Breakthrough in understanding of speech offers hope to the deafScientists on Sunday said intelligible speech is learnt in part through nerve signals from the vocal tract vocal tract n. The airway used in the production of speech, especially the passage above the larynx, including the pharynx, mouth, and nasal cavities. , a discovery that could open up an ambitious avenue of therapy for the deaf. Muscles and receptors in the mouth and throat retain a memory of their position and feeling when a word is uttered, and their signals provide key input for the brain as it hones the power of speech, they suggest. Researchers David Ostry David J. Ostry [1][2] is an engineer and neuroscientist whose research focuses on human motor control. He is a professor of Psychology at McGill University and a senior scientist at Haskins Laboratories in New Haven, Connecticut. and Sazzad Nasir at McGill University McGill University, at Montreal, Que., Canada; coeducational; chartered 1821, opened 1829. It was named for James McGill, who left a bequest to establish it. Its real development dates from 1855 when John W. Dawson became principal. in Montreal carried out an unusual experiment into an enduring mystery: why is it that many deaf people This is an incomplete list of notable deaf people. Important historical figures in deaf history and culture The idea that a person who was deaf could achieve a notable or distinguished status was not common until the latter half of the 18th century, when AbbĂ© Charles-Michel de are still able to speak coherently, sometimes years after losing their hearing? They recruited five middle-aged people who had lost their hearing in adulthood and were now profoundly deaf but had a cochlear implant cochlear implant n. An electronic device that stimulates auditory nerve fibers in the inner ear in individuals with severe or profound bilateral hearing loss, allowing them to recognize some sounds, especially speech sounds. to pick up sounds. With the implant turned off, the five were asked to repeat four specific words while the front of their lower jaw was gently pulled forwards by a small device attached to their bottom row of front teeth. The movement was only tiny but it was sufficient to deform the sounds emitted from the volunteers' mouth. The point of the experiment was to see whether the volunteers were able to adapt to the sudden speech deformation, even if they could not hear the sound they were making. The four words were "saw," "say," "sass" and "sane," chosen because their vowel, dipthong and fricative fricative (frik´  tiv),n a speech sound made by forcing the airstream through such a narrow opening that audible high-frequency air -- the hiss of the "s" -- require a very precise jaw position to be pronounced intelligibly. Even though they were unable to hear the deformed sounds they made, the volunteers progressively learnt to fix the errors in their pronunciation as they ran through a programme of 300 utterances. In fact, they learned as fast as a comparison group of people of a similar age and with normal hearing who performed the same experiment. "The deformation (by the machine) is in the orders of millimetres. Even when these individuals can't hear what they're saying, when the motion path of the jaw is changed just a tiny amount, it's enough to prompt a corrective response," Ostry told AFP (1) (AppleTalk Filing Protocol) The file sharing protocol used in an AppleTalk network. In order for non-Apple networks to access data in an AppleShare server, their protocols must translate into the AFP language. See file sharing protocol. . The study is published online by the journal Nature Neuroscience Nature Neuroscience is a scientific journal published by Nature Publishing Group, the publisher of Nature. Its focus is original research papers relating specifically to neuroscience. . He and Nasir attribute the remarkable adaptive power to "mechanoreceptors Mechanoreceptors Sensory receptors that provide the organism with information about such mechanical changes in the environment as movement, tension, and pressure. ," or nerves and soft tissues in the vocal tract, which remember how they should feel when a word is pronounced properly. Ostry said that the discovery shows that the brain corrects our speech through two simultaneous inputs -- through hearing the sound that we make, and also through these subtler feedback signals. "When a child learns to talk, it gets two kinds of information," Ostry told AFP. "One is the auditory information, being the sound of its own voice. At the same time, it also gets information from receptors that are in the skin and in the muscles. "These receptors develop not only in expectation of what words should sound like, they also develop an expectation of what the word should feel like." Ostry said the experiment focussed only on the muscles of the jaw and facial tissues, but the outcome suggests "mechanoreceptors" are also likely to exist in the lips, the tongue and the muscles of the larynx larynx (lâr`ĭngks), organ of voice in mammals. Commonly known as the voice box, the larynx is a tubular chamber about 2 in. (5 cm) high, consisting of walls of cartilage bound by ligaments and membranes, and moved by muscles. . "It is conceivably a basis for speech therapy, absolutely," he said. "When you're deaf, you've lost one of the two systems that basically support speech, but you still have the other one. And the other one accounts for an enormous proportion for the total sensory inflow that's associated with speech. "It's like having a flat [tyre] and discovering that you have a spare after all." 
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