Development of Phonation PDF

Summary

This document is a presentation on the development and aging of phonation, detailing prenatal development of the phonatory mechanism and the formation of the neural tube. It provides a comprehensive timeline of development, discussing the changes in the vocal folds.

Full Transcript

Development and aging in phonation

JP Louboutin

30/9/2024
 PRENATAL DEVELOPMENT OF THE
PHONATORY MECHANISM
Development of the larynx is intertwined with that of the respiratory mechanism
 Formation of neural tube
- Neurulation: process whereby
neural plate forms neural tube

- The neural plate develops a
neural groove which then
deepens and is bounded
on either side by neural folds

- Gradually, the neural folds
fuse converting the neural
groove into a neural tube
 Formation of neural tube
- Neurulation: process whereby
neural plate forms neural tube

- The neural plate develops a
neural groove which then
deepens and is bounded
on either side by neural folds

- Gradually, the neural folds
fuse converting the neural
groove into a neural tube
 Development of neural tube
- In earliest stages, neural tube remains in communication with amniotic cavity
through anterior and posterior neuropores Anterior neuropore

Neural plate

Fusion of
neural folds

Posterior neuropore

- Later, the anterior neuropore closes first, then the posterior neuropore. Neural tube
closure is complete within 28 days. Neural tube located beneath the surface ectoderm
Closure of neuropores at 25 and 28 days
Formation of neural crest
- During the invagination of the neural plat
form the neural groove, cells forming the la
margin of the plate do not become incorpor
in the neural tube but instead form a strip o
ectodermal cells that lie between the neura
tube and the covering ectoderm. This strip o
cells is called neural crest

- Neural crest will undergo epithelial-to
mesenchymal transition as it leaves
neuroectoderm by active migration to
enter underlying mesoderm

- Cells of the neural crest will
differentiate into cells of posterior
root ganglia, sensory ganglia of
cranial nerves, autonomic ganglia,
melanocytes, cells of suprarenal
medulla, Schwann cells
 WEEK 4

Week 4: Neural crest cell migration occurs
Migrate from margins of neural plate
Will differentiate to form structures of head and
neck
Become the pharyngeal arch system
 THE PHARYNGEAL ARCHES OF PHONATION

Hyoid Arch (2nd arch): Part of hyoid bone
3rd Arch: the rest of the hyoid bone
4th & 6th Arches:
pharyngeal, recurrent, superior laryngeal nerves
of X vagus;
Extrinsic and intrinsic laryngeal muscles
Thyroid, corniculate, cuneiform, and arytenoid
cartilages
 TIMELINE OF DEVELOPMENT
Early in 4th week the laryngotracheal diverticulum develops from
pharyngeal tube, then forms the respiratory bud (later to be lungs)
Respiratory tree communicates with pharyngeal tube by means of
laryngeal inlet: this will become the aditus to the larynx
Splanchnic mesenchyme of 4th & 6th arches will develop into the
cartilages
Arytenoids develop as a swelling; then glottis, laryngeal ventricles,
vocal folds, epiglottis, ventricular folds
End of week 4:
Respiratory system arises from the laryngotracheal pouch of the 4 th
pharyngeal arch
Endoderm of 4th arch forms glands of larynx, trachea and bronchi, and
pulmonary epithelium
WEEKS 4 - 8
 BETWEEN DAYS 28 AND
32
Week 4: Trachea
separates from
esophagus as bronchial
buds emerge
Week 5:
tracheoesophageal
tube develops from the
diverticulum, and there
will be larynx, trachea,
bronchi, lungs
 BIRTH AND GROWTH

Vocal fold length:
Vocal folds are about 4 mm
long at birth
Will be 12-15 mm long in
teens
Changes happen in
puberty
Sexual dimorphism at
puberty
Adult males: 17.5 to 25
mm
Adult females: 12.5 to
17.5 mm
 Histology of larynx: 5 layers
1. Cover
- 3 elements: epithelium (mucosa), basal lamina
or basement membrane zone (BMZ), and
superficial layer of the lamina propria

+ Epithelium

- Free edge of vibratory portion of vocal fold,
anterior glottis, is covered with
stratified squamous non-keratinized epithelium.
This epithelium is five to twenty-five cells thick

- On surfaces of epithelial cells are microridges
and microvilli. Lubrication of the vocal folds
through adequate hydration is essential for
normal phonation to avoid excessive abrasion,
and the microridges and microvilli help to
spread and retain a mucous coat on the
epithelium

- Epithelium described as a thin shell, the
purpose of which is to maintain the shape of the
+ Basal lamina or basement membrane zone (BMZ)

- Two zones, lamina lucida and lamina densa.

+ Lamina lucida: low density clear zone medial to the epithelial basal cells

+ Lamina densa: greater density of filaments and adjacent to lamina propria.
BMZ mainly provides physical support to the epithelium through anchoring fibers
and is essential for repair of epithelium

+ Superficial layer of the lamina propria

- Consists of loose fibrous components and extracellular matrices that can be
compared to soft gelatin. Also known as Reinke’s space but it is virtual space

- Structure that vibrates a great deal during phonation, and the viscoelasticity
needed to support this vibratory function depends mostly on extracellular
matrices

- Primary extracellular matrices of the vocal fold cover contain reticular,
collagenous and elastic fibers, as well as glycoproteins and
glycosaminoglycans

- Fibers serve as scaffolds for structural maintenance, providing tensile
 2. Transition

+ Intermediate and deep layers of the lamina propria

- Intermediate layer of the lamina propria primarily made up of elastic fibers
while the deep layer of the lamina propria primarily made up of collagenous
fibers

