fbpx
Wikipedia

Vein

October 10, 2023

For other uses, see Vein (disambiguation).

Veins (/vn/) are blood vessels in the circulatory system of humans and most other animals that carry blood toward the heart. Most veins carry deoxygenated blood from the tissues back to the heart; exceptions are those of the pulmonary and fetal circulations which carry oxygenated blood to the heart. In the systemic circulation arteries carry oxygenated blood away from the heart, and veins return deoxygenated blood to the heart, in the deep veins.[1]

Vein
Structure of a vein, which consists of three main layers; an outer layer of connective tissue, a middle layer of smooth muscle, and an inner layer lined with endothelium.
Details
SystemCirculatory system
Identifiers
Latinvena
MeSHD014680
TA98A12.0.00.030
A12.3.00.001
TA23904
FMA50723
Anatomical terminology
[edit on Wikidata]

There are three sizes of veins, large, medium, and small. Smaller veins are called venules, and the smallest the post-capillary venules are microscopic that make up the veins of the microcirculation.[2] Veins are often closer to the skin than arteries.

Veins have less smooth muscle and connective tissue and wider internal diameters than arteries. Because of their thinner walls and wider lumens they are able to expand and hold more blood. This greater capacity gives them the term of capacitance vessels. At any time, nearly 70% of the total volume of blood in the human body is in the veins.[3] In medium and large sized veins the flow of blood is maintained by one-way (unidirectional) venous valves to prevent backflow.[3][1] In the lower limbs this is also aided by muscle pumps, also known as venous pumps that exert pressure on intramuscular veins when they contract and drive blood back to the heart.[4]

Structure Edit

 
Layers of vein wall shown in comparison to arterial wall

There are three sizes of vein, large, medium, and small. Smaller veins are called venules. The smallest veins are the post-capillary venules. Veins have a similar three-layered structure to arteries. The layers known as tunicae have a concentric arrangement that forms the wall of the vessel. The outer layer, is a thick layer of connective tissue called the tunica externa or adventitia; this layer is absent in the post-capillary venules.[4] The middle layer, consists of bands of smooth muscle and is known as the tunica media. The inner layer, is a thin lining of endothelium known as the tunica intima. The tunica media in the veins is much thinner than that in the arteries as the veins are not subject to the high systolic pressures that the arteries are. There are valves present in many veins that maintain unidirectional flow.

Unlike arteries, the precise location of veins varies among individuals.[5]

Veins close to the surface of the skin appear blue for a variety of reasons. The factors that contribute to this alteration of color perception are related to the light-scattering properties of the skin and the processing of visual input by the visual cortex, rather than the actual colour of the venous blood which is dark red.[6]

Venous system Edit

See also: List of veins of the human body
Veins of the human body
 
Main veins of the systemic circulation
 
Veins of the circulatory system

The venous system is the system of veins in the systemic and pulmonary circulations that return blood to the heart. In the systemic circulation the return is of deoxygenated blood from the organs and tissues of the body, and in the pulmonary circulation the pulmonary veins return oxygenated blood from the lungs to the heart. Almost 70% of the blood in the body is in the veins, and almost 75% of this blood is in the small veins and venules.[7] All of the systemic veins are tributaries of the largest veins, the superior and inferior vena cava, which empty the oxygen-depleted blood into the right atrium of the heart.[8] The thin walls of the veins, and their greater internal diameters (lumens) enable them to hold a greater volume of blood, and this greater capacitance gives them the term of capacitance vessels.[4] This characteristic also allows for the accommodation of pressure changes in the system. The whole of the venous system, bar the post-capillary venules is a large volume, low pressure system.[9] The venous system is often asymmetric, and whilst the main veins hold a relatively constant position, unlike arteries, the precise location of veins varies among individuals.[5][7]

 
Positions of venae cavae and vessels of the pulmonary circulation

Veins vary in size from the smallest post-capillary venules, and more muscular venules, to small veins, medium veins, and large veins. The thickness of the walls of the veins varies as to their location – in the legs the vein walls are much thicker than those in the arms.[10] In the circulatory system, blood first enters the venous system from capillary beds where arterial blood changes to venous blood.

