Fractal Characterization of Complexity in Dynamic Signals: Application to Cerebral Hemodynamics

We introduce the concept of spatial and temporal complexity with emphasis on how its fractal characterization for 1D, 2D or 3D hemodynamic brain signals can be carried out. Using high-resolution experimental data sets acquired in animal and human brain by noninvasive methods – such as laser Doppler flowmetry, laser speckle, near infrared, or functional magnetic resonance imaging – the spatiotemporal complexity of cerebral hemodynamics is demonstrated. It is characterized by spontaneous, seemingly random (that is disorderly) fluctuation of the hemodynamic signals. Fractal analysis, however, proved that these fluctuations are correlated according to the special order of self-similarity. The degree of correlation can be assessed quantitatively either in the temporal or the frequency domain respectively by the Hurst exponent (H ) and the spectral index (β). The values of H for parenchymal regions of white and gray matter of the rat brain cortex are distinctly different. In human studies, the values of β were instrumental in identifying age-related stiffening of cerebral vasculature and their potential vulnerability in watershed areas of the brain cortex such as in borderline regions between frontal and temporal lobes. Biological complexity seems to be present within a restricted range of H or β values which may have medical significance because outlying values can indicate a state of pathology.