The subclavian artery is a paired major artery in the upper thorax, positioned inferior to the clavicle, that delivers oxygenated blood to the upper limbs, parts of the head, neck, and thorax.[1][2] On the right side, it originates from the brachiocephalic trunk, while on the left, it arises directly from the aortic arch, reflecting the asymmetric vascular anatomy of the region.[1][2][3] With a typical diameter of 0.7 to 1.0 cm, it features three vascular layers—an inner endothelial lining, a middle muscular layer for vessel tone, and an outer connective tissue layer—enabling it to withstand arterial pressures while branching to supply critical structures.[2]The subclavian artery follows a lateral course from its origin, passing between the anterior and middle scalene muscles of the neck, and is conventionally divided into three parts relative to the anterior scalene muscle: the first part medial to the muscle, the second part posterior to it, and the third part lateral to it extending to the outer border of the first rib.[1][2][3] At the lateral margin of the first rib, it transitions into the axillary artery, continuing the blood supply to the upper extremity.[1][3] This trajectory positions it in proximity to bony and muscular structures, making it susceptible to compression in conditions such as thoracic outlet syndrome.[1][2]Key branches arise along its course, including the vertebral artery (supplying the brain and spinal cord), internal thoracic artery (nourishing the chest wall and contributing to the mammary glands), thyrocervical trunk (providing blood to the neck and shoulder), costocervical trunk (serving the upper back), and dorsal scapular artery (to the scapular muscles).[1][2] These branches ensure comprehensive perfusion of the posterior cerebrum, cerebellum, thyroid gland, and upper limb musculature, such as the biceps brachii and triceps brachii, via downstream vessels like the brachial artery.[1][2] Pathologies affecting the subclavian artery, including atherosclerosis and subclavian steal syndrome, can disrupt this vital circulation, often requiring interventions like angioplasty or surgical bypass.[1][2]
Anatomy
Origin and Course
The right subclavian artery originates as the terminal branch of the brachiocephalic trunk posterior to the right sternoclavicular joint.[4] The left subclavian artery arises directly from the arch of the aorta in the superior mediastinum, distal to the origin of the left common carotid artery and posterior to the left brachiocephalic vein.[5][6]The subclavian artery is conventionally divided into three parts based on its relation to the anterior scalene muscle: the first part lies medial to the muscle, the second part is posterior to the muscle, and the third part extends lateral to the muscle.[3][7]From its origin, the subclavian artery courses superolaterally, arching over the first rib and passing through the interval between the clavicle and the first rib to reach the axilla, where it becomes continuous with the axillary artery.[6][2] The vessel measures approximately 5-6 cm in length and has a diameter of about 0.7-1.0 cm at its origin, gradually tapering distally.[7][8]
Anatomical Relations
The subclavian artery is divided into three parts relative to the anterior scalene muscle, each exhibiting unique spatial relationships to adjacent bones, muscles, nerves, and vessels that influence its positioning within the neck and thorax.[1]In its first part, extending from the origin to the medial border of the anterior scalene muscle, the artery lies medial to the anterior scalene muscle and anterior to the roots of the brachial plexus.[3] On the left side, it passes posterior to the left brachiocephalic vein, anterior to the phrenic nerve (which descends over its anterior aspect), trachea, and esophagus, while posteriorly it relates to the apex of the lung and scalenus medius muscle.[6] The subclavian vein courses anterior and inferior to this segment.[3]The second part, situated posterior to the anterior scalene muscle, is enclosed within the interscalene triangle, bounded anteriorly by the anterior scalene muscle, posteriorly by the middle scalene muscle, and inferiorly by the first rib.[9] Here, the artery lies posterior to the anterior scalene muscle (with the phrenic nerve running along the muscle's anterior surface) and anterior to the trunks of the brachial plexus and the middle scalene muscle.[10] The subclavian vein remains anterior to the anterior scalene muscle, thus separated from the arterial segment.[3]The third part extends laterally from the anterior scalene muscle to the lateral border of the first rib, where it continues as the axillary artery.[1] This segment is positioned lateral to the anterior scalene muscle, anterior to the cords of the brachial plexus, and posterior to the clavicle, with the subclavian vein continuing anteriorly.[6] The artery, along with the brachial plexus and subclavian vein, forms a neurovascular bundle that traverses the costoclavicular space between the clavicle and first rib, a site prone to compression due to its confined positioning.[11]
Branches
