Cervical Spine Anatomy

No Results

No Results

processing….

The cervical spine is made up of 7 vertebrae. The first 2, C1 and C2, are highly specialized and are given unique names: atlas and axis, respectively. C3-C7 are more classic vertebrae, having a body, pedicles, laminae, spinous processes, and facet joints.

C1 and C2 form a unique set of articulations that provide a great degree of mobility for the skull. C1 serves as a ring or washer that the skull rests upon and articulates in a pivot joint with the dens or odontoid process of C2. Approximately 50% of flexion extension of the neck happens between the occiput and C1; 50% of the rotation of the neck happens between C1 and C2.

The cervical spine is much more mobile than the thoracic or lumbar regions of the spine. Unlike the other parts of the spine, the cervical spine has transverse foramina in each vertebra for the vertebral arteries that supply blood to the brain.

The cervical spine is made up of the first 7 vertebrae, referred to as C1-7 (see the images below). It functions to provide mobility and stability to the head while connecting it to the relatively immobile thoracic spine. The cervical spine may be divided into 2 parts: upper and lower. 

The upper cervical spine consists of the atlas (C1) and the axis (C2). ^{[1, 2, 3, 4]} These first 2 vertebrae are quite different from the rest of the cervical spine (see the image below). The atlas articulates superiorly with the occiput (the atlanto-occipital joint) and inferiorly with the axis (the atlantoaxial joint). The atlantoaxial joint is responsible for 50% of all cervical rotation; the atlanto-occipital joint is responsible for 50% of flexion and extension. The unique features of C2 anatomy and its articulations complicate assessment of its pathology.

Atlas (C1)

The atlas is ring-shaped and does not have a body, unlike the rest of the vertebrae. Fused remnants of the atlas body have become part of C2, where they are called the odontoid process, or dens. The odontoid process is held in tight proximity to the posterior aspect of the anterior arch of the atlas by the transverse ligament, which stabilizes the atlantoaxial joint. The apical, alar, and transverse ligaments, by allowing spinal column rotation, provide further stabilization and prevent posterior displacement of the dens in relation to the atlas.

The atlas is made up of a thick anterior arch, a thin posterior arch, 2 prominent lateral masses, and 2 transverse processes. The transverse foramen, through which the vertebral artery passes, is enclosed by the transverse process.

On each lateral mass is a superior and inferior facet (zygapophyseal) joint. The superior articular facets are kidney-shaped, concave, and face upward and inward. These superior facets articulate with the occipital condyles, which face downward and outward. The relatively flat inferior articular facets face downward and inward to articulate with the superior facets of the axis.

According to Steele’s rule of thirds, at the level of the atlas, the odontoid process, the subarachnoid space, and spinal cord each occupy one third of the area of the spinal canal.

Axis (C2)

The axis has a large vertebral body, which contains the odontoid process (dens). The odontoid process articulates with the anterior arch of the atlas via its anterior articular facet and is held in place by the transverse ligament. The axis is composed of a vertebral body, heavy pedicles, laminae, and transverse processes, which serve as attachment points for muscles. The axis articulates with the atlas via its superior articular facets, which are convex and face upward and outward.

Embryology

C2 has a complex embryologic development. It is derived from 4 ossification centers: 1 for the body, 1 for the odontoid process, and 2 for the neural arches. The odontoid process fuses by the seventh gestational month.

At birth, a vestigial cartilaginous disc space called the neurocentral synchondrosis separates the odontoid process from the body of C2. The synchondrosis is seen in virtually all children aged 3 years and is absent in those aged 6 years. The apical portion of the dens ossifies by age 3-5 years and fuses with the rest of the structure around age 12 years. This synchondrosis should not be confused with a fracture.

Parts of the occiput, atlas, and axis are derived from the proatlas. The hypocentrum of the fourth sclerotome forms the anterior tubercle of the clivus. The centrum of the proatlas sclerotome becomes the apical cap of the dens and the apical ligaments.

