Medulla oblongata

The medulla oblongata or simply medulla is a long stem-like structure which makes up the lower part of the brainstem.[1] It is anterior and partially inferior to the cerebellum. It is a cone-shaped neuronal mass responsible for autonomic (involuntary) functions, ranging from vomiting to sneezing.[2] The medulla contains the cardiac, respiratory, vomiting and vasomotor centers, and therefore deals with the autonomic functions of breathing, heart rate and blood pressure as well as the sleep–wake cycle.[2]

Medulla oblongata
Medulla oblongata purple, part of the brain stem colored
Section of the medulla oblongata at about the middle of the olivary body
Details
Part ofBrain stem
Identifiers
LatinMedulla oblongata, myelencephalon
MeSHD008526
NeuroNames698
NeuroLex IDbirnlex_957
TA98A14.1.03.003
TA25983
FMA62004
Anatomical terms of neuroanatomy

During embryonic development, the medulla oblongata develops from the myelencephalon. The myelencephalon is a secondary vesicle which forms during the maturation of the rhombencephalon, also referred to as the hindbrain.

The bulb is an archaic term for the medulla oblongata.[1] In modern clinical usage, the word bulbar (as in bulbar palsy) is retained for terms that relate to the medulla oblongata, particularly in reference to medical conditions. The word bulbar can refer to the nerves and tracts connected to the medulla, and also by association to those muscles innervated, such as those of the tongue, pharynx and larynx.

Anatomy

Medulla oblongata (animation)
Medulla and parts (10-16) - (10) pyramid; (11) the anterior median fissure; (15) is the choroid plexus in the fourth ventricle; (13) olive and (7) the pons
Medulla-animated as it protrudes from the foramen magnum of the skull-base, after which it gives rise to the spinal cord.

The medulla can be thought of as being in two parts:

  • an upper open part or superior part where the dorsal surface of the medulla is formed by the fourth ventricle.
  • a lower closed part or inferior part where the fourth ventricle has narrowed at the obex in the caudal medulla, and surrounds part of the central canal.

External surfaces

The anterior median fissure contains a fold of pia mater, and extends along the length of the medulla oblongata. It ends at the lower border of the pons in a small triangular area, termed the foramen cecum. On either side of this fissure are raised areas termed the medullary pyramids. The pyramids house the pyramidal tracts–the corticospinal and the corticobulbar tracts of the nervous system. At the caudal part of the medulla these tracts cross over in the decussation of the pyramids obscuring the fissure at this point. Some other fibers that originate from the anterior median fissure above the decussation of the pyramids and run laterally across the surface of the pons are known as the anterior external arcuate fibers.

The region between the anterolateral and posterolateral sulcus in the upper part of the medulla is marked by a pair of swellings known as olivary bodies (also called olives). They are caused by the largest nuclei of the olivary bodies, the inferior olivary nuclei.

The posterior part of the medulla between the posterior median sulcus and the posterolateral sulcus contains tracts that enter it from the posterior funiculus of the spinal cord. These are the gracile fasciculus, lying medially next to the midline, and the cuneate fasciculus, lying laterally. These fasciculi end in rounded elevations known as the gracile and the cuneate tubercles. They are caused by masses of gray matter known as the gracile nucleus and the cuneate nucleus. The soma (cell bodies) in these nuclei are the second-order neurons of the posterior column-medial lemniscus pathway, and their axons, called the internal arcuate fibers or fasciculi, decussate from one side of the medulla to the other to form the medial lemniscus.

Just above the tubercles, the posterior aspect of the medulla is occupied by a triangular fossa, which forms the lower part of the floor of the fourth ventricle. The fossa is bounded on either side by the inferior cerebellar peduncle, which connects the medulla to the cerebellum.

The lower part of the medulla, immediately lateral to the cuneate fasciculus, is marked by another longitudinal elevation known as the tuberculum cinereum. It is caused by an underlying collection of gray matter known as the spinal trigeminal nucleus. The gray matter of this nucleus is covered by a layer of nerve fibers that form the spinal tract of the trigeminal nerve.

The base of the medulla is defined by the commissural fibers, crossing over from the ipsilateral side in the spinal cord to the contralateral side in the brain stem; below this is the spinal cord.

Blood supply

Blood to the medulla is supplied by a number of arteries.[3]

Development

The medulla oblongata forms in fetal development from the myelencephalon. The final differentiation of the medulla is seen at week 20 gestation.[4]

Neuroblasts from the alar plate of the neural tube at this level will produce the sensory nuclei of the medulla. The basal plate neuroblasts will give rise to the motor nuclei.

Function

The medulla oblongata connects the higher levels of the brain to the spinal cord, and is responsible for several functions of the autonomous nervous system which include:

Clinical significance

A blood vessel blockage (such as in a stroke) will injure the pyramidal tract, medial lemniscus, and the hypoglossal nucleus. This causes a syndrome called medial medullary syndrome.

Lateral medullary syndrome can be caused by the blockage of either the posterior inferior cerebellar artery or of the vertebral arteries.

Progressive bulbar palsy (PBP) is a disease that attacks the nerves supplying the bulbar muscles. Infantile progressive bulbar palsy is progressive bulbar palsy in children.

Other animals

Both lampreys and hagfish possess a fully developed medulla oblongata.[6][7] Since these are both very similar to early agnathans, it has been suggested that the medulla evolved in these early fish, approximately 505 million years ago.[8] The status of the medulla as part of the primordial reptilian brain is confirmed by its disproportionate size in modern reptiles such as the crocodile, alligator, and monitor lizard.

Additional images

References

This article incorporates text in the public domain from page 767 of the 20th edition of Gray's Anatomy (1918)

  1. Webb, Wanda G. (2017-01-01), Webb, Wanda G. (ed.), "2 - Organization of the Nervous System I", Neurology for the Speech-Language Pathologist (Sixth Edition), Mosby, pp. 13–43, doi:10.1016/b978-0-323-10027-4.00002-6, ISBN 978-0-323-10027-4, retrieved 2020-11-15
  2. Waldman, Steven D. (2009-01-01), Waldman, Steven D. (ed.), "CHAPTER 120 - The Medulla Oblongata", Pain Review, Philadelphia: W.B. Saunders, p. 208, doi:10.1016/b978-1-4160-5893-9.00120-9, ISBN 978-1-4160-5893-9, retrieved 2020-11-15
  3. Purves, Dale (2001). Neuroscience. 2nd edition. Sinauer Associates.
  4. Carlson, Neil R. Foundations of Behavioral Neuroscience.63-65
  5. Hughes, T. (2003). "Neurology of swallowing and oral feeding disorders: Assessment and management". Journal of Neurology, Neurosurgery & Psychiatry. 74 (90003): 48iii–52. doi:10.1136/jnnp.74.suppl_3.iii48. PMC 1765635. PMID 12933914.
  6. Nishizawa H, Kishida R, Kadota T, Goris RC; Kishida, Reiji; Kadota, Tetsuo; Goris, Richard C. (1988). "Somatotopic organization of the primary sensory trigeminal neurons in the hagfish, Eptatretus burgeri". J Comp Neurol. 267 (2): 281–95. doi:10.1002/cne.902670210. PMID 3343402. S2CID 45624479.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  7. Rovainen CM (1985). "Respiratory bursts at the midline of the rostral medulla of the lamprey". J Comp Physiol A. 157 (3): 303–9. doi:10.1007/BF00618120. PMID 3837091. S2CID 27654584.
  8. Haycock, Being and Perceiving
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