Anatomy, Head and Neck, Neck Movements

Article Author:
Benjamin Jung
Article Editor:
Beenish Bhutta
Updated:
5/21/2020 5:22:24 PM
PubMed Link:
Anatomy, Head and Neck, Neck Movements

Introduction

The neck refers to the collection of structures that connect the head to the torso. It is a complex structure composed of many bones, muscles, nerves, blood vessels, lymphatics, and other connective tissues. The cervical spine is the bony part of the neck. Its primary function is to provide support for the skull, while still allowing for movement. It is the most flexible part of the spine. This flexibility allows for large movements to scan our surroundings. The majority of sensory inputs occur at the head; thus, proper neck movement is vital to our survival. It also acts as a conduit for the brain to communicate with the rest of the body. Motor and sensory information, as well as nutrients, from the body to the head and vice versa, must all pass through the neck. The neck is also subject to stress and susceptible to injuries. Given its importance, injuries can sometimes have significant consequences for our functionalities and even fatal at times.

Structure and Function

The neck, or cervical spine, is composed of 7 vertebrae. Cervical vertebrae C1 and C2 are known as "atypical" vertebrae due to the presence of special bony structures designed to support and move the skull. While the cervical spine can undergo flexion, extension, rotation, and side-bending, each individual cervical joint has a primary motion.

C1, the atlas, has no spinous process and articulates with the occipital condyles of the occiput bone of the skull, forming the occipital-atlanto (OA) joint. It connects the skull to the neck, also providing attachment points for some neck muscles. It also functions to bear the weight of the skull, providing support. The primary motions of the OA joint are flexion and extension. It is responsible for the vertical movement of the neck. C2, the axis, articulates superiorly with C1 by a unique bony structure called the dens or odontoid process. It projects up from the vertebral body and articulates with the atlas. The dens permit pivoting motion and allow a greater range of motion in rotating the head laterally. 

C3 through C7 are known as "typical" cervical vertebrae. The primary motion of the upper portion of the lower cervical unit is rotation (C2-C4) is rotation. The primary motion of the lower portion of the lower cervical unit is side-bending. The description of all spinal and vertebral movements are relative to motions of their anterior and superior surfaces.[1]

  • Cervical flexion: bending the head forward towards the chest.
  • Cervical extension: bending the head backward with the face towards the sky.
  • Cervical rotation: turning the head to the left or the right.
  • Cervical side-bending: tipping the head to the side or touching an ear to the shoulder of the same side.

The function of the cervical spine is to stabilize and maintain the head in a position that allows our eyes to be parallel to the ground.[2] This function is crucial for the vestibular function, which assists in balance. The cervical spine allows large movements to scan our surroundings and can adjust to interact with our environment. It also aids in swallowing and helps to elevate the rib cage during inhalation. The vertebral bodies protect the spinal cord and vertebral arteries, and the muscles of the neck protect other neurovascular structures necessary for sustaining life. Any interruption of the proper function of the neck can lead to a critical state and is usually the first thing evaluated in any emergency situation.

Embryology

The most primitive form, the axial skeleton, the notochord, appears during the third week of development. The notochord evolves into a segmented vertebral structure in three different stages. The first stage consists of embryonic mesenchymal tissue. The second stage occurs when these mesenchymal cells differentiate and develop into chondrogenic cells. By the beginning of the third month of development, the cartilaginous structure has begun to ossify into the future vertebral segments. The mesoderm is also responsible for skeletal muscle, bone, and connective tissue.[3]

Blood Supply and Lymphatics

Arteries

The neck contains blood vessels that supply blood to structures in the neck as well as pass through the neck to supply blood to the brain and face. The common carotid arteries and the vertebral arteries are the major arteries in the neck. Left and right common carotid and vertebral arteries run on each side of the neck. Each common carotid artery branches into two divisions: the internal and external carotid artery. The internal carotid arteries supply blood to the anterior brain, while the external carotid arteries supply blood to the face and neck. Vertebral arteries also pass through the transverse foramen of the cervical spines before merging to form the basilar artery. Vertebral and basilar arteries supply blood to the posterior brain. The basilar artery anastomoses with the internal carotid arteries, and together they form the circle of Willis, which provides blood to the brain. Vertebral arteries also further branch off to give one anterior spinal artery and two posterior spinal arteries. These arteries supply the anterior and the posterior portion of the spinal cord, respectively. There are also numerous smaller arteries throughout the neck, head, and face that branch off from the common carotid and vertebral arteries.[4]

Veins

The major veins in the neck include jugular veins and vertebral veins. Jugular veins diverge into external and internal jugular veins. The external jugular vein sits more superficially. It collects blood from the superficial skull and deep parts of the face. Blood then and drains to the subclavian vein. Blood from the brain, the superficial face, and superficial neck drains into the internal jugular vein. It then merges into the subclavian vein.[4] The vertebral veins also drain blood into the subclavian vein after running through the foramen transversarium.