The neural arch components of the proatlas are divided into rostral and ventral components. The rostral component forms the anterior portion of the foramen magnum and the occipital condyles; the caudal component forms the superior part of the posterior arch of the atlas and the lateral atlantal masses. The alar and cruciate ligaments are formed from the lateral portions of the proatlas.

Vasculature

There is an extensive arterial anastomotic network around the dens, fed by the paired anterior and posterior ascending arteries arising from the vertebral arteries around the C3 level and the carotid arterial arcade from the base of the skull. The anterior and posterior ascending arteries reach the base of the dens via the accessory ligaments and run cephalad at the periphery to reach the tip of the process. The anastomotic arcade also receives tributaries from the ascending pharyngeal arteries that join the arcade after passing through the occipital condyle.

Ligaments

The craniocervical junction and the atlantoaxial joints are secured by the external and internal ligaments. The external ligaments consist of the atlanto-occipital, anterior atlanto-occipital, and anterior longitudinal ligaments. The internal ligaments have 5 components, as follows:

The transverse ligament holds the odontoid process in place against the posterior atlas, which prevents anterior subluxation of C1 on C2

The accessory ligaments arise posterior to and in conjunction with the transverse ligament and insert into the lateral aspect of the atlantoaxial joint; the apical ligament lies anterior to the lip of the foramen magnum and inserts into the apex of the odontoid process

The paired alar ligaments secure the apex of the odontoid to the anterior foramen magnum

The tectorial membrane is a continuation of the posterior longitudinal ligament to the anterior margin of the foramen magnum

The 3 cm × 5 mm accessory atlantoaxial ligament not only connects the atlas to the axis but also continues cephalad to the occipital bone; functionally, it becomes maximally taut with 5-8° of head rotation, lax with cervical extension, and maximally taut with 5-10° of cervical flexion; it seems to participate in craniocervical stability; future improvements in magnetic resonance imaging (MRI) may lead to better appreciation of its structure and integrity of this ligament ^[5]

The 5 cervical vertebrae that make up the lower cervical spine, C3-C7, are similar to each other but very different from C1 and C2. Each has a vertebral body that is concave on its superior surface and convex on its inferior surface (see the image below). On the superior surfaces of the bodies are raised processes or hooks called uncinate processes, each of which articulates with a depressed area on the inferior lateral aspect of the superior vertebral body, called the echancrure or anvil.

These uncovertebral joints are most noticeable near the pedicles and are usually referred to as the joints of Luschka. ^[6] They are believed to be the result of degenerative changes in the annulus, which lead to fissuring in the annulus and the creation of the joint. ^[7] These joints can develop osteophytic spurs, which can narrow the intervertebral foramina.

The spinous processes of C3-C6 are usually bifid, whereas the spinous process of C7 is usually nonbifid and somewhat bulbous at its end.

Anterior and posterior columns

The subaxial cervical spine can conveniently be divided into anterior and posterior columns. The anterior column consists of the typical cervical vertebral body sandwiched between supporting disks. The anterior surface is reinforced by the anterior longitudinal ligament and the posterior body by the posterior longitudinal ligament, both of which run from the axis to the sacrum.

Articulations include disk-vertebral body articulations, uncovertebral joints, and zygapophyseal (facet) joints. The disk is thicker anteriorly, contributing to normal cervical lordosis, and the uncovertebral joints in the posterior aspect of the body define the lateral extent of most surgical exposures. The facet joints are oriented at a 45º angle to the axial plane, allowing a sliding motion; the joint capsule is weakest posteriorly. Supporting ligamentum flavum, posterior, and interspinous ligaments also strengthen the posterior column. ^[8]

Nerve supply

In the neuroanatomy of the cervical spine (see the image below), the cord is enlarged, with lateral extension of the gray matter consisting of the anterior horn cells. The lateral dimension spans 13-14 mm, and the anterior-posterior extent measures 7 mm. An additional 1 mm is necessary for cerebrospinal fluid (CSF) anteriorly and posteriorly, as well as 1 mm for the dura. A total of 11 mm is needed for the cervical spinal cord. Exiting at each vertebral level is the spinal nerve, which is the result of the union of the anterior and posterior nerve roots.

