Excessive T cell depletion of peripheral blood stem cells has an adverse effect upon outcome following allogeneic stem cell transplantation.

We evaluated the outcome of two modes of T cell depletion for HLA-identical sibling stem cell transplants in 34 consecutive adult patients: group A (n = 11) received PBSC post CliniMACs immuno-magnetic enrichment of CD34(+) cells and group B (n = 23) received bone marrow following in vitro incubation with CAMPATH-1M and complement. All patients received an identical conditioning regimen which consisted of in vivoCAMPATH-1H 20 mg over 5 days, thiotepa 10 mg/kg, cyclophosphamide 120 mg/kg and 14.4 Gy TBI. No additional graft-versus-host disease prophylaxis was given. The mean T cell dose administered was 0.02 +/- 0.05 x 10(6)/kg for group A and 2.8 +/- 2.8 10(6)/kg for group B (P < 0.001). With a median follow-up of 28 months overall survival was 36.4% for group A at 12 months compared to 78.3% for group B (P = 0.001). Transplant-related mortality in group A at 12 months was 63.6% as compared to 18.0% in group B (P = 0.003). Most of the procedure-related deaths in group A occurred secondary to infection. These results suggest that extensive in vitro T cell depletion of peripheral blood stem cells in combination with in vivo T cell depletion may have profound effects upon the incidence of infections following allogeneic stem cell transplantation and this may adversely effect transplant-related mortality.

Remobilization of patients who fail to achieve minimal progenitor thresholds at the first attempt is clinically worthwhile.

A significant proportion of previously treated patients fail to mobilize sufficient stem/progenitor cells to enable high-dose therapy and peripheral blood stem cell transplantation to be performed. In this study, the value of remobilizing such patients has been evaluated in 20 patients who all failed to achieve progenitor yields of 1 x 10(6)/kg CD34+ cells and 1 x 10(5)/kg granulocyte-monocyte colony-forming units (GM-CFCs) at the first attempt. Most patients remained relatively poor mobilizers at the second mobilization, but the yield of CD34+ cells and GM-CFCs on the first apheresis was significantly greater with the second mobilization than the first. A total yield (all aphereses from both mobilizations) of > 1 x 10(6)/kg CD34+ cells and > 1 x 10(5)/kg GM-CFCs was achieved in 14 out of 20 patients. Seven patients have received high-dose therapy with stem cell infusion; neutrophil recovery was rapid in all patients and platelet independence occurred in < 21 d in five out of seven patients. We conclude that remobilization is worth considering in those patients in whom a chemotherapy-free interval of several months is possible.

A clinically applicable method for the ex vivo generation of antigen-presenting cells from CD34+ progenitors.

BACKGROUND AND OBJECTIVES: Dendritic cells (DCs), the most potent of antigen-presenting cells, can be generated in vitro from bone marrow or blood progenitor cells. We have developed a method for producing such cells from mobilised peripheral blood CD34+ cells in the absence of bovine products. METHODS: The culture system developed used X-Vivo 10 culture medium with 10% autologous serum, rhGM-CSF, rhTNF-alpha and rhIL-4. Large-scale cultures were performed in Stericell 12 inch x 15 inch culture bags. RESULTS: In 12-small-scale experiments, over 14 days, there was a median 38-fold increase in cell numbers of which 12.8% were DCs as defined by immunophenotyping. These cells had potent DC activity in functional assays. In two clinical-scale experiments, a 5.7- and 10-fold expansion of total cell numbers was obtained, with 8.2 and 18% of the final population being DCs, respectively. CONCLUSION: This system is suitable for clinical application.

ESHAP and G-CSF is a superior blood stem cell mobilizing regimen compared to cyclophosphamide 1.5 g m(-2) and G-CSF for pre-treated lymphoma patients: a matched pairs analysis of 78 patients.

