Stem cell mobilization in resistant or relapsed lymphoma: superior yield of progenitor cells following a salvage regimen comprising ifosphamide, etoposide and epirubicin compared to intermediate-dose cyclophosphamide

We analysed the factors influencing the efficacy of peripheral blood stem cell (PBSC) collection in patients with lymphoma. Sixty-six patients underwent initial PBSC collection following mobilization with chemotherapy plus recombinant granulocyte colony-stimulating factor (300 μg/d). Patients were mobilized with one of two chemotherapy regimens, either cyclophophamide (3 g/m² or 4 g/m²) (n=50) or ifosphamide, etoposide and epirubicin (IVE; n=16). The target of collecting >2.0×10⁶ CD34⁺ cells/kg was achieved in 43/66 (65%) patients with a median of two apheresis procedures. The IVE plus G-CSF mobilization regimen gave a significantly higher median yield of CD34⁺ cells (8.62 × 10⁶/kg) compared with cyclophosphamide plus G-CSF (3.59 × 10⁶/kg) (P=0.045). The median yield of CD34⁺ cells per leukapheresis was almost twice as high in patients receiving IVE (1.94 × 10⁶/kg) compared to cyclophosphamide (1.03 ×10⁶/kg) (P= 0.035). In a univariate analysis of the factors affecting mobilization, the subtype of lymphoma (high-grade NHL) and the mobilization regimen were the only factors associated with high CD34⁺ cell yield. However, in a multivariate analysis of factors affecting mobilization including age, lymphoma subtype, previous chemotherapy and radiotherapy, only the use of the IVE protocol was predictive of a high yield of CD34⁺ cells. In 13 patients undergoing a second mobilization procedure the use of IVE was associated with a significantly higher yield of CD34⁺ cells compared to cyclophosphamide; three patients who failed cyclophosphamide plus G-CSF mobilization were able to proceed to transplantation following success-ful mobilization with IVE + G-CSF. These results demon-strate that IVE is a highly effective mobilization regimen which is superior to cyclophophamide and has the benefit of being effective salvage therapy for lymphoma patients.     

Allogeneic transplantation using CD34+ selected peripheral blood progenitor cells combined with non‐mobilized donor T cells for refractory severe aplastic anaemia

Allogeneic haematopoietic stem cell transplantation is curative for severe aplastic anaemia (SAA ) unresponsive to immunosuppressive therapy. To reduce chronic graft‐versus‐host disease (GVHD ), which occurs more frequently after peripheral blood stem cell (PBSC ) transplantation compared to bone‐marrow transplantation (BMT ), and to prevent graft rejection, we developed a novel partial T‐cell depleted transplant that infuses high numbers of granulocyte colony‐stimulating factor‐mobilized CD 34⁺ selected PBSC s combined with a BMT ‐equivalent dose of non‐mobilized donor T‐cells. Fifteen patients with refractory SAA received cyclophosphamide, anti‐thymocyte globulin and fludarabine conditioning, and were transplanted with a median 8 × 10⁶ CD 34⁺ cells/kg and 2 × 10⁷ non‐mobilized CD 3⁺ T‐cells/kg from human leucocyte antigen‐matched sibling donors. All achieved sustained engraftment with only two developing acute and two developing chronic GVHD . With a 3·5‐year median follow‐up, 86% of patients survived and were transfusion‐independent. When compared to a retrospective cohort of 56 bone‐marrow failure patients that received the identical transplant preparative regimen and GVHD prophylaxis with the exception that the allograft contained unmanipulated PBSC s, partial T‐cell depleted transplant recipients had delayed donor T‐cell chimerism and relative reduction of 75% in the incidence of acute grade II ‐IV GVHD (13% vs. 52%; P  =  0·010) and of 82% in chronic GVHD (13% vs. 72%; P  =  0·0004). In multivariate analysis, partial T‐cell depleted transplants remained significantly associated with a reduced risk of GVHD . In conclusion, for patients with refractory SAA , this novel transplant strategy achieves excellent engraftment and survival when compared to unmanipulated PBSC transplants and dramatically reduces the incidence of both acute and chronic GVHD .     