The foramina are largest at C2-C3 and progressively decrease in size down to C6-C7. The spinal nerve and spinal ganglion occupy 25-33% of the foraminal space. The neural foramen is bordered anteromedially by the uncovertebral joints, posterolaterally by facet joints, superiorly by the pedicle of the vertebra above, and inferiorly by the pedicle of the lower vertebra. Medially, the foramina are formed by the edge of the end plates and the intervertebral discs.

Interconnections are present between the sympathetic nervous system and the spinal nerve proper. The spinal nerves exit above their correspondingly numbered vertebral body from C2-C7. Because the numbering of the cervical spinal nerves commences above the atlas, 8 cervical spinal nerves exist, with the first exiting between the occiput and the atlas (C1) and the eighth exiting between C7 and T1.

Vasculature

The vascular anatomy consists of a larger anterior spinal artery located in the central sulcus of the cord and paired posterior spinal arteries located on the dorsum of the cord. It is generally accepted that the anterior two thirds of the cord is supplied by the anterior spinal artery and that the posterior one third is supplied by the posterior arteries.

The facet joints in the cervical spine are diarthrodial synovial joints with fibrous capsules. The joint capsules are more lax in the lower cervical spine than in other areas of the spine to allow gliding movements of the facets. The joints are inclined at an angle of 45° from the horizontal plane and 85° from the sagittal plane. This alignment helps prevent excessive anterior translation and is important in weight-bearing. ^[9]

Nerve supply

The fibrous capsules are innervated by mechanoreceptors (types I, II, and III), and free nerve endings have been found in the subsynovial loose areolar and dense capsular tissues. ^[10] In fact, there are more mechanoreceptors in the cervical spine than in the lumbar spine. ^[1] This neural input from the facets may be important for proprioception and pain sensation and may modulate protective muscular reflexes that are important for preventing joint instability and degeneration.

The facet joints in the cervical spine are innervated by both the anterior and posterior rami. The atlanto-occipital and atlantoaxial joints are innervated by the anterior rami of the first and second cervical spinal nerves. The C2-C3 facet joint is innervated by 2 branches of the posterior ramus of the third cervical spinal nerve innervate, a communicating branch and a medial branch known as the third occipital nerve.

The remaining cervical facets, C3-C4 to C7-T1, are supplied by the posterior rami medial branches that arise 1 level cephalad and caudad to the joint. ^{[11, 12]} Therefore, each joint from C3-C4 to C7-T1 is innervated by the medial branches above and below. These medial branches send off articular branches to the facet joints as they wrap around the waists of the articular pillars.

Intervertebral discs are located between the vertebral bodies of C2-C7. Intervertebral disks are located between each vertebral body caudad to the axis. These disks are composed of 4 parts: the nucleus pulposus in the middle, the annulus fibrosis surrounding the nucleus, and 2 end plates that are attached to the adjacent vertebral bodies. They serve as force dissipators, transmitting compressive loads throughout a range of motion. The disks are thicker anteriorly and therefore contribute to normal cervical lordosis.

The intervertebral disks are involved in cervical spine motion, stability, and weight-bearing. The annular fibers are composed of collagenous sheets (lamellae) that are oriented at a 65-70° angle from the vertical and alternate in direction with each successive sheet. As a result, they are vulnerable to injury by rotation forces because only one half of the lamellae are oriented to withstand force applied in this direction. ^[1]

The middle and outer one third of the annulus is innervated by nociceptors. Phospholipase A2 has been found in the disc and may be an inflammatory mediator. ^{[13, 14, 15]}

Although the cervical spine consists of 7 cervical vertebrae interspaced by intervertebral disks, the complex ligamentous network keep the individual bony elements behaving as if they were a single unit.

