Antagonistic aptamer selection is an important issue in the field of aptamer study. In this thesis, a novel methodology of aptamer selection is designed and proposed. This method is called epitope-specific SELEX (systematic evolution of ligands by exponential enrichment), in which antagonistic aptamers are obtained by the SELEX with competition for the receptor-binding epitope on a target protein. Hemagglutinin of human influenza A/New Caledonia/20/99 is chosen as a model to demonstrate this strategy. After nine SELEX rounds, anti-hemagglutinin aptamers with high affinity are obtained, and the mean dissociation constant of the aptamer pool is as low as 1.2 nM. In the aptamer pool, aptamer CP9P536 shows high antagonistic activity against hemagglutinin. It can inhibit the agglutination activity of hemagglutinin with the concentration range from 62.5 to 1000 nM. Furthermore, the specificity of this aptamer is identified by the immunoprecipitation assay, which shows that the aptamer can recognize hemagglutinin in human serum and viral antigen. Also, the structure of CP9P536 is characterized by circular dichroism. It is supposed that the structure of CP9P536 is a parallel G-quadruplex structure. Moreover, CP9P536 is structurally stable between 4 to 37°C. As a result, it is considered that ES-SELEX can effectively screen the aptamer with high affinity and desired functionality. Moreover, the aptamer identified and characterized in this study is structurally stable for clinical applications. It has potential for DNA-based anti-influenza drug development.