Large arteries such as the thoracic aorta, subclavian, femoral and popliteal arteries lie close to a single vein that drains the same region. Other arteries are often accompanied by a pair of veins held in a connective tissue sheath. The accompanying veins are known as venae comitantes, or satellite veins, and they run on either side of the artery. When an associated nerve is also enclosed, the sheath is known as a neurovascular bundle.[11] This close proximity of the artery to the veins helps in venous return due to the pulsations in the artery.[12] It also allows for the promotion of heat transfer from the larger arteries to the veins in a counterflow exchange that helps to preserve normal body heat.[11]

Venules
 
Deep and superficial veins of the arm and near thorax

The first entry of venous blood is from the convergence of two or more capillaries into a microscopic, post-capillary venule.[13] Post-capillary venules have a diameter of between 10 and 30 micrometres (μm), and are part of the microcirculation. Their endothelium is of flattened oval or polygon shaped cells surrounded by a basal lamina. Post-capillary venules are too small to have a smooth muscle layer and are instead supported by pericytes that wrap around them.[14] Post-capillary venules become muscular venules when they reach a diameter of 50 μm,[10] and can reach a diameter of 1 mm.[13] These larger venules feed into small veins.

Small, medium, and large veins

The small veins merge to feed as tributaries into medium-sized veins. The medium veins feed into the large veins which include the internal jugular, and renal veins, and the venae cavae that carry the blood directly into the heart.[13] The venae cavae enter the right atrium of the heart from above and below. From above, the superior vena cava carries blood from the arms, head, and chest to the right atrium of the heart, and from below, the inferior vena cava carries blood from the legs and abdomen to the right atrium. The inferior vena cava is the larger of the two. The inferior vena cava is retroperitoneal and runs to the right and roughly parallel to the abdominal aorta along the spine.

Deep, superficial, and perforator veins

The three main compartments of the venous system are the deep veins, the superficial veins, and the perforator veins.[15] Superficial veins are those closer to the surface of the body, and have no corresponding arteries. Deep veins are deeper in the body and have corresponding arteries. Perforator veins drain from the superficial to the deep veins.[16] These are usually referred to in the lower limbs and feet.[17] Superficial veins include the very small spider veins of between 0.5 and 1 mm diameter, and reticular or feeder veins.[18]

Venous plexuses

There are a number of venous plexuses where veins are grouped or sometimes combined in networks at certain body sites. The Batson venous plexus, runs through the inner vertebral column connecting the thoracic and pelvic veins. These veins are noted for being valveless, believed to be the reason for metastasis of certain cancers.

A subcutaneous venous plexus is continuous, and a high rate of flow is supplied by small arteriovenous anastomoses. The high rate of flow ensures heat transfer to the vein wall.[19]

Venous valves Edit

 
Video of valve in popliteal vein
 
Venous valve stopping backflow

Blood flows back to the heart in the systemic deep veins, with the flow of blood maintained by one-way valves in the deep veins, superficial veins, and in the perforator veins.[20] The venous valves serve to prevent regurgitation (backflow) due to the low pressure of veins, and the pull of gravity.[1] They also serve to prevent the over-widening of the vein.[20][21]

A venous valve is bicuspid (having two leaflets) and is formed by an infolding of part of the tunica intima on either side of the lumen of the veins. The leaflets are strengthened with collagen, and elastic fibres, and covered with endothelium.[10] The endothelial cells on the surfaces of the leaflets facing the vein wall, are arranged transversely. On the leaflet surfaces that open to let the blood flow, the cells are arranged longitudinally in the direction of the flow. The leaflets are attached to the venous wall at their convex edges. Their margins are concave and are directed with the flow lying against the wall.[4] As the valve forms, the vein wall where the leaflets attach, becomes dilated on each side. These widenings form the pockets, hollow cup-shaped regions, on the cardial side, known as the valvular sinuses.[22] The endothelial cells in the sinuses are able to stretch twice as much as those in areas without valves.[22] When the blood tries to reverse its direction (due to low venous pressure and the pull of gravity), the sinuses fill first closing the leaflets and keeping them together.[4][8] Approximately 95% of the venous valves are in the small veins of less than 300 micrometres.[23]

The deep veins of the lower limb include the common femoral vein, femoral vein, and the deep femoral vein; the popliteal vein, the tibial, and fibular veins. In the common femoral vein one valve is located above the saphenofemoral junction called the suprasaphenic valve. There are sometimes two valves in the same tract. In the femoral vein there are often three valves, the most constantly found valve is just below the joining of the deep femoral vein. The deep femoral vein and its perforators have valves. In the popliteal veins there are between one and three valves; in each posterior tibial vein there are between 8 and 19 valves, and in the anterior tibial veins there are between 8 and 11 valves.[20]

In the superficial veins there are between one and seven valves along the thigh portion of the great saphenous vein (GSV); two to six below the knee and one to four in the marginal veins of the foot. There is a valve at the termination of the GSV known as the terminal valve to prevent reflux from the femoral vein A preterminal valve is located just below the openings of the tributaries to prevent reflux form these into the GSV.[20] Incompetence of the GSV is a common cause of varicose veins.

