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Hearing & Language Processing

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Hearing & Language Processing Structure of the Ear How the Ear Works The ear has three main parts: the outer, middle and inner ear. The outer ear (the part you can ... – PowerPoint PPT presentation

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Title: Hearing & Language Processing


1
Hearing Language Processing
2
Structure of the Ear
3
How the Ear Works
  • The ear has three main parts the outer, middle
    and inner ear. The outer ear (the part you can
    see) opens into the ear canal. The eardrum
    separates the ear canal from the middle ear.
    Small bones in the middle ear help transfer sound
    to the inner ear. The inner ear contains the
    auditory (hearing) nerve, which leads to the
    brain.

4
From Sound Wave to Nerve Impulse
  • Any source of sound sends vibrations or sound
    waves into the air. These funnel through the ear
    opening, down the ear, canal, and strike your
    eardrum, causing it to vibrate. The vibrations
    are passed to the small bones of the middle ear,
    which transmit them to the hearing nerve in the
    inner ear. Here, the vibrations become nerve
    impulses and go directly to the brain, which
    interprets the impulses as sound (music, voice, a
    car horn, etc.).

5
Otitis Media
Otitis media is an inflammation in the middle
ear (the area behind the eardrum) that is usually
associated with a buildup of fluid. The fluid may
or may not be infected. The Eustachian tube, a
passage between the middle ear and the back of
the throat, is smaller and more nearly horizontal
in children than in adults. Therefore, it can be
more easily blocked by conditions such as large
adenoids and infections. This allows bacteria and
viruses to find their way into the middle ear
more easily. Their tubes are also narrower and
less stiff, which makes them more prone to
blockage.
http//www.kidsource.com/ASHA/otitis.html
6
Otitis Media How hearing becomes impaired
  • Three tiny bones in the middle ear carry sound
    vibrations from the eardrum to the inner ear.
    When fluid is present in the middle ear, the
    vibrations are not transmitted efficiently and
    sound energy is lost. This is because the
    flexion of the membranes in the cochlea (which
    then causes the fluid to flow past the cilia and
    bend them for the sounds) is affected. The result
    may be a mild or even moderate hearing loss.
    Therefore, some speech sounds may be muffled or
    inaudible (note think about how this might
    affect phonemic processing during the first 3
    years of life during the critical period).
  • Generally, this type of hearing loss is
    temporary. However, when otitis media occurs over
    and over again, damage to the eardrum, the bones
    of the ear, or even the hearing nerve can occur
    and cause permanent hearing loss.

7
Primary Auditory Pathway
  • Sound travels via the 8th cranial nerve
    (vestibulocochlear)
  • Most of the fibers cross over to the
    contralateral side information received in the
    right ear is processed by the left hemisphere and
    vice versa

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8
From Nerve Impulse to Peception
Wernicke-Geshwind Model of Language
  • 7 Components
  • Primary Auditory Cortex
  • Wernickes Area (22)
  • Arcuate fasciculus
  • Primary Visual Cortex
  • Angular Gyrus
  • Brocas Area
  • Primary Motor Cortex

39
Note in this model the dorsal and ventral
streams from the occipital lobe are not included,
only Area 39 that retrieves and assembles the
phonological code. This is the original model
that has since been elaborated.
9
Original Wernicke-Geschwind Model of Language
from Rosenzweig, et al., 2002
10
Subtractive Pet Scans Notice all the brain areas
affected
from Rosenzweig, et al., 2002
11
What is aphasia?
  • An impairment in language understanding or
    production that is caused by brain injury
  • Brocas aphasia
  • Wernickes aphasia
  • Global aphasia
  • Conduction aphasia
  • Subcortical aphasia

12
Brain Areas Affected in Aphasia
from Rosenzweig, et al., 2002
13
from Rosenzweig, et al., 2002
14
Dual Route Models for Reading Writing
  • Reading
  • Writing

Input (text)
Input (picture, spoken work)
Phonological Route
Whole-Word Route
Phonological Route
Whole-Word Route
Grapheme-Phoneme conversion
Orthographic Input lexicon
Grapheme-Phoneme conversion
Orthographic Input lexicon
Semantic System
Semantic System
Phonological Output
Written Output
Response
Response
15
Dual Route Models for Reading Dyslexia
  • Reading
  • Phonological Dyslexia
  • In this form of dyslexia, the problem occurs
    with attributing the correct sound (phoneme) to
    the grapheme (letter). Errors occur in sounding
    out unfamiliar words such as nonsense words
    because of the phoneme-grapheme impairment. Any
    familiar word, even an irregular familiar word,
    is readable (e.g. colonel).
  • The phonological route is impaired.
  • Errors also occur in the form of visual
    paralexias (e.g., leaf and lead).