As noted, the cervical spine can be viewed as being made up of anterior and posterior columns. It can also be useful to think in terms of a third (middle) column, as follows:

The anterior column consists of the anterior longitudinal ligament and the anterior two thirds of the vertebral bodies, the annulus fibrosus, and the intervertebral disks

The middle column is composed of the posterior longitudinal ligament and the posterior one third of the vertebral bodies, the annulus fibrosus, and the intervertebral disks

The posterior column is made up of the posterior arches, including the pedicles, transverse processes, articulating facets, laminae, and spinous processes

The longitudinal ligaments are vital for maintaining the integrity of the spinal column. Whereas the anterior and posterior longitudinal ligaments maintain the structural integrity of the anterior and middle columns, the posterior column alignment is stabilized by a complex of ligaments, including the nuchal and capsular ligaments, and the ligamentum flavum.

If 1 of the 3 columns is disrupted as a result of trauma, stability is provided by the other 2, and cord injury is usually prevented. With disruption of 2 columns, spinal cord injury is more likely because the spine may then move as w separate units.

Several ligaments of the cervical spine that provide stability and proprioceptive feedback are worth mentioning and are briefly described here. ^{[16, 17]}

The transverse ligament, the major portion of the cruciate ligament, arises from tubercles on the atlas and stretches across its anterior ring while holding the odontoid process (dens) against the anterior arch. A synovial cavity is located between the dens and the transverse process. This ligament allows rotation of the atlas on the dens and is responsible for stabilizing the cervical spine during flexion, extension, and lateral bending. The transverse ligament is the most important ligament for preventing abnormal anterior translation. ^[18]

The alar ligaments run from the lateral aspects of the dens to the ipsilateral medial occipital condyles and to the ipsilateral atlas. They prevent excessive lateral and rotational motion while allowing flexion and extension. If the alar ligaments are damaged, as in whiplash, the joint complex becomes hypermobile, which can lead to kinking of the vertebral arteries and stimulation of nociceptors and mechanoreceptors. This may be associated with the typical complaints of patients with whiplash injuries (eg, headache, neck pain, and dizziness).

The anterior longitudinal ligament (ALL) and the posterior longitudinal ligament (PLL) are the major stabilizers of the intervertebral joints. Both ligaments are found throughout the entire length of the spine; however, the ALL adheres more closely to the disks than the PLL does, and it is not well developed in the cervical spine. The ALL becomes the anterior atlanto-occipital membrane at the level of the atlas, whereas the PLL merges with the tectorial membrane. Both continue onto the occiput. The PLL prevents excessive flexion and distraction. ^[19]

The supraspinous ligament, the interspinous ligaments, and the ligamentum flavum maintain stability between the vertebral arches. The supraspinous ligament runs along the tips of the spinous processes, the interspinous ligaments run between adjacent spinous processes, and the ligamentum flavum runs from the anterior surface of the cephalad vertebra to the posterior surface of the caudad vertebra.

The interspinous ligament and (especially) the ligamentum flavum control for excessive flexion and anterior translation. ^{[19, 20, 21]} The ligamentum flavum also connects to and reinforces the facet joint capsules on the ventral aspect. The ligamentum nuchae is the cephalad continuation of the supraspinous ligament and has a prominent role in stabilizing the cervical spine.

Children have significant anatomical variations in the craniocervical junction compared with adults. Surgical management of craniocervical junction instability in children poses unique challenges. While the indications for cervical fusion are similar to adults with regard to technique, in children, significant anatomical variations in the craniocervical junction complicate the approach and limit the use of internal fixation. Treatment is hindered by the diminutive bone and ligamentous structures, which are often complicated by syndromic craniovertebral abnormalities. Recent advances in imaging have improved outcomes. Menezes reviewed 850 children who underwent craniocervical fusion. The author presents detailed review of the technique of fusion, as well as the indications and means of avoidance of complications, their prevention, and their management. ^[22]

Bogduk N, Twomey L. Clinical Anatomy of the Lumbar Spine. 2nd ed. New York, NY: Churchill Livingstone; 1991.

