Recent advances in MRI methodology, such as microvascular and brain oxygenation (StO₂) imaging, may prove useful in obtaining information about the severity of the acute stroke. We assessed the potential of StO₂ to detect the ischaemic core in the acute phase compared to apparent diffusion coefficient and to predict the final necrosis. Sprague-Dawley rats (n = 38) were imaged during acute stroke (D0) and 21 days after (D21). A multiparametric MRI protocol was performed at 4.7T to characterize brain damage within three region of interest: ‘LesionD0’ (diffusion), ‘Mismatch’ representing penumbra (perfusion/diffusion) and ‘Hypoxia’ (voxels < 40% of StO₂ within the region of interest LesionD0). Voxel-based analysis of stroke revealed heterogeneity of the region of interest LesionD0, which included voxels with different degrees of oxygenation decrease. This finding was supported by a dramatic decrease of vascular and perfusion parameters within the region of interest hypoxia. This zone presented the lowest values of almost all parameters analysed, indicating a higher severity. Our study demonstrates the potential of StO₂ magnetic resonance imaging to more accurately detect the ischaemic core without the inclusion of any reversible ischaemic damage. Our follow-up study indicates that apparent diffusion coefficient imaging overestimated the final necrosis while StO₂ imaging did not.