Gastrointestinal System Module - 2023-2024 Anatomy of Oral Cavity, Pharynx & Oesophagus PDF

Summary

These lecture notes cover the functional and applied anatomy of the oral cavity, pharynx, and oesophagus. The document details objectives, definitions, and various anatomical components involved. Key anatomical regions like the vestibule, oral cavity proper, and soft palate are examined.

Full Transcript

Gastrointestinal System Module
Functional & Applied Anatomy of
Oral Cavity, Pharynx & Oesophagus
MUHAMMAD ALBAHADILI
2023-2024
 Objectives
At end of the lecture, we were able to
Describe the anatomy of the inner part of the mouth,
pharynx and oesophagus
Differentiate the types of cells that formed the
mucosa of the mouth, pharynx and oesophagus,
Describe the action of pharyngeal muscles in
swallowing
Differentiate the action of intrinsic ms from extrinsic
ms of the tongue
Numerate the factors that prevent the reflux of
gastric content into the oesophagus
Numerate the portal-systemic anastomosis sites
 The Oral
Cavity

Vestibule proper
Vestibule
Vestibule – space
bounded by the lips
& cheeks anteriorly
and laterally; internal
boundary formed by
dental arches
 Ducts of the parotid
glands discharge their
secretions into the
vestibule; opposite the
upper 2nd maxillary molar
Oral Cavity Proper
 Oral Cavity Proper :
Space posterior &
medial to the dental
arches
 The roof is formed
by the hard and soft
palate
 Soft palate continuous with the wall of the pharynx &
is joined with the tongue by two arches (palatoglossal
& palatopharyngeal) formed by muscles covered by a
mucous membrane; palatine tonsil lies in between
 Communicates posteriorly with the oropharynx
 Tongue lies inferiorly inside
  Beneath and medial to
the lower teeth is the
floor of the mouth
 The tongue is connected
to the floor of the oral
cavity by a midline fold
of mucosa (lingual
frenulum)

The frenulum allows the
anterior part of the tongue to
move freely
Tongue tie
 Ducts of the
submandibular
salivary glands open
at the base of the
frenulum; the ducts of
the sublingual glands
also open alongside
the frenulum
Oral Mucosa
the lining epithelium is stratified squamous
(nonkeratinized)
the exception in areas (gums, hard palate & dorsal
surface of the tongue) that are subjected to abrasive
forces (masticatory mucosa) is stratified squamous
keratinised.
 Mastication muscles
Primary
Masseter
Temporalis
Medial pterygoid
Lateral pterygoid
Mastication muscles
Accessory muscles
Anterior belly of
digastric
Mylohyoid
Geniohyoid
buccinator
 Nerve
muscle origin insertion function
supply
Digastric mandible
mylohyoi Mandibular
Mandible
d Hyoid Depresses of the
bone C1-C2 via mandible
geniohyoi
mandible hypoglossal
d
CN
Compression of
buccinat Outer surface of
Facial cheeks & lips
or maxilla & mandible
against teeth
The Tongue – General Anatomy
 Mobile muscular
(skeletal) organ
capable of assuming
a variety of shapes &
positions
 Composed of a
root, body, an apex,
curved dorsal
surface & an inferior
surface
  A V-shaped dorsal
groove (sulcus
terminalis) marks the
boundary between
anterior (body) &
posterior parts (base)
Posterior
1/3rd

Anterior 2/3rd
 its covered by a
mucosa which is
rough (keratinised s.
s.) on the dorsal
surface
 but thin and
transparent on the
inferior (sublingual)
surface (non-
keratinised s. s.)
Mucous Membrane
Of the anterior 2/3rd
- Contains lingual papillae
- four types of lingual
papillae (filiform,
fungiform, foliate &
vallate)
- Filiform (most numerous) are conical, highly
keratinised & contain afferent nerve endings sensitive to
touch
- Fungiform are scattered, keratinised; most numerous
near the apex & margins of the tongue; appear as red
spots (vascular core)
- Vallate lie anterior to the sulcus and are large,
nonkeratinised & surrounded by deep trenches; walls
contain taste buds (function in the four primary taste
sensations – salty, sweet, bitter & sour)

