Effects of cell concentration, time of fresh storage, and cryopreservation on peripheral blood stem cells: PBSC fresh storage and cryopreservation

Stability of Jurkat cells during short-term liquid storage analyzed by flow imaging microscopy

The viability of cell-based medicinal products (CBMPs) is a critical quality attribute and must be assessed throughout the product lifecycle to contribute to a safe and potent drug product. In this study, we investigated the impact of short-term liquid storage conditions, encountered during manufacturing of CBMPs, such as holding times outside cell culture conditions and medium composition, on cell viability. As a model for T cells Jurkat cells were used and stored in different storage media for up to 24 h outside a freezer and outside of cell culture conditions. The effect of storage in different storage media, i.e., cell culture medium or phosphate buffered saline (PBS), dimethyl sulfoxide (DMSO) at different storage temperatures as well as the impact of pH on the cell viability was assessed. The viability of the cells was assessed by (i) flow cytometry with an Annexin V and CalceinAM staining or (ii) machine learning tools, leveraging the morphological information of flow imaging microscopy images. Cell images obtained by flow imaging microscopy were analyzed with both the ParticleSentryAI imaging software and a convolutional neural network (CNN) for fast and semi-automated viability assessment. Throughout storage conditions similar to those during processing of CBMPs, a decrease in cell viability was observed over time for all conditions based on Annexin V and CalceinAM staining. Additionally, we observed a damaging effect of DMSO over time, whereas this effect was more pronounced at room temperature compared to refrigerated temperatures. The ParticleSentryAI software was useful to detect qualitative differences in the cell viability as a shift towards non-viable cells could be observed throughout storage based on flow imaging microscopy images without prior sample preparation. Viability determination based on the CNN underestimated cell viability when compared to the flow cytometry assays, however the same trends were determined. In summary, non-frozen storage of CBMPs should be kept to a minimum. However, standing times throughout the manufacturing of CBMPs as well as during in-use cannot be completely avoided and therefore, the optimal storage conditions have to be carefully evaluated. Additionally, further analytical development is needed to implement machine learning tools suitable for reliable viability quantification without additional sample preparation such as staining.

Pros and Cons of Cryopreserving Allogeneic Stem Cell Products

The COVID-19 pandemic has precipitously changed the practice of transplanting fresh allografts. The safety measures adopted during the pandemic prompted the near-universal graft cryopreservation. However, the influence of cryopreserving allogeneic grafts on long-term transplant outcomes has emerged only in the most recent literature. In this review, the basic principles of cell cryopreservation are revised and the effects of cryopreservation on the different graft components are carefully reexamined. Finally, a literature revision on studies comparing transplant outcomes in patients receiving cryopreserved and fresh grafts is illustrated.

Liquid Storage of Peripheral Blood Stem Cell Products: Effects of Time and Temperature on Product Quality

Unrelated donor peripheral blood stem cell (PBSC) products often require transport to distant locations, which may take up to 72 hours. Temperature is an important variable that can be controlled during PBSC storage or transport; therefore, we studied the impact of temperature on prolonged storage of clinical-grade, mobilized PBSC products. PBSC products were collected by apheresis from 3 granulocyte colony-stimulating factor-mobilized donors, split into 2 PVC blood bags of equal volume, and stored at room temperature (RT) (18°C to 25 ºC) or 4 °C (2°C to 8 ºC) for 96 hours. Samples were obtained at 24-hour intervals for pH, cell counts, flow cytometry phenotyping and viability (7AAD), and hematopoietic colony-forming units (CFU). Starting PBSC products contained 52, 65, and 38 × 109 total nucleated cells (TNCs), with cell concentrations of 125, 263, and 94.6 × 106 TNCs/mL, respectively. Product pH dropped during storage, with significantly lower values for RT stored products than for 4 ºC stored products, and was greatest in the product with the highest TNC count. The percent recovery of viable CD34+ progenitor cells, CD3+ T cells, CD4+ T helper cells, CD8+ cytotoxic T cells, CD19+ B cells, CD15+ granulocytes, CD14+ monocytes, and CD16+/56+ natural killer (NK) cells all decreased over 96 hours but decreased more dramatically in the RT group. Cell recovery differences were statistically significant at most time points for all cell populations except CD15+ granulocytes. For CD34+ cells stored at 4 °C, mean recovery from prestorage values were 97 ± 3% at 24 hours, 87 ± 4% at 48 hours, 88 ± 10% at 72 hours, and 78 ± 1% at 96 hours, compared to RT product values of 45 ± 11%, 19 ± 19%, 2 ± 2%, and 0 ± 0%, respectively. CFUs were well preserved through 96 hours at 4 ºC but not at RT. During PBSC storage, pH and content of viable CD34+ cells, T cells, B cells, monocytes, NK cells, and CFU all declined. However, at 4 ºC, viable cell recoveries are relatively well preserved, even at 72 hours, whereas RT storage resulted in rapid product deterioration. PBSC products requiring prolonged liquid storage or transport before cryopreservation or infusion should be maintained at 4 ºC.

