Core restorations-Restorative Dentistry Lecture note

A core is the term used to describe the restoration that is placed in order to build up a broken down tooth before receiving an indirect restoration. In some cases it may not be necessary to place a separate core, but an indirect restoration may be constructed to replace all of the missing tooth structure. Typical examples of this include root-filled teeth in which an integral corono-radicular restoration and core may be placed, or for teeth that have suffered cusp fracture where placement of a traditional restoration would leave very little tooth structure (e.g. premolars with a previous mesio-occlusodistal restoration and one lost cusp, a ‘one-piece’ onlay may be the treatment of choice). However, for most teeth requiring an indirect restoration, a core restoration will need to be provided.

The exact nature of any particular core will depend on the degree to which the tooth in question is broken down and how much coronal dentine remains. When attempting to understand the rationale for choice of core restoration, it is helpful to consider the concept of extremes, from a simple space-filling core to a structural core (Fig. 5.3) and relate the different functions to the materials available.

Core Build up Video

Space-filling core

When much coronal dentine remains, the role of a core is simply to fill out any undercuts and give an appropriate shape that will provide adequate retentive and resistance form (described later). The restorative material simply acts to prevent or ‘block out’ any undercuts to the path of insertion of the intended indirect restoration. This situation commonly arises when an intra-coronal restoration (i.e. an inlay) is planned to replace a previous direct restoration. The preparation will have to be modified to eliminate the undercuts; extending the preparation would be unnecessarily destructive compared with placement of a core material to block out the undercuts. Similarly, the same approach can be taken to give smooth axial walls when an extra-coronal restoration such as a full coverage crown is planned.

In the above example, the functional demands and stresses encountered by the core material will be minimal. The mechanical properties of a core material in this situation are not critical, and the material choice is largely determined by secondary factors such as ability to bond to tooth structure, cariostatic properties and ease of handling (e.g. command set).

 

Types of core restorations, (a) structural and (b) space-filling.

Structural core

When a large amount of coronal dentine has been lost, it is more likely that an extra-coronal full-coverage restoration will be planned. The core material will replace a substantial part of the clinical crown and will form the bulk of the final preparation. In this case, the core material will be subjected to significant functional demands and stresses, particularly in molar teeth, and must therefore have adequate mechanical properties to resist these. Although a full-coverage crown may afford some protection to the core if the margins are extended gingivally beyond the core6, this protection is limited. The strongest materials available at present are amalgam (for a direct core) or a cast metal such as gold (for an indirect core in an endodontically treated tooth).

Essentially, there are four types of direct core material available; amalgam, resin composite, glass ionomer or hybrid materials such as light-cured resin-modified glass-ionomer cement (RmGIC).

Amalgam

Amalgam has perhaps the best track record when used for substantial posterior core build-ups. Amalgam has good contrast with tooth substance and is easy to prepare. The long time to full set may predispose to early fracture, which is unfortunate, as the preparation cannot usually be prepared at the same visit, although newer high-copper amalgam alloys have high strength within a short time and may be prepared at the same visit after a short delay. The thermal expansion of amalgam is quite dissimilar to dentine, and this factor may predispose to failure after a period of time. In addition, amalgam cannot be bonded to tooth substance without resorting to proprietary products for amalgam bonding.

Resin composite

The use of resin composite as a core material has advantages and disadvantages. The composite does not require a two-visit crown preparation technique and, when necessary, the crown preparation can be commenced immediately. However, against this, the resin composite is difficult to prepare to the correct form because it may be difficult to differentiate between tooth tissue and core substance, though resin composites of contrasting colour are available. Lightcured resin composites should be used with caution, as full depth of cure may not be achieved in substantial core build-ups. Chemicalcure or dual-cure resin composites (the latter having the advantage of ‘command set’) have an advantage in that those portions of the material not exposed to the curing light will still undergo polymerization due to the chemical cure. However, they may undergo increased discoloration (due to the tertiary amine activator7) compared with light-cured resin composites and thus should be used with caution in anterior teeth in which non-opaque aesthetic restorations are planned. Some resin composites are marketed specifically for core build-up, are coloured and have advantages over tooth-coloured composites. It has been suggested that because of water sorption and expansion, additional die relief should be provided during construction, or impression taking should be delayed after preparation to prevent discrepancy between the working die and the prepared tooth.

