Table 1.
The examples of DTI and fMRI studies in SVCI
| Study | Subjects | N | Neuroimaging technique | Main findings |
| Xu et al 32 | SVCI and normal controls | 42 | DTI and conventional MRI | DTI detected FA and MD alterations in normal-appearing white matter in SVCI subjects. DTI changes correlated with cognition better than did conventional MRI. |
| Kim et al 37 | SVCI | 61 | DTI and conventional MRI | DTI abnormalities in supratentorial regions correlated with cognitive deficits better than did the ischaemic burden detected by conventional structural MRI. |
| Lin et al 38 | SVCI and cognitively normal subjects with subcortical ischaemic vascular disease | 50 | DTI | SVCI subjects displayed decreased FA and increased MD in all supratentorial regions, which correlated with cognitive dysfunction. |
| Kim et al 39 | Subcortical VaD, AD and normal controls | 128 | DTI | Patients with subcortical VaD showed decreased FA and increased MD in all white matter regions. |
| Zhou et al 40 | SVCI and normal controls | 36 | DTI | SVCI subjects showed lower FA values throughout the brain. |
| Jung et al 41 | SVCI and normal controls | 169 | DTI | SVCI subjects displayed decreased FA in multiple white matter tracts neighbouring and providing connections between grey matter regions. |
| Shim et al 42 | SVCI, MCI and normal controls | 57 | DTI | A greater decrease in FA in the centrum semiovale and parietal regions in SVCI subjects, and the lowest FA in the hippocampus in MCI subjects. |
| Chen et al 43 | Subcortical VaD, MCI, AD, FTD and normal controls | 85 | DTI | White matter abnormalities mainly in the frontal cortical regions, the genu of the corpus callosum and periventricular regions in subcortical VaD subjects. |
| Zarei et al 44 | VaD, AD and normal controls | 51 | DTI | The decreased FA in the transcallosal prefrontal tracts was the most significant biomarker for VaD. |
| Sun et al 55 | SVCI and cognitively normal elderly with subcortical ischaemic vascular disease | 34 | Resting-state fMRI | Decreased DMN FC with frontal, anterior cingulate and temporal regions and increased FC with temporal and parietal regions in SVCI subjects. |
| Kim et al 57 | Subcortical VaD, AD, mixed dementia and normal controls | 152 | Resting-state fMRI | Lower FC in frontal and anterior insular regions in subcortical VaD subjects. |
| Zhou et al 56 | SVCI and normal controls | 55 | Structural and resting-state fMRI | Decreased FC between medial prefrontal cortex and anterior cingulate cortex and supplementary motor area in SVCI subjects. |
| Yi et al 58 | SVCI and normal controls | 54 | Structural and resting-state fMRI | Decreased low-frequency oscillations amplitudes in the anterior part of the DMN and increased amplitudes in the posterior part of the DMN in SVCI subjects. |
| Yi et al 59 | SVCI and normal controls | 47 | Resting-state fMRI | Decreased intramodular connectivity in the prefrontal cortex, parietal cortex, anterior insula and middle cingulate cortex and increased intermodular connectivity in the parietal cortex in SVCI subjects. |
| Li et al 62 | Subcortical VaD, AD and normal controls | 20 | Task-fMRI | The activation in the frontal, parietal and anterior cingulate cortex was reduced in subcortical VaD subjects during performing a Stroop test. |
| Li et al 63 | SVCI, subcortical VaD and normal controls | 35 | Task-fMRI | Mild SVCI subjects displayed significantly increased activation in frontal regions, whereas VaD subjects showed decreased activation during performing a Stroop test. |
AD, Alzheimer’s disease; DMN, default mode network; DTI, diffusion tensor imaging; FA, fractional anisotropy; FC, functional connectivity; fMRI, functional MRI; FTD, frontotemporal dementia; MCI, mild cognitive impairment; MD, mean diffusivity; SVCI, subcortical vascular cognitive impairment; VaD, vascular dementia; VCI, vascular cognitive impairment.