CD133 allows elaborated discrimination and quantification of haematopoietic progenitor subsets in human haematopoietic stem cell transplants

The success of haematopoietic stem cell (HSC) transplantation largely depends on numbers of transplanted HSCs, which reside in the CD34⁺ populations of bone marrow (BM), peripheral blood stem cells (PBSC) and umbilical cord blood (UCB). More specifically HSCs reside in the CD38^low/? subpopulation, which cannot be objectively discriminated from mature CD34⁺ CD38⁺ progenitors. Thus, better marker combinations for the quantification of more primitive haematopoietic stem and progenitor cells in transplants are required. Recently, by combining CD34 and CD133 we could clearly distinguish CD133⁺ CD34⁺ multipotent and lympho‐myeloid from CD133^low CD34⁺ erythro‐myeloid progenitors in UCB samples. To qualify the assessment of CD133 for routine quality control of adult HSC sources, we analysed the developmental potentials of CD133⁺ and CD133^low subpopulations in BM and PBSC. Similar to UCB, CD133 expression objectively discriminated functionally distinct subpopulations in adult HSC sources. By implementing anti‐CD45RA staining, which separates multipotent (CD133⁺ CD34⁺ CD45RA^?) from lympho‐myeloid (CD133⁺ CD34⁺ CD45RA⁺) progenitor fractions, UCB was found to contain 2–3 times higher multipotent progenitor frequencies than BM and PBSC. To test for the consistency of CD133 expression, we compared CD133⁺ CD34⁺ contents of 128 UCB samples with maternal and obstetrical factors and obtained similar correlations to related studies focusing on CD34⁺ cell contents. In conclusion, implementation of anti‐CD133 staining into existing routine panels will improve the quality control analyses for HSC transplants.     

Plerixafor on‐demand combined with chemotherapy and granulocyte colony‐stimulating factor: significant improvement in peripheral blood stem cells mobilization and harvest with no increase in costs

To date, no prospective study on Plerixafor ‘on‐demand’ in combination with chemotherapy and granulocyte colony‐stimulating factor (G‐CSF) has been reported. We present an interim analysis of the first prospective study in which Plerixafor was administered on‐demand in patients affected by multiple myeloma and lymphoma who received high dose cyclophosphamide or DHAP (dexamethasone, cytarabine, cisplatin) plus G‐CSF to mobilize peripheral blood stem cells (PBSC). One hundred and two patients were evaluable for response. A cohort of 240 patients receiving the same mobilizing chemotherapy was retrospectively studied. Failure to mobilize CD34⁺ cells in peripheral blood was reduced by ‘on‐demand’ strategy compared to conventional mobilization; from 13·0 to 3·0% (P = 0·004). Failure to harvest CD34⁺ cells 2 × 10⁶/kg decreased from 20·9 to 4·0% (P = 0·0001). The on‐demand Plerixafor strategy also resulted in a lower rate of mobilization failure (P = 0·03) and harvest failure (P = 0·0008) when compared to a ‘bias‐adjusted set of controls’. Evaluation of economic costs of the two strategies showed that the overall cost of the two treatments were comparable when salvage mobilizations were taken into account. When in combination with cyclophosphamide or DHAP plus G‐CSF, the ‘on‐demand’ use of Plerixafor showed, in comparison to conventionally treated patients, a significant improvement in mobilization of PBSC with no increase in overall cost.     

Chemomobilization with high‐dose etoposide and G‐CSF results in effective and safe stem cell collection in heavily pretreated lymphoma patients: report from a single institution study and review