Glass ionomers and resin-modified glass-ionomer cement

Traditional glass-ionomer cements are only suitable for use as a space-filling core, where they will not be subjected to any stresses, as they are inherently weak materials. Several glass-ionomer materials are marketed specifically for use as a core build-up material such as RmGIC. They bond to dentine, release fluoride, have comparable thermal behaviour to dentine, can be made a contrasting colour to tooth (e.g. blue) and are easy to prepare, although the long-term behaviour of these materials is not well documented. Water sorption and expansion are higher with these materials than with resin composites and, for this reason, after preparation there should be a delay before impression taking. At present, their use as a structural core may be questionable. However they may eventually become the materials of choice with further developments.

Choice of core material

The choice of core material depends on several clinical variables. The role of the core material with regard to a space-filling or functional role is critical and the degree to which the core will be subjected to stress and the amount of bracing provided by remaining coronal dentine should be considered when selecting the material. Amalgam alloy should not be used beneath anterior full-veneer crown restorations as corrosion products from the amalgam core may stain the dentine peripheral to the restoration and result in poor aesthetics.

Similarly, an amalgam core underneath a three-quarter crown may shine through the remaining tooth and be unaesthetic. Restoration of the endodontically treated tooth is covered in detail in later posts, though points of particular relevance are repeated here. In most situations the general principles above apply. When little tooth structure remains it is usual to place a post-retained core, although molar teeth may successfully be restored with an amalgam dowel core (Nayyar core). If a direct intra-radicular post has been placed in order to retain a core, then care should be taken to ensure that the properties of the core material are not mismatched to those of the post (e.g. avoid glass-ionomer cement or resin-composite cores with metal intra-radicular posts), although some studies suggest that fibre posts (with a relatively low modulus of elasticity) perform better with a rigid metal core.

In general terms, when there is sufficient coronal dentine remaining to provide some support to the core material, then resin-based restorative materials are the core materials of choice. However, for a tooth that has lost much coronal tooth structure then a stronger core material (amalgam or cast metal if root treated) should be placed.

Anatomy and Physiology of the Salivary Glands and Sialography

Types of salivary glands

The Major Salivary Glands

• Parotid
• Submandibular
• Sublingual

The Minor SalivaryGlands

 

Embryology

• 6th-8th Weeks of Gestation
• Parotid
• First to develop
• Last to become encapsulated
• Autonomic Nervous System Crucial

Anatomy of Parotid Gland

• Wedge shaped with 5 processes
• 3 Superficial
• 2 Deep
• Parotid Compartment
• Superior – Zygoma
• Posterior – EAC
• Inferior – Styloid, ICA, Jugular Veins
• 80% overlies
• Masseter & Mandible
• 20% Retromandibular
• Stylomandibular,Tunnel, Isthmus of Parotid
• Tail of Parotid

Parapharyngeal Space

• Prestyloid Compartment
• Poststyloid Compartment (Paragangliomas)

Stensen’s Duct

• Arises from anterior border
• 1.5 cm inferior to Zygomatic arch
• Pierces Buccinator at 2nd Molar
• 4-6 cm in length
• 5 mm in diameter

Parotid Capsule

• Superficial layer Deep Cervical Fascia
• Superficial layer
• Deep layer

 

CN VII-Facial nerve

• 2 Surgical zones
• 3 Motor branches
• immediately
• Pes Anserinus – 1.3 cm
• Temperofacial Division
• Cervicofacial Division
• 5 Terminal branches

Localization of CN VII

• Tragal pointer
• Tympanomastoid suture
• Posterior belly Digastric
• Styloid process
• Retrograde dissection
• Mastoidectomy

• Great Auricular nerve
• Auriculotemporal nerve
• Superficial Temporal vessels
• Frey’s Syndrome

Neural compartment-VII, Great Auricular, Auriculotemporal

Venous compartment-Retromandibular vein

Arterial compartment-Superficial Temporal/Transverse Facial

Lymphatics

• Paraparotid & Intraparotid nodes
• Superficial & Deep Cervical nodes

Submandibular Gland-Anatomy

 

• The ‘Submaxilla’
• Submandibular Triangle
• Mylohyoid ‘C’
• Marginal Mandibular branch
• Capsule from superficial layer of Deep Cervical fascia

Wharton’s duct

• Exits medial surface
• Between Mylohyoid & Hyoglossus
• 5 cm in length
• Lingual nerve & CN XII

Innervation

Superior Cervical Ganglion (symp)

Submandibular Ganglion (para)

Artery: Submental branch of Facial a.

