Phrenic nerve

The phrenic nerve is a mixed motor/sensory nerve that originates from the C3-C5 spinal nerves in the neck. The nerve is important for breathing because it provides exclusive motor control of the diaphragm, the primary muscle of respiration. In humans, the right and left phrenic nerves are primarily supplied by the C4 spinal nerve, but there is also a contribution from the C3 and C5 spinal nerves. From its origin in the neck, the nerve travels downward into the chest to pass between the heart and lungs towards the diaphragm.

Phrenic nerve
The phrenic nerve as it passes through the thorax to supply the diaphragm.
The phrenic nerve emerges from the cervical plexus, with the right brachial plexus shown here.
Details
FromC3–C5 of cervical plexus
InnervatesDiaphragm
Identifiers
Latinnervus phrenicus
MeSHD010791
TA98A14.2.02.028
TA26380
FMA6191
Anatomical terms of neuroanatomy

In addition to motor fibers, the phrenic nerve contains sensory fibers, which receive input from the central tendon of the diaphragm and the mediastinal pleura, as well as some sympathetic nerve fibers. Although the nerve receives contributions from nerve roots of the cervical plexus and the brachial plexus, it is usually considered separate from either plexus.

The name of the nerve comes from Ancient Greek phren 'diaphragm'.[1]

Structure

The phrenic nerve originates in the phrenic motor nucleus in the ventral horn of the cervical spinal cord. It descends obliquely with the internal jugular vein across the anterior scalene, deep to the prevertebral layer of deep cervical fascia and the transverse cervical and suprascapular arteries. On the left, the phrenic nerve crosses anterior to the first part of the subclavian artery. On the right, it lies on the anterior scalene muscle and crosses anterior to the 2nd part of the subclavian artery. On both sides, the phrenic nerve usually runs posterior to the subclavian vein as it enters the thorax where it runs anterior to the root of the lung and between the fibrous pericardium and mediastinal parietal pleura.[2]

The pericardiacophrenic arteries and veins travel with their respective phrenic nerves.

The phrenic nerve can be marked by a line connecting these two points:

  1. 1st point can be labelled 3.5 cm at the level of the thyroid cartilage from the midsagittal plane.
  2. 2nd point is at the medial end of the clavicle.

Variation

As with most nerves in the neck, multiple anatomic variants have been described. Notably, there may be variability in the course of the phrenic nerve in the retro-clavicular region such that the nerve courses anterior to the subclavian vein, rather than its typical position posterior to the vein (between the subclavian vein and artery).[3] This variant may predispose the phrenic nerve to injury during subclavian vascular cannulation.

In addition, an accessory phrenic nerve is commonly identified, present in up to 75% of a cadaveric study.[3]

In canines, the phrenic nerve arises from C5-C7 with occasional small contributions from C4.[4] In the cat, horse, ox, and small ruminant the phrenic nerve arises variably from C4-C7.

Function

Both of these nerves supply motor fibers to the diaphragm and sensory fibers to the fibrous pericardium, mediastinal pleura, and diaphragmatic peritoneum.

Some sources describe the right phrenic nerve as innervating the gallbladder, other sources make no such mention.[5] The right phrenic nerve may also supply the capsule of the liver.[6]

Clinical significance

Left phrenic nerve palsy (right image side) in fluoroscopy: forced inspiration with the closed mouth leads to paradox elevation of the paralytic left diaphragm while the healthy right side moves down.

Pain arising from structures supplied by the phrenic nerve is often "referred" to other somatic regions served by spinal nerves C3-C5. For example, a subphrenic abscess beneath the right diaphragm might cause a patient to feel pain in the right shoulder.

Irritation of the phrenic nerve (or the tissues it supplies) leads to the hiccup reflex. A hiccup is a spasmodic contraction of the diaphragm, which pulls air against the closed folds of the larynx.

The phrenic nerve must be identified during thoracic surgery and preserved. To confirm the identity of the phrenic nerve, a doctor may gently manipulate it to elicit a dartle (diaphragmatic startle) response.[7] The right phrenic nerve may be crushed by the vena cava clamp during liver transplantation.[8] Severing the phrenic nerve, or a phrenectomy,[9] will paralyse that half of the diaphragm. Bilateral diaphragmatic paralysis or BDP can also be caused by spinal cord injury, motor neuron disease, infection, pneumonia, sarcoidosis, multiple sclerosis, polyneuropathy, myopathy and amyotrophy, cardiac surgery, lung transplantation, or mediastinal tumors.[10][11] Diaphragm paralysis is best demonstrated by sonography.[8] Breathing will be made more difficult but will continue provided the other nerve is intact.

