C. David Ross scite author profile

The purpose of these experiments was to use radiolabelled microspheres to measure blood flow distribution within the brain, and in particular to areas associated with motor function, maintenance of equilibrium, cardiorespiratory control, vision, hearing and smell, at rest and during exercise in miniature swine. Exercise consisted of steady‐state treadmill running at intensities eliciting 70 and 100 % maximal oxygen consumption (V̇O2,max). Mean arterial pressure was elevated by 17 and 26 % above that at rest during exercise at 70 and 100 %V̇O2,max, respectively. Mean brain blood flow increased 24 and 25 % at 70 and 100 %V̇O2,max, respectively. Blood flow was not locally elevated to cortical regions associated with motor and somatosensory functions during exercise, but was increased to several subcortical areas that are involved in the control of locomotion. Exercise elevated perfusion and diminished vascular resistance in several regions of the brain related to the maintenance of equilibrium (vestibular nuclear area, cerebellar ventral vermis and floccular lobe), cardiorespiratory control (medulla and pons), and vision (dorsal occipital cortex, superior colliculi and lateral geniculate body). Conversely, blood flow to regions related to hearing (cochlear nuclei, inferior colliculi and temporal cortex) and smell (olfactory bulbs and rhinencephalon) were unaltered by exercise and associated with increases in vascular resistance. The data indicate that blood flow increases as a function of exercise intensity to several areas of the brain associated with integrating sensory input and motor output (anterior and dorsal cerebellar vermis) and the maintenance of equilibrium (vestibular nuclei). Additionally, there was an intensity‐dependent decrease of vascular resistance in the dorsal cerebellar vermis.

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Transport of Axonal Enzymes in Surviving Segments of Frog Sciatic Nerve

Partlow

Ross

Motwani

et al. 1972

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Redistribution of axonal enzymes as a function of time in vitro was studied in an unbranched segment of frog sciatic nerve. Cholinesterase activity moved peripherally at a rate of 99 mm/day and centrally at 19 mm/day. One-quarter of the total nerve content of the enzyme was estimated to be in motion, one-eighth in each direction. Mitochondrial enzymes (hexokinase and glutamic dehydrogenase) moved peripherally at 20-31 mm/day, centrally at 11-20 mm/day. Only 10% of the total content of these mitochondrial enzymes was in motion. No movement of choline acetylase or 6-phosphogluconic dehydrogenase activity was seen even after 4 days in vitro. However, in a 12 day in vivo experiment choline acetylase moved toward the periphery at a rate of 0.34 mm/day. After a day or so in vitro the distal accumulations of cholinesterase and glutamic dehydrogenase decreased, with a concomitant and quantitatively equivalent increase in enzyme activities at the proximal end of the nerve. It is postulated that during incubation a mechanism for reversing the direction of flow develops in the peripheral stump of the nerve. Vinblastine inhibited central and peripheral flow of both cholinesterase and glutamic dehydrogenase. Movement of cholinesterase was not affected by ouabain, thalidomide, or phenobarbital, nor by K+ excess (110 mM) or absence.

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Effects of large brain stem lesions on the cholinergic system in the rat cochlear nucleus

et al. 1983

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Neurotransmitter Microchemistry of the Cochlear Nucleus and Superior Olivary Complex

Godfrey

Parli

Dunn

et al. 1988

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Effects of trapezoid body and superior olive lesions on choline acetyltransferase activity in the rat cochlear nucleus

et al. 1987

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C. David Ross

Exercise increases blood flow to locomotor, vestibular, cardiorespiratory and visual regions of the brain in miniature swine

Transport of Axonal Enzymes in Surviving Segments of Frog Sciatic Nerve

Effects of large brain stem lesions on the cholinergic system in the rat cochlear nucleus

Neurotransmitter Microchemistry of the Cochlear Nucleus and Superior Olivary Complex

Effects of trapezoid body and superior olive lesions on choline acetyltransferase activity in the rat cochlear nucleus

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