Morphological characteristics of Lugaro cells in the cerebellar cortex.

Two types of Lugaro cells were identified in the cat cerebellar cortex using sections impregnated with silver nitrate by the Golgi-Kopsch method; these cells were fusiform and triangular and their bodies were located at different levels in the granular layer. Their processes were directed horizontally, vertically, or obliquely to the axis of the leaf; axons never left the cerebellar cortex. These cells should therefore be regarded as interneurons. The processes of Lugaro cells were very extended, with the result that these cells formed numerous axosomatic and axodendritic contacts with all cerebellar cortical neurons and fibers. The structural and topographical characteristics of Lugaro cells and the features of their contacts with other cells in the cerebellar cortex, taken together with data on their neurotransmitter contents, show that they function as inhibitory interneurons.

Dynamics of changes in operant reflexes in rats after transection of the corticospinal tract and removal of the sensorimotor region of the cerebral cortex.

Prior unilateral transection of the bulbar pyramid facilitated recovery of operant reflexes and compensatory processes occurring after removal of the ipsilateral sensorimotor cortex in rats. This increase in corticofugal plasticity was absent when only the sensorimotor cortex was removed. This phenomenon is explained by switching of descending influences to the corticorubrospinal system via the following loop: corticobulbar projection--red nucleus--lower olive--cerebellum--thalamus--cortex. A general property of this phenomenon is that prior lesioning of the peripheral part of the descending spinal projection acquires anticipatory signal value for mobilizing the compensatory abilities of the brain with the aim of recovering from the deficit of the central branch of the system.

Compensatory restorative processes and operant reflexes in rats after neurotoxin lesioning of the inferior olive.

Studies on rats showed that complete neurotoxin lesioning of the inferior olive obviated the possibility of developing and restoring previously learned operant balance reflexes. Motor deficit and compensatory-restorative processes in rats treated with 3-acetylpyridine and high section of the dorsolateral funiculus of the spinal cord depended directly on the level of disruption of the inferior olive. Prolonged observation of rats with incomplete lesions to the inferior olive revealed improvements in the compensation of motor lesions and stabilization of operant reflexes.