Vein: Anterior Facial V nerve.

Lymphatics: Deep Cervical and Jugular chains

Facial artery nodes

Between Mandible & Genioglossus

No capsule

Ducts of Rivinus +/- Bartholin’s duct

Sialogram not possible

Innervation: Same as Submandibular

Artery/Vein: Sublingual branch of Lingual & Submental branch of Facial

Lymphatics: Submandibular nodes

Minor Salivary Glands

• 600-1,000
• Simple ducts
• Buccal, Labial,
• Palatal, Lingual
• Tumor sites:
• Palate, upper lip,cheek
• Lingual & Palatine nn.

Imaging of Salivary Gland-Important things to remember

• CT – Inflammatory
• MR – Tumor
• Children: U/S & MR
• NO sialogram during active infection
• Parotid is fatty

The Secretory Unit

• Acinus (serous, mucous, mixed)
• Myoepithelial cells
• Intercalated duct
• Striated duct
• Excretory duct

Microanatomy of Salivary glands

• Striated & Intercalated ducts well developed in serous, NOT mucous glands
• Striated duct: HCO3 into, Cl from lumen
• Intercalated duct: K into lumen, Na from lumen, producing hypotonic fluid
• Excretory ducts do NOT modify saliva

 

The Bicellular Theory

• Intercalated duct
• Excretory duct

The Multicellular Theory

Parotid: serous & fatty

Submandibular: mixed serous

Sublingual: mixed mucous

Stroma: Plasma cells

Function of Saliva

1. Moistens oral mucosa
2. Moistens & cools food
3. Medium for dissolved food
4. Buffer (HCO3)
5. Digestion (Amylase, Lipase)
6. Antibacterial (Lysozyme, IgA, Peroxidase, FLOW)
7. Mineralization
8. Protective Pellicle

 

Effects of Salivary hypofunction

• Candidiasis
• Lichen Planus
• Burning Mouth
• Aphthous ulcers
• Dental caries
• Xerostomia not reliable

 

Production of Saliva

• Primary secretion
• Ductal secretion
• The “secretory potential”
• (hyperpolarizes)
• Increased flow rate yields decreased
• hypotonicity & K

Autonomic Innervation

Parasympathetic

• Abundant, watery saliva
• Amylase down

Sympathetic

• Scant, viscous saliva
• Amylase up

Salivary Flow

• 1-1.5 L/day (1 cc/min)
• Unstimulated state
• Submandibular
• Stimulated state
• Parotid
• Sublingual & minor
• Mucin

Effects of Aging

Total salivary flow independent of age

Acinar cells degenerate with age

Submandibular gland more sensitive to metabolic/physiologic change

Unstimulated salivary flow more greatly affected by physiologic changes

Sialography

Radiologic examination of the salivary glands

The submandibular and parotid glands are investigated by this method

The sublingual gland is usually not evaluated this way-Difficulty in cannulation

Indications

• Ductal obstruction-Stones or tumors
• Inflammation of a duct or gland

Contraindications

• Severe infection of a gland
• Known allergies to contrast media

Equipment

• Fluoroscopic unit w/spot film capabilities
• Cannula for introducing contrast
• Connecting tubing
• Lemons
• Dilators for duct
• 5 mL syringe
• Overhead light
• Gauze
• Contrast

Preliminary and Procedure Radiographs

• Parotid-Tangential
• Perpendicular to cassette, directed to lateral surface of mandibular ramus
• Submandibular-Lateral
• Perpendicular to cassette, directed to 1 in. superior to mandibular angle to demonstrate parotid gland

• Inferior margin of mandibular angle to demonstrate the submandibular gland

Patient Preparation

1. Thorough explanation of examination
2. Any removable dental work, jewelry, and other artifact causing opaque items must be removed
3. Consent must be signed

Procedure

• The patient first sucks on a lemon wedge to open the ducts
• An overhead lamp is used to provide adequate light
• The duct is cannulated, not punctured, and contrast is introduced with fluoroscopic guidance
• Radiographs are obtained
• After the radiographs, the patient then sucks on a lemon wedge to evacuate the contrast
• Obtain post-procedure radiographs as indicated

Lateral Parotid Gland Radiograph

 

Lateral Submandibular Glands

 

A Short note on Mucocele-Oral Surgey

Definition

Mucoceles, or mucous cysts, are a common phenomenon or lesion of the oral mucosa, originating from minor salivary glands and their ducts.