The valves also divide the column of blood into segments which helps move the blood unidirectionally to the heart.[24] Their action is supported by the action of skeletal muscle pumps that contract and compress the veins. A skeletal muscle is confined in its fascia and contraction of the muscle which makes it wider results In compression on the vein that pushes the blood forward.[8] Valves in the perforating veins close when a calf muscle contracts, to prevent backflow from the deep veins to the superficial.[25] There are more valves in the lower leg, due to increased gravitational pull, with the number decreasing as the veins travel to the hip. There are no valves in the veins of the thorax or abdomen.[4]

There is a valve at the junction of the inferior vena cava (one of the great vessels) and the right atrium known as the valve of inferior vena cava also known as the eustachian valve. This valve is an embryological remnant and is insignificant in the adult. However, when persistent it can cause problems.[26]

Circulatory routes Edit

 
Diagram showing venous blood flow from capillary beds in some specific locations including the lungs, liver, and kidneys

There are some separate parallel systemic circulatory routes that supply specific regions, and organs.[8] They include the coronary circulation, the cerebral circulation, the bronchial circulation, and the renal circulation.

Coronary circulation

In the coronary circulation, the blood supply to the heart, is drained by cardiac veins (or coronary veins) that remove the deoxygenated blood from the heart muscle. These include the great cardiac vein, the middle cardiac vein, the small cardiac vein, the smallest cardiac veins, and the anterior cardiac veins. Cardiac veins carry blood with a poor level of oxygen, from the heart muscle to the right atrium. Most of the blood of the cardiac veins returns through the coronary sinus. The anatomy of the veins of the heart is very variable, but generally it is formed by the following veins: heart veins that go into the coronary sinus: the great cardiac vein, the middle cardiac vein, the small cardiac vein, the posterior vein of the left ventricle, and the oblique vein of the left atrium (oblique vein of Marshall). Heart veins that go directly to the right atrium: the anterior cardiac veins, and the smallest cardiac veins (Thebesian veins).[27]

Bronchial circulation

In the bronchial circulation that supplies blood to the lung tissues, bronchial veins drain venous blood from the large main bronchi into the azygous vein, and ultimately the right atrium. Venous blood from the bronchi inside the lungs drains into the pulmonary veins and empties into the left atrium; since this blood never went through a capillary bed it was never oxygenated and so provides a small amount of shunted deoxygenated blood into the systemic circulation.[28]

Cerebral circulation

In the cerebral circulation supplying the cerebrum the venous drainage can be separated into two subdivisions: superficial and deep. The superficial system is composed of dural venous sinuses, which have walls composed of dura mater as opposed to a traditional vein. The dural sinuses are therefore located on the surface of the cerebrum. The most prominent of these sinuses is the superior sagittal sinus which flows in the sagittal plane under the midline of the cerebral vault, posteriorly and inferiorly to the confluence of sinuses, where the superficial drainage joins with the sinus that primarily drains the deep venous system. From here, two transverse sinuses bifurcate and travel laterally and inferiorly in an S-shaped curve that forms the sigmoid sinuses which go on to form the two jugular veins. In the neck, the jugular veins parallel the upward course of the carotid arteries and drain blood into the superior vena cava.

The deep venous drainage is primarily composed of traditional veins inside the deep structures of the brain, which join behind the midbrain to form the vein of Galen. This vein merges with the inferior sagittal sinus to form the straight sinus which then joins the superficial venous system mentioned above at the confluence of sinuses.

Portal venous systems

A portal venous system is a series of veins or venules that directly connect two capillary beds. The two systems in verebrates are the hepatic portal system, and the hypophyseal portal system.

Anastomoses

An anastomosis is a joining of two structures such as blood vessels. In the circulation these are called circulatory anastomoses, one of which is the join between an artery with a vein known as an arteriovenous anastomosis. This connection which is highly muscular, enables venous blood to travel directly from an artery into a vein without having passed from a capillary bed.[19][14]

Abnormal connections can be present known as arteriovenous malformations. These are usually congenital and the connections are made from a tangle of capillaries.[29] A cerebral arteriovenous malformation is one that is located in the brain. An irregular connection between an artery and a vein is known as arteriovenous fistula.