The subclavian artery is conventionally divided into three parts based on its relation to the anterior scalene muscle, with branches arising from each segment to supply structures in the neck, thorax, and upper limb. These branches exhibit a consistent pattern, though their immediate distributions interconnect to form anastomotic networks with branches of the axillary artery distally and the external carotid artery proximally.[1][12]
First Part Branches
The first part of the subclavian artery, extending from its origin to the medial border of the anterior scalene muscle, gives rise to three major branches. The vertebral artery arises most medially as the first branch, coursing superiorly and entering the transverse foramina of the sixth to first cervical vertebrae (C6–C1) before ascending to the base of the brain.[1][12] The internal thoracic artery (also known as the internal mammary artery) originates next, descending medial to the clavicle and posterior to the sternoclavicular joint along the inner surface of the anterior thoracic wall; it arises from the first part of the subclavian artery on both sides.[1][12] The thyrocervical trunk, a short wide vessel, arises immediately distal to the vertebral artery and divides rapidly into four branches: the inferior thyroid artery, which ascends posterolateral to the trachea to reach the thyroid gland; the suprascapular artery, which winds laterally over the anterior scalene muscle and thyrocervical trunk to cross the scapular notch; the transverse cervical artery, which passes laterally across the floor of the posterior triangle of the neck; and the ascending cervical artery, which ascends between the semispinalis cervicis and longissimus cervicis muscles along the cervical vertebrae.[13][14]
Second Part Branches
The second part of the subclavian artery, located posterior to the anterior scalene muscle, typically gives off a single major branch, the costocervical trunk. This trunk arises posteriorly and ascends briefly before bifurcating into the deep cervical artery, which courses superiorly between the semispinalis cervicis and semispinalis capitis muscles to supply the deep muscles of the posterior neck, and the supreme intercostal artery (also called the superior intercostal artery), which descends to distribute to the first and second intercostal spaces via its posterior branches.[1][12]
Third Part Branches
The third part of the subclavian artery, extending from the lateral border of the anterior scalene muscle to the outer border of the first rib, usually produces one principal branch, the dorsal scapular artery. This vessel arises laterally, pierces the middle scalene muscle, and travels posteriorly deep to the levator scapulae to reach the rhomboid muscles and latissimus dorsi.[1][12]
Development and Variations
Embryological Origin
The subclavian arteries develop as part of the complex transformation of the embryonic aortic arch system, which arises from paired pharyngeal arch arteries during early gestation. These arches form bilaterally between the aortic sac and the dorsal aortae, providing the foundational vascular network for the great vessels. The subclavian arteries derive from the fourth aortic arch and seventh intersegmental arteries, along with connections to the dorsal aortae.[15][16]The left subclavian artery originates primarily from the left seventh intersegmental artery, which anastomoses longitudinally with the left dorsal aorta to form its complete course. This connection establishes the artery's continuity from the aortic arch to the upper limb bud. In contrast, the right subclavian artery forms in segments: its proximal portion arises from the right fourth aortic arch, which persists as part of the brachiocephalic trunk, while the distal segment develops from the right seventh intersegmental artery fusing with the right dorsal aorta. This asymmetric formation reflects the differential regression of arch components on each side.[1][15]The aortic arches begin developing around weeks 4 to 6 of gestation, with the first through sixth pairs sequentially appearing and remodeling. Key events include the early regression of the right sixth aortic arch's dorsal segment, which prevents a right-sided ductus arteriosus and contributes to the brachiocephalic trunk's formation, thereby positioning the right subclavian as its terminal branch. Additionally, the seventh intersegmental arteries undergo caudal migration as the vertebral column elongates, allowing the subclavian origins to shift inferiorly and align with the mature thoracic anatomy. These anastomotic and migratory processes ensure the arteries' integration into the systemic circulation.[15][16]
Common Variations