Osmotic properties of T cells determined by flow imaging microscopy in comparison to electrical sensing zone analysis

To develop cryopreservation methods for cell-based medicinal products it is important to understand osmotic responses of cells upon immersion into solutions with cryoprotective agents (CPAs) and during freezing. The aim of this study was to assess the osmotic response of T cells by using flow imaging microscopy (FIM) as a novel cell-sizing technique, and to corroborate the findings with electrical impedance measurements conducted on a Coulter counter. Jurkat cells were used as a potential model cell line for primary T cells. Cell volume responses were used to derive important cell parameters for cryopreservation such as the osmotically inactive cell volume Vb and the membrane permeability towards water and various CPAs. Unlike Coulter counter measurement, FIM, combined with Trypan blue staining can differentiate between viable and dead cells, which yields a more accurate estimation of Vb. Membrane permeabilities to water, dimethyl sulfoxide (Me2SO) and glycerol were measured for Jurkat cells at different temperatures. The permeation of Me2SO into the cells was faster in comparison to glycerol. CPA permeation decreased with decreasing temperature following Arrhenius behavior. Moreover, membrane permeability to water decreased in the presence of CPAs. Vb of Jurkat cells was found to be 49% of the isotonic volume and comparable to that of primary T cells. FIM proved to be a valuable tool to determine the membrane permeability parameters of mammalian cells to water and cryoprotective agents, which in turn can be used to rationally design CPA loading procedures for cryopreservation.

Loss of CD34+ Cells and Effect of the Number of Viable Cryopreserved CD34+ Cells in the Infused Blood Grafts on Hematologic Recovery, Progression-Free Survival and Overall Survival in NHL Patients After Autologous Stem Cell Transplantation

PATIENTS

This post-hoc study aimed to find out factors affecting graft viable CD34+ cell loss during processing and cryopreservation in 129 non-Hodgkin lymphoma (NHL) patients receiving autologous stem cell transplantation (auto-SCT) and the impact of a low (< 2.0 × 106/kg, group A) and a decent number (≥ 2 × 106/kg, group B) of viable CD34+ cells infused on the hematologic recovery, progression-free survival (PFS) and overall survival (OS) after auto-SCT.

RESULTS

The median loss of viable CD34+ cells during cryopreservation was higher in group A (47% vs. 19%, p < .001). A higher yield of CD34+ cells at the first apheresis in group B (p = .002) was linked with greater loss of viable graft CD34+ cells after cryopreservation. Filgrastim (FIL) use for mobilization seemed to associate with higher viable CD34+ cell loss compared to pegfilgrastim (PEG) or lipegfilgrastim (LIPEG) in both groups (in group A FIL 66 vs. PEG 35%, p = .006; in group B FIL 37 vs. PEG 15 vs. LIPEG 13%, p < .001). Hematologic recovery after auto-SCT was faster in group B. Neither viable CD34+ cell loss during storage nor viable CD34+ cell number < 2.0 × 106/kg infused affected on PFS or OS.

CONCLUSIONS

G-CSF type used in mobilization and mobilization capacity were found to correlate with viable CD34+ cell loss during processing and storage. Most importantly, low infused viable CD34+ cell count did not seem to impact on PFS or OS.

Variable recovery of cryopreserved hematopoietic stem cells and leukocyte subpopulations in leukapheresis products

INTRODUCTION

Due to the expansion of cell therapy using not only haematopoietic stem cells (HSC) but also other leukocyte subpopulations, the loss of these cells in cryopreserved apheresis products needs to be evaluated. Various factors that could negatively affect post-thaw recovery, such as leukapheresis product characteristics, storage time and cryopreservation protocols have been identified.

