Abstract Blood components are a perishable resource that play a crucial role in clinical medicine. The blood component inventory is managed by transfusion services, which ultimately aim to balance supply with demand so as to ensure availability whilst minimizing waste. Whilst the blood component inventory problem has been the focus of theoretical approaches for over 50 years, evidence for the direct utilization of existing models in the day-to-day management of blood stocks in clinical settings is limited. In this study, we formulate a discrete mathematical model that describes the main processes in the management of a single population of red blood cells (RBCs) in a clinical setting: ageing, supply and demand. After time averaging the discrete model, a time-delayed integro-partial differential equation model is derived. A steady-state analysis yields expressions for a range of clinically relevant quantities (i.e. age distributions, total stock levels, wastage rates, age of transfused units); key performance indicators (KPIs) and simple formulae that identify optimal restock thresholds in terms of parameters that are readily available in clinical settings. The approach is validated by testing predictions using data from two Scottish hospitals. It is envisaged that the proposed methodology can ultimately be used to aid in situ ‘rule-of-thumb’ decision making in clinical laboratory settings.
Vaz et al. (Sun,) studied this question.