawing procedures for autografting could represent an important tool for predicting poor engraftment. METHODS: To compare the impact of cryopreservation on CD34+ CD38+ and CD34+ CD38- hematopoietic stem cell subsets, 193 autograft products collected in 84 patients with malignancies were assessed before controlled-rate cryopreservation in 10% DMSO and after thawing for autografting. RESULTS: Cell counts after thawing were significantly different from the pre-freezing counts for total CD34+ (P<0.0001) and CD34+ CD38+ (P<0.0001) cells, but not for CD34+ CD38- cells (P=0.252). Median losses for CD34+, CD34+ CD38+ and CD34+ CD38- cells were, respectively, 11.8%, 11.4% and 0.0%. The magnitude of fresh/post-thawing percentage cell variation was significantly different when comparing between the CD34+ CD38+ and CD34+ CD38- cell subsets (P<0.001). Moreover, CD34+ CD38- cells exhibited recovery values > or =100% in 85/160 graft products, compared with 51/193 in CD34+ CD38+ cells (P<0.0001). Also, recovery values > or =90% were significantly better in the CD34+ CD38- (98/160 grafts) than in the CD34+ CD38+ subsets (89/193 grafts) (P<0.01). DISCUSSION: In this work we have demonstrated that CD34+ cells that do not express the CD38 Ag show a significantly better resistance to cryopreservation. This could represent another example of the particular ability of less committed progenitor cells to overcome environmental injuries. Moreover, we consider routine assessment of CD34+ CD38- cells before freezing as clinically relevant, but post-thawing controls may be avoided because of their good resistance to freezing.     

Ex vivo expansion of umbilical cord blood

The efficacy of cord blood (CB) transplantation is limited by the low cell dose available. Low cell doses at transplant are correlated with delayed engraftment, prolonged neutropenia and thrombocytopenia and elevated risk of graft failure. To potentially improve the efficacy of CB transplantation, approaches have been taken to increase the cell dose available. One approach is the transplantation of multiple cord units, another the use of ex vivo expansion. Evidence for a functional and phenotypic heterogeneity exists within the HSC population and one concern associated with ex vivo expansion is that the expansion of lower 'quality' hematopoietic progenitor cells (HPC) occurs at the expense of higher 'quality' HPC, thereby impacting the reserve of the graft. There is evidence that this is a valid concern while other evidence suggests that higher quality HPC are preserved and not exhausted. Currently, ex vivo expansion processes include: (1) liquid expansion: CD34+ or CD133+ cells are selected and cultured in medium containing factors targeting the proliferation and self-renewal of primitive hematopoietic progenitors; (2) co-culture expansion: unmanipulated CB cells are cultured with stromal components of the hematopoietic microenvironment, specifically mesenchymal stem cells (MSC), in medium containing growth factors; and (3) continuous perfusion: CB HPC are cultured with growth factors in 'bioreactors' rather than in static cultures. These approaches are discussed. Ultimately, the goal of ex vivo expansion is to increase the available dose of the CB cells responsible for successful engraftment, thereby reducing the time to engraftment and reducing the risk of graft failure.     

Ex vivo expanded umbilical cord blood T cells maintain naive phenotype and TCR diversity

BACKGROUND: Umbilical cord blood (CB) is a promising source of hematopoietic stem cells for allogeneic transplantation. However, delayed engraftment and impaired immune reconstitution remain major limitations. Enrichment of donor grafts with CB T cells expanded ex vivo might facilitate improved T-cell immune reconstitution post-transplant. We hypothesized that CB T cells could be expanded using paramagnetic microbeads covalently linked to anti-CD3 and anti-CD28 Ab. METHODS: CB units were divided into three fractions: (1) cells cultured without beads, (2) cells cultured with beads and (3) cells cultured with beads following CD3+ magnetic enrichment. All fractions were cultured for 14 days in the presence of IL-2 (200 IU/mL). RESULTS: A mean 100-fold expansion (range 49-154) of total nucleated cells was observed in the CD3+ magnetically enriched fraction. Following expansion, CB T cells retained a naive and/or central memory phenotype and contained a polyclonal TCR diversity demonstrated by spectratyping. DISCUSSION: Our data provide evidence that naive and diverse CB T cells may be expanded ex vivo and warrant additional studies in the setting of human CB transplantation.     

