Deglycerolization of red blood cells: A new dilution-filtration system.

In this work, we present a new version of the dilution-filtration system for rapidly deglycerolizing a large volume of cryopreserved blood. In our earlier system, one of the major problems was the damage induced to the red blood cells (RBCs) due to high osmolality change at the dilution point. Therefore, we devised a new system to solve this problem. First, we theoretically simulated the osmolality variation in the new system and the variation of the maximum and minimum volumes of the RBCs at the dilution point to examine the effects of operating parameters/conditions. Next, we experimentally validated the effects of these operating parameters by deglycerolizing porcine blood. The results show that when the initial NaCl concentration in the hypertonic solution is 18%, the volume of the hypertonic solution is 200 mL, and the flow rate of the filtrate is 50 mL/min, the system can effectively remove glycerin from 200 mL of porcine blood in 30 min, with ∼87% RBC survival rate and ∼73% RBC recovery rate. Our results indicated that in the new system the concentration and the volume of the hypertonic solution used to dilute the blood are the important parameters that need to be adjusted to reduce osmotic damage to the RBCs. In addition, a fast filtrate flow rate is highly recommended. This work can significantly contribute to the development of a more efficient and effective system for deglycerolizing large volumes of cryopreserved blood in clinic.

Unloading of cryoprotectants from cryoprotectant-loaded cells on a microfluidic platform.

In this paper, a multistep dilution-filtration microdevice (MDFD) is developed for unloading cryoprotectants from cryoprotectant-loaded cells. The MDFD contained a diluent producing region, a dilution-filtration execution region, and a filtrate collection region. It was made of two patterned PMMA stamps with four pieces of sandwiched PVDF membranes. Firstly, the performances of the mixers that were used in the diluent producing region and the dilution-filtration execution region were assessed using fluorescence experiments. Then, the effect of the MDFD structure on the loss of cells was investigated by applying the MDFD to unload glycerin from glycerin-loaded porcine red blood cells. Finally, the effects of the cell density, glycerin concentration, and membrane pore size on the clearance efficiency of glycerin (C G ), the survival rate of cells (S C ) and the recovery rate of cells (R C ) have been studied. Under the designed conditions, C G achieved ~80% and S C reached ~90%. However, R C was only ~40%, mainly resulting from the cells detained on the membrane surface and squeezed through the membrane pores into the filtrate. Increasing the membrane pore size caused high C G and S C , but low R C . For a low glycerin concentration, C G , S C , and R C were all high. For a high cell density, C G was high, but both S C and R C were low. This work is of significance to develop a microfluidic chip for unloading cryoprotectants from a small amount of cryopreserved cell samples.

A multistage-dialysis microdevice for extraction of cryoprotectants.

In this study, we present a multistage-dialysis microdevice (MDM) for extraction of cryoprotectants (CPAs) from a CPA-laden cell suspension. We confirmed the functions of the key designs of the MDM using a fluorescence solution, we assessed the performance of the MDM by using the MDM to unload glycerin from glycerin-loaded swine erythrocytes, and we investigated the effects of the cell suspension flow rate, glycerin concentration, cell density, and membrane pore size on the clearance efficiency of glycerin (CG), the survival rate of cells (SC), and the recovery rate of cells (RC). Under the designed conditions, CG, SC, and RC reached ~60%, ~90%, and ~70%, respectively. In addition, a high flow rate causes high SC and RC but a low CG. For a low glycerin concentration, CG, SC, and RC are all high. If a low cell density or a large pore membrane is used, CG is high, whereas both SC and RC are low. This work provides insight into the development of microfluidic devices for the inline extraction of cryoprotectants from a small volume of cryopreserved cells prior to the use of the cells in lab-on-a-chip applications.