The optimal mobilization strategy prior to autologous stem cell transplantation (auto‐SCT) for patients with lymphoma is yet to be determined. We reviewed our institutional experience using chemomobilization with high‐dose (HD) etoposide (1.6 g/m²) and G‐CSF (300 μg/day) in 79 patients with lymphoma. The majority (76%) had received at least two prior regimens of chemotherapy, and 12 (15.2%) patients had previously failed to mobilize following HD cyclophosphamide or DHAP or ICE with G‐CSF. HD etoposide and G‐CSF chemomobilization resulted in successful collection (>2 × 10⁶ CD34+ cells/kg) in 82.3% of patients within a median 2 (1–6) apheresis days. Patients had stem cells collected between days +8 and +15, with a median +12 day. Median total CD34+ cells/kg collected was 5.95 × 10⁶ (0.1–36.8). Seventy‐one percent of patients yielded >2 × 10⁶ CD34+ cells/kg in ≤2 d of apheresis and were defined as good mobilizers. While median CD34+ cells/kg collected for good mobilizers was 7.6 × 10⁶, it was 2.6 × 10⁶ for poor mobilizers (P < 0.001). This regimen was safe with a low rate of febrile neutropenia (7.6%) and acceptable rates of RBC (40.5%) and platelet transfusions (22.8%). Hematopoietic recovery after auto‐SCT was achieved on expected time. Therapy‐related myelodysplastic syndrome/acute myeloid leukemia occurred in only one patient (1.3%) with in a median follow‐up of 16 months after chemomobilization. We conclude that HD etoposide and G‐CSF chemomobilization appear to result in effective, tolerable, and safe stem cell collection in the majority of heavily pretreated lymphoma patients.     

Haemopoietic defect and decreased expansion potential of bone marrow autografts from patients with acute myeloid leukaemia in first remission

Autologous bone marrow (BM) transplantation for acute myeloid leukaemia (AML) in complete remission (CR) is frequently followed by a slow haemopoietic recovery. We assessed the haemopoietic capacity of purified BM stem cell (CD34⁺DR^?) and progenitor cell (CD34⁺DR⁺) populations from patients with AML in CR, and compared these data with those of normal BM. The feasibility of ex vivo expansion in stroma-conditioned medium supplemented with cytokines was also investigated. The number of CFU-GM produced by initial patient CD34⁺DR^? cells was decreased compared to normal, whereas these values were similar to normal for CD34⁺DR⁺ cells. BFU-E, HPP-CFC and LTC-IC were reduced for both patient CD34⁺DR^? and CD34⁺DR⁺ subpopulations. In contrast to normal, the patient CD34⁺DR^? fraction was not enriched in LTC-IC. CFU-GM expansion from patient CD34⁺DR^? cells was poor and decreased after 14 d of culture. No HPP-CFC expansion could be observed for patient cells. LTC-IC were below the level of detection after 14–21 d of expansion culture of CD34⁺DR^? patient cells, whereas they were variably maintained or expanded for normal cells. After expansion culture, cytogenetic and/or FISH analyses did not reveal the anomalies present at diagnosis, regardless of the cell subpopulation analysed. In conclusion, BM cells of patients with AML in CR show a profound defect at the level of a stem cell enriched population. No meaningful ex vivo expansion could be obtained in culture conditions allowing for a significant expansion from a normal stem cell population.     

Infections after CD34-selected or unmanipulated autologous hematopoietic stem cell transplantation

Immune reconstitution may be delayed after CD34-selected compared with unmanipulated autologous peripheral blood stem cell transplantation (PBSCT), resulting in a theoretically increased risk of infections. In a case-control matched study we compared the incidence of infection in 25 recipients of CD34-selected PBSC (CD34 group) and 75 recipients of unmanipulated PBSC (PBSC group) transplants. The population included 52 males and 48 females suffering from non-Hodgkin's lymphoma (n = 32), Hodgkin's disease (n = 8), multiple myeloma (n = 40) or breast cancer (n = 20). Neutrophil engraftment was comparable in the two groups. The actuarial incidence of infection was similar in the two groups (56% vs. 49% at day 30, and 70% vs. 64% at 1 yr respectively). The proportion of patients with 1, 2 or 3 infections, the number of infectious event per patient (1.32 vs. 1.04; NS), the number of infections before day 15 or 30, between days 31 and 100 or after day 100, the risk of varicella-zoster virus or cytomegalovirus infection or disease, or the use of antibiotic or antifungal therapy, were not increased in the CD34 compared with the PBSC group. The main agents responsible for infection were bacteria, particularly gram-positive cocci, in both groups. Bacteremia accounted for 33% of all infectious events in the CD34 group vs. 16% in the PBSC group (P < 0.05). Fungal infections were rare. In conclusion, our results do not support the notion that CD34-selection of the graft is associated with an increased rate of infection after autologous PBSC transplantation. The role of extended infection prophylaxis should be evaluated.     