Lymphatics

The lymphatics from the right and left side of the head and neck drain into the right lymphatic duct and thoracic duct, respectively.

Nerves

The muscles of the neck receive innervation by various cervical nerves and their branches, as well as cranial nerves. Efferent nerves carry impulses from the brain that cause muscles to contract, controlling cervical movements. Sensation to the front areas of the neck originates from cervical nerves C2-C4 and the posterior regions of the neck from cervical roots C4-C5. The sternocleidomastoid and trapezius receive innervation by cranial nerve XI (accessory nerve).

The cervical ganglia are a trio of sympathetic nervous system ganglia that lie alongside the vertebral column. The superior cervical ganglion lies at the C2/C3 intervertebral level, while the middle cervical ganglion lies at the C6/C7 intervertebral level. The interior cervical ganglion is fused with the first thoracic ganglion to create the stellate ganglion at the C7/T1 intervertebral level.

The brachial plexus forms from the anterior rami of C5-T1 nerves and divides into roots, trunks, divisions, cords, and branches. After the roots exit the interscalene triangle between the anterior and middle scalene muscles, they form trunks at the level of the subclavian artery. The C5 and C6 roots form the upper trunk, while the C8 and T1 roots form the lower trunk. The C7 root forms the middle trunk. As these trunks cross the clavicle and exit the neck region, they separate into anterior and posterior divisions.

The anterior rami of the C1-C4 vertebrae constitute the cervical plexus. These are posterior to the sternocleidomastoid muscle and anterior to the middle scalene muscle, supplying both muscular and sensory innervation. It provides sensory innervation to the neck, clavicle, and skin surrounding the ear.  The muscular branches innervate the infrahyoid muscles, excluding the thyrohyoid muscle, as well as the diaphragm through the phrenic nerve. The phrenic nerve arises mostly from the C4 ventral rami, with smaller contributions from the C3 and C5 rami. Phrenic nerve serves to contract the diaphragm, a muscle of breathing that lies between the abdomen and thorax. 

Ansa cervicalis, a part of cervical plexus, is embedded in carotid sheath anterior to the internal jugular vein in the carotid triangle. It consists of superior and inferior roots. The superior root forms from C1 nerve fibers of the cervical plexus, which travel in the cranial nerve XII and then separates in the carotid triangle to make the superior root. The superior root eventually goes around the occipital artery and then falls on the carotid sheath. The inferior root consists of fibers from spinal nerves C2 and C3. It gives off branches to the inferior belly of the omohyoid muscle, and the lower parts of the sternothyroid and sternohyoid muscles. The paralysis of ansa cervicalis may lead to the change in the quality of voice, probably due to loss of support of infrahyoid muscles to the larynx.

Muscles

The muscles of the neck can be largely sub-categorized into anterior, lateral (prevertebral), and posterior neck muscles. Below are the muscle groups, and the action of individual muscles in neck movement:

Anterior Neck Muscles 

Superficial neck muscles:

  • Platysma: depression of mandible and angle of the mouth, the tension of skin of the lower face and anterior neck
  • Sternocleidomastoid: head/neck extension at atlantooccipital joint/ superior cervical spine; neck flexion at inferior cervical vertebrae;  elevation of clavicle and manubrium of the sternum at the sternoclavicular joint; ipsilateral flexion and contralateral rotation of the neck at the cervical spine
  • Subclavius: anchoring and depression of clavicle at sternoclavicular joint

Suprahyoids:

  • Digastric: depression of mandible, elevation of hyoid bone during swallowing and speaking
  • Mylohyoid: serving as the floor of the oral cavity, elevation of hyoid bone and floor of the mouth, depression of mandible
  • Geniohyoid: elevation and drawing of hyoid bone anteriorly
  • Stylohyoid: elevation and drawing of hyoid bone posteriorly

Infrahyoids:

  • Sternohyoid: depression of larynx
  • Sternothyroid: depression of larynx
  • Thyrohyoid: depression of hyoid bone, elevation of the larynx
  • Omohyoid: depression of hyoid bone

Scalenes:

  • Anterior: neck flexion, lateral flexion of the neck (ipsilateral), neck rotation (contralateral), elevation of rib 1
  • Middle: lateral flexion of the neck, elevation of rib 1
  • Posterior: lateral flexion of the neck, elevation of rib 2

