Efrat Landau

Umbilical cord blood expansion with nicotinamide provides long-term multilineage engraftment

BACKGROUND Delayed hematopoietic recovery is a major drawback of umbilical cord blood (UCB) transplantation. Transplantation of ex vivo-expanded UCB shortens time to hematopoietic recovery, but long-term, robust engraftment by the expanded unit has yet to be demonstrated. We tested the hypothesis that a UCB-derived cell product consisting of stem cells expanded for 21 days in the presence of nicotinamide and a noncultured T cell fraction (NiCord) can accelerate hematopoietic recovery and provide long-term engraftment. METHODS In a phase I trial, 11 adults with hematologic malignancies received myeloablative bone marrow conditioning followed by transplantation with NiCord and a second unmanipulated UCB unit. Safety, hematopoietic recovery, and donor engraftment were assessed and compared with historical controls. RESULTS No adverse events were attributable to the infusion of NiCord. Complete or partial neutrophil and T cell engraftment derived from NiCord was observed in 8 patients, and NiCord engraftment remained stable in all patients, with a median follow-up of 21 months. Two patients achieved long-term engraftment with the unmanipulated unit. Patients transplanted with NiCord achieved earlier median neutrophil recovery (13 vs. 25 days, P < 0.001) compared with that seen in historical controls. The 1-year overall and progression-free survival rates were 82% and 73%, respectively. CONCLUSION UCB-derived hematopoietic stem and progenitor cells expanded in the presence of nicotinamide and transplanted with a T cell-containing fraction contain both short-term and long-term repopulating cells. The results justify further study of NiCord transplantation as a single UCB graft. If long-term safety is confirmed, NiCord has the potential to broaden accessibility and reduce the toxicity of UCB transplantation. TRIAL REGISTRATION Clinicaltrials.gov NCT01221857. FUNDING Gamida Cell Ltd.

Cellular copper content modulates differentiation and self‐renewal in cultures of cord blood‐derived CD34+ cells

Summary.  Several clinical observations have suggested that copper (Cu) plays a role in regulating haematopoietic progenitor cell (HPC) development. To further study this role we used an ex vivo system. Cord blood‐derived CD34+ cells were cultured in liquid medium supplemented with Kit‐ ligand, FLt3, interleukin 6 (IL‐6), thrombopoietin and IL‐3. Under these conditions, Cu content, measured by atomic absorption, was 7 ng/107 cells. Modulation of intracellular Cu was achieved by supplementing the cultures with the Cu chelator tetraethylenepentamine, which reduced cellular Cu (4 ng/107 cells), or ceruloplasmin or Cu sulphate that elevated cellular Cu (18 and 14 ng/107 cells respectively). The results indicated that low Cu content delayed differentiation, as measured by the surface antigens CD34, CD14 and CD15, colony‐forming unit (CFU) frequency and cell morphology, while high Cu accelerated differentiation compared with Cu unmanipulated cultures. As a result, expansion of total cells, CFU and CD34+ cells in low Cu was extended (12–16 weeks), and in high Cu was shortened (2–4 weeks), compared with control cultures (6–8 weeks). These effects required modulation of intracellular Cu only during the first 1–3 weeks of the culture; the long‐term effects persisted thereafter, suggesting that the decision process for either self‐renewal or differentiation is taken early during the culture. This novel method of controlling cell proliferation and differentiation by copper and copper chelators might be utilized for ex vivo manipulation of HPC for various clinical applications.

Cohort-Controlled Comparison of Umbilical Cord Blood Transplantation Using Carlecortemcel-L, a Single Progenitor–Enriched Cord Blood, to Double Cord Blood Unit Transplantation

Umbilical cord blood (UCB) transplantation has a high early mortality rate primarily related to transplanted stem cell dose. To decrease early mortality and enhance engraftment, a portion of selected cord blood units (20% to 50%) was expanded with cytokines and the copper chelator tetraethylenepentamine (carlecortemcel-L) and transplanted with the unmanipulated fraction after myeloablative conditioning. The primary endpoint was 100-day survival, which was compared with a contemporaneous double-unit cord blood transplantation (DUCBT) group. We enrolled 101 patients at 25 sites; the DUCBT comparison (n = 295) was selected from international registries using study eligibility criteria. Baseline carlecortemcel-L study group unit nucleated cell (NC) and CD34+ were 3.06 × 107 cell dose/kg and 1.64 × 105 cell dose/kg. Median NC and CD34+ fold expansion were 400 and 77, with a mean total CD34 infused of 9.7 × 105/kg. The 100-day survival was 84.2% for the carlecortemcel-L study group versus 74.6% for the DUCBT group (odds ratio, .50; 95% CI, .26 to .95; P = .035). Survival at day 180 was similar for the 2 groups; the major cause of death after day 100 was opportunistic infections. Faster median neutrophil (21 days versus 28 days; P < .0001), and platelet (54 days versus 105 days; P = .008) engraftment was seen in the carlecortemcel-L study group; acute and chronic graft-versus-host disease rates were similar. In this multinational comparative study, transplanting expanded CD34+ stem cells from a portion of a single UCB unit, with the remaining unmanipulated fraction improved 100-day survival compared with DUCBT control patients while facilitating myeloid and platelet engraftment. This trial was registered at www.clinicaltrials.gov as #NCT00469729.