Etiology

Local minor trauma and duct rupture or ductal obstruction, probably due to a mucous plug.

Mucocele of Lower Lip

Mucocele Of Tongue

Clinical features

Two main types of mucocele are recognized, according to their pathogenesis:  

• Extravasation mucocele (common), which results from duct rupture due to trauma and spillage of mucin into the surrounding soft tissues;
• Mucous retention cyst (uncommon), which usually results fromductal dilation due to ductal obstruction.
  

Clinically, mucocele presents as a painless, dome-shaped, solitary, bluish or translucent, fluctuant swelling that ranges in size from a few millimeters to several centimeters in diameter (Figs.).

Clinical features

A common finding is that the cyst partially empties and then re-forms due to the accumulation of new fluid.

The lower lip is the most common site of involvement, usually laterally, at the level of the bicuspids.

Less common sites are the buccal mucosa, tongue, floor of the mouth, and soft palate.

Extravasation mucoceles display a peak incidence during the second and third decades, while the mucous retention types are more common in older age groups.

Laboratory tests

Histopathological examination.

Differential diagnosis

• Lymphangioma,
• Hemangioma,
• Lipoma,
• Mucoepidermoid
• Carcinoma,
• Sjögren syndrome,
• Lymphoepithelial cyst.

Treatment

Surgical excision or cryosurgery.

Surgical Excision of Mucocele-Videos

Surgical removal of mucocele from lower lip

 

 

Central Nervous System(CNS) -Blood Supply

Arterial Supply

        - Spinal Arteries

                       Anterior (1) & Posterior (2) Spinal Artery

                       From Vertebral artery

          - Radicular Arteries ----- Segmental arteries

                       From Vertebral, Ascending Cervical, Intercostal and Lumbar Artery

     Venous Drainage

           - Longitudinal & Radicular Veins

                  to Intervertebral veins ---- to Internal Vertebral Venous Plexus

                  to external vertebral venous plexus ---- to segmental veins

Anterior spinal artery 

                           

Segmental arteries

Adamkiwicz artery

Blood Supply to the Spinal Cord and Brain Stem

The brain is one of the most metabolically active organs  in the body, receiving 17% of the total cardiac output and about 20% of the oxygen available  in the body.

The brain receives it’s blood from  two pairs of arteries, the carotid and vertebral. About 80% of the brain’s  blood supply comes from the carotid, and the remaining 20% from the vertebral.

The Vertebrobasilar System 

The vertebral arteries originate from the subclavian artery,and ascend through the transverse foramen of the upper six cervical vertebra. At the upper margin of the Axis (C2) it moves outward and upward to the transverse foramen of the Atlas (C1). It then moves backwards along the articular process of atlas into a deep groove, passes beneath the atlanto-occipital ligament and enters the foramen magnum. The arteries then run forward and unite at the caudal border of the pons to form the basilar artery.

The  Spinal Cord receives its blood supply from two major sources;

1. Branches of the vertebral arteries, the major source of blood supply, via the anterior spinal and posterior spinal arteries.

2. Multiple radicular arteries, derives sporadically from segmental arteries  The Medulla, Pons and Midbrain areas receive their major sources of blood  supply from several important branches of the Basilar artery

Branches of the Vertebral Artery

 

1. Posterior Inferior Cerebellar Artery (PICA),  the largest branch of the vertebral, arises at the caudal end of the medulla on each side.

Runs a course winding between the

medulla and cerebellum

Distribution:

   a. posterior part of cerebellar hemisphere

   b. inferior vermis

   c. central nuclei of cerebellum

   d. choroid plexus of 4th ventricle

   e. medullary branches to dorsolateral medulla

2. Anterior Spinal Artery, formed from a Y-shaped union of a branch from each vertebral artery.  Runs down the ventral median fissure the length of the cord.

Distribution:

 a. supplies the ventral 2/3 of the spinal cord.

3. Posterior Spinal Arteries (2), originate from each vertebral artery or Posterior Inferior Cerebellar on each side of the Medulla.  Descends along the dorsolateral sulcus.

Distribution:   supplies the dorsal 1/3 of the cord of each side.

4. Posterior meningeal, one or two branches that originate  from the vertebral opposite the foramen magnum. This branch moves into the dura matter of the cranium

5. Bulbar branches, composed of several smaller arteries which originate from the vertebral and it’s branches. These branches head for the pons, medulla and cerebellum

Branches of the Vertebral Artery

Spinal Cord Blood Supply

                                                    Ventral                                Dorsal

Anterior Spinal Artery, provides sulcal branches which penetrate the ventral median fissure and supply the ventral 2/3 of the spinal cord.

