Vertebral artery explained
The vertebral arteries are major arteries of the neck. Typically, the vertebral arteries originate from the subclavian arteries. Each vessel courses superiorly along each side of the neck, merging within the skull to form the single, midline basilar artery. As the supplying component of the vertebrobasilar vascular system, the vertebral arteries supply blood to the upper spinal cord, brainstem, cerebellum, and posterior part of brain.[1]
Structure
The vertebral arteries usually arise from the posterosuperior aspect of the central subclavian arteries on each side of the body,[2] then enter deep to the transverse process at the level of the 6th cervical vertebrae (C6), or occasionally (in 7.5% of cases) at the level of C7. They then proceed superiorly, in the transverse foramen of each cervical vertebra. Once they have passed through the transverse foramen of C1 (also known as the atlas), the vertebral arteries travel across the posterior arch of C1 and through the suboccipital triangle before entering the foramen magnum.
Nunziante Ippolito, a Neapolitan physician, identified the "angle of Nunziante Ippolito" to find the vertebral artery, between the anterior scalene muscle and the longus colli muscle.[3]
Inside the skull, the two vertebral arteries join to form the basilar artery at the base of the pons. The basilar artery is the main blood supply to the brainstem and connects to the Circle of Willis to potentially supply the rest of the brain if there is compromise to one of the carotids. At each cervical level, the vertebral artery sends branches to the surrounding musculature via the anterior spinal arteries.
The vertebral artery may be divided into four parts:
- The first (preforaminal) part runs upward and backward between the anterior scalene and the longus colli muscles. In front of it are the internal jugular and vertebral veins, and is crossed by the inferior thyroid artery; the left vertebral is also crossed by the thoracic duct. Behind it are the transverse process of the seventh cervical vertebra, the sympathetic trunk and its inferior cervical ganglion
- The second (foraminal) part runs upward through the transverse foramina of the C6 to C2 vertebrae, and is surrounded by branches from the inferior cervical sympathetic ganglion and by a plexus of veins which unite to form the vertebral vein at the lower part of the neck. It is situated in front of the trunks of the cervical nerves, and pursues an almost vertical course as far as the transverse process of the axis.
- The third (extradural or atlantic) part issues from the C2 foramen transversarium on the medial side of the Rectus capitis lateralis. It is further subdivided into the vertical part V3v passing vertically upwards, crossing the C2 root and entering the foramen transversarium of C1, and the horizontal part V3h, curving medially and posteriorly behind the superior articular process of the atlas, the anterior ramus of the first cervical nerve being on its medial side; it then lies in the groove on the upper surface of the posterior arch of the atlas, and enters the vertebral canal by passing beneath the posterior atlantoöccipital membrane. This part of the artery is covered by the Semispinalis capitis and is contained in the suboccipital triangle—a triangular space bounded by the Rectus capitis posterior major, the Obliquus superior, and the Obliquus inferior. The first cervical or suboccipital nerve lies between the artery and the posterior arch of the atlas.
- The fourth (intradural or intracranial) part pierces the dura mater and inclines medialward to the front of the medulla oblongata; it is placed between the hypoglossal nerve and the anterior root of the first cervical nerve and beneath the first digitation of the ligamentum denticulatum. At the lower border of the pons it unites with the vessel of the opposite side to form the basilar artery.
Triangle
Triangle of the vertebral artery is a region within the root of the neck and has following boundaries:[4]
The vertebral artery runs from base to apex (prior to entering the transverse foramen of 6th cervical vertebra).
The carotid tubercle separates the vertebral artery which passes directly behind it from the common carotid artery which lies directly in front of it. The ideal site for palpating the carotid pulse is to gently press the common carotid artery against the carotid tubercle.[5]
Variation
There is commonly variations in the course and size of the vertebral arteries, usually on both sides artery diameters are asymmetrical.[6] For example, differences in size between left and right vertebral arteries may range from a slight asymmetry to marked hypoplasia of one side, with studies estimating a prevalence of unilateral vertebral artery hypoplasia between 2% and 25%.[7] In 3-15% of the population, a bony bridge called the arcuate foramen covers the groove for the vertebral artery on vertebra C1. Rarely, the vertebral arteries enter the subarachnoid space at C1-C2 (3%) or C2-C3 (only three cases have been reported) vertebral levels instead of the atlanto-occipital level.[8]
The portion of vertebral arteries located within the skull (intracranial) have diameters of 3.17 mm. The intracranial length for the left vertebral artery (32.4 mm) is longer than the right (31.5 mm). The angle where vertebral arteries meet the basilar artery (vertebrobasilar junction), is 46 degrees.[9]
Vertebral artery dominance
Vertebral artery dominance (VAD) is typically a normal congenital vascular variation of the vertebral arteries. It refers to the asymmetry of the VA diameters on both sides, with the larger diameter being the dominant side and the smaller diameter being the nondominant side.
In one study, the left vertebral artery diameter dominance was present in 54% of cases, while the right diameter was dominant in 30%. In 16% of cases, the left and right arterial diameters were equal.[10]
Function
As the supplying component of the vertebrobasilar vascular system, the vertebral arteries supply blood to the upper spinal cord, brainstem, cerebellum, and posterior part of brain.
Clinical significance
As the supplying component of the vertebrobasilar vascular system, the vertebral arteries supply blood to the upper spinal cord, brainstem, cerebellum, and posterior part of brain. A stroke of the arteries may result in a posterior circulation stroke.
Chiropractic manipulation of the neck has the potential to cause a vertebral arterial dissection.[11] [12] [13]
Diagnostics
The condition and health of the vertebral carotid arteries is usually evaluated using Doppler ultrasound, CT angiography or phase contrast magnetic resonance imaging (PC-MRI).