The subclavian artery exhibits anatomical variations in approximately 5-10% of individuals, with a higher prevalence on the right side due to the greater frequency of aberrant origins.[17] These variations primarily involve deviations in origin, course, branching patterns, and inherent bilateral asymmetries.One of the most common variations is the aberrant right subclavian artery (ARSA), which arises directly from the distal aortic arch rather than the brachiocephalic trunk and courses posterior to the esophagus. This anomaly occurs in 0.5-1.8% of the population and may lead to compressive symptoms such as dysphagia lusoria.[18] In contrast, variations of the left subclavian artery are rarer, with an incidence less than 1%; these include retroesophageal or retrotracheal courses and, in cases of right aortic arch, origin from the descending aorta.[19]Branching anomalies also occur, such as the vertebral artery originating directly from the aortic arch instead of the subclavian artery, with a reported incidence of 1-5%. Additionally, absence of the thyrocervical trunk occurs in approximately 6% of cases, resulting in separate origins of its branches (inferior thyroid, suprascapular, and transverse cervical arteries) directly from the subclavian artery.[20][14][21]Bilateral asymmetries are inherent to the normal anatomy but can be exaggerated in variations; the right subclavian artery is typically shorter (about 5-6 cm) and more vertical compared to the left (about 10 cm and more horizontal), reflecting its origin from the brachiocephalic trunk versus direct aortic arch origin. The bovine arch variant, characterized by a common origin of the brachiocephalic trunk and left common carotid artery, indirectly affects the right subclavian artery and has an incidence of 20-25%.[1][22]
Function
Supply to the Upper Limb
The subclavian artery serves as the primary conduit for oxygenated blood to the upper limb, with its third part transitioning into the axillary artery at the lateral border of the first rib.[1] The axillary artery then continues as the brachial artery in the arm, delivering blood to the muscles and bones of the humerus, forearm, and hand, ensuring nutrient supply and oxygen delivery essential for limb function.[23]Key branches from the subclavian artery contribute directly to the shoulder and scapular regions. The suprascapular artery, arising from the thyrocervical trunk, supplies the rotator cuff muscles and scapula, supporting shoulder mobility.[24] The dorsal scapular artery, often originating directly from the subclavian or as a branch of the transverse cervical artery, perfuses the posterior shoulder muscles, including the rhomboids and levator scapulae.[25] Additionally, the transverse cervical artery provides blood to the trapezius muscle and participates in the scapular anastomosis.[23]The scapular anastomosis forms a critical collateral network around the shoulder, involving branches of the subclavian artery such as the suprascapular and transverse cervical (or dorsalscapular) arteries, which connect with the subscapular artery from the axillary circulation and intercostal arteries from the thoracic aorta.[26] This network enables alternative blood flow pathways, bypassing potential blockages in the subclavian or axillary arteries to maintain upper limbperfusion.[23] The subclavian arteries direct blood flow to the upper limbs, varying with activity to support metabolic demands.The subclavian pulse can be palpated laterally to the sternoclavicular joint in the supraclavicular fossa, often requiring deep pressure due to the artery's deep position beneath the clavicle.[27]
Supply to the Head, Neck, and Thorax
The subclavian artery contributes significantly to the vascular supply of the head and neck through its major branches originating from the first part, notably the vertebral artery, which arises near the origin of the subclavian and ascends through the transverse foramina of the cervical vertebrae to enter the cranium.[1] Upon reaching the pontomedullary junction, the two vertebral arteries unite to form the basilar artery, which provides the primary blood supply to the posterior circulation of the brain, accounting for approximately 20-25% of the cerebral blood flow.[28][29] This posterior circulation perfuses critical structures including the cerebellum, brainstem, and occipital lobes, ensuring oxygenation for motor coordination, vital autonomic functions, and visual processing.[28]The thyrocervical trunk, another key branch from the first part of the subclavian artery, emerges distal to the vertebral artery and rapidly divides into several vessels that nourish neck structures.[1] Its inferior thyroid artery, the largest branch, courses superiorly and posteriorly to supply the thyroid gland, parathyroid glands, and adjacent larynx, anastomosing with the superior thyroid artery for robust glandular perfusion.[13] Complementing this, the ascending cervical artery ascends along the neck's posterior aspect, providing blood to deep neck muscles such as the scalenes and prevertebral muscles, as well as contributing to the vascularization of the spinal cordmeninges and vertebral bodies through anastomoses with the vertebral and occipital arteries.[13]Further supporting thoracic circulation, the internal thoracic artery (also known as the internal mammary artery) originates directly from the first part of the subclavian artery and descends along the inner surface of the anterior chest wall, approximately 1-2 cm lateral to the sternum.[30] It supplies the mammary glands via medial mammary branches, the pericardium through the pericardiophrenic branch that accompanies the phrenic nerve, and the diaphragm via the musculophrenic artery, which runs along the costal margin to perfuse the upper abdominal diaphragm.[30] Additionally, its continuation as the superior epigastric artery delivers blood to the anterior abdominal wall through perforating branches that penetrate the rectus sheath, facilitating cutaneous and muscular nourishment up to the umbilicus level.