A small specialised arteriovenous anastomosis known as a glomus body or organ serves to transfer heat in the fingers and toes. The small connection is surrounded by a capsule of thickened connective tissue. In the hands and feet there are a great number of glomera.[14]

Vascular shunt

A vascular shunt can also bypass the capillary bed and provide a route for blood supply directly to a collecting venule. This is achieved by a metarteriole that supplies around a hundred capillaries. At their junctions are precapillary sphincters that tightly regulate the flow of blood into the capillary bed. When all of the sphincters are closed blood can flow from a metarteriole into a thoroughfare channel and into a collecting venule bypassing the capillary bed.[21][4]

Other

A communicating vein directly connects two parts of the same system such as the Giacomini vein that connects the (superficial) small saphenous vein with the (superficial) great saphenous vein. Peripheral veins carry blood from the limbs and hands and feet.

Microanatomy Edit

 
Diagram of different sized veins with differing component proportions

The three layers of the vein wall are the outer tunica externa, the middle tunica media and the inner tunica intima. There are also numerous valves present in many of the veins.

The outer tunica externa, also known as the tunica adventitia is a sheath of thick connective tissue. This layer is absent in the post-capillary venules.[8]

The middle tunica media is mainly of vascular smooth muscle cells, elastic fibers and collagen. This layer is much thinner than that in arteries [30] Vascular smooth muscle cells control the size of the vein lumens, and thereby help to regulate blood pressure.[31]

The inner tunica intima is a lining of endothelium comprising a single layer of extremely flattened epithelial cells, supported by delicate connective tissue.[8] This subendothelium is a thin but variable connective tissue.[4] The tunica intima has the most variation in blood vessels, in terms of their wall thickness and relative size of their lumen. The endothelial cells continuously produce nitric oxide a soluble gas, to the cells of the adjacent smooth muscle layer. This constant synthesis is carried out by the enzyme endothelial nitric oxide synthase (eNOS).[32] Other endothelial secretions are endothelin, and thromboxane (vasoconstrictors), and prostacyclin a vasodilator.[9]

Development Edit

The development of the embryo is completely reliant on the vitelline circulation, the bidirectional flow of blood between the yolk sac and the embryo. The yolk sac is the first extraembryonic structure to appear. This circulation is critical in allowing the exchange of nutrients, prior to the full development of the placenta.[33] By day 17 vessels begin to form in the yolk sac, arising from the splanchnic mesoderm of the yolk sac wall.[34] The capillaries are formed during vasculogenesis, and they lengthen and interconnect to form an extensive primitive vascular network.[35] Blood is supplied from the primitive aorta, and drained by vitelline veins from the yolk sac to the embryo. By the end of the third week the yolk sac, connecting stalk, and chorionic villi are entirely vascularised.[35]

In the middle of the fourth week the heart begins to beat and the circulation of blood begins. The primitive outflow tract is of three pairs of aortic arches. The inflow tract is formed of six paired veins, the vitelline veins, umbilical veins, and the cardinal veins.[36]

Function Edit

Main article: Circulatory system

In the systemic circulation, veins serve to return oxygen-depleted blood from organs, and tissues to the right heart. From here it passes to the pulmonary arteries for the pulmonary circulation to return oxygen-rich blood to the left heart in the pulmonary veins, to be pumped back into the systemic circulation to complete the cycle. Veins have thinner walls than arteries, and a wider diameter that allow them to expand and hold a greater volume of blood. This gives them a functional role of capacitance that makes possible the accommodation of different pressures in the system. The venous system apart from the post-capillary venules is a high volume, low pressure system. Vascular smooth muscle cells control the size of the vein lumens, and thereby help to regulate blood pressure.[31]

The post-capillary venules are exchange vessels whose ultra-thin walls allow the ready diffusion of molecules from the capillaries.[10]

The return of blood to the heart is assisted by the action of the muscle pump, and by the thoracic pump action of breathing during respiration. Standing or sitting for a prolonged period of time can cause low venous return from venous pooling (vascular) shock. Fainting can occur but usually baroreceptors within the aortic sinuses initiate a baroreflex such that angiotensin II and norepinephrine stimulate vasoconstriction and heart rate increases to return blood flow. Neurogenic and hypovolaemic shock can also cause fainting. In these cases, the smooth muscles surrounding the veins become slack and the veins fill with the majority of the blood in the body, keeping blood away from the brain and causing unconsciousness. Jet pilots wear pressurized suits to help maintain their venous return and blood pressure.