Typically, blood flow velocities in the carotid artery are measured in terms of peak systolic velocity (PSV) and end diastolic velocity (EDV).[14]
Normally, vertebral artery blood flow velocity can be 63.6 ± 17.5 cm/s during PSV and 16.1 ± 5.1 cm/s during EDV according to a study done by Kuhl et al.[15] Due to vertebral artery dominance, measurements can vary on both sides, for example, another study by Seidel et al. found that the right side had an average of 45.9 cm/s and the left side 51.5 cm/s during PSV, and 13.8 cm/s on the right side and 16.1 cm/s on the left side during EDV.[16]
External links
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- Web site: Anatomy diagram: 13048.000-1 . Roche Lexicon - illustrated navigator . Elsevier . https://web.archive.org/web/20140101000000/http://www.tk.de/rochelexikon/pics/s13048.000-1.html . 2014-01-01.
- Web site: Anatomy diagram: 13048.000-3 . Roche Lexicon - illustrated navigator . Elsevier . https://web.archive.org/web/20140101000000/http://www.tk.de/rochelexikon/pics/s13048.000-3.html . 2014-01-01.
Notes and References
- Book: Gray's Anatomy: The Anatomical Basis of Clinical Practice . Susan . Standing . Neil R. . Borely . Patricia . Collins . Alan R. . Crossman . Michael A. . Gatzoulis . Geremiah C. . Healy . David . Hohnson . Vishy . Mahadevan . Richard L.M. . Newell . Caroline B. . Wigley . vanc . 6 . 2008 . Churchill Livingstone . 978-0-8089-2371-8 . 40th . London . .
- Yuan SM . Aberrant Origin of Vertebral Artery and its Clinical Implications . Brazilian Journal of Cardiovascular Surgery . 31 . 1 . 52–9 . February 2016 . 27074275 . 5062690 . 10.5935/1678-9741.20150071 .
- Web site: Ippolito, Nunziante . Trecanni .
- Book: Campero . A. . Rubino . P. A. . Rhoton . L. Jr. . Pathology and surgery around the vertebral artery . 2011 . Springer . Paris . 978-2-287-89787-0 . 29 . 10.1007/978-2-287-89787-0_4 .
- Tubbs RS, Salter EG, Wellons JC, Blount JP, Oakes WJ . April 2005 . The triangle of the vertebral artery. . Neurosurgery . 56 . suppl. 4 . 252–5 . 10.1227/01.neu.0000156797.07395.15 . 15794821. 10515351 .
- Sun . Yan . Shi . Yan-Min . Xu . Ping . 2022-02-03 . The Clinical Research Progress of Vertebral Artery Dominance and Posterior Circulation Ischemic Stroke . Cerebrovascular Diseases . 51 . 5 . 553–556 . 10.1159/000521616 . 35114670 . 1015-9770.
- Park JH, Kim JM, Roh JK . Hypoplastic vertebral artery: frequency and associations with ischaemic stroke territory . Journal of Neurology, Neurosurgery, and Psychiatry . 78 . 9 . 954–8 . September 2007 . 17098838 . 2117863 . 10.1136/jnnp.2006.105767 .
- Moon . Jong Un . Kim . Myoung Soo . 2019-09-01 . C3 segmental vertebral artery diagnosed by computed tomography angiography . Surgical and Radiologic Anatomy . en . 41 . 9 . 1075–1078 . 10.1007/s00276-019-02193-z . 30762086 . 61807570 . 1279-8517.
- Omotoso BR, Harrichandparsad R, Satyapal KS, Moodley IG, Lazarus L . Radiological anatomy of the intracranial vertebral artery in a select South African cohort of patients . Scientific Reports . 11 . 1 . 12138 . June 2021 . 34108602 . 8190432 . 10.1038/s41598-021-91744-9 . 2021NatSR..1112138O .
- Cagnie . Barbara . Petrovic . Mirko . Voet . Dirk . Barbaix . Erik . Cambier . Dirk . May 2006 . Vertebral artery dominance and hand preference: Is there a correlation? . Manual Therapy . en . 11 . 2 . 153–156 . 10.1016/j.math.2005.07.005. 16380285 .
- Vertebral artery dissection after a chiropractor neck manipulation. Jeremy. Jones. Catherine. Jones. Kenneth. Nugent. January 5, 2015. Proceedings (Baylor University. Medical Center). 28. 1. 88–90. 10.1080/08998280.2015.11929202. 25552813. 4264725.
- Web site: Stroke Risk Associated With Aggressive Chiropractic Neck Adjustments. healthblog.uofmhealth.org. August 28, 2017 .
- ucsf.edu/news/2003/05/97065/chiropractic-treatment-neck-can-be-risk-factor-stroke
- Web site: Themes . U. F. O. . 2019-12-30 . Ultrasound Assessment of the Vertebral Arteries . 2024-03-08 . Radiology Key . en-US.
- Kuhl . V. . Tettenborn . B. . Eicke . B. M. . Visbeck . A. . Meckes . S. . 2016-02-04 . Color-coded duplex ultrasonography of the origin of the vertebral artery: normal values of flow velocities . Journal of Neuroimaging . 10 . 1 . 17–21 . 10.1111/jon200010117 . 1051-2284 . 10666977.
- Seidel . E. . Eicke . B. M. . Tettenborn . B. . Krummenauer . F. . 1999-12-01 . Reference values for vertebral artery flow volume by duplex sonography in young and elderly adults . Stroke . 30 . 12 . 2692–2696 . 10.1161/01.str.30.12.2692 . 0039-2499 . 10582999.