Abstract
Introduction: Transplantation of functional hematopoietic stem cells (HSC) using peripheral blood (PB), bone marrow (BM) or cord blood (CB) cells is widely used to treat malignant and nonmalignant disorders. Because long-term cryopreservation is performed for PB, BM and CB cells, and these are often used years after cell harvests, the implementation of a quality-assurance is a major requirement to ensure graft safety for clinical use.
Methods: We assessed the efficiency of recovery of viable HSC from 37 patients (pts; n=20 NHL, n=6 Hodgkin, n=9 MM, n=2 AML) and 6 allogeneic-donors (AD) with stored PBSC samples. All pts had received an auto-PBSCT between 1992–2004. Stored PBSC samples used in this analysis had been cryopreserved for a median of 5.6 years (y; range: 1.3–12). We determined post-thawing recovery, cell viability, ex vivo expansion potential, CD34+ numbers, CFU growth in methylcellulose culture and LTC-ICs. Viable cells were determined by trypan blue and propidium iodide via FACS analysis, CFUs in 0.9% methylcellulose (supplemented with IMDM, 30% FCS and EPO, IL-3+GM-CSF) and LTC-IC as previously described. Pts and AD were analyzed as a total group and within 3 subgroups of: A) ‘long-term’ cryopreservation: n=21 PBSC harvests had a median cryopreservation of 9.5y (8–12), B) ‘short-term’ cryopreservation: n=16 harvests had a 2.9y (1.3–5.6) cryopreservation period, and C) n=6 pts showing delayed engraftment (EG) or early death after auto-PBSCT: the cryopreservation in these 6 pts was 2.7y (2.2–3.5). Cryopreservation results were correlated with clinical results and EG.
Results: Hematopoietic EG in group A and B was prompt with WBC>1000/μl and platelets>20,000/μl on d10–11 post PBSC reinfusion. EG in group C was delayed albeit 4.3x106 CD34+ cells/kg bw (2.1–8.6) had been retransfused (WBC>1000/μl + platelets>20,000/μl: d+13 post PBSC infusion, non-platelet-EG >20,000/μl before death: n=5). Primary cause of death in group C was progressive disease in 3 and serious infections in 5 pts. Group A showed 74.3% viable cells post-thawing in PBSC grafts. Median number of CD34+ cells were 2.9%. Median numbers of CFU-C, BFU-E and GEMM were 36, 60 and 7, respectively. This was comparable with results in group B, showing 70% viable cells post-thawing, CD34+ cells of 4.2% and CFUs of 43, 75 and 6, respectively (p>0.05). Proliferative capacity was intact in both groups after 7 days of suspension culture, generating CFU-C, BFU-E and GEMM of 67, 29 and 1, respectively. In group C, viable cells were present in only 58% and median CFU-C, BFU-E and GEMM were 21, 5 and 0, respectively (p<0.05). After 7 days of suspension culture, total CFUs were 5 (<5% as compared to group A+B). Mean CFU-Cs before and after LTC-IC were 9 and 8 after LTC-IC culture in group C, whereas these were 18 and 16 in group A (p<0.05). Thus, the percentage of viable cells, CFUs and LTC-ICs was preserved after long-term cryopreservation (group A), showed no significant difference between group A+B, but were decreased in group C.
Conclusions: We show that human PBSC can be stored for more than a decade without apparent loss of HSC activity and can be efficiently retrieved. These results reinforce that expiration dates cannot be set for safely stored cryopreserved HSC. Assessment of CD34+ cell numbers, clonogenic potential via methylcellulose and LTC-IC assays are clinically relevant, since they may correlate with clinical outcome. Thus, these hematopoietic assays are valuable to assess the quality of cryopreservation and possibly also outcome of PBSCT.
Long term expansion of undifferentiated human iPS and ES cells in suspension culture using a defined medium