Bone marrow characterization in sickle cell disease: inflammation and stress erythropoiesis lead to suboptimal CD34 recovery

Stress erythropoiesis and chronic inflammation in subjects with sickle cell disease (SCD) may have an impact on the bone marrow (BM) haematopoietic stem and progenitor cell (HSPC) quality and yield necessary for effective autologous, ex vivo HSPC gene therapy. BM from 19 subjects with SCD and five volunteers without SCD (non-SCD) was collected in different anticoagulants and processed immediately (day 0) or the following day (day 1). Inflammatory, contamination and aggregation markers within the mononuclear layer, and CD34, CD45 and Glycophorin-A (GPA) expression on HSPCs after CD34⁺ selection were analysed by conventional and imaging flow cytometry. Compared to non-SCD BM, multiple markers of inflammation, contamination (red cells, P < 0·01; platelets, P < 0·01) and aggregates (platelet/granulocytes, P < 0·01; mononuclear/red cells, P < 0·01) were higher in SCD BM. Total CD34⁺ cell count was lower in SCD BM (P < 0·05), however CD34⁺ count was higher in SCD BM when collected in acid citrate dextrose-A (ACDA) versus heparin (P < 0·05). Greater than 50% of CD34⁺ HSPCs from SCD BM are CD34^dim due to higher erythroid lineage expression (P < 0·01) as single cell CD34⁺CD45⁺GPA⁺ (P < 0·01) and CD34⁺CD45⁻GPA⁺ (P < 0·01) HSPCs. SCD BM is characterized by increased inflammation, aggregation and contamination contributing to significant differences in HSPC quality and yield compared to non-SCD BM.     

Characterization of CD34+ peripheral blood cells from healthy adults mobilized by recombinant human granulocyte colony-stimulating factor

Primed peripheral blood hematopoietic stem cells (PBSC) generate and sustain lymphohematopoiesis in myeloablated animals, and recent reports indicate that allogeneic transplantation using PBSC grafts may be feasible in humans. A major concern with the use of PBSC transplants is that permanent engraftment may be limited because of lack of sufficient numbers of primitive progenitor cells in the graft. In the present study, in vitro colony formation and immunophenotype of CD34+ cells in PB of healthy adults during short-term granulocyte colony-stimulating factor (G-CSF) administration were compared with that of CD34+ cells in normal bone marrow (BM). The number of CD34+ cells mobilized to PB peaked at day 4 or 5 of G-CSF administration. The phenotypic profile of CD34+ PB cells showed a substantial increase in the percentage of CD34+CD13+ and CD34+CD33+ cells (myeloid progenitors) and a corresponding decrease in the percentage of CD34+CD10+ and CD34+CD19+ cells (B lymphoid progenitors) compared with CD34+ BM cells. The other subsets studied, including CD34+CD38- and CD34+HLA-DR- cells, were present in both compartments in similar proportions. Furthermore, primed CD34+ PB cells were enriched for colony-forming cells (CFC) and displayed an increased clonogenicity when compared with their counterparts in BM. A comparison between a postulated PBSC graft and an average BM graft is presented, showing that such PBSC grafts will be enriched for CD34+ cells as a whole, CD34+CD33+ cells, and colony- forming cells (CFC), factors which have been shown to correlate to acceleration of hematologic reconstitution and reduction in requirements for supportive care in autografting. Hence, we predict that allogeneic transplantation using G-CSF-primed PBSC grafts will result in a more rapid hematologic reconstitution after myeloablative conditioning than BM grafting. The question of whether PBSC allografting will result in permanent engraftment and clinical benefits as observed in autografting has to be determined in prospective clinical studies.     

