Viral infections pose a serious threat to global public health. Heat shock protein 90 (Hsp90) plays many different roles in viral infections as it interacts with several viral proteins. Viruses require a host cell to replicate and spread. The goal in the treatment is to use antiviral drugs that interfere with one of the phases and prevent further steps in the life cycle of a virus. The main problem of antiviral agents is development of resistance. The aim of our study was to explore Hsp90 inhibitors as agents with antiviral activity. First, we summarized the main findings from previously published articles and then used three different programs to dock Hsp90 inhibitors with the greatest antiviral activity potential. Geldanamycin and its derivatives are selective Hsp90 inhibitors with antiviral activity, but their biggest problem is cytotoxicity. The radicicol derivative pochonin D inhibited human rhinovirus 1B replication by 90 % in a concentration of 2 µM. Compound 4l showed the potential to treat HIV infection by inhibiting Hsp90. Among the 4,5,6,7-tetrahydrobenzo[1,2-d]thiazole derivatives, compound 7 had the greatest potential for the treatment of hepatitis C virus infections, being less toxic than the reference inhibitor 17-DMAG. Among the benzo[d]thiazoles, compound 9b had the best binding affinity to Hsp90 and anti-influenza virus activity without displaying cytotoxicity. Gedunin selectively binds to the N-terminal domain of Hsp90 and does not cause toxicity at the tested concentrations up to 100 µM. Comparing different docking programs, we found that FRED (OpenEye Scientific Software) best reproduced the experimentally determined binding mode of the inhibitors. 17-AAG was docked to the binding site in a similar manner as inhibitor 17-DMAG. When comparing the Kd values and scoring functions, we found no correlation between them. The docking results gave us insight into the potential binding of the inhibitors, but it is necessary to determine the binding mode experimentally as well. This would provide us a suitable basis for further optimization of compounds for the treatment of viral infections and other diseases.