Showing posts with label pain perception. Show all posts
Showing posts with label pain perception. Show all posts

Tuesday, October 5, 2010

The Neurology of Pain Perception

Feelings of pain are processed differently than other senses. This post explains the basic neurological processing of pain, including pain receptors and brain regions. Nociception is the sense of pain. Although the feeling of pain seems related to the sense of touch, the two sensations operate very differently at a neurological level. Many think that pain is just the overstimulation of touch, but it is actually its own sense, using its own dedicated receptors and pathways to send its unique signal.When detecting pain, the body uses nociceptors. These receptors are the bare axon terminals of neurons that emanate from the spinal nerve. They are sometimes referred to as free nerve endings. Usually, neurons that have to bring a signal up to the brain are covered in a material called myelin,which allows the signal to be transported very quickly. The neurons that are associated with nociceptors, however, usually only have a little (if any) myelin, which means their signal is transported relatively slowly. There are two types of nociceptors: Aδ nociceptors and C-fiber nociceptors. The Aδ cells are faster and respond to dangerously intense stimuli, and C-fiber cells are slower and respond to thermal, mechanical, and chemical stimuli. Once a pain receptor detects the painful stimulus, it sends a signal down its neuron to the spinal cord. When the signal gets there, it crosses over to the opposite side and shoots up to the brain. This means that an injury to the right side of the body sends a signal that climbs up the left side of the spinal cord. This switching-sides organization gives rise to dissociated sensory loss. If a person experiences a spinal injury, it will affect different processes on either side of the body, depending on where the spine was injured. For example, if a person is injured on the right side of the spine, he or she will not be able to feel a touch on the right foot but will be able to feel pain on that foot. Likewise, the person will feel a touch on the left foot but will not be able to feel pain on that foot.
Once the pain signal gets to the brain, it is sent to a number of structures for processing. The location and intensity of the stimulus is deciphered by the primary and secondary somatosensory cortex. The emotions and automatic reactions to pain are processed in a number of locations, including the hypothalamus, superior colliculus, and amygdala. The complete pain experience, however, arises from the co-operation of a network of brain areas. When pain is induced by tissue damage like cuts and bruises, nociceptors become even more sensitive to pain, a phenomenon known as hyperalgesia. When the tissue is damaged, a number of substances are released into the site of damage. These substances include histamine, serotonin, and prostaglandin, and their presence can modify the activity of nociceptive neurons, making them quicker to send signals to the brain. To reduce the feeling of pain, one must limit the effect of these substances. Some medications, for example, like aspirin and ibuprofen, work by inhibiting the production of one of the substances (prostaglandin). In doing so, the feeling of pain will be reduced, but because it does not account for all of the substances, the pain persists, though to a smaller degree. I have enclosed a video on pain perception, it is the first of a series of three. Click on the title to watch the video and if you like what you see part two and three are available on YouTube.