[30]The costocervical trunk, branching from the second part of the subclavian artery (typically on the right side, with variations on the left), divides into vessels that target posterior neck and upper thoracic regions.[31] The deep cervical artery supplies the deep posterior muscles of the neck and upper back, passing between the semispinalis cervicis and longissimus cervicis muscles to reach the suboccipital region and anastomosing with branches of the occipital artery.[31] Meanwhile, the supreme (or superior) intercostal artery courses posteriorly to supply the upper two intercostal spaces, including the intercostal muscles and pleura, while also contributing to the spinal cord's blood supply via radicular branches that enter the vertebral canal.[31]These branches underscore the subclavian artery's role in collateral circulation during occlusive diseases, where the vertebral artery can support the vertebrobasilar system through interconnections within the circle of Willis, and the internal thoracic artery facilitates alternative pathways to coronary and thoracic structures via its extensive anastomoses.[1][32]
Clinical Significance
Associated Pathologies
Subclavian steal syndrome arises from stenosis or occlusion of the subclavian artery proximal to the origin of the vertebral artery, leading to retrograde blood flow in the ipsilateral vertebral artery to compensate for reduced perfusion to the arm, thereby "stealing" blood from the vertebrobasilar system.[33] This condition manifests with symptoms such as arm claudication during exercise, along with vertebrobasilar insufficiency signs including dizziness, vertigo, syncope, and visual disturbances.[33] The incidence is approximately 1.9% in free-living populations and up to 7.1% in clinical cohorts with cardiovascular risk factors, particularly atherosclerosis.[34]Vascular thoracic outlet syndrome involves extrinsic compression of the subclavian artery, often by a cervical rib, anomalous scalene muscles, or fibrous bands, resulting in post-stenotic dilatation, aneurysm formation, or thrombosis.[35] This arterial subtype accounts for 1-2% of all thoracic outlet syndrome cases, with arterial compression leading to symptoms like upper extremity ischemia, pulsatile masses, or embolic events to the hand.[36]Subclavian artery aneurysms are classified as true aneurysms, typically arising from atherosclerotic degeneration of the vessel wall, or false (pseudoaneurysms), often due to trauma or iatrogenic injury.[37] True aneurysms are rare; both carry risks of thromboembolism to the distal upper limb digits, causing ischemia or gangrene.[37] Additional etiologies include connective tissue disorders or infection, with potential for rupture if untreated.[37]Atherosclerotic stenosis or occlusion of the subclavian artery is prevalent in older adults, affecting approximately 2% of the general population and up to 15% of those over 70 years with peripheral artery disease, frequently coexisting with coronary artery disease due to shared risk factors like smoking and hypertension.[38] This narrowing proximal to the vertebral artery origin can precipitate subclavian steal phenomena, while distal lesions may cause arm ischemia without systemic effects.[38]Traumatic injuries to the subclavian artery include penetrating wounds from gunshot or stab injuries, which carry high mortality due to rapid exsanguination or dissection, and blunt mechanisms such as motor vehicle accidents causing intimal tears, pseudoaneurysms, or arteriovenous fistulas.[39] Iatrogenic trauma commonly occurs during central venous catheterization or surgical procedures, leading to puncture, hematoma, or delayed pseudoaneurysm formation.[39]Congenital aberrant right subclavian artery, the most common aortic arch anomaly, has an incidence of 0.5-1.8% and arises as the last branch from the distal aortic arch, coursing retroesophageally.[40] This variant can cause dysphagia lusoria from esophageal compression or, less commonly, respiratory distress in infants due to tracheal impingement, with rare associations to aneurysms or dissection in adulthood.[40]
Diagnostic Methods
The diagnosis of subclavian artery conditions begins with a thorough physical examination, which can reveal key indicators of pathology. Pulse deficits in the affected arm, diminished or absent radial and brachial pulses compared to the contralateral side, suggest occlusion or severe stenosis. Supraclavicular bruits, audible vascular murmurs over the supraclavicular fossa, indicate turbulent flow due to narrowing. Additionally, a blood pressure asymmetry exceeding 15 mmHg between the arms is a reliable sign of subclavian stenosis, prompting further imaging.Duplex ultrasound, combining B-mode imaging with Doppler spectral analysis, serves as the first-line non-invasive modality for evaluating subclavian artery stenosis and subclavian steal syndrome. It detects elevated peak systolic velocities (typically >200 cm/s indicating >50% stenosis) and velocity gradients across the lesion, with a sensitivity of approximately 65-70% for hemodynamically significant (>50%) stenoses.