Input (text)
Phonological Route
Whole-Word Route
Grapheme-Phoneme conversion
Orthographic Input lexicon
Semantic System
Phonological Output
Response
16
Dual Route Models for Reading Dyslexia
  • Reading
  • Surface Dyslexia
  • In this form of dyslexia, the problem occurs
    only with unfamiliar words (e.g., colonel), but
    sparing of regular (e.g., dog) or nonwords. The
    whole-word route is impaired, but the reader is
    able to apply the grapheme-phoneme conversion.
  • Errors occur in understanding the meaning of
    words that sound the same (i.e. homophones such
    as son and sun).

Input (text)
Phonological Route
Whole-Word Route
Grapheme-Phoneme conversion
Orthographic Input lexicon
Semantic System
Phonological Output
Response
17
Dual Route Models for Reading Dyslexia
  • Deep Dyslexia
  • This form of dyslexia is similar to phonological
    dyslexia, but the problem occurs only in reading
    nonwords or words that do not have strong visual
    or phonetic components (on, it,the).
  • Substituting one word with another word that has
    a similar semantic meaning occurs Infant was
    crying is changed to Baby was crying (semantic
    paralexia).
  • Etiology? Perhaps a disconnection between the
    phonological and the whole-word routes.
  • Reading

Input (text)
Phonological Route
Whole-Word Route
Grapheme-Phoneme conversion
Orthographic Input lexicon
Semantic System
Phonological Output
Response
18
A few final points
  • Dysgraphia follows the same model as dylexia
    (phonolological, surface, deep)
  • Impairment in prosody is a right hemisphere
    problem it can significantly affect the meaning
    of language.
  • Typically, children do not fall into one distinct
    dyslexic subtype rather, they might have a
    stronger orientation or approach to reading that
    follows this model because of a problem that
    affects the other path (e.g., strong visual
    memory or visuospatial skills and otitis media
    affecting phonological processing).

19
Visual and Spatial Abilities
20
  • Visual processing is accomplished in distinct
    neuroanatomic pathways.
  • One such pathway, known as the where pathway
    involves a dorsal route through magnocellular
    thalamic cells to occipital and parietal cortices
    and conveys location and motion information.
  • A second pathway, known as the what pathway
    involves a ventral route through parvocellular
    thalamic cells to occipital and temporal cortices
    and conveys color and form information.
  • Note Subtle differences in this process as it
    applies to reading

21
Neural Mechanisms for Reading the Left Hemisphere
Written word is sent along the ventral stream to
the word-form area (inferior temporal cortex),
which links the orthographic representation
(visual pattern) with the phonological code (Area
39). The neural networks that retrieve and
assemble phonological codes (Area 39) and those
that associate meaning with words are distributed
over the dorsal stream. Note This occurs in the
left hemisphere and reflects mature reading. In
young children, Wernickea area is more involved
as well as the ventral stream in the right
hemisphere (which later disengages) for
visuospatial information. Also, the left frontal
lobe becomes engaged and is associated with
reading fluency, which can be affected by frontal
lobe immaturity.
39
philosophy.hku.hk/courses/cogsci/ncc.php
22
What about the Right Hemisphere?
  • Dorsal and ventral streams follow a similar
    pathway in the right hemisphere, but because
    there is complementary communication between
    hemispheres, some psychologists prefer to think
    of only dorsal and ventral streams as the basis
    for reading.
  • Nonetheless, the brain is lateralized for
    speech/language in the left hemisphere and
    spatial processing in the right hemisphere.
  • In the right hemisphere
  • dorsal stream discrimination of spatial
    location (includes where the item is located in
    space).
  • ventral stream discrimination of form
    (includes how to interact with an item) and is
    actively involved in early reading.
  • Mathematics involves these spatial properties of
    the right hemisphere and later merges with left
    hemisphere language areas (i.e., math develops
    language components).
  • Early reading involves the spatial components of
    the right hemisphere as well, until it becomes
    more lateralized to the left.
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