The phrenic nerve arises from the neck (C3-C5) and innervates the diaphragm, which is much lower. Hence, patients suffering spinal cord injuries below the neck are still able to breathe effectively, despite any paralysis of the lower limbs.

Brachial plexus injuries can cause paralysis in various regions in the arm, forearm, and hand depending on the severed nerves. The resulting palsy has been clinically treated using the phrenic nerve as a donor for neurotization of the musculocutaneous nerve and the median nerve.[12] This treatment has a high success rate (84.6%) in partial to full restoration of the innervation to the damaged nerve.[12] Furthermore, this procedure has resulted in restored function to nerves in the brachial plexus with minimal impact to respiratory function of the phrenic nerve. The instances where pulmonary vital capacity is reduced have typically been a result of use of the right phrenic as the donor for the neurotization whereas use of left phrenic nerve has not been significantly linked to reduced pulmonary vital capacity.[13]

See also

References

  1. O'Rahilly, Ronan (2008). Basic Human Anatomy. Hanover, New Hampshire: Geisel School of Medicine. Retrieved 3 April 2019.
  2. Moore, Keith L. (1999). Clinically oriented anatomy. Philadelphia: Lippincott Williams & Wilkins. ISBN 978-0-683-06141-3.
  3. Prakash; Prabhu, L. V.; Madhyastha, S; Singh, G (2007). "A variation of the phrenic nerve: Case report and review" (PDF). Singapore Medical Journal. 48 (12): 1156–7. PMID 18043847.
  4. Evans, Howard (1979). Miller's Anatomy of the Dog. Philadelphia, PA: W. B. Saunders Company. p. 978. ISBN 978-0-7216-3438-8.
  5. Alexander, William (1940). "The innervation of the biliary system". Journal of Comparative Neurology. 72 (2): 357–370. doi:10.1002/cne.900720205. S2CID 83974380.
  6. Lautt, W. Wayne (2009). Hepatic Nerves. Morgan & Claypool Life Sciences.
  7. Dalman, Ronald; Thompson, Robert (2015). "7. Neurogenic Thoracic Outlet Syndrome Exposure and Decompression: Supraclavicular". Operative Techniques in Vascular Surgery. Philadelphia, PA: Wolters Kluwer Health. p. 50. ISBN 9781451190205.
  8. McAlister, Vivian C.; Grant, David R.; Roy, Andre; Brown, William F.; Hutton, Linda C.; Leasa, David J.; Ghent, Cameron N.; Veitch, James E.; Wall, William J. (1993). "Right phrenic nerve injury in orthotopic liver transplantation". Transplantation. 55 (4): 826–30. doi:10.1097/00007890-199304000-00027. PMID 8475559.
  9. Hine, Maynard Kiplinger (1975). Review of dentistry: questions and answers (6th ed.). Mosby. p. 421. ISBN 978-0-8016-2196-3.
  10. Mizubuti GB, Wang L, Ho AM, Tanzola RC, Leitch J (November 2017). "Perioperative Management for Abdominal Surgery in Bilateral Diaphragmatic Paralysis: A Case Report and Literature Review". A&A Case Reports. 9 (10): 280–282. doi:10.1213/XAA.0000000000000592. PMID 28691979. S2CID 44462495.
  11. Chen HY, Chen HC, Lin MC, Liaw MY (August 2015). "Bilateral Diaphragmatic Paralysis in a Patient With Critical Illness Polyneuropathy: A Case Report". Medicine (Baltimore). 94 (31): e1288. doi:10.1097/MD.0000000000001288. PMC 4616567. PMID 26252301.
  12. Gu YD, Wu MM, Zhen YL, Zhao JA, Zhang GM, Chen DS, Yan JG, Cheng XM (1989). "Phrenic nerve transfer for brachial plexus motor neurotization". Microsurgery. 10 (4): 287–9. doi:10.1002/micr.1920100407. PMID 2593799. S2CID 74732561.
  13. Luedemann W, Hamm M, Blömer U, Samii M, Tatagiba M (March 2002). "Brachial plexus neurotization with donor phrenic nerves and its effect on pulmonary function". J Neurosurg. 96 (3): 523–6. doi:10.3171/jns.2002.96.3.0523. PMID 11883837.
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