- These fibers run roughly parallel to the vocal fold edge and these two layers of
the lamina propria comprise the vocal ligament

- Transition layer primarily structural, giving the vocal fold support as well as
providing adhesion between the mucosa, or cover, and the body, the
thyroarytenoid muscle
 3. Body

+ Thyroarytenoid muscle

- Muscle variously described as being divided intovocalis muscles or
thyrovocalis and the thyromuscularis, depending on the source
 VOCAL FOLD TISSUE CHANGES

5 layers of vocal folds
Superficial lamina propria
(SLP)
Intermediate lamina propria
(ILP)
Deep lamina propria (DLP)
 FROM BIRTH THROUGH
PUBERTY
At 2 months, SLP starts to
differentiate. Only one in young
child
By 7-10 years all three layers can
be found
By 10-16 years layers are adult-
like
Lamina propria has important
implications for vibratory
qualities, and this differentiates
the voices of children versus
adults
 ELASTIN AND COLLAGEN
CHANGES
These are part of the extracellular matrix, which
supports the cells of the tissues themselves
Elastin: provides elasticity
Collagen: provides structure/support that reduces
injury
What changes from infancy to adulthood?
 ELASTIN AND COLLAGEN DURING
DEVELOPMENT
Adults:
SLP has no collagen or elastin
ILP has elastin but little collagen
DLP has mostly collagen, with little elastin
Infants:
Have about 50% of adult elastin and collagen
Develops and distributes into the layers as infant
develops
Older adults:
Lose elastin, but keep or increase collagen
 CARTILAGE CHANGES DURING
DEVELOPMENT
At birth: Larynx is about 33% of adult
size
Cartilage continues to grow into
adulthood
Cartilage becomes stiffer with age
At puberty:
Thyroid and cartilage grow
Male thyroid cartilage is twice
the weight of female
Prominent thyroid angle
(“Adam’s apple”)
Cartilage growth is complete at 20
 HYOID AND LARYNGEAL DESCENT
DURING DEVELOPMENT
Hyoid:
Ossification of hyoid occurs shortly after birth
At birth, hyoid is at level of C2/C3 vertebrae, larynx is at C3/C4
By 2 years, larynx and hyoid are at adult locations (C3/C6 and C4)
Torso is also growing, so vocal tract is lengthening
Increases resonatory volume, including subglottal space
 FUNDAMENTAL
FREQUENCY CHANGE
DURING
DEVELOPMENT
Neonate has highest f0,
and it drops steadily
towards puberty
Sexual dimorphism
strongly present at 30
28 27.52

puberty as vocal fold 25 24.48
22.96

Maximum duration in seconds
mass and length 20
22
20 20
22 22
21 21 21.18

increases 17
18

15 15
14
As respiration develops,
10 10 10
ability to sustain 8

5
phonation increases to
peak in 20s 0

3

5

7

9

11

13

15

17

0

9
-7

-8
61

81
Age in Years
 FUNDAMENTAL
FREQUENCY CHANGES
WITH AGING

Adult male f0 is around 130 Hz at 20
years, then starts increasing around
140 Hz at 80 years 30
28 27.52
25
Female f0 is 190 Hz at 20, and it
24.48

Maximum duration in seconds
22.96
22 2222
2121 21.18
20 2020

holds relatively steady into older age 15 15
17
18

14

10 1010
8
5

0

Age in Years
AGING EFFECTS ON STRUCTURE AND FUNCTION
OF THE PHONATORY MECHANISM
Change as we age co-occur with respiratory changes
Remember that respiration and phonation go hand-in-hand: The
weaker the respiration, the weaker the phonatory product
Respiration begins decline in 20s, and so does the vocal mechanism
Presbyphonia: phonatory characteristics of geriatric vocal mechanism
Prebylarynx: the aging laryngeal structures
 VOCAL EFFECT OF PRESBYPHONIA

Hoarseness
Low vocal intensity
Increased breathiness
Vocal fatigue
Reduced vocal harmonics
 SUPPORTIVE TISSUE CHANGES

Remember the lamina propria: SLP, ILP, DLP
Both collagen and elastin, giving strength and
elasticity
Elastin decreases with age and collagen increases
This means that the vocal folds get stiffer and less
elastic
Produces increased vocal fatigue and hoarseness,
as well as reduced f0 range
Vocal ligament becomes more thins and frail
 MUSCLE CHANGES WITH AGING

Sarcopenia: muscle atrophy
Lose muscle fibers, and the existing fibers become
thinner and smaller in diameter
Thyroarytenoid is very vulnerable, starting at
around 60 years old
Weak thyrovocalis results in breathy phonation
and inefficient use of already weakened
respiration
Loss of elastin may result in bowing of vocal folds
Larynx descends farther into pharynx because of
weak supraglottal muscles
CARTILAGE AND NERVE CHANGES WITH AGING

Cartilage:
Laryngeal cartilage ossifies with age (except epiglottis)
Ossification starts around 18 years of age and is complete around 70
years
Nerves:
Laryngeal nerves are very vulnerable to aging
Progressive deterioration causes the action potential declines after
60 years
Results in inadequate adduction, f0 change, breathiness, increased
vocal jitter
Also has reduced sensitivity, so more vulnerable to foreign body entry
into larynx
 OTHER ACOUSTIC PARAMETERS AND AGING

Vocal jitter: as we age it gets larger, because of
increased variability of phonation
Vocal intensity: Phonation gets weaker as we age
Vocal range: it gets smaller as we age
Harmonic-to-Noise ratio: This increases as we age
THANK YOU!