Clinical significance Edit

Further information: Vascular surgery § Management of venous diseases

Most venous diseases involve obstruction such as a thrombus or insufficiency of the valves, or both of these.[37][20] Other conditions may be due to inflammation, or compression. Ageing is a major independent risk factor for venous disorders.[38] The medical speciality involved with the diagnosis and treatment of venous disorders is known as phlebology (also venology), and the specialist concerned is a phlebologist.[39] There are a number of vascular surgeries and endovascular surgeries carried out by vascular surgeons to treat many venous diseases.

Venous insufficiency Edit

Main article: Chronic venous insufficiency

Venous insufficiency is the most common disorder of the venous system, and is usually manifested as either spider veins or varicose veins. Several treatments are available including endovenous thermal ablation (using radiofrequency or laser energy), vein stripping, ambulatory phlebectomy, foam sclerotherapy, laser, or compression.

Postphlebitic syndrome is venous insufficiency that develops following deep vein thrombosis.[40]

Venous thrombosis Edit

Further information: Deep vein thrombosis

Venous thrombosis is the formation of a thrombus (blood clot) in a vein. This most commonly affects a deep vein known as deep vein thrombosis (DVT), but can also affect a superficial vein known as superficial vein thrombosis (SVT).

Deep vein thrombosis Edit

DVT usually occurs in the veins of the legs, although it can also occur in the deep veins of the arms.[41] Immobility, active cancer, obesity, traumatic damage and congenital disorders that make clots more likely are all risk factors for deep vein thrombosis. It can cause the affected limb to swell, and cause pain and an overlying skin rash. In the worst case, a deep vein thrombosis can extend, or a part of a clot can break off as an embolus and lodge in a pulmonary artery in the lungs, known as a pulmonary embolism.

The decision to treat deep vein thrombosis depends on its size, symptoms, and their risk factors. It generally involves anticoagulation to prevents clots or to reduce the size of the clot. Intermittent pneumatic compression is a method used to improve venous circulation in cases of edema or in those at risk from a deep vein thrombosis.

Superficial vein thrombosis Edit

SVT is the development of a thrombus in a superficial vein. SVT is not normally clinically significant, but the thrombus can migrate into the deep venous system where it can also give rise to a pulmonary embolism.[42] The main risk factor for SVT in the lower limbs is varicose veins.[42]

Portal hypertension Edit

The portal vein also known as the hepatic portal vein carries blood drained from most of the gastrointestinal tract to the liver. Portal hypertension is mainly caused by cirrhosis of the liver. Other causes can include an obstructing clot in a hepatic vein (Budd Chiari syndrome) or compression from tumors or tuberculosis lesions. When the pressure increases in the portal vein, a collateral circulation develops, causing visible veins such as esophageal varices.

Phlebitis Edit

Phlebitis is the inflammation of a vein. It is usually accompanied by a blood clot when it is known as thrombophlebitis. When the affected vein is a superficial vein in the leg, it is known as superficial thrombophlebitis, and unlike deep vein thrombosis there is little risk of the clot breaking off as an embolus.[43]

Compression Edit

Some disorders as syndromes result from compression of a vein. These include a venous type of thoracic outlet syndrome, due to compression of a subclavian vein; nutcracker syndrome most usually due to compression of the left renal vein, and May–Thurner syndrome associated with compression of the iliac vein which can lead to iliofemoral DVT. Compression of the superior vena cava most usually by a malignant tumor can lead to superior vena cava syndrome.[44]

Vascular anomalies Edit

A vascular anomaly can be either a vascular tumor or a birthmark, or a vascular malformation. [45] In a tumor such as infantile hemangioma the mass is soft, and easily compressed, and their coloring is due to the dilated anomalous involved veins.[46] They are most commonly found in the head and neck. Venous malformations are the type of vascular malformation that involves the veins. They can often extend deeper from their surface appearance, reaching underlying muscle or bone.[47] In the neck they may extend into the lining of the mouth cavity or into the salivary glands.[46] They are the most common of the vascular malformations.[48] A severe venous malformation can involve the lymph vessels as a lymphaticovenous malformation.[46]

Venous access Edit

See also: Venipuncture

Venous access is any method used to access the bloodstream through the veins, either to administer intravenous therapy such as medication, or fluid, parenteral nutrition, to obtain blood for analysis, or to provide an access point for blood-based treatments such as dialysis or apheresis. Access is most commonly achieved via the placement of a central venous catheter, a Seldinger technique, and guidance tools such as ultrasound and fluoroscopy can also be used to assist with access location.

