Storage of volume-reduced washed platelets in M-sol additive solution for 7 days.

BACKGROUND: Volume-reduced washed platelets (VR-wPLTs), which are prepared by concentrating platelets (PLTs) into a smaller volume of additive solution (AS), may prevent not only circulatory overload, but also adverse reactions caused by plasma components. Although VR-wPLTs may be quickly degraded due to high PLT concentrations, few studies have examined the effects of storage on VR-wPLTs. We examined here the in vitro properties of VR-wPLTs prepared with M-sol AS during their storage for 7 days. STUDY DESIGN AND METHODS: Platelet concentrates (PCs) were divided into two equal aliquots (control group and test group). After the centrifugation of both aliquots and removal of as much supernatant as possible, the pellet of the control group was resuspended in 160 mL of M-sol while that of the test group was resuspended in 80 or 40 mL of M-sol. The wPLTs of both groups were stored in polyolefin bags with agitation at 20 to 24°C for 7 days. RESULTS: The pH values of both groups were maintained at higher than 7.0 during the 7-day storage. Differences in %disk, CD62P, annexin V, percent hypotonic shock response, and aggregation values between the test group and control group were small for at least 2 days after washing. CONCLUSIONS: The in vitro properties of VR-wPLTs were not markedly degraded for at least 2 days. Therefore, the storage properties of PLTs may be maintained in VR-wPLTs prepared at blood centers until they are administered to patients in hospitals.

Replaced platelet concentrates containing a new additive solution, M-sol: safety and efficacy for pediatric patients.

BACKGROUND: Allergic transfusion reactions (ATRs), particularly those caused by plasma-rich platelet concentrates (P-PCs), are an important concern in transfusion medicine. Replacing P-PCs with PCs containing M-sol (M-sol-R-PCs) is expected to prevent ATRs. However, this has not yet been verified by sufficient clinical evidence. STUDY DESIGN AND METHODS: A retrospective cohort study was performed between 2008 and 2011. Pediatric patients with hematologic disorders, solid tumors, primary immunodeficiency disorders, or inherited metabolic disorders were transfused with M-sol-R-PCs between 2010 and 2011; the transfusions of P-PCs administered between 2008 and 2011 were compared in terms of frequency and severity of ATRs, corrected count increment (CCI), and occurrence of bleeding. Data were collected for 6 consecutive months on a per-patient basis. RESULTS: Data obtained during 2008 to 2011 showed that of the 78 patients receiving 515 P-PC transfusions, 14 (17.9%) had 17 ATRs (3.3%); 14 and three ATRs were of Grades 1 and 2, respectively. In 2010 to 2011, 49 patients received 620 transfusions of M-sol-R-PCs, and two patients (4.1%) had Grade 1 ATRs (0.3%). Thus, the frequency of ATRs per bag and per patient differed significantly between the two transfusions. No steroid agents were used for the prevention or treatment of ATRs in the M-sol-R-PC group. The CCI (24 hr) for M-sol-R-PCs did not differ from that for P-PCs. CONCLUSION: M-sol-R-PCs were found to be effective in preventing ATRs without loss of transfusion efficiency in children; however, its efficacy should be further evaluated in prospective clinical trials.

Effects of helicopter transport on red blood cell components.

BACKGROUND: There are no reported studies on whether a helicopter flight affects the quality and shelf-life of red blood cells stored in mannitol-adenine-phosphate. MATERIALS AND METHODS: Seven days after donation, five aliquots of red blood cells from five donors were packed into an SS-BOX-110 container which can maintain the temperature inside the container between 2 °C and 6 °C with two frozen coolants. The temperature of an included dummy blood bag was monitored. After the box had been transported in a helicopter for 4 hours, the red blood cells were stored again and their quality evaluated at day 7 (just after the flight), 14, 21 and 42 after donation. Red blood cell quality was evaluated by measuring adenosine triphosphate, 2,3-diphosphoglycerate, and supernatant potassium, as well as haematocrit, intracellular pH, glucose, supernatant haemoglobin, and haemolysis rate at the various time points. RESULTS: During the experiment the recorded temperature remained between 2 and 6 °C. All data from the red blood cells that had undergone helicopter transportation were the same as those from a control group of red blood cell samples 7 (just after the flight), 14, 21, and 42 days after the donation. Only supernatant Hb and haemolysis rate 42 days after the donation were slightly increased in the helicopter-transported group of red blood cell samples. All other parameters at 42 days after donation were the same in the two groups of red blood cells. DISCUSSION: These results suggest that red blood cells stored in mannitol-adenine-phosphate are not significantly affected by helicopter transportation. The differences in haemolysis by the end of storage were small and probably not of clinical significance.

Platelet additive solution - electrolytes.

Recent attention to solutions that replace most or all plasma in platelet concentrates, while maintaining satisfactory platelet function, is motivated by the potential of plasma reduction or depletion to mitigate various transfusion-related adverse events. This report considers the electrolytic composition of previously described platelet additive solutions, in order to draw general conclusions about what is required for platelet function and longevity. The optimal concentrations of Na(+) and Cl(-) are 69-115 mM. The presence of both K(+) and Mg(2+) in platelet suspension at nearly physiological concentrations (3-5mM and 1.5-3mM, respectively) is indispensable for good preservation capacity because both electrolytes are required to prevent platelet activation. In contrast to K(+) and Mg(2+), Ca(2+) may not be important because no free Ca(2+) is available in M-sol, which showed excellent platelet preservation capacity at less than 5% plasma concentration. The importance of bicarbonate (approximately 40 mM) can be recognized when the platelets are suspended in additive solution under less than 5% residual plasma concentration.

Reduction in adverse reactions to platelets by the removal of plasma supernatant and resuspension in a new additive solution (M-sol).

BACKGROUND: Leukodepletion reduces but does not eliminate adverse reactions to platelet concentrate (PC). As an alternative strategy, plasma reduction or washing of platelets should be considered. However, the efficacy of this strategy is still unclear. STUDY DESIGN AND METHODS: A total of 12 patients who experienced adverse reactions at a 29 to 100 percent reaction rate for plasma-PC were enrolled. The reactions were allergic reactions and nonhemolytic transfusion reactions, such as chills. Plasma-removed PC (W/R-PC), which was suspended in a recently developed additive solution (M-sol) containing less than 20 mL plasma, was prepared. W/R-PCs in M-sol were then transfused into patients after an overnight storage period; the occurrence of adverse reactions was monitored and 1- and 24-hour corrected count increment (CCI) values were evaluated. RESULTS: Although plasma-PC caused reaction in 12 patients, W/R-PC prevented reactions in 11 of 12 patients, with 1 patient having one minor allergic reaction of 15 transfusions. There was a significant difference in the incidence of reaction (p < 0.0001, Fisher's exact test). On a per-transfusion basis, the reaction rate for W/R-PC (1/156, 0.64%; 95% confidence interval [CI], 0.02%-3.5%) was reduced significantly compared to that for plasma-PC (117/276, 42%; 95% CI, 36%-48%; p < 0.0001). W/R-PC gave findings of satisfactory CCI at 1 hour (22,400 +/- 8,000/microL) and 24 hours (15,400 +/- 8,000/microL). No clinically evident bleeding episodes were recorded. CONCLUSIONS: W/R-PC suspended in M-sol in the presence of less than 20 mL plasma can be transfused safely and eliminate a wide range of adverse reactions to plasma-PC.