Immune reconstitution after purified autologous and allogeneic blood stem cell transplantation compared with unmanipulated bone marrow transplantation in children

Immune reconstitution is critical for the long-term success of haematopoietic stem cell transplantation (HSCT). We prospectively analysed immune reconstitution parameters after transplantation of autologous (group 1; n = 10) and allogeneic (group 2; n = 12) highly purified CD34+ peripheral blood stem cells (PBSC) and unmanipulated allogeneic bone marrow (BM) (group 3; n = 9) in children. Median follow-up after HSCT was 56 (group 1), 61 (group 2), and 40.5 months (group 3). Median CD34-cell dose transplanted in the three groups was 9.4 x 10(6)/kg, 20.3 x 10(6)/kg, and 4.25 x 10(6)/kg recipient's body weight (BW) respectively. Complete haematopoietic engraftment was seen in all patients without any significant differences between the three groups. T-cell reconstitution at 6 months was significantly delayed in autologous peripheral blood stem cell transplantation (PBSCT) compared with allogeneic BM transplantation (P < 0.028) and allogeneic PBSCT (P < 0.034). At 3 months after transplantation numbers of CD56+/3- natural killer cells were higher in the allogeneic PBSC group (P < 0.01) compared with the BM group. The numbers of proven bacterial and viral infections were equally distributed between the three groups. In conclusion, recipients of allogeneic highly purified CD34+ PBSC or unmanipulated BM have higher lymphocyte subset counts at 6 months after transplantation than recipients of autologous CD34-selected PBSC. Infection rates and outcome, however, were not significantly different.     

Re‐evaluation of progenitor thresholds and expectations for haematopoietic recovery based on an analysis of 810 autologous transplants: Implications for quality assurance

Haematological engraftment was assessed in 804 autologous transplants. Neutrophil recovery occurred in over 99% within 14 d but platelet recovery was delayed beyond this time in 14·8%. Time to recovery was dependent on the progenitor cell dose infused. The minimum CD34⁺ cell threshold adopted in this study (2 × 10⁶/kg) was safe although recovery was faster with a dose >5 × 10⁶/kg. CD34⁺ cell doses of between 1 and 2 × 10⁶/kg were also acceptable if either the granulocyte‐macrophage colony‐forming cell dose exceeded 2 × 10⁵/kg or this dose was due to splitting a higher yield harvest. Prompt neutrophil recovery affords important quality assurance for laboratory processing.     

Mobilizing peripheral blood stem cells with high-dose G-CSF alone is as effective as with Dexa-BEAM plus G-CSF in lymphoma patients

We compared retrospectively the efficacy of granulocyte colony stimulating factor (G-CSF) alone with chemotherapy plus G-CSF in mobilizing CD34-positive cells in patients with malignant lymphoma. 35 patients underwent peripheral blood stem cell (PBSC) collection following mobilization either with 24 μg/kg G-CSF for 4 consecutive days (n = 18) or Dexa-BEAM chemotherapy plus 5 μg/kg G-CSF (n = 17). High-dose G-CSF was well tolerated with only slight bone pain and/or myalgia. The Dexa-BEAM therapy required hospitalization with a median duration of 21 d. The median number of apheresis procedures in both groups was two (range two to four), resulting in a median of 5.3 and 5.1 × 10⁶ CD34⁺ cells/kg. No patients in the G-CSF group, but one in the Dexa-BEAM group, failed to reach the target of collecting >2.0 × 10⁶ CD34⁺ cells/kg. The number of CFU-GM (10.4 v 6.0 × 10⁵/kg) and of BFU-E (10.6 v 4.5 × 10⁵/kg; P = 0.04) was higher in the G-CSF group than in the Dexa-BEAM group. A subset analysis of CD34⁺ cells was performed in 16 patients showing a higher mean of Thy-1 (CD90w) coexpression in the G-CSF than in the Dexa-BEAM group (4.8 v 1.8%, P = 0.12). Additionally the percentage of CD34⁺/CD38^? cells was higher in the G-CSF group (10.6% v 8.8%). However, these differences were not stastistically significant. The median time to leucocyte and platelet engraftment after high-dose chemotherapy was slightly shorter in the G-CSF than in the Dexa-BEAM group (9 v 10 and 12 v 13.5 d, respectively). These results demonstrate that high-dose G-CSF is as effective as Dexa-BEAM plus G-CSF in mobilizing peripheral blood stem cells and produces prompt engraftment. The major advantages of G-CSF mobilization were the safe outpatient self-application and the fixed-day apheresis.     