Lateral neck muscles

  • Rectus capitis anterior: head flexion at atlanto-occipital join
  • Rectus capitis lateralis: lateral head flexion(ipsilateral) at the atlanto-occipital joint
  • Longus capitis: head flexion by bilateral contraction, ipsilateral head rotation by unilateral contraction
  • Longus colli: neck flexion and neck lateral flexion (ipsilateral) by bilateral contraction, contralateral rotation of the neck by unilateral neck contraction

Posterior neck muscles

Superficial muscles:

  • Splenius capitis: extension of head/neck by bilateral contraction, lateral flexion and rotation of the head (ipsilateral) by unilateral contraction
  • Splenius cervicis:  extension of the neck by bilateral contraction, lateral flexion and rotation of neck (ipsilateral) by unilateral contraction

Suboccipital muscles:

  • Rectus capitis posterior major: head extension at the atlantooccipital joint by bilateral contraction, head rotation (ipsilateral) at the atlantoaxial joint by unilateral contraction
  • Rectus capitis posterior minor: head extension at the atlantooccipital joint by bilateral contraction, head rotation (ipsilateral) at the atlantoaxial joint by unilateral contraction
  • Obliquus capitis superior: head extension at the atlantooccipital joint by bilateral contraction, lateral head flexion (ipsilateral) at the atlantoaxial joint by unilateral contraction
  • Obliquus capitis inferior: head extension at the atlantooccipital joint by bilateral contraction, head rotation (ipsilateral) at the atlantoaxial joint by unilateral contraction

Transversospinalis muscles:

  • Semispinalis capitis: extension of head, cervical and thoracic spine by bilateral contraction, lateral flexion of the head, cervical and thoracic spine (ipsilateral), rotation of the head, cervical and thoracic spine (contralateral) by unilateral contraction
  • Semispinalis cervicis: extension of head, cervical and thoracic spine by bilateral contraction, lateral flexion of the head, cervical and thoracic spine (ipsilateral), rotation of the head, cervical and thoracic spine (contralateral) by unilateral contraction
  • Rotatores cervicis: extension of the spine by bilateral contraction, lateral flexion of the spine by unilateral contraction
  • Interspinales: extension of the cervical and lumbar spine
  • Intertransversarii:  assisting in lateral flexion of the spine, stabilization of the spine

Physiologic Variants

Cervical dystonia, or spasmodic torticollis, is a condition due to an abnormal contracture of the sternocleidomastoid (SCM) muscle. This condition causes a rotational deformity away from the affected side with a head tilt toward the affected side. It may result from an intrauterine compartment syndrome of the SCM muscle. Clinicians may use passive stretching, botox injections, and possible surgical bipolar release of the sternocleidomastoid or Z plastic lengthening to treat this condition.[5][6] Untreated torticollis may lead to permanent rotational deformity, positional plagiocephaly, facial asymmetry, and dysplasia of the skull, atlas, and axis.

Surgical Considerations

A platysmaplasty, more commonly known as neck lift surgery, is the surgery that tightens the skin and underlying muscles to lift the neck. It also serves to improve and sharpen the contour of the jawline.

Clinical Significance

A cervical spine injury must be considered in every trauma patient until further evaluation proves otherwise. There is a higher level of concern with a history of high energy trauma; this would include: a motor vehicle accident >35 mph, a fall from >10 feet, closed head injuries, and associated pelvis or extremity fractures. A common mechanism of accidents is an older person who falls and hits their forehead and a person who is rear-ended and has a whiplash-like injury. A cervical collar should be placed for stabilization until cervical spine injury can be ruled out. Confirmation of the absence of a cervical spine injury can be performed with a physical exam or radiographically (usually with a lateral c-spine view and CT of the head and neck).[7] 

"Whiplash" is a term describing a neck injury due to a forceful bending of the neck forward and then backward, or vice versa, past the physiological barriers. The injury can involve muscles, vertebral discs, nerves, ligaments, and tendons of the neck. Most whiplash injuries involve a sudden acceleration or deceleration in a motor vehicle collision. They also commonly occur in contact sports. The ligaments commonly involved are anterior longitudinal ligament, posterior longitudinal ligament, and ligamentum flavum. [8] Common symptoms include: neck pain, stiffness, dizziness, shoulder and low back pain, tinnitus, blurred vision, concentration problems, irritability, and fatigue. They can mimic other medical conditions, such as concussions. Diagnosis is possible with a complete medical history and physical exam, as well as radiographical imaging (i.e., X-ray, MRI, CT scan). Treatment determination is on a case to case basis but may include a cervical collar, physical therapy, nonsteroidal anti-inflammatory medicines, and surgery if there is structural damage.[9]

