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In recent years, there has been a huge development of innovative engineered nanomaterials with potential use in industrial and biomedical applications. This increased widespread use raised concerns that nanomaterials may elicit human adverse health effects through occupational, environmental or consumer exposure. Many toxicity studies, mainly in vitro, have showed that some nanomaterials, such as carbon nanotubes or titanium dioxide nanoparticles (TiO 2 NP), may cause genotoxicity, inflammation, and associated adverse health effects. Nevertheless, few studies have focused on the nanomaterials effect s on the epigenome, namely, modifications of histone tails, microRNA expression or DNA methylation. Here we wil l present two “omics” studies based on next generation sequencing , one focusing on the effect of three nanocellulose s derived from Eucaliptus globulus kraft pulp on the microRNA expression of BEAS 2B, and an other one focusing on the effect of three types of TiO 2 NP on the DNA methylation of Caco 2 cells. Regarding the former 24h exposure to fibrillar micro/nanocellulose s did not induced significant (FDR ≤ 0.05) differentially expressed microRNAs, as compared to non exposed cells. By contrast, the crystalline nanocelul l ose induced the over and under expression of 22 and 30 microRNAs, respectively. These microRNAs can be f urther explored as potential biomarkers for human biomonitoring and co ntribute to elucidate the mechanisms of action of crystalline nanocellulose. As to the genome wide methylation study Reduced Representative Bisulfite Sequencing allowed the identification of significant ( p ≤ 0.05) differential methylation of 92, 70, and 88 gene sequences for the anatase, rutile and brookite phase TiO 2 NP exposures, respectively. Functional pathway analysis of these methylation changes showed that all TiO 2 NP may affect cell proliferation, differentiation, and survival, and suggested different molecular mechanisms of action for each type of TiO 2 NP. In conclusion, epigenomics revealed to be a powerful tool to understand the key molecular events underlying nanomaterials effects.