We employed the tracer kinetic model based on the T2* perfusion in the study to improve MR imaging analysis by adding noteworthy information of BBB permeability in brain tumors and ischemic strokes. We examined the accuracy and precision of estimated pharmacokinetic parameters, using the values of Monte Carlo simulations to better understand the origin of error distribution in fitting process. The FPPM model offers a potentially advantageous approach for simultaneous generation of the estimates of permeability and cerebral blood volume from dynamic T2*-weighted echo-planar images. This model accurately reflected the underlying cerebral pathophysiology in patient with brain tumors and ischemic stroke from observations with calculated maps of clinical practice in this study. We have applied the patients’ data in our institute to confirm that the FPPM model could be an effective means of detecting brain damage in patients with ischemic stroke at the onset of first few days in this study. These data suggest that only at the chronic phase can a leakage of contrast medium lead to a parenchymal enhancement such that brain blood barrier (BBB) disruption is severe enough to be monitored in contrast-enhanced T1-weighted images, while the abnormal permeability performance can already be clearly found with a higher sensitivity to the hemodynamic changes of lesion areas at the acute stage for these patients.