[en] Aimed at better understanding of the mechanism of oxide particles dissolution in dispersion-strengthened ferritic-martensitic steels the methods of electron microscopy and scanning energy dispersive spectrometry are applied to study variation of microstructure and strengthening phase chemical composition in steels DY (Fe-13 Cr-1.5 Mo + TiO₂ + 0.5 Y₂O₃), EM10 + Y₂O₃ and EM10 + MgO irradiated under various conditions. Neutron irradiation is performed up to 81 dpa maximal dose at temperatures of 400-580 deg C in Phenix reactor. The irradiation with 1 and 1.2 MeV electrons is carried out in an electron microscope column at 300-550 deg C, and 1 MeV helium ion irradiation is performed in an accelerator at 400 deg C. It is stated that helium ion irradiation has no effect on steel structure and oxide chemical composition as the most part of ion energy is lost in inelastic interactions. The irradiation with 1.2 MeV electrons is shown to promote the dissolution of yttrium oxides as this taken place radii of particles decrease with a dose growth, suggesting that point defects play an important role in dissolution processes. In-core irradiation of dispersion-strengthened steels in the form of fuel pin cans results in the following changes: a disappearance of uniform distribution of fine (< 20 nm) particles; the formation of haloes of fine particles around the larger ones; the occurrence of irregular oxide-matrix interfaces; variations in oxide chemical composition