METHODS

The post-thaw recovery of HSCs, lymphocytes, NK cells and monocytes, as well as the factors that could adversely affect it were analysed in autologous and allogeneic leukapheresis products.

RESULTS

The lowest post-thaw recovery was observed in autologous and allogeneic CD34+ cells, with the median of 73.7% and 68.1%, respectively. In leukocyte subpopulation, the lowest post-thaw recovery was observed for CD14+ cells, both autologous and allogeneic. The highest post-thaw recovery was observed for CD3+/CD8+ cells in autologous, and for CD19+ cells in allogeneic samples. The statistically significant difference was observed between autologous and allogeneic PBSC products for CD3+ cell recovery (P = 0.031) and CD3+/CD8+ cell recovery (P = 0.009). The evaluation of factors that could adversely affect the post-thaw recovery in autologous samples showed weak negative correlations between platelet concentration and CD3+ recovery, as well as between storage time and CD3+CD8+ recovery. In allogeneic samples, a strong negative correlation was observed only between the percentage of granulocytes and CD3+, CD3+/CD8+ and CD3+/CD4+ cell recoveries.

CONCLUSION

Since various post-thaw recoveries of leukocyte subpopulations were observed, the cell therapy manufacturing centers should evaluate how their cryopreservation method and other factors affect the recovery of cell population of interest in their settings.

SERIOUS STEM CELL DONATION EVENTS AND RECIPIENT ADVERSE REACTIONS RELATED TO SARS-CoV-2: REVIEW OF REPORTS TO THE WORLD MARROW DONOR ASSOCIATION

BACKGROUND

The SARS-CoV-2 pandemic has deeply impacted hematopoietic stem cell (HSC) donations and transplants. Many changes in practice have been introduced and it is vital to monitor the impact of these on donations and transplants. As part of a global response to this pandemic, the World Marrow Donor Association (WMDA) asked that its member registries and cord blood banks submit SARS-CoV-2-related adverse events to the WMDA-operated Serious Product Events and Adverse Reactions (SPEAR) database.

OBJECTIVE

This article reviews SARS-CoV-2-related SPEARs that occurred in 2020.

STUDY DESIGN

The WMDA Serious Product Events and Adverse Reactions (SPEAR) Committee reviewed reports submitted via an online tool. The Committee reviewed each report following the EU definitions of a serious adverse event or reaction and determined the imputability and its impact. Reports submitted in 2020 were included in this analysis RESULTS: 74 such reports were received and were classified as: donor-related 41 (55.4%); recipient-related 3 (4.1%); technical issues 31 (41.8%) transport-related issues 4 (5.4%). Five cases appeared in more than one category. The commonest adverse events reported were of cells being unused. Many of these cases were caused by the uncoupling of the donation and transplant consequent on the cryopreservation of products as well as technical issues related to cell viability. Experience in some registries suggests these issues have become less frequent as transplant centres have become used to the changes in practice.

CONCLUSION

Lessons learnt include the importance of confirming recipient eligibility before the donors starts mobilisation or collection and minimising the time from collection of cells to transplant. Transplant centres should familiarise themselves with the expected cell losses when PBSC and BM products are cryopreserved and have validated viability assays for quality assurance. Reassuringly there were no reports of donors becoming severely unwell because of G-CSF or of transmission of SARS-CoV-2 to recipients and only one report of complete failure of transport of a donation.

Validation of long-term handling and storage conditions for hematopoietic stem cell products for autologous transplants

Hematopoietic stem cells (HPSCs) are multipotent stem cells that can differentiate into lymphoid and myeloid progenitors, giving rise to white blood cells (WBCs), red blood cells (RBCs), and platelets. HPSCs are a widely used treatment for many hematological non-malignant and malignant disorders. HPSCs can be used in the fresh or cryopreserved state for future use. Fresh HPSCs are typically stored at 2-6°C for up to 72 hours and are primarily used for allogeneic transplants or autologous transplants in myeloma and lymphoma patients. However, in some cases of autologous donations, HPSC transplantation is delayed more than three days after collection. In such situations, the cells are thawed after short-term preservation, resulting in a 35% cell viability loss. This study aimed to investigate the quality of HPSCs products after long-term storage exceeding 72 hours. The quality of HPSCs products was assessed by measuring viable CD34+ cell count, the total number of nucleated cells (TNC), and HPSCs recovery after different storage intervals of up to 120 hours in hypothermal storage. The mean total cell viability decreased by 2.18% within 72 hours and 7.4% within 120 hours, while mean CD34+ cell recovery was 92.61 % at 72 hours and 83.83 % at 120 hours in hypothermal storage. The mean TNC recovery was 89.93% at 72 hours and 76.18 % at 120 hours. All products were free from bacterial contamination for up to 120 hours under hypothermal storage conditions.