T cell depletion utilizing CD34(+) stem cell selection and CD3(+) addback from unrelated adult donors in paediatric allogeneic stem cell transplantation recipients

CD34‐selected haploidentical and unrelated donor allogeneic stem cell transplantation (AlloSCT) in paediatric recipients is associated with sustained engraftment and low risk of acute graft‐versus‐host disease (aGVHD), but limited by delayed immune reconstitution and increased risk of viral and fungal infection. The optimal dose of donor T cells to prevent graft failure and minimize risk of early opportunistic infection and post‐transplant lymphoproliferative disorder (PTLD), while avoiding severe aGVHD, remains unknown. We prospectively studied CD34‐selected 8–10/10 human leucocyte antigen (HLA)‐matched unrelated donor (MUD) peripheral blood stem cell transplantation (PBSCT) in a cohort of 19 paediatric AlloSCT recipients with malignant (n = 13) or non‐malignant (n = 6) diseases. T cells were added back to achieve total dose 1·0–2·5 × 10⁵ CD3⁺/kg. GVHD pharmacoprophylaxis consisted only of tacrolimus. All patients engrafted neutrophils. Probabilities of grade II–IV aGVHD, limited chronic GVHD (cGVHD), and extensive cGVHD were 15·8%, 23·3%, and 0%, respectively. One patient developed PTLD. One‐year infection‐related mortality was 5·6%. T cell immune reconstitution was delayed. One‐year overall survival was 82·3%. Five patients with malignant disease ultimately died from progressive disease. CD34‐selected MUD PBSCT using a defined dose of T cell add‐back resulted in high rates of engraftment and low risk of grade II–IV aGVHD, early transplantation‐related mortality, and extensive cGVHD.     

Mobilized peripheral blood stem cells compared with bone marrow from HLA-identical siblings for reduced-intensity conditioning transplantation in acute myeloid leukemia in complete remission: a retrospective analysis from the Acute Leukemia Working Party of EBMT

Reduced‐intensity conditioning (RIC)‐alloSCT is increasingly used for acute myelogenous leukemia. Limited data are available for the comparison of peripheral blood stem cells with bone marrow for RIC‐alloSCT. We used the European Group for Blood and Marrow Transplantation (EBMT) ALWP data to compare the outcome of mobilized peripheral blood stem cells (PBSC) (n = 1430) vs. bone marrow (BM) (n = 107) for acute myelogenous leukemia (AML) patients with complete remission that underwent RIC‐alloSCT from compatible sibling donors. The leukemia features, the disease status, and the time from diagnosis were similar between the two groups. Engraftment was achieved in 99% and 93% in the PBSC and BM groups, respectively (P < 0.0001). The day of engraftment was significantly earlier for the PBSC vs. the BM group, 15 (1–59) and 19 (5–69), respectively (P < 0.001). Acute GVHD, severe GVHD (grade III–IV) and chronic GVHD did not differ between the groups. leukemia‐free survival (LFS), relapse, and non‐relapsed mortality (NRM) were 51 ± 2%, 32 ± 1%, and 17 ± 1% vs. 50 ± 6%, 38 ± 6%, and 12 ± 3% for the PBSC and BM groups, respectively. Our results indicate faster engraftment, but no difference in GVHD, LFS, relapse, and NRM when comparing PBSC to BM grafts from sibling donors following RIC conditioning. This is the first study comparing PBSC to BM grafts in the RIC setting, analyzing a homogeneous population of patients with AML in remission. Whether PBSC should be preferred for advanced phases of the disease, where the outcome is dominated by relapse incidences, needs further investigation.     

