The topographic organization of cortical barrel in layer IV of rat primary somatosensory cortex is a good model for studying neural function and plasticity. However, mapping brain function and plasticity with high spatial resolution and accurate spatial localization methods non-invasively remained challenges. The overall objectives of this dissertation were to develop novel imaging techniques to monitor functional processes of the brain, including anatomy, neural activity, and neural plasticity. We sought to establish a feasible working protocol of applying manganese- enhanced magnetic resonance imaging (MEMRI) to map the cortical barrels of the rat following whisker stimulation. We’d also like to test the feasibility of using functional MRI (fMRI) to map the forepaw digit representations in the primary somatosensory cortex of the rat and to apply to the study of cortical plasticity after digit amputation. The development of these technologies provided two techniques, i.e. fMRI and MEMRI, that can be used to study brain function in minimally invasive ways. In addition, the study allowed us to better understand the range of applicability of new brain functional imaging techniques that were developed. In our results, we have mapped rat whisker barrels using the MEMRI method and have shown a clear relationship between manganese-enhanced cortical regions and whisker tactile-sense-evoked activity. In the right cortical barrels, the enhancement ratios (1.72 ± 0.22) and R1 values (1.12 ± 0.16) in the whisker stimulation group were significantly higher than those (1.27 ± 0.14, p<0.05; 0.83 ± 0.21, p<0.05) in the control group. We have also demonstrated that forepaw barrel subfields of single digits can be reliably mapped using fMRI at 11.7T. The alteration of the digit representation after digit amputation was also detected. The distance between the centers of mass of two digits representations decreased from 1.45 ± 0.29 mm in the control group to 0.90 ± 0.21 mm (p<0.01) in the amputated group. The method will be useful to study neural plasticity in rat brains after surgical or genetic manipulation. In conclusions, exciting MEMRI strategies showed great promise for enabling non-invasive techniques to map neuronal activity throughout the rat brain non-invasively. Combined with established whole brain fMRI techniques, it became possible to get an increasing range of information non-invasively that in the past required invasive histology or time consuming electrophysiology. To the best of out knowledge this is the first fMRI demonstration of plasticity in cortical columns by fMRI. In the future, these MRI techniques developed in rats can often be extended for use in humans. The development of these new imaging techniques will be used to study the normal rodent brain and changes in the brain that occur during learning and plasticity or due to specific genetic changes.