Hints to blood groupers, 1950.

Sixty years ago, the premier blood grouping laboratory was that of Robert Race in London. Agglutination tests and blood grouping had provided breakthroughs in immunology, genetics, and the solution of clinical problems. The significance of immunohematology was recognized by the clinical hematology community as a potent force in the expanding field of disorders of the blood and blood-forming organs. The instructions by Race to his London workers entitled Hints to Blood Groupers provide a picture of the immunohematology laboratory even before automation and differed slightly from the American techniques that derived from Landsteiner. Before agglutination is replaced in the near future by the emergence of molecular methods, the detailed method of a superb laboratory is recorded.

The how and why of exocytic vesicles.

The purpose of this review is to draw the attention of general readers to the importance of cellular exocytic vesiculation as a normal mechanism of development and subsequent adjustment to changing conditions, focusing on red cell (RBC) vesiculation. Recent studies have emphasized the possible role of these microparticles as diagnostic and investigative tools. RBCs lose membrane, both in vivo and during ex vivo storage, by the blebbing of microvesicles from the tips of echinocytic spicules. Microvesicles shed by RBCs in vivo are rapidly removed by the reticuloendothelial system. During storage, this loss of membrane contributes to the storage lesion and the accumulation of the microvesicles are believed to be thrombogenic and thus to be clinically important.

Collection of two units of leukoreduced RBCs from a single donation with a portable multiple-component collection system.

BACKGROUND: A portable automated component collection system that produces double (2) units of leukoreduced RBCs (DRBCs) from a single donation was evaluated. This study analyzed quality of the collected and final products, the efficacy of automated leukoreduction, and donor safety. STUDY DESIGN AND METHODS: The system was used to collect 120 DRBCs. WBCs were removed from 90 products with machine-controlled filtration. DRBCs were collected in ACD-A and stored in AS-1 for 42 days at 1 to 6 degrees C. Pre- and postprocedure donor vital signs and hematologic parameters were measured. Procedure time, product characteristics, and adverse events were also recorded. In vitro studies were performed on all products on Day 0 and at end of storage. In vivo recoveries of 28 leukoreduced and 9 nonleukoreduced products were measured on Day 42. RESULTS: Day 0 mean percentage of hemolysis for leukoreduced and nonleukoreduced units was 0.05 percent. DRBCs had residual WBC counts of less than 1 x 106 cells per unit and mean RBC recovery after filtration of 91.9 +/- 2.7 percent. Mean 24-hour recovery after infusion for leukoreduced units at end of storage was 80.9 +/- 6.9 percent and nonleukoreduced units was 77.6 +/- 5.8 percent (p> 0.05). No clinically significant changes in donor vital signs or serious adverse events were observed. CONCLUSIONS: The quality of leukoreduced RBCs collected with this portable automated component collection system met or exceeded FDA requirements. This automated system is safe and effective for collection and processing of 2 units of RBCs suitable for transfusion.

Twelve-week RBC storage.

BACKGROUND: Better storage can improve RBC availability and safety. Optimizing RBC ATP production and minimizing hemolysis has allowed progressively longer storage. STUDY DESIGN AND METHODS: In the first study, 24 units of packed CPD RBCs were pooled in groups of four, realiquoted, and added to 300 mL of one of four variants of experimental additive solution 76 (EAS-76) containing 45, 40, 35, or 30 mEq per L NaCl. Units were sampled weekly for 12 weeks for morphologic and biochemical measures. In the second study, 10 volunteers donated 2 units of RBCs for a crossover comparison of Tc/Cr 24-hour in vivo recovery of 6-week storage in AS-1 versus 12-week storage in EAS-76 variant 6 (EAS-76v6) having 30 mEq per L NaCl. RESULTS: RBCs stored in the lower salt variants of EAS-76 had higher concentrations of RBC ATP with less hemolysis and microvesiculation. RBC 2,3 DPG was preserved for two weeks. RBCs stored for 12 weeks in EAS-76v6 exhibited 78 +/- 4 percent 24-hour in vivo recovery. CONCLUSIONS: It is possible to store RBCs for 12 weeks with acceptable recovery and 0.6 percent hemolysis and with normal 2,3 DPG concentrations for 2 weeks.

Alkaline CPD and the preservation of RBC 2,3-DPG.

BACKGROUND: Concentrations of 2,3-DPG decline rapidly in the first week of RBC storage because of the low pH of conventional storage solutions. Alkaline additive solutions, which can preserve RBCs for up to 11 weeks, still do not preserve 2,3-DPG because the starting pH is below 7.2. STUDY DESIGN AND METHODS: Alkaline CPD (pH=8.7) was made with trisodium citrate, dextrose, and disodium phosphate. Twelve units of whole blood were collected into heparin and pooled in groups of four units. Each pool was then aliquoted into four units; 63 mL of CPD with pH 5.7, 6.5, 7.5, or 8.7 was added to one unit of each pool, and 300 mL of the alkaline experimental additive solution-76 was added. In Study 2, 12 units were collected into alkaline CPD, pooled in groups of four, aliquoted as described, and stored in four variants of experimental additive solution-76 containing 0, 9, 18, and 27 mM of disodium phosphate. RBC ATP and 2,3-DPG concentrations, intracellular and extracellular pH and phosphate concentrations, hemolysis, and other measures of RBC metabolism and function were measured weekly. RESULTS: RBCs stored in more alkaline conditions made 2,3-DPG, but at the expense of ATP. Concentrations of 2,3-DPG decreased after 2 weeks storage, but ATP concentrations never fully recovered. Providing more phosphate both increased the duration of 2,3-DPG persistence and raised ATP concentrations in the later stages of storage. CONCLUSIONS: Maintaining both 2,3-DPG and ATP requires both high pH and high concentrations of phosphate.