Increasing the time-to-freezing for clinical apheresis plasma meets quality specifications.

BACKGROUND AND OBJECTIVES: In Australia, the vast distances between blood collection centres and processing facilities make it challenging to align supply with demand. Increasing the time to freezing for clinical plasma beyond 6 h would alleviate supply issues. This study aimed to determine the quality of clinical apheresis plasma frozen within 12 h of collection. MATERIALS AND METHODS: Apheresis plasma (n = 20) collected at donor centres was immediately transported to a blood processing facility, stored at 26°C and sampled aseptically at 6, 8 and 12 h post collection. Frozen samples were thawed, and coagulation factors (F) II, V, VII, VIII and XIII, von Willebrand factor (vWF) and fibrinogen were measured using a coagulation analyser. RESULTS: FVIII concentrations declined in plasma frozen at 6, 8 and 12 h post collection (1.22 ± 0.27, 1.21 ± 0.25 and 1.16 ± 0.24 IU/mL, respectively) but not significantly (p = 0.3338). Importantly, all components met the FVIII specification (>0.7 IU/mL) for clinical plasma. Fibrinogen concentrations were stable from 6 to 12 h (p = 0.3100), as were vWF concentrations (p = 0.1281). Coagulation factors II, V, VII and XIII were not significantly different (p > 0.05 for all factors). CONCLUSION: Clinical apheresis plasma can be frozen within 12 h of collection, allowing collections from donor centres further from processing centres and increasing supply.

Red cells manufactured from lipaemic whole blood donations: Do they have higher haemolysis?

BACKGROUND AND OBJECTIVES: Lipaemia in blood donations is thought to influence haemolysis in stored red blood cell (RBC) components. Higher lipid concentrations are believed to increase red cell fragility, exacerbating haemolysis during collection and subsequent red cell storage. This study aimed to investigate associations between lipoproteins in plasma and haemolysis of red cells stored in saline-adenine-glucose-mannitol (SAGM). MATERIALS AND METHODS: Fifty-four plasma and matched RBCs were obtained from lipaemic whole blood donations. Plasma was tested for coagulation factors, triglycerides and cholesterol. Haemolysis, glucose, lactate, extracellular potassium, lactate dehydrogenase and adenosine triphosphate (ATP) were measured in RBC on Days 7, 21 and 42 of storage. Additionally, 20 plasma and matched RBCs from non-lipaemic donations were tested as controls. RESULTS: Lipaemic plasma had significantly higher triglyceride concentrations compared with non-lipaemic plasma. However, there was no significant difference in plasma cholesterol between the two groups. There were no significant differences in glucose, extracellular potassium or ATP concentrations in RBC from either group. There was no significant difference in haemolysis at expiry in lipaemic-derived and control RBC, with a weak correlation between haemolysis and either triglycerides or cholesterol. CONCLUSION: There was no significant difference in haemolysis in RBC manufactured from lipaemic and non-lipaemic whole blood donations when stored in SAGM; however, the proportion of RBC from lipaemic donations with higher haemolysis was greater than in the controls. There was a weak correlation between red cell haemolysis and plasma triglycerides. Therefore, RBCs derived from lipaemic donations are suitable for blood bank inventories.

X- and gamma-irradiation have similar effects on the in vitro quality of stored red cell components.

BACKGROUND: Blood components are irradiated to inactivate lymphocytes to prevent transfusion-associated graft versus host disease. As there are little data regarding the effects of X-irradiation on red blood cell components (RBCs), the in vitro quality of stored red cells (standard, pediatric, washed, and intra-uterine transfusion [IUT]) following X- or gamma-irradiation was compared. STUDY DESIGN AND METHODS: RBCs were pooled, split, and processed to produce standard (<14 days and < 5 days post-collection), pediatric (<5 days post-collection), washed (<14 days post-collection), or IUT RBCs (<5 days post-collection). Standard RBCs were either X- or gamma-irradiated (n = 10 pairs). A further 10 replicates were prepared by pooling and splitting three matched RBCs (X-, gamma-, and non-irradiated). All other RBCs were either X- or gamma-irradiated (n = 20 pairs). Red cell indices, hemolysis, potassium release, metabolism, microparticles, ATP, and 2,3-DPG were measured pre-irradiation and 6 h, 1, 2, 3, 7, 10, and 14 days post-irradiation, depending on the component type. Data were analyzed using two-way repeated measures ANOVA. RESULTS: There were no significant differences in any in vitro quality measurements, with the exception of marginally higher potassium release in washed, IUT, and RBCs <5 days old (p < .0001) following X-irradiation. Both irradiation types increased generation of microvesicles, particularly in components that were older at the time of irradiation or stored for longer post-irradiation. CONCLUSION: X- and gamma-irradiation have similar effects on the in vitro quality of RBCs, indicating that either technology is suitable for blood component irradiation.

Serum growth factor stability in different eye drop packaging systems during storage.

Serum eye drops (SED) have shown beneficial effects in patients suffering from dry eye syndrome and are manufactured for an increasing number of patients in Australia every year. Previous studies have examined the stability of serum growth factors during storage in either experimental vessels not used as the final packaging system or in eye drop bottles. To ensure the quality and safety of SED product manufactured in Australia, the stability of growth factors in serum packaged into two different systems during storage at different temperatures was examined. Healthy blood donors provided a whole blood donation, from which serum was prepared, diluted to 20% and dispensed into either a tube or a vial packaging system. The stability of growth factors, fibronectin and total protein in tube segments was comparable to matched vials samples during storage at -30 °C, 4 °C, 22 °C and 37 °C, with the exception of EGF and fibronectin in 20% SED stored in tube segments, which were more sensitive to storage conditions at 4 °C and 22 °C when compared to vials. Additionally, the growth factor, fibronectin and total protein concentration in both tube segments and vials was stable during storage at -30 °C for at least 9 months. This study highlights the impact of different manufacturing procedures on serum growth factor stability during storage.