Posterior Spinal Arteries, each descends along the dorsolateral surface of the spinal cord and supplies the dorsal 1/3.

Radicular arteries, originating from segmental arteries at  various levels, which divide into anterior and posterior radicular arteries as they move along ventral and dorsal roots to reach the spinal cord. Here they reinforce spinal arteries and anastomose with their branches.

From these varied sources of blood supply, a series of circumferential anastomotic channels are formed around the spinal cord, called the arterial vasocorona, from which short branches penetrate and supply the lateral parts of the cord

The radicular arteries provide the main blood supply to the cord at the thorasic, lumbar and sacral segments. There are a greater number on the posterior (10-23) than anterior (6-10 only) side of the cord.

One radicular artery, noticeably larger than the others, is called the artery of Adamkiewicz, or the artery of the lumbar enlargement. Usually located with the lower thorasic or upper lumbar spinal segment on the left side of the spinal cord

The spinal cord lacks adequate collateral supply in some areas, making  these regions prone to ischemia after vascular occlusions. The upper

Thorasic (T1-T4) and first lumbar segments are the most vulnerable regions of the cord.

There are several arteries that reinforce the spinal cord blood supply and are termed segmental arteries

1. The Vertebral arteries, spinal branches which are present in the upper cervical (~C3-C5) levels

2. Ascending Cervical arteries, present in the lower cervical areas

3. Posterior Intercostal, present in the  mid-thorasic region

4. First Lumbar arteries, present in the  mid-lumbar regions

The spinal veins arranged in an irregular pattern.

The anterior spinal veins run along the midline and the ventral roots. The posterior spinal veins run along the midline and the dorsal roots. These are drained by the anterior and posterior radicular veins. These in turn empty into an epidural venous plexus which connects into an external vertebral venous plexus, the vertebral, intercostal and lumbar veins.

Occlusion of the anterior spinal artery may lead to the anterior  cord syndrome, characterized by;

1. Loss of ipsilateral motor function, due to damage to ventral gray matter and the ventral corticospinal tract.

2. Loss of contralateral pain and temperature sensation, due to damage to the spinothalamic pathway

Occlusion of the posterior spinal arteries may lead to the rare posterior cord syndrome, characterized by;

1. Ipsilateral motor deficits, due to damage to corticospinal tract

2. Ipsilateral loss of tactile discrimination, position sense, vibratory sense, due to damage to the dorsal columns

Blood Supply to the brain stem

The brain stem (medulla, pons midbrain) receives the bulk of its blood supply from the  vertebrobasilar system. Except for the labyrynthine branch, all other branches supply the brain stem and cerebellum

The posterior cerebral has only a small contribution, its main target being the posterior cerebral hemispheres

Branches of the Basilar Artery

1. Anterior Inferior Cerebellar Arteries  (AICA), originates near the lower border of the Pons just past the union of the vertebral arteries.

Distribution:

 a. supplies anterior inferior surface and underlying white matter of cerebellum

 b. contributes to supply of central cerebellar nuclei

 c. also contributes to upper medulla and lower pontine areas

2. Pontine arteries, numerous smaller branches that can be subdivided into Paramedian and Circumferential pontine arteries. The Circumferential can be  further subdivided into Long and Short  pontine arteries.

Distribution:

 a. paramedian pontine - basal pons

 b. circumferential pontine - lateral pons and middle cerebellar peduncle, floor of fourth ventricle and pontine tegmentum

3. Superior Cerebellar arteries, originates near the end of the Basilar artery,  close to the Pons-Midbrain junction. Runs along dorsal surface of cerebellum

Distribution:

 a. cerebellar cortex, white matter and central nuclei

 b. Additional contribution to rostral pontine tegmentum, superior cerebellar peduncle and inferior colliculus

4. Posterior cerebral arteries, the terminal branches of the Basilar artery. They appear as a bifurcation of the Basilar,  just past the Superior Cerebellar arteries and the oculomotor nerve.  Curves around the midbrain and reaches the medial surface of the cerebral hemisphere beneath the splenium of the corpus callosum

Distribution:

a. mainly neocortex and diencephalon

b. some contribution to interpeduncular plexus

5. Labyrynthine arteries, may branch from the basilar, but variable in its  origin. Supplies the region of the inner ear

Blood Supply to the Medulla 

The Medulla is supplied by the;

1. Anterior spinal artery, sends blood to the paramedian region of the caudal medulla.

2. Posterior spinal artery, supplies rostral areas, including the gracile and cuneate fasiculi and nuclei, along with dorsal areas of the inferior cerebellar peduncle.