- Foliate are located just in front of V of vallate p. they
are clustered in tow groups on iether side of the tongue,
content taste buds
Mucous Membrane of (posterior 1/3rd)
- No lingual papillae
- Cobblestone surface because of the
presence of lymphoid nodules (lingual
tonsil)
 Taste buds:
Areas of specialised epithelia (specialised mucosa)
where intraepithelial structures (taste buds) function
for taste perception (gustation); most taste buds on
the dorsal surface of the tongue
What is about the water?
 Intrinsi
c
The Muscles Of The Tongue
Extrinsi
c

 Intrinsic (confined) muscles permit changes in
the shape of the tongue:

 Longitudinal

 Transvers

 Vertical
Extrinsic muscles of the tongue allow for movement and
changes in position;
Styloglossus: create a trough for swallowing, retracting
the tongue.
Hyoglossus: depresses and retracts the tongue,
making the dorsum more convex.
Palatoglossus: elevation of the posterior part of the
tongue
Genioglossus:
protruding the
tongue and
deviating it
towards the
opposite side.
When acting
together, the
muscles depress
the center of the
 nerve supply:
anterior 2/3 of the tongue originated
from 1st pharyngeal arch & posterior 1/3
from 3rd pharyngeal arch.
Sensory: general sensation for anterior
2/3 is lingual (branch of CN V) &Taste
fibres (special innervation) derived from
the facial (CN VII) nerve (Chorda
tympani)
But for posterior 1/3 glossopharyngeal
(CN IX) nerves for both general
sensation & teste
Motor: all the muscles of the tongue is
innervated by Hypoglossal (XII CN)
except palatoglossus is pharyngeal
branch of Vagus (X CN)
 The Tongue – Clinical Correlates
Gag reflex
The gag reflex, (pharyngeal reflex), is an involuntary
reflex involving bilateral pharyngeal muscle
contraction and elevation of the soft palate.
This reflex may be evoked by stimulation of the
posterior pharyngeal wall, tonsillar area, or base of the
tongue.
afferent (sensory) IX CN & efferent (motor) X CX.
 The Tongue – Clinical Correlates
Paralysis of genioglossus
(forms the bulk of tongue
mass) obstructing the
airway with a risk of
suffocation;
during general
anaesthesia, the muscle
relaxes and thus the
tongue of the patient is
prevented from a
backward move. by
inserting an airway
Protection of the airway
The Tongue – Clinical Correlates
Any cause lead to injury of CN XII leading to atrophy of
same side of the tongue > the tongue deviates to the
paralysed side?
Thin mucous membrane on the inferior side of the
tongue allows for quick absorption of drugs into the
deep lingual veins
 Salivary Glands

Salivary
Glands

Major minor

Parotid >800 glands

Submandibula
r

lingual
 Minor salivary glands

These lie just under mucosa.
Distributed over lips, cheeks,
palate, floor of mouth & retro-
molar area.
Also appear in upper
aerodigestive tract
Contribute 10% of total salivary
volume.
 Sublingual Salivary glands
This is the smallest of the
major salivary glands.
The sublingual glands are a
paired set of salivary glands
lying in the anterior part of
the floor of the mouth
between the mucous
membrane above , the
mylohyoid muscle below and
the body of the mandible
close to the mental
symphysis anteriorly.
Sublingual gland has no true
fascial capsule.
 The gland has a head portion that drains by
numerous excretory ducts (Ducts of Rivinus)
directly into the oral cavity and the tail that
drains into the submandibular duct or directly
into the mouth
Submandibular Gland
This gland lies in the
submandibular triangle formed
by the anterior and posterior
bellies of the Digastric muscle
and the inferior margin of the
mandible.
 The gland forms a ‘C’shape
around the posterior margin
of the Mylohyoid muscle,
which divides the gland into
a superficial (large) and
deep (small) lobe.
The gland is surrounded by
a well-defined capsule that
is derived from the deep
cervical fascia which splits
to enclose it
 Submandibular Gland……

