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The pons (Latin for "bridge") is part of the brainstem, and in humans and other bipeds lies inferior to the midbrain, superior to the medulla oblongata and anterior to the cerebellum.

Pons
Brain bulbar region.PNG
Pons in the brainstem
Gray679.png
Details
Part ofBrain stem
Arterypontine arteries
Veintransverse and lateral pontine veins
Identifiers
MeSHD011149
NeuroNames547
NeuroLex IDbirnlex_733
TAA14.1.03.010
FMA67943
Anatomical terms of neuroanatomy

The pons is also called the pons Varolii ("bridge of Varolius"), after the Italian anatomist and surgeon Costanzo Varolio (1543–75).[1] This region of the brainstem includes neural pathways and tracts that conduct signals from the brain down to the cerebellum and medulla, and tracts that carry the sensory signals up into the thalamus.[2]

StructureEdit

The pons is in the brainstem situated between the midbrain and the medulla oblongata, and in front of the cerebellum. A separating groove between the pons and the medulla is the inferior pontine sulcus.[3] The superior pontine sulcus separates the pons from the midbrain.[4] The pons can be broadly divided into two parts: the basilar part of the pons (ventral pons), and the pontine tegmentum (dorsal pons). Running down the midline of the ventral surface is the basilar sulcus, a groove for the basilar artery. Most of the pons is supplied by the pontine arteries, which arise from the basilar artery. A smaller portion of the pons is supplied by the anterior and posterior inferior cerebellar arteries.

The pons in humans measures about 2.5 centimetres (0.98 in) in length. Most of it appears as a broad anterior bulge above the medulla. Posteriorly, it consists mainly of two pairs of thick stalks called cerebellar peduncles. They connect the cerebellum to the pons (middle cerebellar peduncle) and midbrain (superior cerebellar peduncle).[2]

DevelopmentEdit

During embryonic development, the metencephalon develops from the rhombencephalon and gives rise to two structures: the pons and the cerebellum.[2] The alar plate produces sensory neuroblasts, which will give rise to the solitary nucleus and its special visceral afferent (SVA) column; the cochlear and vestibular nuclei, which form the special somatic afferent (SSA) fibers of the vestibulocochlear nerve, the spinal and principal trigeminal nerve nuclei, which form the general somatic afferent column (GSA) of the trigeminal nerve, and the pontine nuclei which relays to the cerebellum.

Basal plate neuroblasts give rise to the abducens nucleus, which forms the general somatic efferent fibers (GSE); the facial and motor trigeminal nuclei, which form the special visceral efferent (SVE) column, and the superior salivatory nucleus, which forms the general visceral efferent fibers (GVE) of the facial nerve.

NucleiEdit

 
Cross-section of lower pons, axons shown in blue, grey matter in light grey. Anterior is down and posterior is up

A number of cranial nerve nuclei are present in the pons:

FunctionEdit

The functions of these four cranial nerves (V-VIII) include regulation of respiration, controls involuntary actions, sensory roles in hearing, equilibrium, and taste, and in facial sensations such as touch and pain, as well as motor roles in eye movement, facial expressions, chewing, swallowing, and the secretion of saliva and tears.[2]

The pons contains nuclei that relay signals from the forebrain to the cerebellum, along with nuclei that deal primarily with sleep, respiration, swallowing, bladder control, hearing, equilibrium, taste, eye movement, facial expressions, facial sensation, and posture.[2]

Within the pons is the pneumotaxic center consisting of the subparabrachial and the medial parabrachial nuclei. This center regulates the change from inhalation to exhalation.[2]

The pons is implicated in sleep paralysis, and may also play a role in generating dreams.[citation needed]

Clinical significanceEdit

Other animalsEdit

EvolutionEdit

The pons first evolved as an offshoot of the medullary reticular formation.[5] Since lampreys possess a pons, it has been argued that it must have evolved as a region distinct from the medulla by the time the first agnathans appeared, 505 million years ago.[6]

Additional imagesEdit

ReferencesEdit

  1. ^ Henry Gray (1862). Anatomy, descriptive and surgical. Blanchard and Lea. pp. 514–. Retrieved 10 November 2010.
  2. ^ a b c d e f Saladin Kenneth S.(2007) Anatomy & physiology the unity of form and function. Dubuque, IA: McGraw-Hill
  3. ^ "BrainInfo". braininfo.rprc.washington.edu.
  4. ^ Carpenter, M (1985). Core text of neuroanatomy (3rd ed.). Williams & Wilkins. p. 42. ISBN 0683014552.
  5. ^ Pritchard and Alloway Medical Neuroscience
  6. ^ Butler and Hodos Comparative vertebrate neuroanatomy: evolution and adaptation

External linksEdit