Brachiocephalic vein

Medically Reviewed by Anatomy Team

The brachiocephalic vein is a large vein located in the upper chest, near the base of the neck. It is formed by the union of the subclavian vein and the internal jugular vein on each side of the body. The left and right brachiocephalic veins are situated in the mediastinum and merge to form the superior vena cava, which carries deoxygenated blood to the heart. The left brachiocephalic vein is longer than the right, as it must cross the midline of the chest to join the right brachiocephalic vein. These veins are major conduits for venous return from the head, neck, upper limbs, and thorax.

Location

The brachiocephalic veins are located in the superior mediastinum of the chest, at the base of the neck. They form a crucial part of the venous system, merging in the upper thoracic cavity to eventually drain into the superior vena cava. The right and left brachiocephalic veins differ slightly in their length and course due to their anatomical position relative to the midline of the body.

Anatomy

Formation

Each brachiocephalic vein is formed by the union of the subclavian vein and the internal jugular vein on both the right and left sides of the body. This junction occurs near the sternoclavicular joint, which is where the clavicle meets the sternum. The subclavian vein drains blood from the upper limbs, while the internal jugular vein drains blood from the head and neck.

  • Right Brachiocephalic Vein: The right brachiocephalic vein is formed just behind the right sternoclavicular joint and is shorter than the left brachiocephalic vein. It travels almost vertically downward for a short distance before merging with the left brachiocephalic vein to form the superior vena cava.
  • Left Brachiocephalic Vein: The left brachiocephalic vein is longer because it has to cross the midline of the chest. It runs obliquely from left to right, passing behind the manubrium of the sternum, and eventually meets the right brachiocephalic vein. This vein travels across important structures, including the thymus in infants and children, or remnants of it in adults, and lies in front of major arteries like the aortic arch and its branches.

Course

  • Right Brachiocephalic Vein: The right brachiocephalic vein descends almost vertically, running just lateral to the brachiocephalic trunk and anterior to the right pleura and right lung apex. It follows a short path, usually about 2-3 cm, before joining with the left brachiocephalic vein to form the superior vena cava.
  • Left Brachiocephalic Vein: The left brachiocephalic vein runs more obliquely and horizontally across the upper chest, starting near the left sternoclavicular joint. It passes anterior to the major arteries (such as the left common carotid and left subclavian arteries) and the aortic arch. It runs just behind the manubrium of the sternum and crosses the midline to meet the right brachiocephalic vein, forming the superior vena cava.

Termination

Both the left and right brachiocephalic veins terminate by merging into the superior vena cava, which is located behind the first right costal cartilage. The superior vena cava then directs the deoxygenated blood into the right atrium of the heart, allowing it to be pumped to the lungs for oxygenation.

Tributaries

The brachiocephalic veins receive several important tributaries as they collect venous blood from various regions of the body:

  • Internal Jugular Vein: Drains blood from the head and neck, including the brain, face, and neck muscles.
  • Subclavian Vein: Drains blood from the upper limbs and also receives venous blood from structures such as the shoulder and chest wall.
  • Vertebral Vein: Drains the cervical vertebrae and muscles of the neck.
  • Internal Thoracic Vein: Drains blood from the anterior chest wall and breasts, running parallel to the internal thoracic artery.
  • Inferior Thyroid Vein: Drains blood from the lower part of the thyroid gland.
  • Superior Intercostal Veins: Drain blood from the first and second intercostal spaces (ribs).
  • Thymic Veins: Drain venous blood from the thymus gland or its remnants in adults.

Relations to Neighboring Structures

  • Right Brachiocephalic Vein:
    • Lies lateral to the brachiocephalic trunk.
    • Anterior to the right pleura and apex of the right lung.
    • Closely related to the right phrenic nerve, which runs along its surface.
  • Left Brachiocephalic Vein:
    • Passes anterior to the aortic arch and its branches (the left common carotid artery and the left subclavian artery).
    • Anterior to the left phrenic nerve and left vagus nerve, which lie deeper in the chest.
    • Crosses over the left lung apex and runs behind the manubrium.

Both veins are located anterior to the vertebral bodies of the thoracic spine, and their junction is positioned anterior to the first thoracic vertebra.

Variations

The anatomy of the brachiocephalic veins is generally consistent, but some variations can occur:

  • Asymmetry: The left brachiocephalic vein is longer and more horizontal, while the right is shorter and more vertical.
  • Additional Tributaries: Some individuals may have additional small veins draining into the brachiocephalic veins, such as accessory thyroid veins or extra venous connections with the thymus or intercostal spaces.
  • Abnormal Drainage Patterns: Rarely, anomalies in the course of the brachiocephalic veins can occur, such as persistent left superior vena cava or anomalies in the development of the great veins, affecting venous return.