Wharton’s duct empties
lateral to the lingual
frenulum on the anterior
floor of mouth
Submandibular Gland……
Important anatomical
relations include:

the anterior facial vein
and artery
hyoglossus muscle
lingual nerve
hypoglossal nerve.
Parotid Gland

The parotid gland represents the
largest salivary gland
The gland lies in a recess
bounded by the ramus of the
mandible, base of skull and the
mastoid process. its lies on
carotid sheath and extended over
the masseter ms.
Parotid Gland……
80% of the gland overlies the Masseter and
mandible. The remaining 20% of the gland (the
retromandibular portion
 Structures through gland:
Fascial N
Terminal branches of ex.
Carotid A.
Retromandibular vein
Intra-parotid LNs.

Divided into 80%
superficial and 20%
deep to facial N.
 Parotid Gland……
Stensen’s duct arises from the
anterior border of the Parotid
and parallels the Zygomatic
arch, 1.5 cm inferior to the
inferior margin of the arch.
It runs superficial to the
masseter muscle, then turns
medially 90 degrees to pierce
the Buccinator muscle at the
level of the second maxillary
molar where it opens onto the
oral cavity.
 Facial N. & parotid
After exiting the foramen, it turns anterior to enter the
gland at its posterior margin.
The nerve then branches approximately 1.3 cm from
the stylomastoid foramen. The nerve then gives rise
to 2 divisions:
1)Temporofacial (upper)
2)Cervicofacial (lower)
Facial CN & parotid gland
Facial CN

Temporofaci Cervicofacia
al l

Temporal Buccal

zygomatic Marginal

cervical
Facial nerve palsy is the diminished
function of the facial nerve or one of
its branches. Bell’s palsy, which
results in the complete inability to
move one side of the face, is the
most common cause of facial nerve
palsy. This condition completely or
partially improves within a few
months.
Symptoms
Sudden paralysis on one side of the face,
including the muscles of the forehead
Difficulty in closing eyelids and smiling
Drooling
A decrease in the ability to taste
Difficulty in chewing
Pain or numbness behind the ears
Salivary Glands Functions
Saliva: It’s a clear, viscous fluid
98% water plus electrolytes, mucus, white blood
cells, epithelial cells (from which DNA can be
extracted), enzymes (amylase, lipase)
antimicrobial agents (IgA, and lysozymes).
Keeps the mucous membrane of the oral
cavity moist
Lubricates the food during mastication
Begins digestion of carbohydrates
Serves as a mouthwash
Role in the prevention of tooth decay
Facilitates taste
Facilitates speech
 Salivary Gland – Histology

Parotid Sublingual Submandibular
- Mainly serous - Mostly mucus - Serous/mucus

Mucous acini Mucous acini

Serous acini Serous acini

High content of Mucins Weak amylase &
amylase Lysozyme
 Secretion of saliva
 The afferent is in response to stimulation
centrally or stimulation of taste bud
receptors; nerves from taste buds in the
anterior tongue pass in the chorda
tympani (branch of Facial Nerve - CVII) &
from the posterior tongue pass in the
glossopharyngeal nerve (CIX)
Salivary Glands – Functional Correlates
 Parasympathetic secretomotor fibres to the
submandibular & sublingual glands are conveyed via
the chorda tympani which joins the lingual nerve
(branch of Trigeminal Nerve – CV3) to reach the
glands
 Parasympathetic secretomotor fibres to the parotid
gland first pass into the glossopharyngeal nerve and
then join the auriculotemporal nerve (branch of CV3)
to reach the gland
Salivary secretion

Both parasympathetic & sympathetic ANS
stimulate the secretion of saliva
Parasympathetic: large volume, watery & rich
with enzymes, when?
Sympathetic: small vol. rich in mucus, when?
 Secretions from the gland acini into a
duct system; striated duct > excretory
duct > collecting duct

 – cells lining the striated & excretory
ducts modify the composition of the
saliva, how?
Salivary Glands – Clinical Correlates
Sialography: radiographic examination of
major ducts & secretory units of the parotid &
submandibular gland by injection of contrast
medium for diagnosis of stricture, stone cause
obstruction

