Altered Cellular Sedimentation during Apheresis Impacts Outcomes of Peripheral Blood Stem Cell Collection Efficiency in Patients with Sickle Cell Disease

Recent reports have demonstrated the potential for gene therapy as a therapeutic option to achieve a durable cure in patients with sickle cell disease (SCD). However, for these emerging cell therapies, relatively large numbers of peripheral blood hematopoietic stem cells (PB HSCs) are required to generate a therapeutic dose. Outcomes of stem cell collections in patients with SCD are highly variable, at times yielding far fewer numbers of HSCs in the product than predicted by the number of PB CD34+ cells. While the CXCR4 antagonist plerixafor has emerged as a safe and reliable drug to mobilize CD34+ cells in patients with SCD, collection failures continue to occur requiring additional cycles or failure to generate a gene therapy product. We sought to understand the mechanics affecting stem cell sedimentation in real time and posited that SCD disease associated changes to red cells results in altered HSC sedimentation during apheresis, negatively impacting collection.

Methods

Autologous PB stem cell collections were performed in patients with SCD following mobilization with 240ug/kg plerixafor. To uncover the mechanisms impacting apheresis efficiency for collecting PB HSCs, we devised a method to interrogate the sedimentation of cells in peripheral blood in real time, by interrupting the return collection circuit line. Cellular composition analyses of the collecting interfaces were performed including CD34+ enumeration by flow cytometry, CBC and differential, reticulocyte counts, and surface CD47 expression of red blood cells (RBCs).

Results

Patients were mobilized with 240ug/kg of plerixafor up to 6 hours before apheresis collection. We collected fewer cells than predicted (3.78 million cells/kg) in these patients with an overall average apheresis collection efficiency of 38%, and a strikingly wide range of 2%-107%. We determined that the lower collection efficiency outcomes were primarily derived when using standard apheresis interface settings. The pre-apheresis PB CD34+ counts were less predictive of total CD34+ cells collected (p=0.012) in patients with SCD (r²=0.2557, p=0.0023) when compared to historical control patients without SCD (r²=0.7638, p<0.0001). Real time measurement of cell counts at standard (Hematocrit 3%, S) and deep (Hematocrit 5%, D) collecting interfaces of the apheresis machine showed a significant decrease in lymphocytes (p=0.0146), increase in monocytes (p=0.0496), and increase enrichment in CD34+ cells at the D interface (Panel A). Enrichment of CD34+ cells correlated with monocyte enrichment and (n=21, r²=0.6706, p<0.0001) and an increased fold change in CD34+ cells between the S and D interfaces correlated with higher PB reticulocyte percentage (r²=0.5295, p=0.0111).

Further analysis of the individual collection interfaces revealed that most RBCs were HbS containing despite a PB HbS concentration <30%, consistent with an enrichment for shorter lived sickle red cells. CD47 expression has been previously reported in higher concentrations on the surface of younger RBCs during erythropoiesis. Surface expression of CD47 was found to be significantly higher at both the S and D interfaces compared to the PB of patients, indicating that the accumulation of a younger population of RBCs at the collecting interfaces. As microcytic RBCs have been associated with poor collection efficiencies, the SCD red cell hemoglobin concentration in the PB was used as a marker for size and a significant correlation was determined (r²=0.6086, p=0.0001).

Patients with SCD can mobilize PB HSC in response to plerixafor but demonstrate specific characteristics that impede the collection of stem cells. During apheresis, CD34+ stem cells sediment at a deeper hematocrit interface in the buffy coat as a result of displacement by the younger patient-derived population of RBCs. The relative shift in erythrocyte sedimentation requires a corresponding alteration in collection strategies to improve the collection efficiency. In addition to red cell age, other factors that affect red cell buoyancy including iron status or additional globin gene mutations negatively impact apheresis stem cell collections. Full assessment of red cell parameters can identify patients that are at risk for poor stem cell collection outcomes.

Esrick:bluebird bio: Consultancy, Other: Provides vector for trial. Heeney:FORMA Therapeutics: Consultancy; Novartis: Consultancy; Oric Pharmaceuticals: Consultancy; Bluebird Bio: Consultancy; Vertex/ Crisper Therapeutics: Consultancy. Williams:Bluebird: Consultancy, Other: Provides Vector; Orchard Therapeutics: Other: Provides vector; Novartis: Consultancy, Other: Steering Committee (fees donated to NAPAAC); Insertion Site Analysis Advisory Board, Bluebird Bio: Consultancy; Scientific Advisory Board, Beam Therapeutics: Consultancy; Chief Scientific Chair, Emerging Therapy Solutions: Consultancy; Scientific Advisory Board, Skyline Therapeutics: Consultancy; Insertion Site Advisory Board, Biomarin: Consultancy; Novartis: Other: Provision of study materials, medical writing. Manis:Terumo BCT Inc: Speakers Bureau.