3. Vertebral artery, bulbar branches supply areas of both the caudal and rostral medulla.

4. Posterior inferior cerebellar artery, supplies lateral medullary areas.

Occlusion of branches of the anterior spinal artery will produce

a inferior alternating hemiplegia (aka medial medullary syndrome), characterized by;

1. A contralateral hemiplegia of the limbs, due to damage to the pyramids or the corticospinal fibers

2. A contralateral loss of position sense, vibratory sense and discriminative touch, due to damage to the medial leminiscus

3. An ipsilateral deviation and paralysis of the tongue, due to damage to the hypoglossal nucleus or nerve

Occasionally, these symptoms will develop after occlusion of the vertebral artery before gives off its branches to the anterior spinal  artery

The posterior spinal arteries supply the  gracile and cuneate fasiculi and nuclei,  spinal trigeminal tract and nucleus,  portions of the inferior cerebellar peduncle

The vertebral arteries supply  the pyramids at the level of the Pons,  the inferior olive complex,  the medullary reticular formation,  solitary motor nucleus  dorsal motor nucleus of the Vagus  (cranial nerve X),  hypoglossal nucleus  (cranial nerve XII).  spinal trigeminal tract, spinothalamic tract  spinocerebellar tract

The posterior inferior cerebellar arteries (PICA) supply  spinothalamic tract,  spinal trigeminal nucleus and tract, fibers from the nucleus ambiguous,  dorsal motor nucleus of the Vagus (cranial nerve X)  inferior cerebellar peduncle

Occlusion of the posterior inferior cerebellar artery (or contributing vertebral) will produce a lateral medullary syndrome or Wallenberg’s syndrome, characterized by;

1. A contralateral loss of pain and temperature sense, due to damage to the anterolateral system (spinothalamic tract)

2. An ipsilateral loss of pain and temperature sense on the face, due to damage to the spinal trigeminal nucleus and tract

3. Vertigo, nausea and vomiting, due to damage to the vestibular nuclei

4. Hornor’s syndrome, (miosis [contraction of the pupil],  ptosis [sinking of the eyelid], decreased sweating), due to  damage to the descending hypothalamolspinal tract

Blood Supply to the Pons

The Pons is supplied by the;

1. The Basilar artery, contributions of this main artery can be further

subdivided;

                a. paramedian branches, to medial pontine region

                b. short circumferential branches, supply anterolateral pons

                c. long circumferential branches, run laterally over the anterior  surface of the Pons to anastomose with branches of the anterior inferior cerebellar artery (AICA).

2. Some reinforcing contributions by the anterior inferior cerebellar and superior cerebellar arteries

Additional branches of the Basilar artery can be found branching off within the  region of the Pons;

1. Anterior Inferior Cerebellar Arteries (AICA), originates near the lower border of the Pons just past the union of the vertebral arteries.

Distribution:

 a. supplies anterior inferior surface and underlying white matter of cerebellum

 b. contributes to supply of central cerebellar nuclei

 c. also contributes to upper medulla and lower pontine areas

2. Superior Cerebellar arteries, originates near the end of the Basilar artery, close to the  Pons-Midbrain junction. Runs along dorsal surface of cerebellum

Distribution:

 a. cerebellar cortex, white matter and central nuclei

 b. Additional contribution to rostral pontine tegmentum, superior cerebellar peduncle and inferior colliculus

2. Labyrynthine arteries, may branch from the basilar, but variable in its origin. Supplies the region of the inner ear.

Divides into two branches;

  a. anterior vestibular

  b. common cochlear

The labyrinthine has a variable origin, according to a study done by Wende et. al., 1975, (sample size of 238) the artery originated from;

1. Basilar (16%)

2. AICA (45%)

3. Superior cerebellar (25%)

4. PICA (5%)

5. Remaining 9% were of duplicate origin

The paramedian branches of the Basilar artery supplies the paramedian regions of the Pons, this includes corticospinal fibers (basis pedunculi),  the medial leminiscus, abducens nerve and nucleus (cranial nerve VI) ,  pontine reticular area, and periaquaductal gray areas

