Since last few years, magnetic resonance imaging (MRI) has become an important approach to map the complex neural connectivity between different functional areas for neuroscience research and clinical applications. With the ability of mapping fiber orientations non-invasively, diffusion MRI provides a novel aspect of depicting the structural connectivity of brain. Compared with conventional diffusion MRI techniques, high angular resolution diffusion MRI (HARDI) techniques have the capability of resolving complex neural fiber architectures. However, the histological correspondence of HARDI and its potential on clinical applications have not been well demonstrated yet. Therefore, the overall objective of this dissertation is threefold and targeted to facilitate HARDI techniques for clinical use. First, we demonstrated the histological correspondence of one of the HARDI techniques, diffusion spectrum imaging (DSI), on a rat epilepsy model. Second, we developed a systematic approach to investigate two HARDI techniques, DSI and q-ball imaging (QBI), on a clinical 3T MRI system. Finally, we verified the capability of high-temperature superconducting (HTS) radiofrequency (RF) coil on diffusion tensor imaging (DTI) and investigated the association between signal-to-noise ratio (SNR) and accuracy of neural fiber tractography. In our results, significant subregion-dependent correlations were found between DSI indices and histological evaluation, namely Timm’s score. For mean diffusivity, positive correlation was found in cornu ammonis (CA3), r = 0.62; p = 0.0174. The correlation between diffusion anisotropy and Timm’s score showed positive correlation in dentate gyrus (DG), r = 0.71; p = 0.0047, and negative correlation in CA3, r = -0.63; p = 0.0151. For optimization study, our results indicated that the optimum maximum b-value (bmax) was a trade-off between SNR and angular resolution. At their own optimum bmax, the reduced sampling schemes yielded angular precision and accuracy comparable to the high sampling schemes. Finally, our results showed that HTS coil provided an average SNR gain of approximately three folds on our 3T MRI system, the standard deviation of deviation angles was significantly reduced from 40.11° to 34.88°, which also significantly improved the connectivity of fiber tracking. In summary, we successfully demonstrated the histological correspondence of our proposed DSI indices and their potential use on clinical applications. Additionally, we verified the clinical feasibility of HARDI techniques, DSI and QBI, and found the optimum sequence parameters for their reduced sampling schemes. Finally, we demonstrated the capability of HTS coil on improving neural fiber tractography inferred from DTI data. Conclusively, our proposed methods can further advance the translation of HARDI techniques from laboratory to clinical setting, which will be potentially useful to facilitate the neuroscience research and clinical applications.