Cryopreservation of living cells: principles and practice.

Increasingly, the cryopreservation of living cells is being attempted by researchers whose primary interest and experience is with the medical applications of those cells or tissues and whose prior experience with cryobiology may be negligible. It is therefore generally necessary to imitate some regimen used by others, perhaps with some other cell type and attempt to optimize the recovery empirically. This article makes no attempt to provide specific protocols for the many individual cell types. Rather it is a primer that may help to give such investigators an insight into the basic principles of cell freezing, cryoprotectants, and, particularly, their addition and removal. Finally, the article summarizes the five different approaches to applied cryopreservation: ultrarapid freezing and thawing, controlled-rate freezing, freezing with nonpenetrating polymers, vitrification, and equilibrium freezing.

Storage of red blood cells with improved maintenance of 2,3-bisphosphoglycerate.

BACKGROUND: During storage, red blood cells (RBCs) rapidly lose 2,3-bisphosphoglycerate (2,3-DPG) leading to an increase in the affinity for O(2) and a temporary impairment of O(2) transport. Recent clinical evaluations indicate that the quality of transfused RBCs may be more important for patient survival than previously recognized. STUDY DESIGN AND METHODS: Glucose-free additive solutions (ASs) were prepared with sodium citrate, sodium gluconate, adenine, mannitol, and phosphates at high pH, a solution that can be heat-sterilized. CP2D was used as an anticoagulant. Additional CP2D was added to the AS to supply glucose. RBCs were stored at 4 degrees C and assayed periodically for intracellular pH (pHi), extracellular pH, glucose, lactate, phosphate, ATP, 2,3-DPG, hemolysis, and morphology. RESULTS: Storage in 175 mL of the chloride-free, hypotonic medium at a hematocrit (Hct) level of 59 to 60 percent resulted in an elevated pHi and the maintenance of 2,3-DPG at or above the initial value for 2 weeks without loss of ATP. The addition of 400 mL of storage solution followed by centrifugation and removal of 300 mL of excess solution to a Hct level of 60 to 66 percent further reduced the chloride concentration, resulting in the maintenance of 2,3-DPG for 4 weeks. Hemolysis was at 0.1 percent at 6 weeks. CONCLUSION: Improvements in the maintenance of 2,3-DPG were achieved with 175 mL of a chloride-free storage solution with familiar additives at nontoxic concentrations to increase pHi. Adding, instead, 400 mL of storage solution followed by the removal of 300 mL reduced the chloride concentration, increasing the pHi and extending the maintenance of 2,3-DPG to 4 weeks.

Red blood cells intended for transfusion: quality criteria revisited.

Great variation exists with respect to viability and function of fresh and stored red blood cells (RBCs) as well as of the contents of RBC hemoglobin (Hb) in individual units. Improved technology is available for the preparation as well as the storage of RBCs. The authors raise the question whether it may be time to revise current standards for RBC units. The establishment of a standard unit of blood based on Hb content should be a high-priority goal. It is recommended that a standard RBC unit should contain 50 g of Hb. Major organizations concerned with the collection and distribution of blood components should agree on the criteria for a standard unit of RBCs based on Hb content and for the collection of double units. Manufacturers of blood collection equipment should provide suitable technology for collecting a standard unit with defined contents of RBC Hb. Efforts should be directed at the design of storage solutions acceptable for transfusion that maximize the maintenance of both RBC viability and function during storage. The ideal storage protocol would require sterile, high-pH solutions containing both glucose and electrolytes.

Depletion of CD25+ cells from human T-cell enriched fraction eliminates immunodominance during priming with dendritic cells genetically modified to express a secreted protein.

The ability of dendritic cells (DCs), genetically modified with one of two types of plasmid DNA vaccines to stimulate lymphocytes from normal human donors and to generate antigen-specific responses, is compared. The first type, also called "secreted" vaccine (sVac), encodes for the full length of the human prostate-specific antigen (PSA) with a signal peptide sequence so that the expressed product is glycosylated and directed to the secretory pathway. The second type, truncated vaccines (tVacs), encodes for either hPSA or human prostate acidic phosphatase (hPAP), both of which lack signal peptide sequences and are retained in the cytosol and degraded by the proteasomes following expression. Monocyte-derived dendritic cells are transiently transfected with either sVac or one of two tVacs. The DCs are then used to activate CD25+-depleted or nondepleted autologous lymphocytes in an in vitro model of DNA vaccination. Lymphocytes are boosted following priming with transfected DCs, peptide-pulsed DCs or monocytes. Their reactivity is tested against tumor cells or peptide-pulsed T2 target cells. Both tVacDCs and sVacDCs generate antigen-specific cytotoxic T-cell responses. The immune response is restricted towards one of the three antigen-derived epitopes when priming and boosting is performed with sVacDCs. In contrast, tVac-transfected DCs prime T cells towards all antigen-derived epitopes. Subsequent repeated boosting with transfected DCs, however, restricts the immune response to a single epitope due to immunodominance. While CD25+ cell depletion prior to priming with sVacDCs alleviates immunodominance, cotransfection of dendritic cells with GITR-L does so in some but not all cases.

WBC reduction in cryopreserved RBC units.

BACKGROUND: WBC reduction of blood components by filtration is widely practiced to decrease the incidence of alloimmunization. Freezing RBCs reduces the WBC load but is insufficient to achieve the currently recommended US limit of 5 x 10(6) cells per unit. STUDY DESIGN AND METHODS: Blood units were WBC reduced by filtration or by buffy-coat (BC) removal and then frozen in the presence of a high-glycerol concentration. The count of residual WBCs was determined by flow cytometry after deglycerolization. RESULTS: Without WBC reduction, the total number of WBCs present after freezing and thawing was 11.5 +/- 9.2 x 10(6) WBCs per unit (n = 18). Particulate residues from monocytes and neutrophils that were detected in the remaining cell populations were positive for CD66b, CD3, CD14, and CD41. Removal of 40 mL of BC at the time of blood collection lowered the number of WBCs after freezing and deglycerolization to 1.9 +/- 1.20 x 10(6) per unit (n = 11). Similar results were obtained when only 20 mL of BC was removed using a modified blood-bag design. Unfiltered RBC units that were stored for 15 days at 4 degrees C after BC removal contained fewer than 5 x 10(6) WBCs after deglycerolization. Units WBC reduced by filtration before freezing had no detectable WBCs after thawing and washing (n = 14) and did not contain particulate residues. Filtration after deglycerolization was effective in reducing the WBC count below 10(6), although some debris was still present. CONCLUSION: RBC freezing alone will not reduce residual counts to recommended levels. However, initial removal of BC can provide an economical alternative to WBC filtration for cryopreserved units. Units that were not WBC reduced before freezing can be filtered after deglycerolization when needed.