Schizophrenia is a mental illness; most affected people live in developing countries, and neither appropriate treatment nor commercial drugs are currently available. One possibility is to inhibit human-D-amino acid oxidase (h-DAAO). In this study, molecular dynamic simulations of the monomer, dimer and tetramer forms of h-DAAO complexed with the inhibitor 3-hydroxyquinolin-2(1H)-one(2) were performed. Seven residues, Leu51, Gln53, Leu215, Tyr228, Ile230, Arg283 and Gly313, were identified as essential for interacting with the inhibitor. Molecular docking of h-DAAO with pyrrole, quinoline and kojic acid derivatives, representing 69 known or potential h-DAAO inhibitors, was also performed. The results indicated that the activity of the inhibitor can be improved by modifying the compounds to have a substituent group capable of interacting with the side chain of Tyr228. Van der Waals interactions of the inhibitor with the hydrophobic pocket of h-DAAO and electrostatic interactions or H-bonds with Arg283 and Gly313 were important elements in determining the efficiency of the inhibitor. These results provide information on the interaction between h-DAAO and its inhibitors at the molecular level and can aid in the design of novel inhibitors against h-DAAO for new drug development in the treatment of schizophrenia.