Blockage of submandibular duct by calculi
(stones)
Salivary Glands – Clinical Correlates
Majority of salivary gland tumours occur in the parotid
gland; most of the tumours are benign.
parotidectomy presents surgical challenges because
the facial nerve & its branches are embedded in the
gland so:
Superficial
parotidectomy For
benign or low-grade
malignancy
Radical parotidectomy
for high-grade
malignancy
 Salivary Glands – Clinical
Correlates
Viral infection of the parotid gland
(mumps) causes inflammation
(parotiditis); parotid gland capsule
& cervical fascia limit swelling and
thus cause severe pain – pain in the
auricle, external acoustic meatus,
temporal region &
temporomandibular joint because
of common nerve supply via the
auriculotemporal nerve (branch of
CV3) (sensory branch)
 Gums & Teeth

Gums (gingivae) are composed of fibrous
tissue covered with mucosa; the attached
portion to the jaws & necks of the teeth is
covered by SSKE – unattached is NKSSE
Gums & Teeth
 Improper oral hygiene results in food &
bacterial deposits in gum crevices > cause gum
inflammation (gingivitis); if left untreated >
supporting structures & alveolar bone affected
causing periodontitis (inflammation &
destruction of bone & periodontium) > dental
abscesses
Gum & teeth

 Teeth set in tooth sockets are used in
mastication & assist in speech; deciduous
(primary) or permanent (secondary); children (20
deciduous), adults (32 permanent)
 Decay of teeth results in dental caries (‘cavities’
) > eventually invade the pulp cavity > pulpitis –
cavity is small & rigid & swelling cause intense
pain (toothache)
 Abscesses from maxillary molar teeth may
extend into the maxillary air sinus causing
sinusitis
 The Palate
Consists of a bony part (hard palate)
and a muscular part (soft palate)
 Hard palate
Consist of four layers,
a bony skeleton of palatine processes of
maxillae and horizontal plates of palatine bones
Submucosa relatively dense containing minor
salivary glands
Lamina propria densely collagenous
cover with KSSE
Separates the oral cavity from the nasal cavity &
nasopharynx
The soft Palate

 Composed of musculoaponeurotic tissue
attached anteriorly to the hard palate,
posteriorly free mobile, on either side bound to
tongue and pharynx by palatoglossus &
palatopharyngeus MMS.
 The soft palate has two actions,
 becomes tense against elevated tongue
(CV3)
 Elevation during swallowing prevents the
passage of food into the nasal cavity &
nasopharynx (CX)
Soft palate muscles
Cleft palate: Failure of
fusion of palatal
processes during
development > cleft
palate; feeding problems
& food in the nasal cavity >
aspiration of food into
the respiratory system
  Pharynx – expanded
Pharynx portion of digestive
system posterior to the
oral cavity
 Divided into
nasopharynx,
oropharynx &
Nasopharynx
laryngopharynx

Oropharynx

Laryngopharynx
  Pharynx wall –
The muscles of the pharynx voluntary muscle
(external circular &
inner longitudinal)

Sty cle
mu
 External muscle

lop
s
layer – three

ha r
pharyngeal

ngey
constrictors

us
Sa uscl
 Internal muscle

m
lpi e
layer – three other

ng
op
muscles

ha
ry n
ge
u
Pala cle

s
s
toph
a ry
nge
us
Pharyngeal Muscles
The outer circular layer includes:
superior constrictor muscle
Middle constrictor muscle
inferior constrictor muscle
 Pharyngeal Muscles
The inner
longitudinal layer
includes:
Stylopharyngeus
muscle
Salpingopharynge
us muscle
Palatopharyngeus
muscle

