Abstract
Ex vivo (EV)-derived megakaryocytes (MKs) have shown great promise as a substitute for platelets in transfusion medicine to alleviate a severe shortage of donor-platelets. Challenges remain that include poor efficiency, a limited scale of production, and undefined short-term storage conditions of EV-derived MKs. This study aims to develop a high-efficiency system for large-scale production of Good Manufacturing Practice (GMP)-grade MKs and determine the short-term storage condition for the MKs. A roller-bottle culture system was introduced to produce GMP-grade MKs from small-molecule/cytokine cocktail expanded hematopoietic stem cells. Various buffer systems and temperatures for the short-term storage of MKs were assessed by cell viability, biomarker expression, and DNA ploidy levels. MKs stored for 24 hours were transplanted into sublethally irradiated nonobese diabetic/severe combined immunodeficient (NOD/SCID) mice to confirm their platelet-releasing and tissue-homing ability in vivo. A yield of ~ 2.5 × 104 CD41a+ /CD42b+ MKs with purity of ~ 80% was achieved from one original cord blood CD34+ cell. Compared with the static culture, the roller-bottle culture system significantly enhanced megakaryopoiesis, as shown by the cell size, DNA ploidy, and megakaryopoiesis-related gene expression. The optimal storage condition for the MKs was defined as normal saline with 10% human serum albumin at 22℃. Stored MKs were capable of rapidly producing functional platelets and largely distributing in the lungs of NOD/SCID mice. The novel development of efficient production and storage system for GMP-grade MKs represents a significant step toward application of these MKs in the clinic.