The Vertebral Column - Joints - Vertebrae (2024)

The vertebral columnis a series ofapproximately 33 bones called vertebrae, which are separated by intervertebral discs.

The column can be divided into five different regions, with each region characterised by a different vertebral structure.

Inthis article, we shall look at the anatomy of the vertebral column – its function, structure, and clinical significance.

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Functions

The vertebral column has four main functions:

  • Protection –encloses and protects the spinal cord within the spinal canal.
  • Support –carries the weight of the body above the pelvis.
  • Axis –forms the central axis of the body.
  • Movement –has roles in both posture and movement.

Fig 1
The vertebral column viewed from the side. The five different regions are shown and labelled.

Structure of a Vertebrae

All vertebrae share a basic common structure.They eachconsist of an anterior vertebral body, and a posterior vertebral arch.

Vertebral Body

The vertebral body forms the anterior part of each vertebrae.

It is theweight-bearingcomponent, and vertebrae in the lower portion of the column have larger bodies than those in the upper portion (to better support the increased weight).

The superior and inferior aspects of the vertebral body are lined with hyaline cartilage. Adjacentvertebral bodies are separated by a fibrocartilaginous intervertebral disc.

Fig 2
The general structure of a vertebrae.

Vertebral Arch

The vertebral arch forms the lateral and posterioraspect of each vertebrae.

In combination with the vertebral body, the vertebral arch forms an enclosed hole – the vertebral foramen. The foramina of all the vertebrae line up to form the vertebral canal, which encloses the spinal cord.

The vertebral arches have several bonyprominences, which act asattachmentsites for muscles and ligaments:

  • Spinous processes – each vertebra has a single spinous process, centred posteriorly at the point of the arch.
  • Transverse processes – each vertebra has two transverse processes, which extend laterally and posteriorly from the vertebral body. In the thoracic vertebrae, the transverse processes articulate with the ribs.
  • Pedicles–connect the vertebral body to the transverse processes.
  • Lamina –connect the transverse and spinous processes.
  • Articular processes – form joints between one vertebra and its superior and inferior counterparts. The articular processes are located at the intersection of the laminae and pedicles.

Fig 3
Superior view of a lumbar vertebrae, showing its characteristic features.

Clinical Relevance

Intervertebral Disc Herniation

The intervertebraldisc is afibrocartilaginouscylinder that lies between the vertebrae, joining them together. They permit theflexibilityof the spine, and act as shock absorbers. In the lumbar and thoracic regions, they arewedgeshaped – supporting the curvature of the spine.

Each vertebral disc has two parts:thenucleus pulposusandannulus fibrosus. The annulus fibrosus is tough and collagenous, and it surrounds the jelly-like nucleus pulposus.

Herniation of an intervertebral disc occurs when thenucleus pulposusruptures, breaking through the annulus fibrosus. The rupture usually occurs in a posterior-lateral direction, after which the nucleus pulposis can irritate nearby spinal nerves – resulting in a variety of neurological and muscular symptoms.

Classifications of Vertebrae

Cervical Vertebrae

There aresevencervical vertebraein the human body. They have three main distinguishing features:

  • Bifid spinous process –the spinous process bifurcates at its distal end.
    • Exceptions to this are C1 (no spinous process) and C7 (spinous process is longer than that of C2-C6 and may not bifurcate).
  • Transverse foramina– an opening in each transverse process, through which the vertebral arteries travel to the brain.
  • Triangular vertebral foramen

Two cervical vertebrae that are unique. C1 and C2 (called the atlas and axis respectively), are specialised to allow for the movement of the head.

Fig 5
Characteristic features of a cervical vertebrae

Thoracic Vertebrae

The twelvethoracic vertebraeare medium-sized, and increase in size from superior to inferior. Their specialised function is to articulate with ribs, producing thebony thorax.

Each thoracic vertebra has two ‘demi facets,’ superiorly and inferiorly placed on either side of its vertebral body. The demi facets articulate with the heads of two different ribs.