Cyclophosphamide 1.5 g m(-2) followed by granulocyte colony-stimulating factor (G-CSF) is an effective peripheral blood stem cell (PBSC) mobilizing regimen, but has limited anti-lymphoma activity. We therefore assessed the mobilizing potential of ESHAP (etoposide, ara-C, methylprednisolone and cisplatin), a potent second-line lymphoma regimen followed by G-CSF. The results were compared in 78 patients with relapsed or resistant lymphomas with the use of cyclophosphamide 1.5 g m(-2) followed by G-CSF in a matched pairs analysis, matching the ESHAP recipients (for predetermined prognostic factors) from a cohort of 178 lymphoma patients mobilized with cyclophosphamide and G-CSF. The total numbers of mononuclear cells collected at apheresis was similar with both regimens but ESHAP plus G-CSF resulted in a significantly higher percentage of CD34+ cells, absolute number of CD34+ cells and GM-CFC (all with P-values < 0.001). The number of patients requiring only one apheresis harvest to achieve a CD34+ cell yield of > 2.0 x 10(6) kg(-1) was greatly increased in the ESHAP recipients (56/78 vs 17/78, P < 0.001). The total number of progenitor cells collected was not significantly different with the two mobilization regimens because of this higher number of apheresis in the cyclophosphamide group. The proportion of patients who failed to achieve a minimum CD34+ cell target of 1 x 10(6) kg(-1) with the pooled harvests was less in the ESHAP arm (four patients vs nine patients) despite an increased number of aphereses in the cyclophosphamide recipients. ESHAP plus G-CSF is well tolerated and is an excellent mobilization regimen in patients with pre treated lymphoma.

Cord blood progenitor cells have greater transendothelial migratory activity and increased responses to SDF-1 and MIP-3beta compared with mobilized adult progenitor cells.

When cord blood is used as a source of haemopoietic stem cells for transplantation, fewer cells are required per kg of recipient. This greater engraftment efficiency of cord blood cells may relate to an increased ability to traverse sinusoidal endothelium, a crucial step in the homing of stem cells. We report that freshly isolated cord blood progenitors migrated more efficiently than mobilized adult cells. Cord blood progenitors responded rapidly to growth factor stimulation with an increase in migratory ability within 24 h whereas mobilized adult cells responded only after 72 h (P < 0.01). Cord blood cells also exited G0/G1 rapidly; after 24 h of growth factor exposure, 20.2 +/- 1.2% of cord blood CD34+ cells were in S + G2/M compared to 6.9 +/- 1.2% of adult CD34+ cells (P < 0.01). Proliferating CFC migrated more efficiently (13.3 +/- 3.4% for GM-CFC) than non-proliferating CFC (1.4 +/- 0.5%, P < 0.01) as determined using a 3H-thymidine suicide assay. Cord blood progenitor cells also demonstrated a greater transmigratory response to chemokine stimulation compared with adult cells; this was manifested as a differential response of freshly isolated cells to SDF-1, and of growth factor activated cells to MIP-3beta. Finally, cord blood CD34+ cells express higher levels of the chemokine receptor for SDF-1, CXCR4, when compared with mobilized adult CD34+ cells (P < 0. 05).

Optimal timing for collection of PBPC after glycosylated G-CSF administration.

Daily administration of granulocyte colony-stimulating Factor (G-CSF) results in progenitor cell mobilization with maximum blood levels achieved after 4-7 days. In this study the short-term effects of glycosylated G-CSF at a dose of 5 microg/kg s.c. were determined so as to allow optimization of the timing of progenitor cell collection. In the first study involving 20 normal volunteers, a significant fall in neutrophil count and G-CSF levels was observed 2 h after the G-CSF injection. To investigate this phenomenon serial measurements were made in a further six volunteers after the 6th daily injection of G-CSF. A fall in the neutrophil count occurred which was maximal at 1 h and recovered to baseline within 3 h. There was also a fall in CD34+ cells (P = 0.034), GM-CFC (P = 0.025) and BFU-E (P = 0.066) and recovery to baseline levels took 4-12 h. We conclude that glycosylated G-CSF should not be given immediately prior to stem cell collection.

Evaluation of clinical scale CD34+ cell purification: experience of 71 immunoaffinity column procedures.

Seventy-one mobilised PBSC collections were subject to CD34+ cell purification using the CEPRATE SC stem cell concentration system. The overall median purity of CD34+ cells was 69% (6-93%). CD34+ cell, and GM-CFC recoveries were 52% (8-107%) and 36% (3-118%). Purity was logarithmically related to the input percentage of CD34+ cells and starting requirements were established of 1% CD34 cell content for optimal purity and a minimum of 2 x 10(6)/kg CD34+ cells to ensure recovery of our minimum engraftment threshold of 1 x 10(6)/kg CD34+ cells. Reduction of the washing steps reduced non-specific cell losses and shortened the procedure but did not affect progenitor cell recovery. Purified CD34+ cells were reinfused following high-dose therapy in 35 patients. The median time to neutrophil recovery of 0.5 x 10(9)/l was 12 (10-23) days and to the attainment of platelet independence was 13 (7-100) days. The risks of delayed platelet recovery were related to the CD34+ cell dose infused and were identical to the risks when non-purified PBSC collections were used. In conclusion, purification of CD34+ cells using the CEPRATE device is reliable and the purified product results in prompt engraftment. The cell losses that occur do however restrict its use in many patients.