Title: II' The Phonatory System:
1II. The Phonatory System
2A. Structures of the Phonatory Tract
- The phonatory tract is the pathway a sound takes
from the moment it is produced until it leaves a
persons head. - The four regions of the vocal tract are the
nasal, the oral, the laryngeal, and the
pharyngeal cavities. - For this module, we will focus on the pharyngeal
and laryngeal regions.
31. The Pharynx
- The pharynx is a musculo-membranous tube lined
entirely with mucous membrane. - It is 4-5 long and somewhat oval in shape.
- It extends from the base of the skull to in
between C6 and the cricoid cartilage of the
larynx.
41. The Pharynx
- The pharynx is divided into three parts
- the nasopharynx,
- the oropharynx and the
- laryngopharynx.
5a. The Nasopharynx
- The nasopharynx is the uppermost portion of the
pharynx. - Its superior boundary is the base of the skull.
- Its anterior boundary is the nasal cavity.
- Its inferior boundary is the soft palate.
6a. The Nasopharynx
- The lateral walls of the nasopharynx contain the
pharyngeal orifice, the opening into the
Eustachian tube. - This opening allows communication with the middle
ear.
7a. The Nasopharynx
- The posterior nasal port can be opened or closed
depending on the position of the soft palate.
8b. The Oropharynx
- The oropharynx begins superiorly at the soft
palate. - It extends inferiorly to the hyoid bonea bone
running roughly parallel to the chin at the base
of the tongue.
9b. The Oropharynx
- Anteriorly, the oropharynx communicates with the
faucial pillars of the oral cavity. - The palatine tonsils are found lying between the
faucial pillars.
10c. The Laryngopharynx
- The laryngopharynx begins superiorly at the hyoid
bone. - Its inferior anterior border is the epiglottis.
- Its inferior posterior border is continuous with
the esophagus.
112. The Larynx
- The larynx is a cartilaginous structure supported
in the neck by a series of flat strap muscles.
122. The Larynx
- Its superior support is the hyoid bone.
- Its inferior point of attachment is the trachea.
132. The Larynx
- The entire laryngeal structure is lined with
mucous membrane. - The underlining of the glottis, down to the
trachea has a very rich, wet mucous membrane that
constantly lubricates the vocal folds.
142. The Larynx
- Nerve supply to the larynx is provided by the
Vagus (Xth) cranial nerve. - The blood supply is from a branch of the common
carotid artery.
152. The Larynx
- The larynx is comprised of three sets of folds
- The aryepiglottic folds are found at the upper
rim of the larynx connected to the epiglottis.
162. The Larynx
- The ventricular or false folds are thick bands of
tissue above the glottis. - The vocal (true) folds are the phonatory
vibrators.
172. The Larynx
- The space between the true and false folds is
termed the ventricle. - At the level of the vocal folds (glottis) the
larynx is anatomically divided into two parts. - The vestibule constitutes the supraglottic
region. - The atrium constitutes the infraglottic region
18B. Laryngeal Anatomy
- There are no bones in the larynx.
- The entire laryngeal framework is cartilaginous.
- However, the larynx is suspended from the hyoid
bone, but it is not part of the larynx proper. - All cartilages, ligaments, membranes, and muscles
of the larynx are utilized in phonation.
19B. Laryngeal Anatomy
- The 9 cartilages of the larynx are the thyroid
cartilage, the cricoid cartilage, the epiglottis,
the paired arytenoids, the paired corniculates,
and the paired cuneiforms.
20Cartilagesa. Thyroid Cartilage
- The thyroid cartilage is the most prominent
cartilage. - It is a type of hyaline cartilage comprised of
two flat plates (laminae) fused together at an
angle to form the laryngeal prominence.
211. Cartilages a. Thyroid Cartilage
- In adult females, the angle of the laryngeal
prominence is 120 degrees. - In adult males, the angle is more acute at 90
degrees.
221. Cartilages a. Thyroid Cartilage
- Along the superior border of the thyroid
cartilage is the thyroid notch. - From the superior posterior edge of each lamina
are the superior cornu. - Inferiorly, the inferior cornu descend from the
laminae.