[41] In steal syndrome, reversed flow in the ipsilateral vertebral artery during hyperemia (e.g., arm exercise) confirms diagnosis, making it particularly useful for initial screening due to its portability and lack of radiation.Computed tomography angiography (CTA) is considered the gold standard for detailed anatomical assessment of the subclavian artery, including variations, aneurysms, and relations to adjacent structures. Intravenous contrast administration enables high-resolution multiplanar and 3D reconstructions, visualizing the vessel from its origin to the axillary bifurcation with submillimeter accuracy. The typical effective radiation dose ranges from 5-10 mSv, balancing diagnostic yield against exposure risks.Magnetic resonance angiography (MRA) provides a non-ionizing alternative, ideal for evaluating soft tissue involvement and cerebral supply in subclavian-related conditions. Time-of-flight MRA exploits blood flow differences for non-contrast imaging, while contrast-enhanced MRA using gadolinium offers superior resolution for vessel lumen and wall assessment, with sensitivities comparable to CTA (85-95%) but without radiation. It is particularly valuable in patients with contraindications to iodinated contrast or those requiring repeated evaluations.Conventional catheter angiography remains the invasive gold standard for precise delineation prior to interventions, offering real-time digital subtraction imaging to map collaterals, plaque morphology, and distal perfusion. Performed via femoral or radial access, it provides the highest spatial resolution (0.1-0.2 mm) and allows simultaneous pressure measurements, though it carries risks of arterial injury (1-2%).Recent advances since 2019 have enhanced diagnostic precision through artificial intelligence integration in duplex ultrasound for carotid artery applications, with machine learning algorithms analyzing velocity waveforms achieving accuracy around 90-92% in validation studies; similar applications are emerging for subclavian artery stenosis.[42] Similarly, 4D flow MRI has been used for hemodynamic analysis of the subclavian-vertebral system, including flow visualization.[43]
Therapeutic Interventions
Conservative management forms the initial approach for subclavian artery disorders, particularly atherosclerosis-related stenosis, where antiplatelet therapy such as aspirin and lipid-lowering agents like statins are employed to mitigate progression and reduce cardiovascular risk.[38] For thoracic outlet syndrome (TOS) involving vascular compression of the subclavian artery, physical therapy is recommended as first-line treatment, focusing on postural correction, stretching exercises for tight muscles (e.g., scalenes and pectoralis minor), and strengthening of shoulder stabilizers to alleviate decompression without invasive procedures.[44][45]Endovascular interventions have become the preferred method for treating subclavian artery stenosis due to their minimally invasive nature and high technical success rates exceeding 90%.[46]Angioplasty combined with stenting restores luminal patency, with primary patency rates around 75-85% at five years and restenosis occurring in 10-20% of cases during that period, often managed with repeat intervention if symptomatic.[47][48] For subclavian artery aneurysms, covered stents are utilized to exclude the aneurysmal sac while preserving flow, achieving exclusion in the majority of cases with low rates of endoleak.[49]Surgical options are reserved for cases unsuitable for endovascular repair, such as proximal occlusions or complex anatomies. Carotid-subclavian bypass, typically using a synthetic polytetrafluoroethylene graft, reroutes blood flow from the common carotid to the subclavian artery, offering durable revascularization with five-year patency rates of 85-96%.[50][51] In traumatic ruptures, resection of the damaged segment followed by ligation or interposition grafting is performed to control hemorrhage and restore continuity, often via supraclavicular or combined thoracic approaches.[39]For vascular TOS leading to subclavian artery compression or post-stenotic aneurysm, surgical decompression involves scalenectomy and first rib excision through a supraclavicular incision to relieve extrinsic pressure, with vascular reconstruction (e.g., resection and reanastomosis) added if aneurysmal dilation is present.[52][53]Congenital aberrant right subclavian artery (ARSA) repair, indicated for symptomatic cases or aneurysmal degeneration, commonly entails division of the aberrant vessel at its origin and reimplantation or transposition to the right carotid or axillary artery to normalize arch anatomy.[54]Hybrid approaches combine endovascular embolization of the ARSA origin with open transposition to minimize risks in high-morbidity patients.[55]Overall procedural mortality for both endovascular and surgical interventions remains low at less than 1% in elective settings, with endovascular approaches showing reduced perioperative complications compared to open surgery.[56] Five-year patency for carotid-subclavian bypass exceeds 85%, supporting its role in long-term symptom relief.[50] Atherosclerosis-related subclavian interventions occur in approximately 2-5% of peripheral artery disease patients annually, reflecting the condition's prevalence within this cohort.[57]