Mathematical Modeling of Lateralization and Asymmetries in Cortical Maps
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Abstract
Recent experimental work in neurobiology has defined asymmetries and
lateralization in the topographic maps found in mirror-image regions of
the sensorimotor cerebral cortex. However, the mechanisms underlying
these asymmetries are currently not established, and in some cases are
quite controversial. In order to explore some possible causes of map
asymmetry and lateralization, several neural network models of cortical
map lateralization and asymmetries based on self-organizing maps are
created and studied both computationally and theoretically. Activation
levels of the elements in the models are governed by large systems of highly
nonlinear ordinary differential equations (ODEs), where coefficients
change with time and their changes depend on the activation levels.
Special metrics for objective evaluation of simulation results
(represented as paired receptive field maps) are introduced and analysed.
The behavior of the models is studied when their parameters are varied
systematically and also when simulated lesions are introduced into one of
the hemispheric regions. Some very sharp transitions and other
interesting phenomena have been found computationally. Many of these
computationally observed phenomena are explained by theoretical analysis
of total hemispheric activation in a simplified model. The connection
between a bifurcation point of the system of ODEs and the sharp transition
in the model's computational behavior is established. More general
understanding of topographic map formation and changes under various
conditions is achieved by analysis of activation patterns (i.e.,
$\omega$-limit sets of the above system of ODEs).
This is the first mathematical model to demonstrate spontaneous map
lateralization and asymmetries, and it suggests that such models may be
generally useful in better understanding the mechanisms of cerebral
lateralization. The mathematical analysis of the models leads to a better
understanding of the mechanisms of self-organization in the topographic
maps based on competitive distribution of activation and competitive learning.
Also cross-referenced as UMIACS-TR-99-40