Variation in the osmotic characteristics of aging red blood cells: insights for cryopreservation optimization.

IF 3.7 3区医学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Cytotherapy Pub Date : 2025-01-31 DOI:10.1016/j.jcyt.2025.01.010

Sanaz Hemmatibardehshahi, Mackenzie Brandon-Coatham, Andrew Holt, Jason P Acker

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引用次数: 0

Abstract

Cryopreservation is a long-term storage strategy for maintaining the quality of red blood cells (RBCs) used for clinical and industrial purposes. However, cryopreservation can induce osmotic stress, leading to a 15 to 20% loss of RBCs during freezing/thawing and cryoprotectant addition/removal. This study investigated how the biological aging of RBCs influences their osmotic characteristics. We hypothesized that biologically older RBCs (O-RBCs) would exhibit diminished osmotic features compared to biologically younger RBCs (Y-RBCs), thereby contributing to their loss during cryopreservation. Seven red cell concentrates (RCCs) were pooled, and their density profile was determined using Percoll separation. Y-RBCs and O-RBCs, representing the extremes of the density spectrum, were isolated. Rheological parameters (O_hyper, EI_max, EI_hyper, K_EI) were measured with laser ektacytometry. Osmotic fragility and hemolysis tests were performed to assess subpopulation responses to osmotic stress. Water (L_p) and solute permeability (P_s) of these subpopulations, in addition to unseparated RBCs (U-RBCs), were measured using stopped-flow spectroscopy. Aliquots of Y- and O-RBCs were differentially labeled with biotin and spiked back into a pooled unit. The pooled unit was split into five, and cryopreserved via a high glycerol/slow-cooling method, a standard method adopted by international blood banks. Glycerolization and deglycerolization were conducted using the Haemonetics ACP 215 Automated Cell Processor. Flow cytometry was used to assess the recovery of biotinylated RBCs (BioRBCs) before glycerolization and following post-thaw deglycerolization on days 1 and 14. O-RBCs exhibited the highest rigidity (K_EI) and lowest O_hyper, EI_max, and EI_hyper. Osmotic hemolysis and osmotic fragility indicated that O-RBCs exhibited superior tolerance to hypotonic solutions than Y- and U-RBCs (P < 0.05). O-RBCs demonstrated significantly higher L_p values than Y-RBCs across hypo- and hypertonic conditions (P < 0.05). O-RBCs had the highest P_s during deglycerolization (P < 0.05). Y- and O-BioRBCs showed a stable trend throughout the 14 days of hypothermic storage (1-4°C) post-deglycerolization, with no significant difference between subpopulations. The study revealed that biological aging is associated with alterations in the osmotic and rheological properties of RBCs. Despite notable differences in osmotic characteristics, under the test conditions, survival rates of Y- and O-BioRBCs remained comparable after 14 days of hypothermic storage. These findings potentially support that tailoring cryopreservation protocols to specific RBC subpopulations can improve recovery rates and make cryopreservation more clinically efficient and broadly applicable.

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低温保存是一种长期储存策略，可保持临床和工业用红细胞（RBC）的质量。然而，低温保存会引起渗透压应激，导致红细胞在冷冻/解冻和添加/移除低温保护剂过程中损失 15% 至 20%。本研究调查了红细胞的生物老化如何影响其渗透特性。我们假设，与生物学上较年轻的红细胞（Y-RBCs）相比，生物学上较老的红细胞（O-RBCs）会表现出较低的渗透特性，从而导致其在冷冻保存过程中流失。将七种红细胞浓缩物（RCC）汇集在一起，使用 Percoll 分离法测定它们的密度曲线。分离出代表密度谱极端的 Y-RBC 和 O-RBC。流变学参数（Ohyper、EImax、EIhyper、KEI）通过激光电子流变仪进行测量。进行渗透脆性和溶血试验，以评估亚群对渗透压力的反应。除了未分离的红细胞（U-RBC）外，还使用停流光谱法测量了这些亚群的水分（Lp）和溶质渗透性（Ps）。用生物素对等分的 Y 型和 O 型 RBC 进行差异化标记，并将其重新添加到一个汇集单元中。集合单位被分成五个，并通过国际血库采用的标准方法--高甘油/低温冷冻法进行冷冻保存。使用 Haemonetics ACP 215 自动细胞处理器进行甘油化和脱甘油。流式细胞术用于评估甘油化前和解冻后脱脂后第 1 天和第 14 天生物素化 RBC（BioRBC）的恢复情况。O 型 RBC 的刚性（KEI）最高，Ohyper、EImax 和 EIhyper 最低。渗透性溶血和渗透性脆性表明，O 型红细胞对低渗溶液的耐受性优于 Y 型和 U 型红细胞（P < 0.05）。在低渗和高渗条件下，O 型红细胞的 Lp 值明显高于 Y 型红细胞（P < 0.05）。在脱甘油过程中，O 型红细胞的 Ps 值最高（P < 0.05）。Y型和O型生物红细胞在脱甘油后的14天低温储存（1-4°C）期间表现出稳定的趋势，亚群之间没有显著差异。研究表明，生物老化与红细胞渗透压和流变特性的改变有关。尽管渗透特性存在明显差异，但在测试条件下，Y 型和 O 型生物红细胞在低温储存 14 天后的存活率仍然相当。这些发现可能证明，针对特定的 RBC 亚群制定低温保存方案可以提高存活率，使低温保存更有效、更广泛地应用于临床。

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来源期刊

Cytotherapy 医学-生物工程与应用微生物

CiteScore

6.30

自引率

4.40%

发文量

683

审稿时长

49 days

期刊介绍： The journal brings readers the latest developments in the fast moving field of cellular therapy in man. This includes cell therapy for cancer, immune disorders, inherited diseases, tissue repair and regenerative medicine. The journal covers the science, translational development and treatment with variety of cell types including hematopoietic stem cells, immune cells (dendritic cells, NK, cells, T cells, antigen presenting cells) mesenchymal stromal cells, adipose cells, nerve, muscle, vascular and endothelial cells, and induced pluripotential stem cells. We also welcome manuscripts on subcellular derivatives such as exosomes. A specific focus is on translational research that brings cell therapy to the clinic. Cytotherapy publishes original papers, reviews, position papers editorials, commentaries and letters to the editor. We welcome "Protocols in Cytotherapy" bringing standard operating procedure for production specific cell types for clinical use within the reach of the readership.