Function

Venous Return from the Upper Body

The primary function of the brachiocephalic veins is to collect and transport deoxygenated blood from the head, neck, upper limbs, and upper chest back to the heart. These veins are formed by the union of the subclavian vein and the internal jugular vein, which are responsible for draining blood from the upper limbs and head, respectively. This venous return is essential for maintaining systemic circulation, ensuring that blood is efficiently transported to the heart for oxygenation in the lungs.

Drainage from the Head and Neck

The brachiocephalic veins collect blood from several key tributaries in the head and neck region, including the internal jugular vein and vertebral veins. The internal jugular vein is a major vessel that drains deoxygenated blood from the brain, face, and neck, while the vertebral vein drains blood from the cervical spine and surrounding muscles. The brachiocephalic veins ensure that this blood is directed back toward the heart for reoxygenation and removal of metabolic waste.

Drainage from the Upper Limbs

The subclavian vein, which merges with the internal jugular vein to form the brachiocephalic vein, is responsible for draining venous blood from the upper limbs. The brachiocephalic veins transport this blood from the arms back to the central circulation. The subclavian vein collects blood from the superficial and deep veins of the arms, including the cephalic vein and axillary vein, ensuring the proper return of deoxygenated blood to the heart. By facilitating this return, the brachiocephalic veins support the overall venous circulation of the upper body.

Drainage from the Thoracic Region

The brachiocephalic veins also drain blood from structures within the upper thorax. This includes venous blood from the internal thoracic veins, which collect blood from the anterior chest wall and breasts, and the superior intercostal veins, which drain the upper intercostal spaces (between the first and second ribs). These veins contribute to the drainage of the chest wall, diaphragm, and other important structures in the upper thorax.

Drainage from the Thyroid Gland and Thymus

The brachiocephalic veins collect blood from the thyroid gland through the inferior thyroid veins, which drain the lower part of the thyroid. This is particularly important for the regulation of thyroid blood flow and the prevention of venous congestion in this highly vascular gland. Additionally, small thymic veins drain into the brachiocephalic veins, carrying blood from the thymus or its remnants, a gland involved in immune function located in the upper chest.

Formation of the Superior Vena Cava

The brachiocephalic veins on the right and left sides merge to form the superior vena cava (SVC), which is the major vein responsible for returning deoxygenated blood from the entire upper body to the right atrium of the heart. This is the most critical function of the brachiocephalic veins, as they serve as the final conduit for blood to enter the superior vena cava and then the heart, completing the venous return cycle. Proper functioning of the brachiocephalic veins is essential for maintaining cardiac output and ensuring efficient circulation.

Regulation of Venous Pressure in the Upper Body

The brachiocephalic veins help regulate venous pressure in the upper body, ensuring that blood flow is properly balanced between the head, neck, upper limbs, and chest. By efficiently draining blood from these regions, the brachiocephalic veins prevent venous congestion and maintain steady blood flow into the superior vena cava. This is especially important in the regulation of pressure within the brain and upper limbs, where venous congestion could cause swelling or discomfort.

Collateral Circulation and Alternative Venous Pathways

In cases where there is blockage or compression of the major veins, such as the internal jugular vein or subclavian vein, the brachiocephalic veins can play a role in collateral circulation, offering alternative pathways for venous return. The numerous tributaries feeding into the brachiocephalic veins allow for redistribution of blood flow, ensuring that venous return to the heart is maintained even in the event of partial obstruction or venous injury.

Removal of Metabolic Waste Products

The brachiocephalic veins also assist in the removal of metabolic waste products from the tissues they drain. These veins transport deoxygenated blood, which carries carbon dioxide and other waste products, back to the heart. From there, the blood is sent to the lungs for oxygenation and removal of waste. This process is essential for maintaining the health of the tissues in the head, neck, upper limbs, and chest, preventing the buildup of harmful metabolic byproducts.

Temperature Regulation

Through their role in venous return, the brachiocephalic veins contribute to thermoregulation by removing heat-laden blood from the upper body and transporting it back to the central circulation. Blood carries heat generated by metabolic processes, and by draining the head, neck, and upper limbs, the brachiocephalic veins help regulate body temperature, particularly in areas exposed to environmental temperature changes.

Clinical Significance

The brachiocephalic veins are clinically significant due to their vital role in venous return from the head, neck, upper limbs, and upper thorax. These veins are frequently involved in central venous access for procedures such as central venous catheterization, where access to large veins is needed for intravenous medication administration, fluid management, or hemodynamic monitoring.

Thrombosis or occlusion of the brachiocephalic veins, known as brachiocephalic vein thrombosis, can lead to venous congestion in the upper body, causing swelling in the neck, face, or upper limbs. Additionally, compression of the brachiocephalic vein, which may occur in conditions like superior vena cava syndrome, can impair venous return to the heart, leading to symptoms like shortness of breath, facial swelling, and cyanosis.

The left brachiocephalic vein’s longer and more horizontal course makes it more vulnerable during surgical procedures involving the thorax, such as mediastinal surgeries. Careful management of these veins is essential to avoid life-threatening complications such as hemorrhage or venous obstruction.

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