Neural Mechanisms In Tactile, Kinaesthetic And Pain Sensation
Funder
National Health and Medical Research Council
Funding Amount
$644,113.00
Summary
Our knowledge of the world around us depends upon our sensory systems which provide a series of windows on the world, enabling the mind and brain to sample information about selected events through the energy forms that impinge upon us. Much of this sensing process takes place through our special sense systems such as the eye, the ear, and the taste and olfactory systems. However, other crucial sensory systems are more generalized throughout the body and are referred to as the somatic sensory sy ....Our knowledge of the world around us depends upon our sensory systems which provide a series of windows on the world, enabling the mind and brain to sample information about selected events through the energy forms that impinge upon us. Much of this sensing process takes place through our special sense systems such as the eye, the ear, and the taste and olfactory systems. However, other crucial sensory systems are more generalized throughout the body and are referred to as the somatic sensory systems. These include our senses of touch, temperature, pain and body position, the last of which is known as our kinaesthetic sense. Our research into the neural mechanisms in sensation and perception is concerned with the tactile, kinaesthetic and pain senses. Although many thousands of nerve fibres travel in the nerves arising from particular regions of the skin or from individual muscles or joints, the sensory nerve fibres that serve these forms of sensation fall into fewer than ten broad classes, made up of five major tactile classes, two or three major kinaesthetic classes, and two broad groups of fibres that mediate pain sensation. However, there is quite striking evidence that when single fibres of these different classes are activated in conscious human subjects, there are marked differences among the fibre classes in their capacity to generate a perceptual response. Under the new NH and MRC grant we propose to examine the transmission and processing of input signals from these fibre classes at the highest levels of the brain, in particular, within the cerebral cortex, in order to reveal the neural mechanisms responsible for their differential perceptual contributions. The proposed analysis will provide fundamental insights into the neural basis for perceptual recognition and will provide information that may be important for our eventual understanding of the disorders of sensory perception that characterize psychiatric conditions such as schizophreniaRead moreRead less
Brain And Skin Blood Flow: New Animal Model For Understanding Psychiatric Disorders And Evaluating Psychotropic Agents
Funder
National Health and Medical Research Council
Funding Amount
$874,840.00
Summary
We suddenly become pale when we get a fright; cutaneous blood vessels are linked to psychological function. The skin vessel constriction response occurs because special neurochemical pathways in the brain send messages to the spinal cord, and from there messages traverse peripheral sympathetic nerves to constrict the blood vessels in the skin. By measuring skin blood flow in the rabbit ear and the rat tail we have been able to discover the major brain pathway by which the constrict-the-skin-bloo ....We suddenly become pale when we get a fright; cutaneous blood vessels are linked to psychological function. The skin vessel constriction response occurs because special neurochemical pathways in the brain send messages to the spinal cord, and from there messages traverse peripheral sympathetic nerves to constrict the blood vessels in the skin. By measuring skin blood flow in the rabbit ear and the rat tail we have been able to discover the major brain pathway by which the constrict-the-skin-blood-vessels message reaches the spinal cord. The pathway involves the amygdala, a forebrain region important in emotional expression and the raphe nuclei in the medulla oblongata. Drugs which affect psychological function also effect skin blood flow. Ecstasy, the street drug used to induce euphoria also constricts the skin vessels, and, sadly, the body temperature may increase so much that death ensues. Ecstasy vigorously constricts the skin blood vessels in rabbits, and temperature increases. Ecstasy is thought to act on serotonin-containing nerve cells in the brain, releasing serotonin (5-HT) onto special 5-HT2A receptors. Activation of these receptors affects both psychological function and skin blood flow. Modern drugs used to treat schizophrenia, so called atypical antipsychotics like clozapine and olanzapine, are thought to act as antagonists at 5-HT2A receptors in the brain. We were thus very excited when we discovered in our rabbit model that clozapine reverses the skin vasoconstriction induced by ecstasy. This means that we have specific hypotheses concerning the actual brain pathways and neurotransmitters whereby ecstasy and clozapine exert their effects on skin blood flow. Elucidating these pathways in rabbits and rats will provide solid knowledge concerning the mechanism of action of the atypical antipsychotics, and it may well prove possible to use our animal model to predict whether proposed new antipsychotic agents will be therapeutically effective.Read moreRead less