The suboccipital triangle forms from a group of muscles located at the base of the skull (rectus capitis posterior major and minor and the obliquus capitis superior and inferior). There is a myodural bridge between the rectus capitus posterior minor muscle and the intracranial dura. A cerviogenic headache can result when this bridge is stretched or inflamed from cervical spine joint dysfunction or suboccipital triangle muscles being too tight. Spinal manipulation, soft tissue intervention, and therapeutic exercise may be useful in treating and preventing future myodural bridge, causing headaches.[10]

Chronic degenerative changes of the cervical vertebrae and the intervertebral discs can lead to the narrowing of the intervertebral foramina, potentially leading to the compression of the blood vessels and nerves of the neck, causing cervical radiculopathy.[11] 

Hyperextension of the neck could also result in a hangman's fracture, a fracture of the axis (C2). The name derives from the fact that this type of fracture often occurs in people who hang themselves. However, it can also occur due to traumatic injuries. In the event of a sudden, extreme neck hyperextension, the axis bears most of the force, often resulting in a fracture that completely dissociates of the anterior and posterior aspects of the axis. The axis is critical in the structural support of the skull and spinal cord. Without an intact axis, spinal cord damage which leads to paralysis of the respiratory muscles. Most cases are lethal.[12][13]


References

[1] Kaiser JT,Lugo-Pico JG, Anatomy, Head and Neck, Cervical Vertebrae . 2020 Jan     [PubMed PMID: 30969556]
[2] Shaikh AG,Wong AL,Zee DS,Jinnah HA, Keeping your head on target. The Journal of neuroscience : the official journal of the Society for Neuroscience. 2013 Jul 3;     [PubMed PMID: 23825431]
[3] Williams S,Alkhatib B,Serra R, Development of the axial skeleton and intervertebral disc. Current topics in developmental biology. 2019;     [PubMed PMID: 30902259]
[4] Johnson MH,Thorisson HM,Diluna ML, Vascular anatomy: the head, neck, and skull base. Neurosurgery clinics of North America. 2009 Jul;     [PubMed PMID: 19778697]
[5] Barbosa P,Warner TT, Dystonia. Handbook of clinical neurology. 2018;     [PubMed PMID: 30482316]
[6] Driehuis F,Hoogeboom TJ,Nijhuis-van der Sanden MWG,de Bie RA,Staal JB, Spinal manual therapy in infants, children and adolescents: A systematic review and meta-analysis on treatment indication, technique and outcomes. PloS one. 2019;     [PubMed PMID: 31237917]
[7] Izzo R,Popolizio T,Balzano RF,Pennelli AM,Simeone A,Muto M, Imaging of cervical spine traumas. European journal of radiology. 2019 Aug;     [PubMed PMID: 31307656]
[8] Sayit E,Daubs MD,Aghdasi B,Montgomery SR,Inoue H,Wang CJ,Wang BJ,Phan KH,Scott TP, Dynamic changes of the ligamentum flavum in the cervical spine assessed with kinetic magnetic resonance imaging. Global spine journal. 2013 Jun;     [PubMed PMID: 24436854]
[9] Ricciardi L,Stifano V,D'Arrigo S,Polli FM,Olivi A,Sturiale CL, The role of non-rigid cervical collar in pain relief and functional restoration after whiplash injury: a systematic review and a pooled analysis of randomized controlled trials. European spine journal : official publication of the European Spine Society, the European Spinal Deformity Society, and the European Section of the Cervical Spine Research Society. 2019 Jun 18;     [PubMed PMID: 31214856]
[10] Kitamura K,Cho KH,Yamamoto M,Ishii M,Murakami G,Rodríguez-Vázquez JF,Abe SI, Suboccipital Myodural Bridges Revisited: Application to Cervicogenic Headaches. Clinical anatomy (New York, N.Y.). 2019 May 22;     [PubMed PMID: 31116454]
[11] Sharrak S,Al Khalili Y, Cervical Disc Herniation 2020 Jan;     [PubMed PMID: 31536225]
[12] Bransford RJ,Alton TB,Patel AR,Bellabarba C, Upper cervical spine trauma. The Journal of the American Academy of Orthopaedic Surgeons. 2014 Nov;     [PubMed PMID: 25344597]
[13] Murphy H,Schroeder GD,Shi WJ,Kepler CK,Kurd MF,Fleischman AN,Kandziora F,Chapman JR,Benneker LM,Vaccaro AR, Management of Hangman's Fractures: A Systematic Review. Journal of orthopaedic trauma. 2017 Sep;     [PubMed PMID: 28816880]