CD34+ selected stem cell boosts can improve poor graft function after paediatric allogeneic stem cell transplantation

Poor graft function (PGF) is a severe complication of haematopoietic stem cell transplantation (HSCT) and administration of donor stem cell boosts (SCBs) represents a therapeutic option. We report 50 paediatric patients with PGF who received 61 boosts with CD34⁺ selected peripheral blood stem cells (PBSC) after transplantation from matched unrelated (n = 25) or mismatched related (n = 25) donors. Within 8 weeks, a significant increase in median neutrophil counts (0·6 vs. 1·516 × 10⁹/l, P < 0·05) and a decrease in red blood cell and platelet transfusion requirement (median frequencies 1 and 7 vs. 0, P < 0·0001 and <0·001), were observed, and 78·8% of patients resolved one or two of their cytopenias. 36·5% had a complete haematological response. Median lymphocyte counts for CD3⁺, CD3⁺CD4⁺, CD19⁺ and CD56⁺ increased 8·3‐, 14·2‐, 22.‐ and 1·6‐fold. The rate of de novo acute graft‐versus‐host disease (GvHD) grade I–III was only 6% and resolved completely. No GvHD grade IV or chronic GvHD occurred. Patients who responded to SCB displayed a trend toward better overall survival (OS) (P = 0·07). Thus, administration of CD34⁺ selected SCBs from alternative donors is safe and effective. Further studies are warranted to clarify the impact on immune reconstitution and survival.     

Temporal definition of haematopoietic stem cell niches in a large animal model of in utero stem cell transplantation

The fetal sheep model has served as a biologically relevant and translational model to study in utero haematopoietic stem cell transplantation (IUHSCT), yet little is known about the ontogeny of the bone marrow (BM) niches in this model. Because the BMmicroenvironment plays a critical role in the outcome of haematopoietic engraftment, we have established the correlation between the fetal‐sheep and fetal‐human BM niche ontogeny, so that studies addressing the role of niche development at the time of IUHSCT could be accurately performed. Immunofluorescence confocal microscopic analysis of sheep fetal bone from gestational days (gd) 25–68 showed that the BM microenvironment commences development with formation of the vascular niche between 25 and 36 gd in sheep; correlating with the events at 10–11 gestational weeks (gw) in humans. Subsequently, between 45 and 51 gd in sheep (c. 14 gw in humans), the osteoblastic/endosteal niche started developing, the presence of CD34⁺ CD45⁺ cells were promptly detected, and their number increased with gestational age. IUHSCT, performed in sheep at 45 and 65 gd, showed significant haematopoietic engraftment only at the later time point, indicating that a fully functional BM microenvironment improved engraftment. These studies show that sheep niche ontogeny closely parallels human, validating this model for investigating niche influence/manipulation in IUHSCT engraftment.     

G-CSF-mobilized peripheral blood progenitor cells for allogeneic transplantation: safety,kinetics of mobilization,and composition of the graft

Allogeneic transplantation of peripheral blood progenitor cells (PBPC) markes the general anaesthesia of the donor unnecessary and may result in more rapid engraftment and faster recovery of the immune system. We have studied G-CSF-mediated PBPC mobilization in healthy donors and analysed the cellular composition of the resulting PBPC grafts. PBPC grafts were obtained from nine healthy donors (18-67 years old) for allogeneic or syngeneic transplantation. Six donors received 10 μg/kg G-CSF per day, the others 5-6 μg/kg. Mobilization and harvesting were well tolerated except for moderate bone pain which occurred in all donors primed with 10 μg/kg. With 10 μg/kg, a 31-fold (9-62) enrichment of circulating CD34⁺ cells was observed with peak values constantly occurring on day 5 after the start of G-CSF administration. Starting harvest on day 5, one to three collections on consecutive days yielded 5.5 x 10⁶/kg (0.9-10.7) CD34⁺ cells, 219 x 10⁶/kg (106–314) T cells, and 34 x 10⁶/kg (23–67) NK cells per 10 litres leukapheresis volume. Altogether, PBPC grafts contained 3 times more CD34⁺ cells, 7 times more T cells, and 20 times more NK cells than five allogeneic marrow grafts that were analysed for comparison. The yield of CD34⁺ cells per 10 litres apheresis volume as well as the height of the CD34⁺ peak in peripheral blood were inversely correlated to the age of the donor. In the donors primed with 5–6μg/kg G-CSF the increase of circulating CD34⁺ cells (4–7-fold enrichment) and the CD34⁺ cell yield per 10 litres leukapheresis volume (1 x 10⁶/kg [0.8-2-2]) was much smaller compared with the 10μg/kg group. In conclusion, sufficient amounts of PBPC capable of restoring haemopoiesis in allogeneic recipients can be mobilized safely by administration of G-CSF (10 μg/kg s.c. for 5 d) in healthy donors, and harvested with one or two leukapheresis procedures. Whether the large numbers of T-cells and NK cells that are contained in the collection products may influence graft-versus-host and graft-versus-leukaemia reactivities of PBPC grafts remains to be determined.     