Malanga GA. The diagnosis and treatment of cervical radiculopathy. Med Sci Sports Exerc. 1997 Jul. 29(7 Suppl):S236-45. [Medline].

Tong HC, Haig AJ, Yamakawa K. The Spurling test and cervical radiculopathy. Spine (Phila Pa 1976). 2002 Jan 15. 27(2):156-9. [Medline].

Fryholm R. Cervical nerve root compression resulting from disc degeneration and root-sleeve fibrosis. Acta Chirurg Scand. 1951. 160(suppl):1-149.

Tubbs RS, Salter EG, Oakes WJ. The accessory atlantoaxial ligament. Neurosurgery. 2004 Aug. 55(2):400-2; discussion 402-4. [Medline].

Johnson R. Anatomy of the cervical spine and its related structures. Torg JS, ed. Athletic Injuries to the Head, Neck, and Face. 2nd ed. St Louis, Mo: Mosby-Year Book; 1991. 371-83.

Parke WW, Sherk HH. Normal adult anatomy. Sherk HH, Dunn EJ, Eismon FJ, et al, eds. The Cervical Spine. 2nd ed. Philadelphia, Pa: JB Lippincott Co; 1989. 11-32.

Milligram MA, Rand N. Cervical spine anatomy. Spine State of the Art Reviews. 2000. 14(3): 521-32.

Bland J. Disorders of the Cervical Spine. Philadelphia, Pa: WB Saunders Co; 1987.

McLain RF. Mechanoreceptor endings in human cervical facet joints. Spine (Phila Pa 1976). 1994 Mar 1. 19(5):495-501. [Medline].

Dreyfus P. The cervical spine: non-surgical care. Presented at: The Tom Landry Sports Medicine and Research Center; April 8, 1993. Dallas, Texas:

Bogduk N. The clinical anatomy of the cervical dorsal rami. Spine (Phila Pa 1976). 1982 Jul-Aug. 7(4):319-30. [Medline].

Bogduk N, Windsor M, Inglis A. The innervation of the cervical intervertebral discs. Spine (Phila Pa 1976). 1988 Jan. 13(1):2-8. [Medline].

Mendel T, Wink CS, Zimny ML. Neural elements in human cervical intervertebral discs. Spine (Phila Pa 1976). 1992 Feb. 17(2):132-5. [Medline].

Franson RC, Saal JS, Saal JA. Human disc phospholipase A2 is inflammatory. Spine (Phila Pa 1976). 1992 Jun. 17(6 Suppl):S129-32. [Medline].

Panjabi MM, Oxland TR, Parks EH. Quantitative anatomy of cervical spine ligaments. Part I. Upper cervical spine. J Spinal Disord. 1991 Sep. 4(3):270-6. [Medline].

Panjabi MM, Oxland TR, Parks EH. Quantitative anatomy of cervical spine ligaments. Part II. Middle and lower cervical spine. J Spinal Disord. 1991 Sep. 4(3):277-85. [Medline].

Fielding JW, Cochran GB, Lawsing JF 3rd, Hohl M. Tears of the transverse ligament of the atlas. A clinical and biomechanical study. J Bone Joint Surg Am. 1974 Dec. 56(8):1683-91. [Medline].

Panjabi MM, Vasavada A, White A III. Cervical spine biomechanics. Semin Spine Surg. 1993. 5:10-6.

White AA III, Panjabi MM. The problem of clinical instability in the human spine: a systematic approach. White AA III, Panjabi MM, eds. Clinical Biomechanics of the Spine. 2nd ed. Philadelphia, Pa: JB Lippincott Co; 1990. 277-378.

White AA III, Panjabi MM. Kinematics of the spine. White AA III, Panjabi MM, eds. Clinical Biomechanics of the Spine. 2nd ed. Philadelphia, Pa: JB Lippincott Co; 1990. 92-102.

