A. Pellionisz scite author profile

The natural complexity of the brain, its hierarchical structure, and the sophisticated topological architecture of the neurons organized in micronetworks and macronetworks are all factors contributing to the limits of the application of Euclidean geometry and linear dynamics to the neurosciences. The introduction of fractal geometry for the quantitative analysis and description of the geometric complexity of natural systems has been a major paradigm shift in the last decades. Nowadays, modern neurosciences admit the prevalence of fractal properties such as self-similarity in the brain at various levels of observation, from the microscale to the macroscale, in molecular, anatomic, functional, and pathological perspectives. Fractal geometry is a mathematical model that offers a universal language for the quantitative description of neurons and glial cells as well as the brain as a whole, with its complex three-dimensional structure, in all its physiopathological spectrums. For a holistic view of fractal geometry of the brain, we review here the basic concepts of fractal analysis and its main applications to the basic neurosciences.

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Brain modeling by tensor network theory and computer simulation. The cerebellum: Distributed processor for predictive coordination

Pellionisz

Llinás

1979

Neuroscience

523

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Space-time representation in the brain. The cerebellum as a predictive space-time metric tensor

Pellionisz

1982

Neuroscience

387

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A. Pellionisz

Fractals in the Neurosciences, Part I: General Principles and Basic Neurosciences

Brain modeling by tensor network theory and computer simulation. The cerebellum: Distributed processor for predictive coordination

Space-time representation in the brain. The cerebellum as a predictive space-time metric tensor

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