231. Cartilages a. Thyroid Cartilage
- The thyrohyoid ligament attaches the superior
cornu to the hyoid bone. - The ceratocricoid ligament attaches the inferior
cornu to the cricoid cartilage.
241. Cartilages b. Cricoid Cartilage
- The cricoid cartilage is found inferior to the
thyroid cartilage. - It forms a considerable portion of the posterior
wall of the larynx. - It is shaped like a signet ring, wider
posteriorly than anteriorly.
251. Cartilages b. Cricoid Cartilage
- On its lateral borders are articular facets which
receive the inferior cornu of the thyroid
cartilage. - On its superior posterior surface are articular
facets for the arytenoid cartilages.
261. Cartilages b. Cricoid Cartilage
- Ligaments secure the cricoid cartilage to the
thyroid cartilage and to the trachea. - Specifically, the cricothyroid ligament secures
the cricoid and thyroid cartilages. - The cricotracheal ligament secures the cricoid
cartilage to the first tracheal ring.
271. Cartilages c. Arytenoid Cartilages
- The paired arytenoid cartilages are three-sided
pyramidal structures that rest on the superior
posterior border of the cricoid cartilage.
281. Cartilages c. Arytenoid Cartilages
- Each arytenoid has a broad base and diminishes in
size as it rises toward the apex. - The lateral posterior base has a large knob-like
projection called the muscular process. - The medial anterior base has a small projection
called the vocal process. - The vocal process is the point of attachment for
the vocal folds.
291. Cartilages d. Corniculate Cartilages
- The paired corniculate cartilages are small
elastic cartilages fused with the apex of the
arytenoids. - These seem to do little more than support the
aryepiglottic folds.
301. Cartilages d. Corniculate Cartilages
- Another pair of small elongated cartilages, the
cuneiform cartilages, are embedded with the
mucous membrane of the aryepiglottic folds. - They support these folds during swallow, when the
epiglottis moves to cover the larynx.
31Figure 1 The Corniculate Cuneiform Cartilages
in Situ
321. Cartilages e. Epiglottis
- The flat, leaf-shaped cartilage rising out of the
larynx is the epiglottis. - It is attached inferiorly to the thyroid
cartilage below the notch by the thyroepiglottic
ligament. - Superiorly it is attached to the body of the
hyoid bone by the hyoepiglottic ligament.
332. Laryngeal Muscles
342. Laryngeal Muscles
- The muscles found in the larynx are of two types
- The extrinsic muscles have one point of
attachment external to the larynx. - The intrinsic muscles have both points of
attachment within the larynx.
352. Laryngeal Muscles
- Most of the extrinsic muscles are responsible for
either elevating or depressing the entire larynx,
especially during swallow. - In trained singers, the extrinsic muscles may
help produce notes outside the normal singing
range.
362a. Extrinsic Laryngeal Muscles
- The suprahyoid muscles are those extrinsic
muscles with a point of attachment above the
hyoid bone. - They raise the larynx for swallowing and high
note singing functions. - The infrahyoid muscles have a point of attachment
below the hyoid bone. - They lower the larynx after swallow and for low
note singing functions.
372b. Intrinsic Laryngeal Muscles
- There are 5 groups of intrinsic laryngeal
muscles. - They perform important functions in positioning
the larynx for phonation. - They are categorized by the actions they perform.
382b. Intrinsic Laryngeal Muscles
- Abductors open the vocal folds.
- There is one pair of glottal abductors.
- Adductors close the vocal folds.
- There are two muscles that adduct the folds.
- Glottal tensors raise vocal pitch.
- There is one pair of muscles that lengthens the
vocal folds. - Glottal relaxers lower vocal pitch.
- There is one pair of muscles that shortens the
vocal folds.
392b 1). Abductors
- When the posterior cricoarytenoid muscle
contracts, it pulls the muscular processes toward
midline, which moves the vocal processes apart
and abducts (opens) the vocal folds. - It is located on the posterior lamina of the
cricoid cartilage and attaches to the muscular
process of the arytenoid cartilage.