Menezes AH. Craniocervical fusions in children. J Neurosurg Pediatr. 2012 Jun. 9(6):573-85. [Medline].

Robert E Windsor, MD, FAAPMR, FAAEM, FAAPM President and Director, Georgia Pain Physicians, PC; Clinical Associate Professor, Department of Physical Medicine and Rehabilitation, Emory University School of Medicine

Robert E Windsor, MD, FAAPMR, FAAEM, FAAPM is a member of the following medical societies: American Academy of Pain Medicine, American Academy of Physical Medicine and Rehabilitation, American College of Sports Medicine, American Medical Association, International Association for the Study of Pain, Texas Medical Association

Disclosure: Nothing to disclose.

Gerard A Malanga, MD Founder and Partner, New Jersey Sports Medicine, LLC and New Jersey Regenerative Institute; Director of Research, Atlantic Health; Clinical Professor, Department of Physical Medicine and Rehabilitation, University of Medicine and Dentistry of New Jersey-New Jersey Medical School; Fellow, American College of Sports Medicine

Gerard A Malanga, MD is a member of the following medical societies: Alpha Omega Alpha, American Academy of Physical Medicine and Rehabilitation, American College of Sports Medicine, American Institute of Ultrasound in Medicine, International Spine Intervention Society, North American Spine Society

Disclosure: Serve(d) as a speaker or a member of a speakers bureau for: Lipogems.

Ali Nawaz Khan, MBBS, FRCS, FRCP, FRCR Consultant Radiologist and Honorary Professor, North Manchester General Hospital Pennine Acute NHS Trust, UK

Ali Nawaz Khan, MBBS, FRCS, FRCP, FRCR is a member of the following medical societies: American Association for the Advancement of Science, American Institute of Ultrasound in Medicine, British Medical Association, Royal College of Physicians and Surgeons of the United States, British Society of Interventional Radiology, Royal College of Physicians, Royal College of Radiologists, Royal College of Surgeons of England

Disclosure: Nothing to disclose.

J Allan Goodrich, MD Staff Physician, Orthopaedic Spine Surgeon, Doctor’s Hospital

J Allan Goodrich, MD is a member of the following medical societies: American Academy of Orthopaedic Surgeons, North American Spine Society, Society of Lateral Access Surgery

Disclosure: Received income in an amount equal to or greater than $250 from: Globus medical, Nuvasive<br/>Received consulting fee from Nuvasive for speaking and teaching; Received royalty from Globus for consulting.

Benjamin McVay Petre, MD Orthopedic and Sports Medicine Surgeon, Orthopaedic and Sports Medicine Center, Annapolis, MD

Benjamin McVay Petre, MD is a member of the following medical societies: American Academy of Orthopaedic Surgeons, American Orthopaedic Society for Sports Medicine, Arthroscopy Association of North America

Disclosure: Nothing to disclose.

Jasvinder Chawla, MD, MBA Chief of Neurology, Hines Veterans Affairs Hospital; Professor of Neurology, Loyola University Medical Center

Jasvinder Chawla, MD, MBA is a member of the following medical societies: American Academy of Neurology, American Association of Neuromuscular and Electrodiagnostic Medicine, American Clinical Neurophysiology Society, American Medical Association

Disclosure: Nothing to disclose.

Mary L Windle, PharmD Adjunct Associate Professor, University of Nebraska Medical Center College of Pharmacy; Editor-in-Chief, Medscape Drug Reference

Disclosure: Nothing to disclose.

Thomas R Gest, PhD Professor of Anatomy, Department of Medical Education, Texas Tech University Health Sciences Center, Paul L Foster School of Medicine

Disclosure: Nothing to disclose.

Cervical Spine Anatomy

Research & References of Cervical Spine Anatomy|A&C Accounting And Tax Services
Source

Share on Facebook

Tweet

Follow us