Efficient generation of quinone methides (QMs) from quinone methide precursors (QMPs) under mild conditions, such as reagent free UV-light irradiation, and exceptional reactivity of QMs towards nucleophiles and, in case of o-QMs, towards dienophiles have attracted a lot of attention to these compounds in computation, chemical, biological and engineering spheres. Our research group has demonstrated successful application of o-napthoquinone methide precursors (o-NQMPs) as photolabile protecting groups (PPGs) and linkers, that can be employed in the design of multifunctional surfaces, used as PPGs for biological molecules that carry different functional groups and as a linker for peptide and protein reversible modification.o-QMs and p-QMs demonstrate different chemical properties and different reactivity. However, to the best of our knowledge, the molecules containing competing o-NQM and p-QM moieties, have not been studied. Thus, the major goal of the first project was to develop and synthesize novel QMPs with ability to generate o-NQM and p-QM under light irradiation. Physical properties, chemical properties, such as ability to react with nucleophiles and undergo inter- and intra-molecular Diels-Alder reaction, as well as kinetic behavior of new QM-system have been studied.We were also interested in investigating the ability of o-NQMPs decorated with thiol moieties to form smart polymers, that could be generated upon UV-light irradiation. The photo-induced degradation of the polymers could be achieved on demand upon light irradiation in the presence of vinyl ethers. Unfortunately, light-induced polymerization of the synthesized monomers resulted in exclusive formation of oligomers.Another project has been focused on the development of a novel photocleavable analog of calcium-selective chelating ligand, which was based on the combination of properties of photolabile 3-(hydroxymethyl)-2-naphthol core and high calcium affinity of 1,2-bis(o-aminophenoxy)ethane-N,N,N,N-tetraacetic acid (BAPTA).Finally, we have worked towards the design of a new fluorogenic PPG that could also serve as an intracellular pH indicator. 9H-xanthene-1,8,9-triol derivatives can be considered as photoactivatable fluorophores and fluorogenic PPGs, as 9H-xanthen-1,8,9-triols are expected to generate relatively stable quinone methide upon UV-light irradiation. Due to its structural similarity with fluorescein derivatives, we expected 8-hydroxy-1H-xanthen-1-one to be highly fluorescent. However, attempted synthesis resulted in the formation of a different unexpected product.