Jeffrey McCullough

Transfusion Medicine


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lysed by normally appearing fibrinolytic enzymes, leaving liquid defibrinated blood.

      The use of cadaver blood in the Soviet Union received much publicity and was believed by many to be the major source of transfusion blood there. Actually, not many more than 40,000 200‐mL units were used, and most of them at Yudin’s Institute [1]. In 1967, the procedure was quite complicated, involving the use of an operating room, a well‐trained staff, and extensive laboratory studies. This was never a practical or extensive source of blood.

      In 1939, Levine, Newark, and Stetson [24] published in less than two pages in the Journal of the American Medical Association their landmark article, a case report describing hemolytic disease of the newborn (HDN) and the discovery of the blood group that later became known as the Rh system. A woman who delivered a stillborn infant received a transfusion of red cells from her husband because of intrapartum and postpartum hemorrhage. Following the transfusion, she had a severe reaction but did not react to subsequent transfusions from other donors. The woman’s serum reacted against her husband’s red cells, but not against the cells of the other donors. Levine, Newark, and Stetson postulated that the mother had become immunized by the fetus, who had inherited a trait from the father that the mother lacked. In a later report, they postulated that the antibody found in the mother and subsequently in many other patients was the same as the antibody Landsteiner and Wiener prepared by immunizing Rhesus monkeys [25]. This also began a long debate over credit for discovery of the Rh system.

      During the early 1900s, immunologic studies had established that active immunization could be prevented by the presence of passive antibody. This strategy was applied to the prevention of Rh immunization in the early 1960s in New York and England at about the same time [26, 27]. Subjects were protected from Rh immunization if they were given either Rh‐positive red cells coated with anti‐Rh or anti‐Rh followed by Rh‐positive red cells. Subsequent studies established that administration of anti‐Rh in the form of Rh immune globulin could prevent Rh immunization, and thus almost eliminate HDN. Currently, control of HDN is a public health measure similar to ensuring proper immunization programs for susceptible persons.

      Techniques for collection, storage, and transfusion of whole blood were not well developed during the 1930s. The outbreak of World War II added further impetus to the development of methods to store blood for periods longer than a few days. Although the method of blood anticoagulation was known by the mid‐1920s, red blood cells hemolyzed after storage in sodium citrate for 1 week. This limitation also slowed the development of blood transfusion. Although it was also known that the hemolysis could be prevented by the addition of dextrose, the practical value of this important observation was not recognized for more than a quarter of a century. Anticoagulant preservative solutions were developed by Mollison [30] in Great Britain. However, when the glucose–citrate mixtures were autoclaved, the glucose caramelized, changing the color of the solution to various shades of brown. The addition of citric acid eliminated this problem and also extended the storage time of blood to 21 days. The advance of World War II also brought an understanding of the value of plasma in patients with shock [31, 32]. In the early 1940s, Edwin J. Cohn, PhD, a Harvard biochemist, developed methods for the continuous flow separation of large volumes of plasma proteins [33, 34]. This made possible during World War II the introduction of liquid and lyophilized plasma and human albumin as the first‐line management of shock. Initial work using plasma for transfusion was carried out by John Elliott [31, 32]. This combination of technological and medical developments made it possible for Charles R. Drew to develop the “Plasma for Britain” program [35].

      One of the next major developments in blood banking was the discovery and patenting of the plastic blood container by Carl Walter in 1950. This made possible the separation of whole blood and the creation of blood component therapy. Dr. Walter’s invention was commercialized by the Baxter Corporation. The Fenwal division later became a freestanding company; the “‐wal” of “Fenwal” represents Dr. Walter’s name. The impact of the introduction of multiple connected plastic containers and the separation of whole blood into its components also began to generate enormous amounts of recovered plasma, which made possible the development of large‐scale use of coagulation factor VIII concentrates.

      The role of 2,3‐diphosphoglycerate in oxygen transport by red cells was discovered in the mid‐1960s [37, 38]. It had been known previously that this compound was better maintained at higher pH, whereas adenosine triphosphate, which appeared to be involved in red cell survival, was maintained better at a lower pH. The addition of adenine was shown to improve adenosine triphosphate maintenance and prolong red cell survival and storage for transfusion [39]. The next major advance in red cell preservation was the development of preservative solutions designed to be added after removal of most of the original anticoagulated plasma, thus further extending the storage period of red cells [40].

      In 1926, Doan [41] described the sera of some individuals that caused agglutination of the leukocytes from others. Subsequent studies established the presence of leukocyte antibodies, the presence of these antibodies in the sera of polytransfused patients, the occurrence of white cell agglutinins in response to fetomaternal immunization, and the alloimmune and autoimmune specificities associated with these antibodies. These studies, along with studies of the murine histocompatibility system, led to the description of the major histocompatibility system (human lymphocyte antigens) [42] in humans and the understanding that there are separate antigenic specificities limited to neutrophils as well [43]. These studies also defined the causative role of leukocytes in febrile nonhemolytic transfusion reactions [44]. Strategies were sought to prevent these reactions by removing the leukocytes from blood [45, 46], one of the first methods being reported by Fleming [46], who discovered penicillin.