402b 2). Adductors
- The arytenoideus muscle, both the transverse and
oblique portions, is a singular muscle running
between the two arytenoid cartilages. - When it contracts, it pulls the vocal processes
toward midline and tips the apices forward to
adduct (close) the vocal folds.
412b 2). Adductors
- The paired lateral cricoarytenoid muscle attaches
to either side of the cricoid cartilage and to
the muscular process of each arytenoid. - When it contracts, it pulls the muscular
processes laterally, which approximates the vocal
processes in adduction.
422b 2). Adductors
- Heres is another view of the lateral
cricoarytenoid muscle. - You can see its insertion of the muscular process
of the arytenoid cartilage.
432b 3). Glottal Tensors
- Each pair of the cricothyroid muscle has two
different fiber types vertical and oblique. - These muscles originate at the lateral sides of
the cricoid cartilage and insert into the
posterior lamina of the thyroid cartilage.
442b 3). Glottal Tensors
- When contracted, the muscle pulls down and tilts
the thyroid cartilage forward. - The vocal folds are stretched, which reduce their
mass and results in a rise in pitch.
452b 4). Glottal Relaxers
- The thyroarytenoid muscles, the muscular base of
the vocal folds themselves, constitute the
glottal relaxers. - Contraction of this muscle draws the arytenoids
toward the thyroid cartilage, increasing the
thickness of the vocal folds, and lowering the
pitch.
462b 4). Glottal Relaxers
- The thyroarytenoid muscles originate on the
internal surface of the thyroid cartilage near
the angle. - Each muscle has two fiber bundles.
- The thyromuscularis portion inserts into the
muscular process of the arytenoid cartilage. - The thyrovocalis portion inserts into the vocal
process of the arytenoid process.
473. Histology of the Vocal Folds
- Hirano (1974, 1981) has shown that the vocal
folds are composed of five microscopically
distinct tissue layers. - The outermost layer, the epithelium, is a thin,
stiff cover that maintains the shape of the vocal
folds.
483. Histology of the Vocal Folds
- Next we have the lamina propria.
- The superficial layer
- consists of loose fibers in a mass of soft
gelatin. - It is thought to serve as a shock absorber for
the ligament, which is made up of the
intermediate and deep layers.
493. Histology of the Vocal Folds
- Finally, the thryoarytenoid muscle makes up the
final layer of vocal fold tissue. - It makes up the main body of the vocal fold and
is capable of contraction.
503. Histology of the Vocal Folds
- To understand vocal fold mechanics, it is easier
to think of them as consisting of three sections - A cover
- A transition and
- A body.
513. Histology of the Vocal Folds
- The cover has the stiff thin epithelium and the
underlying fluid-like mucosa - The transition is the vocal ligament where large
mechanical stress occurs. - The body consists of the muscle itself which
controls the shape of the VF and the degree of
tonicity.
523. Histology of the Vocal Folds
- For clear phonation, the margins of the vocal
folds must be mobile. - During phonation, the cover of the fold produces
a wave-like motion.
533. Histology of the Vocal Folds
- The undulating wave of movement travels from the
lower surface to the upper surface of the VF in
each cycle of vibration. - Indeed, the mucous membrane cover vibrates more
than the muscle during phonation.
543. Histology of the Vocal Folds
- In patients with scarred or dry vocal folds, the
mucosa loses its mobility, and phonation is
breathy and elevated in pitch because the VFs are
stiff not pliable.
55C. Laryngeal Physiology
- 1. Properties of Sound Waves
561. Properties of Sound Waves
- Undisturbed air is in a state of equilibrium.
- When an external force impinges on the air
particles, the may move closer together or
farther apart, depending upon the location of the
disturbance. - Compression occurs when air molecules move closer
together - Rarefaction occurs when air molecules move
farther apart.
