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The current COVID-19 pandemic has showed the threats that viruses can cause to the whole world. Over 200 million infections and over 4.5 million deaths and enormous socio-economic impact were the output of the emergence of a single new pathogen: SARS-CoV-2. The development of vac-cines is the paramount solution to overcome the pandemic. However, even with extraordinary and unprecedented worldwide efforts, it took almost one year to have a first validated vaccine and it will take longer to have a global vaccination. In addition, vaccines are preventive drugs, that need to be administered before the infection to stimulate the immune-system of the patient. In the meanwhile, in case of an infection, we were harmless in the fight against the virus.Antivirals are curative drugs, that inhibit one step of the viral replication. Many approaches have been investigated: antibodies, peptides, peptomimics, small molecules. Most of them are specif-ic to a single family of virus, making the development slow and expensive. Entry inhibitors are a class of antivirals that binds to the virus, preventing the attachment to the cell membrane. Such antivirals usually have a broad-spectrum of action, since they mimic cell receptors, such as heparan sulfate pro-teoglycans (HSPGs), exploited by different viruses. Many compounds have been developed throughout the years; however, the reversible nature of the virus inhibition mechanism has prevented their trans-lation to the clinic. Our group has recently shown that the simple addition of a long hydrophobic linker makes the inhibition irreversible, proving this hypothesis with two compounds: gold-nanoparticles and beta-cyclodextrins. The goal of this thesis is to develop novel antivirals able to inhibit a broad-spectrum of viruses with an irreversible mechanism of action and to investigate the key features responsible of such properties. In this thesis, we further expand the broad-spectrum activity of gold-nanoparticles and beta-cyclodextrins showing that they are capable of inhibiting viruses beyond HSPG-dependent ones. In addition, we show their ability of reversibly inactivating SARS-CoV-2. Moreover, we have investigated the role of the hydrophobic linker's length in the virucidal inhibition in case of cyclodextrins, proving the need of such moiety to have an irreversible viral inactivation. Envisioning a translation of such drug, we have performed a preliminar pharmacokinetic study performed via intranasal administration.A novel class of compounds has been also proposed: sulfated/sulfonated dendritic polyglyc-erol. A broad investigation of the molecular design rules needed to achieve nanomolar irreversible viral inhibition is discussed. We also show that the most active compound proves to be active against HSV-2 and RSV, thus with a broad-spectrum activity. In addition, we demonstrate that the virucidal activity is leading to the release of viral DNA upon interaction between the virus and our dendritic polyglycerol. A different modification of dendritic polyglycerol, bearing carboxylic acid, showed activi-ty against SARS-CoV-2; such inhibition results to be irreversible. This compound has been further test-ed in a hamster model, where initial studies confirm its feasibility as antiviral. In addition to these studies on development of virucidal antivirals, different technological so-lutions to prevent viral spreading are proposed. In particular, we focused on an antiviral filter and antiviral surfaces.