Dimethyl sulfoxide-free cryopreservation solutions for hematopoietic stem cell grafts

Background aimsThe use of effective methods for the cryopreservation of hematopoietic stem cells (HSCs) is vital to retain the maximum engraftment activity of cord blood units (CBUs). Current protocols entail the use of dimethyl sulfoxide (DMSO) as intracellular cryoprotective agent (CPA) and dextran and plasma proteins as extracellular CPAs, but DMSO is known to be cytotoxic, and its infusion in patients is associated with mild to moderate side effects. However, new, commercially available, DMSO-free cryopreservation solutions have been developed, but their capacity to protect HSCs remains poorly investigated.MethodsHerein the authors compared the capacity of four DMSO-free freezing media to cryopreserve cord blood (CB) HSCs: CryoProtectPureSTEM (CPP-STEM), CryoScarless (CSL), CryoNovo P24 (CN) and Pentaisomaltose (PIM). Clinical-grade DMSO/dextran solution was used as control.ResultsOf the four cryopreservation solutions tested, the best post-thaw cell viability, recovery of viable CD45+ and CD34+ cells and potency were achieved with CPP-STEM, which was equal or superior to that seen with the control DMSO. CSL provided the second best post-thaw results followed by PIM, whereas CN was associated with modest viability and potency. Further work with CPP-STEM revealed that CB CD34-enriched HSCs and progenitors cryopreserved with CPP-STEM maintained high viability and growth expansion activity. In line with this, a pilot transplantation assay confirmed that CPP-STEM-protected CB grafts supported normal short- and long-term engraftment kinetics.ConclusionsThe authors’ results suggest that new, valuable alternatives to DMSO are now available for the cryopreservation of HSCs and grafts, including CBUs.     

Differentiation of CD34+ cells from human cord blood and murine bone marrow is suppressed by C6 beta-chemokines

Several recently identified chemokines, Lkn-1, CKbeta8-1, MRP-2, and Mu C10 (MRP-1), are classified as C6 beta-chemokines. All of these chemokines have been found to suppress colony formation by bone marrow (BM) myeloid progenitors. Since cord blood (CB), like BM, contains CD34-positive cells, we examined the effects of these chemokines on CD34+ cells isolated from human CB. Lkn-1 and CKbeta8-1 suppressed colony formation by multi-potential granulocyte erythroid mega-karyocyte macrophages (CFU-GEMM), granulocyte-macrophages (CFU-GM), and erythroid (BFU-E) cells among the CD34+ cells from CB. CC chemokine receptor 1 (CCR1) that is known to be a receptor for Lkn-1 and CKbeta8-1 in neutrophils, monocytes, and lymphocytes, was also present on the surface of CD34+ cells from CB. Taken together these results suggest that Lkn-1 and CKbeta8-1 are active in inhibiting myeloid progenitor cells from both BM and CB. Macrophage inflammatory protein related protein-2 (mMRP-2) and Mu C10 (mMRP-1), which are murine C6 beta-chemokines, also inhibited colony formation by CB CD34+ cells. The inhibitory activity of these chemokines suggests that they may protect hematopoietic progenitors from the cytotoxic effects of the antiblastic drugs used in cancer therapy.     

Expansion of CD34+ cells from human umbilical cord blood by FL and/or TPO gene transfected human marrow stromal cell lines

To elucidate the effect of gene transfected marrow stromal cell on expansion of human cord blood CD34+ cells, a culture system was established in which FL and TPO genes were transfected into human stromal cell line HFCL. To establish gene transfected stromal cells co-culture system, cord blood CD34+ cells were purified by using a magnetic beads sorting system. The number of all cells and the number of CD34+ cells and CFC (CFU-GM and BFU-E) were counted in different culture systems. The results showed that in all 8 culture systems, SCF+IL-3+HFT manifested the most potent combination, with the number of total nucleated cells increasing by (893.3±52.1)-fold, total progenitor cells (CFC) by (74.5±5.2)-fold and CD34+ cells by 15.7-fold.Maximal expansions of CFC and CD34+ cells were observed at the end of the second week of culture. Within 14 days of culture, (78.1 ± 5.5)-fold and (57.0 ± 19.7)-fold increases in CFU-GM and BFU-E were obtained. Moreover, generation of LTC-IC from amplified CD34+ cells within 28 days was found only in two combinations, I.e. SCF+IL-3+FL+TPO and SCF+IL-3+HFT, and there was no significant difference between these two groups statistically. These results suggest that human umbilical cord blood CD34+ cells can be extensively expanded ex vivo by using gene transfected stromal cells along with cytokines.     

Analyses to clarify rich fractions in hepatic progenitor cells from human umbilical cord blood and cell fusion