571. Properties of Sound Waves
581. Properties of Sound Waves
- Like liquid, air is fluid, and molecules tend to
flow from regions of higher pressure to regions
of lower pressure. - Air molecules also tend to remain in motion until
the energy imparted has been dissipated. - Like a rock thrown into an undisturbed pond, air
molecules, like water ripples, will move outward
in all directions, compressing the air ahead
(increasing pressure) and leaving a drop in
pressure behind.
591. Properties of Sound Waves
601. Properties of Sound Waves
- A periodic air wave is generated any time there
is a disturbance of air particles by force. - As they travel through the air, progressive
longitudinal wave forms are produced.
61a. Frequency
- Periodic air waves travel as pulses of
compression and rarefaction from their point of
origin. - Each cycle of one compression and one rarefaction
is termed an oscillation. - Frequency, perceived as pitch, is dependent upon
the number of oscillations or cycles per second.
62a. Frequency
- The perceived pitch of a sound increases in
proportion to its frequency of oscillation. - Frequency of oscillation is expressed in Hertz
(Hz).
63b. Intensity
- The amplitude of a sound wave is determined by
the amount of air particle displacement from its
position of equilibrium. - The greater the displacement of air particles,
the larger the wave generated and the more
intense the sound.
64b. Intensity
- Loudness is the perceptual correlate of the
amplitude of a sound wave. - The greater the amplitude the louder the sound.
- Intensity of sound is measured in decibels (dB).
65Figure 2 Sinusoidal Waves
- Looking at the sinusoidal wave on the overhead,
consider the following - Which waves have the same frequency?
- Which wave has the greatest amplitude?
- Which waves have the same amplitude?
- Which wave has the greatest frequency?
662. Normal Voice Characteristics Variants
- A normal speaking voice has the following
characteristics - It operates on a mechanism which is structurally
sound, free from disease, or pathologies - It is esthetically pleasing.
- It is appropriate to the age, sex, and size of
the speaker. - It is physiologically efficient, producing
maximum output with minimal energy.
672a. Fundamental Frequency
- The fundamental frequency (fo) of the voice is
determined by three things - Vocal fold length
- Vocal fold tension and
- Vocal fold mass in combination with subglottic
pressure. - The measure of fo reflects the vibratory rate of
the vocal folds during vowel prolongation tasks.
682a. Fundamental Frequency
- Vocal fold length is greater for men than women,
and greater for adults than children. - It is during puberty that significant increases
in vocal fold length occur. - The male vocal fold increases 1/3 to 1/2 in
length to range from 2/3 to 3/4 in total length. - The female vocal fold increases 1/4 to 1/3 in
length to range from 1/2 to 2/3 in total length.
692a. Fundamental Frequency
- Vocal fold tension is determined by the
relationship of the vocal folds to the cartilages
to which they are attached. - If the vocal folds are stretched and elongated by
the contraction of the cricothyroid muscle, they
will vibrate more quickly. - If the vocal folds are lax and shortened by
contraction of the thyroarytenoid muscles, they
will vibrate more slowly.
702a. Fundamental Frequency
- Vocal fold mass refers to the amount of vocal
tissue, not to weight. - Generally, the bigger the person, the greater the
mass of his/her vocal folds. - Changes in tension will change vocal fold mass.
- When vocal fold tension increases, the mass of
the vocal fold is reduced. - When vocal fold tension decreases, the mass of
the vocal fold is increased.
712a. Fundamental Frequency
- A voice of higher pitch is produced when the
vocal folds are tense, thin (reduced mass), and
vibrating quickly. - A voice of lower pitch is produced when the vocal
folds are lax, bulky (increased mass), and
vibrating slowly.
722b. Vocal Intensity
- Vocal loudness varies according the the
respiratory airflow and subglottic air pressure
passing through the glottis. - Air pressure and airflow affect the size of the
excursions (movement away from midline) executed
by the vocal folds.
733c. Relationship between Frequency, Intensity,
and Subglottic Air Pressure
- With natural vibration, frequency of vibration is
based on natural mass of vocal folds and
intensity is based on natural air pressure
energy. - An easy way to remember how frequency of
vibration, intensity of vibration, and air
pressure are inter-related is the Puff Theory.
