Experimental brain research. Experimentelle Hirnforschung. Expérimentation cérébrale
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Electrical stimulation of the spinal cord above the sacral segments was used to produce coordinated micturition in the paralysed decerebrate cat. Stimulation of the superficial aspect of the dorsolateral funiculus (DLF) within the lower thoracic (T9-T13) segments produced a bladder contraction coordinated with decreased activity in the external urethral sphincter (EUS) branch of the pudendal nerve during which time fluid was expelled. In addition, a similar response was observed with DLF stimulation at the boundary of the L5/L6 segments. ⋯ Stimulation caudal to the lesion produced a decrease in pudendal nerve activity but did not produce a void or bladder pressure change. This reduction in pudendal nerve activity could be abolished with a second lesion of the superficial DLF caudal to the stimulation site. It was concluded that stimulation of the thoracic dorsolateral funiculus activates both ascending and descending fibres which can influence the bladder and/or sphincter muscles.(ABSTRACT TRUNCATED AT 250 WORDS)
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Branching neurons with descending propriospinal collaterals and ascending collaterals to the dorsal medulla, the thalamus and the tectum were studied in the rat's cervical spinal cord (C1-C8), using the retrograde fluorescent double-labeling technique: Diamidino Yellow Dihydrochloride (DY) was injected in the cord at T2, True Blue (TB) was injected in the brain stem. DY-labeled descending propriospinal neurons were present in all laminae, except lamina IX. They were concentrated in lamina I, laminae IV to VIII, and in the lateral spinal nucleus, LSN. ⋯ Conversely, only about 1% of the labeled descending propriospinal neurons gave rise to an ascending spinothalamic collateral, and even fewer (0.1 to 0.6%) to a collateral to the dorsal midbrain. The LSN displayed the highest relative content of branching neurons. Up to 20% of its ascending spinothalamic and spinotectal neurons and up to 8% of its descending propriospinal neurons were found to be branching neurons, indicating that the LSN constitutes an unique cell-group in the rat spinal cord.
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The motor nerve supplying the medial gastrocnemius (MG) muscle was transected in the popliteal fossa of adult cats. The proximal nerve stump was ligated to prevent reinnervation. Three, six or twelve weeks later, axotomized MG motoneurons were intracellularly labelled with horseradish peroxidase, and the morphology of their intramedullary axon collateral systems was investigated quantitatively. ⋯ In the axon collateral trees persisting in the axotomized MG neurons the tree size, branching patterns and number of synaptic boutons were all normal. Thus, no signs of a gradual deterioration of individual axon collateral systems were observed at any postoperative stage studied. The results are discussed in relation to other retrograde degenerative and regenerative events induced by axotomy.
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Chronic axotomy of a peripheral motor nerve in cat causes a gradual reduction in the number of intramedullary axon collaterals originating from the axotomized motoneurons (Havton and Kellerth 1984, 1989). This axon collateral elimination would be expected to reduce the amount of recurrent inhibitory reflex actions mediated by these cells. ⋯ The results, which were obtained by means of intracellular recordings and monosynaptic reflex testing, indicate that postoperative enhancement of reflex actions may take place in the recurrent inhibitory pathways persisting in the axotomized motoneurons as well as in those originating from synergistic nonlesioned motoneurons. It is suggested that the site of compensatory enhancement is at the synaptic reflex contacts between the motoraxon collaterals and the inhibitory Renshaw interneurons.
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To determine speed-related changes in hindlimb motion that might account for the mutability of bifunctional (hip extensor/knee flexor) muscle activity during the E1 phase of swing, we studied hip and knee joint kinematics and kinetics during swing over a ten-fold increase in locomotor speed (0.35 to 3.5 m/s). Three cats were filmed (100 frames/s) while locomoting on a motorized treadmill; kinematics were analyzed for the entire step cycle and kinetics for the swing phase. During swing, angular excursions at the hip and knee joints were similar for walking and trotting, but hip flexion and extension were significantly less after the transition from trot to gallop, while knee-angle range of motion increased during gallop phases E1, E2, and E3. ⋯ Our data on speed-related changes in hindlimb dynamics suggest that the E1 burst amplitude (and perhaps duration) of posterior thigh muscles will be speed related during the walk and trot. After the trot-gallop transition at about 2.5 m/s, the recruitment of these bifunctional muscles may decline due to the changes in hindlimb dynamics. Because activity of these muscles counteracts interactive torques primarily related to leg angular acceleration, we suggest that motion-related feedback decoding this action may be important for regulating recruitment during E1.