This research is motivated by a project on improving hospital logistics. The purpose is to reduce workload and customer waiting under limited resource with innovative strategy for all systems of similar characteristics. Strategy redesign on both storage and transportation is used to approach this logistics problem. (1) For storage, a recency-based storage assignment policy and a cascaded warehouse configuration for essential accessory of recurrent demand are proposed. The objectives are to reduce traverse and operation cost respectively. A model of recurrent demand is first built. Efficiency of the new policy and current ID-based policy is then analyzed. After that, a programming model for optimal configuration of cascaded warehouses is presented. Finally, a case study of hospital visits is performed. (2) For transportation, it proposes an operation design of hub transshipment across time periods and flexible period setting for dual-objective multi-period pickup and delivery routing problem. The objectives are to reduce workload and delivery time. The new policy and existing periodical routing policy are first compared. A case study is then performed by using field data of the hospital. Finally, flexibility in application and its programming models are presented. Being verified with mean-value analysis and simulation, all proposed innovative methods in this dissertation are outdoing the current ones. Thresholds for applying these new policies are also analytically derived. The new policies can be extendedly applied to other logistics fields of similar pattern.