743c. Relationship between Frequency, Intensity,
and Subglottic Air Pressure
- The Puff Theory states that
- small, rapid puffs create soft, high pitch.
- large, rapid puffs create loud, high pitch.
- small, slow puffs create soft, low pitch.
- large, slow puffs create loud, low pitch.
- This is a short answer on the exam.
753c. Relationship between Frequency, Intensity,
and Subglottic Air Pressure
- If an additional energy source is used to affect
vibration, the mass must be altered in some way
to keep the vocal folds closed beyond the time
needed for a regular amount of subglottic air
pressure to open them. - Only muscle force can ensure extra resistance.
- Therefore, the vocal folds must tense, and that
tension reduces mass, and pitch rises
correspondingly.
76Figure 3. Stroboscopic View of Vocal Folds
773d. Normal Vocal Variants
- On average, the habitual pitch level is estimated
to be roughly 128 Hz in men, 225 Hz in women, and
265 Hz in children. - Maximum frequency ranges can extend from a low fo
of 77 Hz to a high fo of 567 Hz in men - In women, the average range is from a low fo of
134 Hz to a high fo 895 Hz. - Average intensity of conversational speech 3
from the listener is 60 dB. - Quiet speech is 35-40 dB and loud speech can
exceed 110 dB.
783e. Vocal Registers
- The shape, length, density, and elasticity of the
vocal folds alter constantly in the production of
notes of different frequency. - The vibratory pattern of the vocal folds and the
acoustic parameters they produce can be changed
over some ranges of pitch and loudness.
793e. Vocal Registers
- Three perceptually distinct registers of vocal
quality have been identified (Hollien, 1974). - For speaking they are called pulse (fry)
modal and falsetto (loft). - For singing, they are called chest head and
falsetto.
803e. Vocal Registers
- To produce a vocal fry, the thyroarytenoid
muscles are active. - As they shorten, the vocal folds thicken, which
results in their remaining closed over an
appreciable part of each cycle of vibration.
813e. Vocal Registers
- Vocal fry is a fairly common occurrence in
everyday speech. - Sometimes known as creaky voice, it is frequent
in vocal strain and abuse. - The frequency involved is within the 20-60 Hz
range.
823e. Vocal Registers
- The modal register encompasses the range of notes
employed most frequently in normal phonation.
833e. Vocal Registers
- The falsetto register occurs in human vocal
activities such as singing, war cries, yodeling,
and giggling. - The thyroarytenoid muscles are passive offering
little resistance to the cricothyroids, which
apply substantial longitudinal tension to the
vocal folds, lengthening and thinning the vocal
ligaments. - In phonation, the glottis closely only briefly,
or not at all, allowing only the edges of the
vocal folds (vocal ligaments) vibrate.
843f. Vocal Attacks
- To initiate phonation, subglottic air pressure
builds up under the vocal folds which are closely
approximated in midline. - There are three basic vocal or phonatory attacks.
- Simultaneous attack
- Glottal attack and
- Breathy attack.
853f. Vocal Attacks 1) Simultaneous Attack
- Simultaneous attack results when vibration of the
vocal folds begins just as air is being released
and the vocal folds are approximating in midline.
- When there is simultaneous release of air
pressure through the glottis and onset of
phonation, the attack is healthy and not
damaging.
863f. Vocal Attacks 2) Glottal Attack
- Some phonatory initiation results from laryngeal
hyperfunction. - The glottal attack is such a form of laryngeal
hyperfunction. - With hyperfunction, the entire laryngeal
apparatus is tensed. - Physiologically, a hard glottal attack is
produced by firmly compressing the vocal folds at
the midline before phonation. - The breath stream is then released explosively as
exhalation begins
873f. Vocal Attacks 3) Breathy Attack
- Onset of phonation that results from laryngeal
hypofunction is termed a breathy or aspirate
attack. - In the soft attack, the vocal folds are being
adducted while there is an air flow through the
glottis. - While this type of attack rarely damages the
vocal cords, it causes a breathy tone quality. - This technique may, however, be utilized to help
correct a hard glottal attack.