Applying polymer coatings to wood-based materials is a simple and economically acceptable way to preserve surfaces and protect them from external influences. However, polymer coatings do not provide adequate UV protection. Therefore, the addition of inorganic nanofillers such as titanium dioxide (TiO2), which absorb UV radiation in the polymer, is of great importance. Emulsion polymerization was used to synthesize aqueous polyacrylate (PA)/titanium dioxide emulsions from which coating films were prepared. The research in this work is divided into 3 phases. In phase 1, the effect of adding different types of TiO2 (aqueous dispersions, powder form) and the method of ex situ and in situ preparation on the properties of PA before and after UV exposure was investigated. In phase 1, the best nanofiller or DW filler was selected and in the phase 2 of the study, it was observed how the concentration of that filler and the preparation method affected the properties of PA before and after UV exposure. In phase 3 of the study, the effect of surface modification of TiO2 with (3-Aminopropyl)trimethoxysilane (AMPTS), polyhedral oligomeric silsesquioxane (POSS), initiator 2,2´-Azobis(2-methylpropionamidine) dihydrochloride (AIBA) and nonionic emulsifier diethyl-phenol-ethylene-oxide TX-100 on the properties of PA before and after UV exposure was investigated. The nanofiller concentration of 0.75% used in the phase 3 of the study was obtained from the 2nd phase of the study. Characterization of the emulsions was aimed at determining particle size distribution and rheological properties, while characterization of the coating films before UV exposure was aimed at determining morphology, transparency, thermal stability and mechanical properties. After UV exposure structural changes, changes in glass transition temperature and changes in molecular weight distribution of coating were determined. Research showed that the addition of TiO2 nanofiller in the form of an aqueous dispersion achieved better properties of the nanocomposite compared to coatings with powder nanofillers. The method of preparation of the coating has a significant effect on the properties of the coating and ultimately on its application. The results of particle size distribution showed that the addition of nanofiller TiO2 changed the particle size distribution of PA. The in situ preparation of the coating with the addition of nanoparticles in the form of an aqueous dispersion DW obtained a bimodal particle size distribution in which no agglomerated particles were present, while the emulsion prepared ex situ showed a significant amount of agglomerated particles, especially when higher concentrations of DW were added. The particle size distribution of emulsions with the addition of modified DW nanoparticles indicates that the modification increases the hydrodynamic particle diameter and emulsion with TiO2 modified with non-ionic emulsifier TX-100 shows a significant amount of agglomerates. Emulsions prepared in situ show an increase in the viscosity of PA due to the addition of TiO2 filler, which can be attributed to the establishment of significant interactions between nanofillers and PA, whereas in ex situ emulsions the subsequent addition of filler has no effect on the viscosity of PA. The viscosity of PA is significantly increased by the addition of modified TiO2 nanoparticles. In situ preparation method achieves better distribution and dispersion of the nanofillers in PA, resulting in better transparency and UV protection. The in situ polymerization of PA is carried out from the surface of TiO2, which reduces the possibility of agglomeration of fillers. The modification of TiO2 filler impairs the distribution and dispersion of filler in PA, significantly worse dispersion and distribution of nanofiller is visible by the addition of TiO2 modified with non-ionic emulsifier TX -100, while surface modification of TiO2 with silane AMPTS does not impair the distribution and dispersion of TiO2 in PA. The results of the measurement of the light transmittance of the coating show that the in situ method of preparation and the addition of fillers in the aqueous dispersion improve the UV protective properties of the PA film and do not significantly affect the transparency of the coating. The addition of modified fillers does not affect the transparency of the coating and slightly increases the UV protection properties. The addition of modified TiO2 nanofiller significantly improves the thermal stability of PA, which can be attributed to the increase in the interfacial interactions between TiO2 and PA due to the modification, thus significantly limiting the thermally-induced mobility of polymer chains and chain scission due to thermal degradation. The glass transition temperature of the coating increases during UV radiation due to the formation of crosslinked structures that limit the mobility of polymer chains. In situ prepared coating with DW filler has the smallest change in glass transition temperature after 144 h of UV exposure indicating that it slows down structural changes in polyacrylate. In ex situ coatings, the photocatalytic effect of TiO2 nanoparticles was more pronounced. This may be due to the presence of agglomerates of TiO2 nanoparticles in ex situ coatings that prevent efficient evaporation of water from the coating during drying time and part of the water remains in the coating creating water-rich regions that catalyze the process of UV degradation. Structural changes of coating and changes in the distribution of molecular weight due to UV exposure are less pronounced in in situ prepared coatings with the addition of fillers in an aqueous dispersion compared to other coatings. TiO2 surface modification can have positive and negative effects on the UV absorbance of TiO2. For example, the modification of TiO2 with AMPTS increases the UV absorbing ability of TiO2, while the modification with other modifiers increases the photocatalytic ability of TiO2. The coating with TiO2 modified with AMPTS shows the best thermal stability and mechanical properties, low transmittance in the UV part of the spectrum, the smallest change in glass transition temperature, and the least structural changes during UV exposure. Thus, by modifying the surface of TiO2 with AMPTS and adding such a filler to the PA polymer, a significant improvement in properties is achieved.