Blood Platelet Inventory Management

• Published in: Markov Decision Processes in Practice pp. 293 - 317
• Main Authors: Haijema, Rene, van Dijk, Nico M., van der Wal, Jan
• Format: Book Chapter
• Language: English
• Published: Cham Springer International Publishing 2017; Springer
• Series: International Series in Operations Research & Management Science
• Subjects: Blood inventory management; Blood platelets; Finite horizon; Leerstoelgroep Operationele research en logistiek; Non-stationary; Operationele Research en Logistiek; Operations Research and Logistics; Perishable products; WASS
• ISBN: 3319477641; 9783319477640
• ISSN: 0884-8289; 2214-7934
• DOI: 10.1007/978-3-319-47766-4_10

This paper illustrates how MDP or Stochastic Dynamic Programming (SDP) can be used in practice for blood management at blood banks; both to set regular production quantities for perishable blood products (platelets) and how to do so in irregular periods (as holidays). The state space is too large to solve most practical problems using SDP. Nevertheless an SDP approach is still argued and shown to be most useful in combination with simulation. First the recipe for the stationary case is briefly reviewed as referred to earlier research. Here the regular production problem is periodic: demand and supply are weekday dependent but across weeks the problem is usually regarded as stationary. However, during a number of periods per year (roughly monthly) the problem is complicated by holiday periods and other events that imply non-stationary demand and production processes. This chapter particularly focuses on how to deal with the Blood Platelet (PPP) problem in non-stationary periods caused by holidays. How should production quantities anticipate holidays and how should production resume after holidays. The problem will therefore also be modelled as a finite horizon problem. To value products left in stock at the end of the horizon we propose to use the relative state values of the original periodic SDP. An optimal policy is derived by SDP. The structure of optimal policies is investigated by simulation. Next to its stationary results, as reported before, the combination of SDP and simulation so becomes of even more practical value to blood bank managers. Results show how outdating or product waste of blood platelets can be reduced from over 15% to 1% or even less, while maintaining shortage at a very low level.