Peripheral Blood Progenitor Cell Transplantation

Abstract: Peripheral blood progenitor cells (PBPCs) have become increasingly popular over the last 15 years as the source of hematopoietic stem cells for transplantation. In the early 1990s, PBPCs replaced bone marrow (BM) as the preferred source of autologous stem cells, and recently the same phenomenon is seen in the allogeneic setting. Under steady‐state conditions, the concentration of PBPCs (as defined by CFU‐GM and/or CD34+ cells) is very low, and techniques were developed to increase markedly this concentration. Such mobilization techniques include daily injections of filgrastim (G‐CSF) or a combination of chemotherapy and growth factors. Leukapheresis procedures allow the collection of large numbers of circulating white blood cells (and PBPCs). One or two leukapheresis procedures are often sufficient to obtain the minimum number of CD34+ cells considered necessary for prompt and consistent engraftment (i.e., 2.5–5.0 × 10⁶/kg). As compared to BM, autologous transplants with PBPCs lead to faster hematologic recovery and have few, if any, disadvantages. In the allogeneic arena, PBPCs also result in faster engraftment, but at a somewhat higher cost of chronic graft‐versus‐host disease (GvHD). This may be a double‐edged sword leading to both increased graft‐versus‐tumor effects and increased morbidity. The rapid advances in the study of hematopoietic, and even earlier, stem cells will continue to shape the future of PBPC transplantation.     

Retroviral gene transfer into cord blood stem/progenitor cells using purified vector stocks

Cord blood (CB) progenitor/stem cells (P/SC) are ideal targets for early gene therapy in individuals prenatally diagnosed with genetic disorders. Most retroviral transduction protocols were developed using adult peripheral blood stem cells (PBSC) and bone marrow (BM). Less is known about retroviral transduction of CB P/SC. We examined how timing, multiplicity of infection (MOI), and polycations in the transduction media affect transduction efficiency. Rates of transduction were determined in recently isolated CD34⁺ enriched CB cells and in colonies derived after various times in liquid cultures (LC). CB mononuclear cells (MNC) were separated by ficoll-hypaque centrifugation and enriched for CD34⁺ cells. Purity was assessed by flow cytometry. Transduction were performed with clinical-grade retroviral stocks at MOIs of 1–20. Transduction was performed with fetal bovine serum (FBS) or autologous plasma, IL-3, GM-CSF, IL-6, and SCF. The retroviral vector contained LacZ and neomycin resistance (neo) reporter genes. Transduction was determined by X-gal stain and by PCR amplification of the reporter genes. No drug selection was used. Twenty-five experiments were done. CB volumes ranged from 35–150 ml. MNC and CD34⁺ cell counts ranges were: 0.14–840 × 10⁶ and 0.1–4.2 × 10⁶, respectively. Transduction efficiency in liquid cultures ranged from 4–63%. Higher rates were seen using MOI ≥ 10, 2 μg/ml polybrene, and 10% autologous CB plasma. In colonies, transduction rates were 63 to 72% by PCR and 32% by X-gal staining. In LTC-IC derived colonies, transduction was 7% by PCR. Short incubations of CD34⁺ CB cells with purified retroviral stocks, polybrene, and autologous sera result in high transduction rates of committed progenitors and moderately low efficiencies of transduction of LTC-IC in the absence of drug selection. Am. J. Hematol. 57:16–23, 1998. © 1998 Wiley-Liss, Inc.