Pharyngeal Muscles are innervated by the pharyngeal
branch of the Vagus nerve (CN X) except for the
stylopharyngeus muscle which is innervated by the
glossopharyngeal nerve (CN IX).
what is the epithelial cells that lining
the pharynx ?
pharyngeal pouch; (Zenker’s diverticulum)
The inferior pharyngeal constrictor
consists of two parts;
thyropharyngeal and
cricopharyngeal. The
thyropharyngeal part is located
superiorly and it comprises most
of the muscle.
The specific orientation of muscle
fibers defines a triangular gap
between the thyropharyngeal and
cricopharyngeal parts of the
muscle called Killian’s dehiscence
(or triangle). This is a weak spot of
the pharyngeal wall through which
the pharyngeal diverticulum may
prolapse.
The Oesophagus
25 cm long muscular tube; upper part contains
striated muscle, middle part contains striated &
smooth muscle & lower part contains smooth
muscle; under vagus nerve control
Has three regional location – cervical, thoracic &
abdominal
 Relations of esophagus in the neck
Located anterior to the vertebral column
Posterior to the trachea
On either side of the thyroid, recurrent laryngeal
NNs & carotid sheath
Esophageal relations in the chest
Anterior
Posterior Right Left

Thoracic
Trachea vertebral
Subclavian
Left bodies Pleura
artery
recurrent Thoracic Terminal
Aortic arch
laryngeal duct part of
Thoracic
nerve Azygous azygous
duct
Pericardiu veins vein
Pleura
m Descending
aorta

Right
Left vagus
vagus
nerve
nerve
Abdominal Right crus
Left crus
of the
of the
diaphragm
diaphragm
 Anatomical Relations
The anatomical relations of the
esophagus give rise to four
physiological constrictions in its
lumen – it is these areas where
food/foreign objects are most
likely to become impacted. They
can be remembered using the
acronym ‘ABCD‘:
Arch of aorta
Bronchus (left main stem)
Cricoid cartilage
Diaphragmatic hiatus
 SITES OF CONSTRICTION IN THE ESOPHAGUS

Site of constriction

Distance from

Vertebral level upper incisor
teeth
At the pharyngo-esophageal C6 6 inches (15 cm)
junction (cervical constriction)

At crossing of arch of aorta T4 9 inches (22 cm)
(aortic constriction)

At crossing of left principal T6 11 inches (27 cm)
bronchus (bronchial
constriction)

At the opening in the T10 15 inches (40 cm)
diaphragm (diaphragmatic
constriction)
Esophagus: histology
Has two sphincters
– Upper fibres of inferior
constrictor muscle called
the cricopharyngeus
muscle)
- lower oesophageal
sphincter (not an
‘anatomical sphincter’)
 factors that prevent reflux of gastric contents into
oesophagus:
- angle of entry of oesophagus into the stomach
- right crus of the diaphragm
- location of the fundus
- mucosal flap in the cardiac region of the stomach
- intra-abdominal pressure
NERVE SUPPLY
The esophagus is supplied by both parasympathetic
and sympathetic fibres.
The parasympathetic fibres are originated from
recurrent laryngeal nerves and esophageal plexuses
created by vagus nerves. They supply sensory, motor,
and secretomotor supply to the esophagus.
The sympathetic fibres are originated from T5-T9
spinal segments are sensory and vasomotor.
 The Oesophagus – Blood Supply
 Three arterial sources :
 inferior thyroid for (cervical
region),
 aorta (thorax)
 & left gastric artery (abdomen)
Venous
drainage:
Inferior
thyroid,
azygos
system & left
gastric vein
(into the
portal
system)
naturally occurring venous communications
between tributaries of the portal venous system and
tributaries of the systemic venous system.
Oesophagus – Clinical Correlates

 Narrowing at three points – at its commencement, where it
is crossed by the left bronchus and at its entry into stomach
 Portal hypertension – oesophageal
varices > may rupture > haemoptysis
 Metaplasia in the oseophageal mucosa
due to continual gastric reflux (GORD)
Left
 Mitral stenosis > left atrial hypertroph Bronchus
y > displacement of oesophagus
 Dysphagia – swallowing difficulties
 Achalasia – motor disorder, failure of
the ‘lower oesophageal sphincter’ to
relax & abnormality of function of the Oesophagus
smooth muscle in lower oesophagus