Umbilical cord blood (UCB) is a source of hematopoietic stem cells and other stem cells, and human UCB cells have been reported to contain transplantable hepatic progenitor cells. However, the fractions of UCB cells in which hepatic progenitor cells are rich remain to be clarified. In the present study, first, the fractionated cells by CD34, CD38, and c-kit were transplanted via portal vein of NOD/SCID mice, and albumin mRNA expression was examined in livers at 1 and 3 months posttransplantation. At 1 and 3 months, albumin mRNA expression in CD34+UCB cells-transplanted livers was higher than that in CD34- cells-transplanted livers. Albumin mRNA expression in CD34+CD38+ cells-transplanted livers was higher than that in CD34+CD38- cells-transplanted [corrected] liver at 1 month. However, it was much higher [corrected] in CD34+CD38- cell-transplanted livers at 3 months. Similar expression of albumin mRNA was obtained between CD34+CD38+c-kit+ cells- and CD34+CD38-c-kit- cells-transplanted livers, and between CD34+CD38-c-kit+ cells- and CD34+CD38-c-kit- cells-transplanted livers, respectively. Second, fluorescence in situ hybridization and immunohistochemistry were performed to examine whether UCB cells really transdifferentiated into hepatocytes or they only fused with mouse hepatocytes. In mouse liver sections, of 1.2% cells which had human chromosomes, 0.9% cells were due to cell fusion, whereas 0.3% cells were transdifferentiated into human hepatocytes. These results suggest that CD34+UCB cells are rich fractions in hepatic progenitor cells, and that transdifferentiation from UCB cells into hepatocytes as well as cell fusion simultaneously occur in this situation.     

Telomere length of cord blood cells chromosomes as additional quality characteristic of sample for transplantation

Telomeres are the ends of the chromosomes and represent repeated DNA sequence and protein complex. Telomeres shorten with each cell division, which limits proliferative potential of cells. There is a great progress in clinical application of telomere length now. Additional characteristic of stem cell proliferation activity estimated by telomere length can be an informative indicator of transplant quality. In this work, we analyzed 14 cord blood samples by flow-FISH, ELISA and gematologycal analisator, and also the number of CD34 + CD45dim cells. Average telomere length of leukocytes fraction CB cells was 20.4-4.9 % respectively the control cells 1301 (T-cell lymphoblastic leukemia).     

Novel cryoprotectant significantly improves the post-thaw recovery and quality of HSC from CB

BACKGROUND: Hematopoietic stem cells (HSC) have traditionally been frozen using the cryoprotectant DMSO in dextran-40, saline or albumin. However, the process of freezing and thawing results in loss of HSC numbers and/or function. METHODS: This study investigated the use of CryoStor for the freezing of HSC from cord blood (CB). CB donations (n = 30) were collected under an Institutional Ethics Committee-approved protocol, volume reduced and frozen using three different methods of cryoprotection. Aliquots were frozen with either 10% DMSO in dextran-40, 10% DMSO in CryoStor or 5% DMSO in CryoStor. Prior to freezing samples were separated for nucleated cell (NC) and CD34+ counts and assessment of CD34+ viability. Aliquots were frozen and kept in vapor phase nitrogen for a minimum of 72 h. Vials were rapidly thawed at 37 degrees C and tested for NC and CD34+ counts and CD34+ viability and colony-forming unit (CFU) assay. RESULTS: Cells frozen with CryoStor in 10% DMSO had significantly improved NC (P < 0.001), CD34+ recovery, viable CD34+ (P < 0.001) and CFU numbers (P < 0.001) compared with dextran in 10% DMSO. CryoStor in 5% DMSO resulted in significantly improved NC (P < 0.001) and CFU (P < 0.001). Discussion: These results suggest that improved HSC recovery, viability and functionality can be obtained using CryoStor with 10% DMSO and that similar if not better numbers can be obtained with 5% DMSO compared with dextran-40 with 10% DMSO.     

Expression of hyaluronan synthase genes in umbilical cord blood stem/progenitor cells

Scientific progress reveals an ever-expanding role of hyaluronan (HA) in diverse biological functions. It has become increasingly clear that HA might also be essential for certain functions of stem cells. CD133+ cells isolated from umbilical cord blood (UCB) seem to represent an alternative to CD34+ cells as a source of transplantable haematopoietic progenitor cells. The aim of this study was to investigate expression patterns of hyaluronan synthases (HAS) genes in freshly isolated and cultured UCB progenitor cells and to compare HAS mRNA levels to those found in non-progenitor cells. CD133+ stem cells were isolated from UCB using an immunomagnetic procedure. Investigation of HAS mRNA expression patterns in CD133+ and CD133- cells by RT-PCR was performed immediately after isolation as well as after cultivation towards myelomonocytic lineage. In addition, activation patterns of mitogen activated protein kinases (MAPK) were analyzed by Western blot experiments. mRNA for HAS1 is undetectable but HAS3 mRNA can be readily detected in freshly isolated CD133+ as well as in CD133- UCB cells. More importantly, our data demonstrate that mRNA for HAS2 can only be detected in CD133+ progenitor cells. In addition, while MAPK are slightly activated in CD133- UCB cells, no significant phosphorylation of MAPK could be observed in CD133+ cells, excluding a role of these kinases in the regulation of HAS2. HAS2 is expressed only in freshly isolated CD133+ cells and quickly diminishes during differentiation. Because of this, HAS2 gene expression might be suitable as a new marker for CD133+ UCB-derived stem cells.