Patients with thrombocytopenia require frequent platelet (PLT) transfusions to prevent bleeding complications. Unfortunately, long-term PLT transfusions are complicated by refractoriness, which is defined as an insufficient PLT count increment after repeated PLT transfusions. HLA alloimmunization is the major factor for platelet transfusion refractoriness (PTR) and HLA-matched PLTs are widely used to improve the PLT transfusion outcome in HLA-alloimmunized PTR patients. Traditionally, HLA-matched PLTs are selected via serological cross-reactive groups (CREGs) method. CREGs method is based on the comparison of the HLA public epitopes between patient and donor’s HLA antigens. However, many HLA antigens contain more than one public epitope within the same CREGs that consequently develop different epitope-specific antibodies. As a result, the CREGs method was not effective enough to predict transfusion outcomes for PTR patients. In our studies, we conducted a prospective trial with a novel HLA matching approach (called epitope-based matching; EBM method) to provide suitable platelet concentrates for HLA-alloimmunized PTR patients. The EBM method used bead-based single antigen HLA antibody detection and HLAMatchmaker software to define the epitopes recognized by HLA-specific antibodies. We evaluated 142 platelet transfusion outcomes with different matching strategies (A/BU, CREGS, and EBM method) in 9 HLA-alloimmunized PTR patients and monitored the alteration of HLA antibody patterns in patients in a follow-up study. The results indicated that the selection of platelets for HLA-alloimmunized PTR patients by EBM method is as effective as that by A/BU matching, and follow-up antibody analysis confirmed that no specific antibodies were detected against EBM-matched antigens. In conclusion, we suggested that the EBM strategy could be used for proper selection of PLT concentrates for PTR patients. In addition, the polymorphism of human platelet antigens (HPA) leads to alloimmunizations and immune-mediated platelet disorders including neonatal alloimmune thrombocytopenia (NAIT), post-transfusion purpura (PTP), and platelet transfusion refractoriness (PTR). HPA typing and knowledge of antigen frequency in a population is important in particular for the provision of HPA-matched blood components for patients with PTR. We have performed allele genotyping for HPA-1 through -6 and -15 among 998 platelet donors from 6 blood centers in Taiwan using sequence-specific-primer polymerase chain reaction. Based on allele frequency study, the HPA-3 and -15 might play an important role in the HPA imcompatibility platelet transfusion and need to set up a large scale HPA-typed donor file in Taiwan. However, there are several disadvantages in the conventional methods of HPA genotyping for large-scale-sample laboratory. Therfore, we developed a new high throughput method for detecting genetic polymorphism of HPA-1, -3 and -15 systems using the pyrosequencing technology and validated this method with Sanger sequencing. Beside, we also developed a simultaneously detecting HPA-1 and HPA-3 genotypes in a single-tube (one test) for cost and time saving. Repeat test and reliability test indicated that the agreement between the pyrosequencing and the Sanger sequencing methods was 100%. Our results indicated that HPA pyrosequencing genotyping is a simple, accuracy, sensitive and high-throughput method for blood donor centers.