Pathogen reduction and blood transfusion safety in Africa: strengths, limitations and challenges of implementation in low-resource settings.

Transfusion-transmitted infection risk remains an enduring challenge to blood safety in Africa. A high background incidence and prevalence of the major transfusion-transmitted infections (TTIs), dependence on high-risk donors to meet demand, suboptimal testing and quality assurance collectively contribute to the increased risk. With few exceptions, donor testing is confined to serological evaluation of human immunodeficiency virus (HIV), hepatitis B and C (HBV and HCV) and syphilis. Barriers to implementation of broader molecular methods include cost, limited infrastructure and lack of technical expertise. Pathogen reduction (PR), a term used to describe a variety of methods (e.g. solvent detergent treatment or photochemical activation) that may be applied to blood following collection, offers the means to diminish the infectious potential of multiple pathogens simultaneously. This is effective against different classes of pathogen, including the major TTIs where laboratory screening is already implemented (e.g. HIV, HBV and HCV) as well pathogens that are widely endemic yet remain unaddressed (e.g. malaria, bacterial contamination). We sought to review the available and emerging PR techniques and their potential application to resource-constrained parts of Africa, focusing on the advantages and disadvantages of such technologies. PR has been slow to be adopted even in high-income countries, primarily given the high costs of use. Logistical considerations, particularly in low-resourced parts of Africa, also raise concerns about practicality. Nonetheless, PR offers a rational, innovative strategy to contend with TTIs; technologies in development may well present a viable complement or even alternative to targeted screening in the future.

A multicentre study investigating vital sign changes occurring in complicated and uncomplicated transfusions.

BACKGROUND AND OBJECTIVES: Many hospitals require transfusions to be discontinued when vital signs stray from predetermined ranges, regardless of clinical symptoms. Variations in vital signs may be unrelated to transfusion, however, and needlessly stopping a transfusion may delay medical care while increasing donor exposures and healthcare costs. We hypothesized that a detailed study of vital sign changes associated with transfusion of blood product by component, including those associated with potential reactions (complicated) and those deemed to be uncomplicated, would establish a useful framework of reference for treating clinicians and transfusion services alike. MATERIALS AND METHODS: A retrospective electronic record review of transfusion service and transfusion recipient data was completed on 3852 inpatient transfusion episodes over a 6-month period at four academic tertiary care hospitals across the United States. Vital signs pre- and post-transfusion were recorded by trained clinical research nurses. Serious reactions were adjudicated by a panel of transfusion medicine experts. RESULTS: In both uncomplicated transfusions (n = 3765) and those including an adverse reaction (n = 87), vital sign fluctuations were generally modest. Compared to uncomplicated transfusions, transfusions complicated by febrile reactions were associated with higher pretransfusion temperature and higher pretransfusion pulse rates. Episodes of transfusion circulatory overload were associated with higher pretransfusion respiration rates compared to uncomplicated transfusions. CONCLUSION: Most transfusions are associated with only modest changes in vital signs. Pretransfusion vital signs may be an important yet previously understudied predictor of vital sign changes during transfusion. The optimal role of vital sign assessment during blood transfusion deserves further study.

Measuring the influence of blood component infusion rate on recipient vital signs.

BACKGROUND AND OBJECTIVES: One of the challenges surrounding blood component administration is the determination of an appropriate rate of infusion. There are very few evidence-based guidelines available to guide healthcare providers looking for a 'standard' infusion rate for red blood cells (RBCs), plasma or platelets (PLTs). Our objective was to determine the extent to which blood component infusion rates were associated with changes in transfusion recipient vital signs. MATERIALS AND METHODS: We retrospectively examined records of 3496 component infusions (RBCs, n = 2359; PLTs, n = 478; plasma, n = 659) over a 1-year period at a 362-bed multispecialty hospital. The following data were collected for each transfusion: blood product volume and infusion time, recipient pre- and post-transfusion temperature, blood pressure and pulse rate, and hospital ward where transfusion occurred. RESULTS: Plasma (median 10.4 ml/min) was infused faster than PLTs (median 7.2 ml/min, P < 0.0001) or RBCs (median 2.3 ml/min, P < 0.0001). For all blood components, infusion rates varied based on the hospital unit performing the infusion. No association was found between relatively fast RBC, plasma or PLT infusion rates (>20 ml/min) and clinically significant reported changes in vital signs. CONCLUSIONS: There does not appear to be a strong correlation between infusion rate and significant changes in recipient temperature, blood pressure or pulse rate. Based on these data, a reasonable rate for routine transfusion is 2-3 ml/min for RBCs and 7-10 ml/min for plasma and PLTs. Faster infusion rates (>20 ml/min) likely can be applied with close patient monitoring if there is a more urgent need for transfusion.