Impact of the number of cryopreserved CD34+ cells in the infused blood grafts on hematologic recovery and survival in myeloma patients after autologous stem cell transplantation: Experience from the GOA study

BACKGROUND

Prospective data on the impact of CD34⁺ cell loss during cryopreservation and the amount of cryopreserved CD34⁺ cells infused after high-dose therapy on hematologic recovery and post-transplant outcome in multiple myeloma (MM) are scarce.

PATIENTS AND METHODS

This post-hoc study aimed to investigate factors associating with CD34⁺ cell loss during cryopreservation and the effects of the infusion of a very low number (<1.0 × 10⁶ /kg, group A), low number (1-1.9 × 10⁶ /kg, group B), and optimal number (≥2 × 10⁶ /kg, group C) of thawed viable CD34⁺ cells on hematologic recovery, progression free survival, and overall survival after autologous stem cell transplantation among 127 patients with MM.

RESULTS

In group C, pegfilgrastim use (P = 0.001), plerixafor use (P = 0.039), and older age ≥ 60 years (P = 0.026) were associated with less loss of CD34⁺ cells during cryopreservation. Better mobilization efficacy correlated with greater CD34⁺ cell loss in group B (P = 0.013 and P = 0.001) and in group C (P < 0.001 and P < 0.001). Early platelet engraftment was slowest in group A (20 d vs 12 d in group B vs 11 d in group C, P = 0.003). The infused viable CD34⁺ cell count <1.0 × 10⁶ /kg seemed not to have influence on PFS (P = 0.322) or OS (P = 0.378) in MM patients.

CONCLUSIONS

Cryopreservation impacts significantly on the CD34⁺ cell loss. A very low number of graft viable CD34⁺ cells did not affect PFS or OS.

Non-cryopreserved peripheral blood stem cells as a safe and effective alternative for autologous transplantation in multiple myeloma

BACKGROUND

Autologous stem cell transplantation is the standard procedure for multiple myeloma and the grafts are usually cryopreserved. Previous studies reported advantages in the use of fresh peripheral blood stem cells (PBSC) autotransplantation compared to cryopreservation of the grafts. This study compared the transplant-related outcomes of two graft preservation methods: fresh storage (4°C/72 h) and cryopreservation (-80°C).

STUDY DESIGN AND METHODS

We performed an analysis of 45 patients with multiple myeloma under autotransplantation (17 fresh and 28 cryopreserved) from 2017 to 2021. Fresh PBSC were maintained in the refrigerator for three days in a concentration up to 300 × 10³ TNC/μL. Cryopreserved PBSC were concentrated by plasma reduction after centrifugation (950 g/10 min/4°C) and an equal volume of cryoprotection solution was added for a final concentration of 300 × 10³ TNC/μL, 5% DMSO, 6% hydroxyethyl starch, and 3% human albumin.

RESULTS

Neutrophil engraftment was significantly faster with fresh PBSCs (10 vs. 11.5 days, p = 0.045). Adverse effects were more common in cryopreserved PBSC transplantation (75% vs. 35.3% patients; p = 0.013). Post transplantation hospital stay was 20 and 22 days for fresh and cryopreserved PBSCs respectively (p = 0.091). There was no difference in platelet engraftment time (10.5 days for both; p = 0.133), number of antibiotics used after transplantation (3 for fresh and 2.5 for cryopreserved; p = 0.828), days of antibiotic use after transplantation (12.2 days for fresh and 13.3 days for cryopreserved, p = 0.579), and overall survival (p = 0.736).

CONCLUSION

The infusion of fresh PBSC refrigerated for up to three days is effective and safe for autologous transplantation in patients with multiple myeloma, which is a useful alternative to cryopreserved PBSC.