On thetransverse processesof the thoracic vertebrae, there is a costal facet for articulation with the shaft of a single rib. For example, the head of Rib 2 articulates with the inferior demi facet of thoracic vertebra 1 (T1) and the superior demi facet of T2, while the shaft of Rib 2 articulates with the costal facets of T2.

Thespinous processes of thoracic vertebraeare oriented obliquely inferiorly and posteriorly. In contrast to the cervical vertebrae, the vertebral foramen of thoracic vertebrae iscircular.

Fig 6
Lateral view of a thoracic vertebrae.

Lumbar Vertebrae

There are five lumbar vertebrae in most humans, which are thelargestin the vertebral column. They are structurally specialised to support the weight of the torso.

Lumbar vertebraehave verylarge vertebral bodies, which are kidney shaped. They lack the characteristic features of other vertebrae, with no transverse foramina, costal facets, or bifid spinous processes.

However, like the cervical vertebrae, they have atriangular-shaped vertebral foramen. Their spinous processes are shorter than those of thoracic vertebrae and do not extend inferiorly below the level of the vertebral body.

Their size and orientation permits needle access to the spinal canal and spinal cord (which would not be possible between thoracic vertebrae). Examples include epidural anaesthesia administration and lumbar puncture.

Sacrum and Coccyx

The sacrum and coccyx lie at the caudal (tail) end of the vertebral column. They are composed of fused vertebrae, and are referred to as the ‘false’ vertebrae.

  • Sacrum – formed by five fused vertebrae. It is shaped as an inverted triangle, and forms the posterior wall of the bony pelvis. On the lateral walls of the sacrum are facets for articulation with the ilium at the sacroiliac joints.
  • Coccyx – formed by four fused vertebrae. It is a small bone which articulates with the apex of the sacrum. It is recognised by its absent vertebral canal and vertebral arches.

Separation of S1 from the sacrum is termed “lumbarisation”, while fusion of L5 to the sacrum is termed “sacralisation”. These conditions are congenital abnormalities.

Fig 7
Diagram of the sacrum and coccyx, articulating with the pelvic bones.

Joints and Ligaments

The mobile vertebrae articulate with each other via joints between their bodies and articular facets:

  • Left and right superior articular facets articulate with the vertebra above.
  • Left and right inferior articular facets articulate with the vertebra below.
  • Vertebral bodies indirectly articulate with each other via the intervertebral discs.

The vertebral body joints arecartilaginousjoints, designed for weight-bearing. The articular surfaces are covered by hyaline cartilage, and are connected by the intervertebral disc.

Two ligaments strengthen the vertebral body joints: the anterior and posteriorlongitudinal ligaments, which run the full length of the vertebral column. The anterior longitudinal ligament is thick and prevents hyperextension of the vertebral column. The posterior longitudinal ligament is weaker and prevents hyperflexion.

The joints between the articular facets, called facet joints, allow for some gliding motions between the vertebrae. They are strengthened by several ligaments:

  • Ligamentum flavum –extends between lamina of adjacent vertebrae.
  • Interspinous and supraspinous –join the spinous processes of adjacent vertebrae. The interspinous ligaments attach between processes, and the supraspinous ligaments attach to the tips.
  • Intertransverse ligaments –extends between transverse processes.

Fig 8
Ligaments of the lumbar vertebrae

Clinical Relevance

Abnormal Morphology of the Spine

Fig 9
Radiograph of scoliosis of the spine.

There are several clinical syndromes resulting from an abnormal curvature of the spine:

  • Kyphosis– excessive thoracic curvature, causing a hunchback deformity.
  • Lordosis –excessive lumbar curvature, causing a swayback deformity.
  • Scoliosis –lateral curvature of the spine, usually of unknown cause.
  • Cervical spondylosis –decrease in the size of the intervertebral foramina, usually due to degeneration of the joints of the spine. The smaller size of the intervertebral foramina puts pressure on the exiting nerves, causing pain.
The Vertebral Column - Joints - Vertebrae (2024)
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