The paramedian branches of the Basilar artery supply  corticospinal fibers,  the medial leminiscus, abducens nerve and nucleus (cranial nerve VI) ,  pontine reticular area, periaquaductal gray areas

Obstruction of the paramedian pontine arteries will produce a  middle alternating hemiplegia  (also termed medial pontine syndrome)  which is characterized by;

1. Hemiplegia of the contralateral arm and leg, due to damage to the corticospinal tracts

2. Contralateral loss of tactile discrimination, vibratory and position sense, due to damage to the medial leminiscus

3. Ipsilateral lateral rectus muscle paralysis, due to damage to the  abducens nerve or tract (can cause diplopia “double vision”)

The short circumferential branches supply, pontine nuclei,  pontocerebellar fibers,  medial leminiscus  the anterolateral system (spinothalamic fibers)

The long circumferential branches supply, along with the anterior inferior cerebellar (caudally),  and superior cerebellar artery (rostrally). middle and superior cerebellar peduncles,  vestibular and cochlear nerves and nuclei,  facial motor nucleus (cranial nerve VII) trigeminal nucleus (cranial nerve V)  spinal trigeminal nucleus and tract (cranial nerve V),  hypothalamospinal fibers,  the anterolateral system (spinothalamic) pontine reticular nuclei.

Occlusions of long branches circumferential branches of the basilar artery produce a lateral pontine syndrome, characterized by;

1. Ataxia, due to damage to the cerebral peduncles (middle and superior)

2. Vertigo, nausea, nystagmus, deafness, tinitus, vomiting, due to damage to vestibular and cochlear nuclei and nerves

3. Ipsilateral pain and temperature deficits from face, due to damage to the spinal trigeminal nucleus and tract

4. Contralateral loss of pain and temperature sense from the body, due to damage to the anterolateral system (spinothalamic)

5. Ipsilateral paralysis of facial muscles and masticatory muscles, due to damage to the facial and trigeminal motor nuclei (cranial nerves VII and V)

Blood Supply to the Midbrain

The major blood supply to the midbrain is derived from branches of the basilar artery;

1. Posterior cerebral artery, forms a plexus with the posterior communicating arteries in the interpeduncular fossa, branches from this plexus supply a wide area if the midbrain

2. Superior cerebellar artery, supplies dorsal areas around the central gray and inferior colliculus with support from branches of the posterior cerebral artery.

3. Quadrigeminal, (some posterior choroidal) a branch of the posterior cerebral, provides support for the tectum (superior and inferior colliculi)

4. Posterior communicating artery, derived from the internal carotid, joins the posterior cerebral to form portions of the circle of Willis  (arterial circle). Contributes to the interpeduncular plexus

5. Branches of these arteries are best understood when grouped into paramedian, short circumferential and long circumferential

The paramedian arteries, derived from the posterior communicating and posterior cerebral, form a plexus in the interpeduncular fossa, enter the  through the posterior perforated substance, this system supplies

• raphe region,
• oculomotor complex,
• medial longitudinal fasiculus,
• red nucleus
• substantia nigra
• crus cerebri

Occlusion of midbrain paramedian branches produces a medial midbrain or superior alternating hemiplegia (or Weber’s syndrome) characterized by;

1. Contralateral hemiplegia of the limbs, and contralateral face and tongue due to damage to the descending motor tracts

(crus cerebri).

2. Ipsilateral deficits in eye motor activity, caused by damage to the oculomotor nerve

The short circumferential arteries originate from the interpeduncular plexus and portions of the posterior cerebral and superior cerebellar arteries, this system supplies

• crus cerebri,
• substantia nigra
• midbrain tegmentum

The long circumferential branches originate mainly from the posterior  cerebral artery, one important branch, the quadrigeminal (collicular artery) supplies the superior and inferior colliculi.

The posterior choroidal arteries originate near the basilar  bifurcation into the posterior  cerebral arteries. In addition to providing reinforement to the midbrain short and long circumferential arteries they move forward to supply portions of the diencephalon and the choroid plexus of the third  and lateral ventricles

Other Clinical Points

Substantial infarcts within the Pons are generally rapidly fatal, due to failure of central control of respiration Infarcts within the ventral portion of the Pons can produce paralysis of all movements except the eyes. Patient is conscious but can communicate only with eyes. LOCKED-IN-SYNDROME