Imaging Edit

Ultrasound, particularly duplex ultrasound, is the most usual and widely used way of viewing veins in the diagnosis of venous disease.[49][50] Venography is an invasive procedure that uses a catheter to deliver a contrast agent in giving an X-ray of veins. An augmented reality healthcare application is a near-infrared vein finder that films subcutaneous veins, and projects their image either onto a screen or onto the person's skin.[51]

Recognition techniques Edit

Some imaging techniques using veins have been developed for identification purposes. These vein matching technologies, include finger vein recognition,[52] and eye vein verification.

History Edit

Further information: Circulatory system § History

The Greek physician Herophilus (born 335 BC) distinguished veins from arteries, noting the thicker walls of arteries, but thought that the pulse was a property of arteries themselves. Greek anatomist Erasistratus observed that arteries that were cut during life bleed. He ascribed the fact to the phenomenon that air escaping from an artery is replaced with blood that entered by very small vessels between veins and arteries. Thus he apparently postulated capillaries but with reversed flow of blood.[53]

In 2nd century AD Rome, the Greek physician Galen knew that blood vessels carried blood and identified venous (dark red) and arterial (brighter and thinner) blood, each with distinct and separate functions. Growth and energy were derived from venous blood created in the liver from chyle, while arterial blood gave vitality by containing pneuma (air) and originated in the heart. Blood flowed from both creating organs to all parts of the body where it was consumed and there was no return of blood to the heart or liver. The heart did not pump blood around, the heart's motion sucked blood in during diastole and the blood moved by the pulsation of the arteries themselves.

 
Image of veins from William Harvey's Exercitatio Anatomica de Motu Cordis et Sanguinis in Animalibus

Galen believed that the arterial blood was created by venous blood passing from the left ventricle to the right by passing through 'pores' in the interventricular septum, air passed from the lungs via the pulmonary artery to the left side of the heart. As the arterial blood was created 'sooty' vapors were created and passed to the lungs also via the pulmonary artery to be exhaled.

In addition, Ibn al-Nafis had an insight into what would become a larger theory of the capillary circulation. He stated that "there must be small communications or pores (manafidh in Arabic) between the pulmonary artery and vein," a prediction that preceded the discovery of the capillary system by more than 400 years.[54] Ibn al-Nafis' theory, however, was confined to blood transit in the lungs and did not extend to the entire body.

Finally, William Harvey, a pupil of Hieronymus Fabricius (who had earlier described the valves of the veins without recognizing their function), performed a sequence of experiments, and published Exercitatio Anatomica de Motu Cordis et Sanguinis in Animalibus in 1628, which "demonstrated that there had to be a direct connection between the venous and arterial systems throughout the body, and not just the lungs. Most importantly, he argued that the beat of the heart produced a continuous circulation of blood through minute connections at the extremities of the body. This is a conceptual leap that was quite different from Ibn al-Nafis' refinement of the anatomy and bloodflow in the heart and lungs."[55] This work, with its essentially correct exposition, slowly convinced the medical world. However, Harvey was not able to identify the capillary system connecting arteries and veins; these were later discovered by Marcello Malpighi in 1661.[56]

See also Edit

References Edit

  1. ^ a b c Moore HM, Gohel M, Davies AH (October 2011). "Number and location of venous valves within the popliteal and femoral veins: a review of the literature". J Anat. 219 (4): 439–43. doi:10.1111/j.1469-7580.2011.01409.x. PMC 3196749. PMID 21740424.
  2. ^ Guven G, Hilty MP, Ince C (2020). "Microcirculation: Physiology, Pathophysiology, and Clinical Application". Blood Purif. 49 (1–2): 143–150. doi:10.1159/000503775. PMC 7114900. PMID 31851980.
  3. ^ a b "Classification & Structure of Blood Vessels | SEER Training". training.seer.cancer.gov. Retrieved 29 January 2023.
  4. ^ a b c d e f g h GRAYS 2016, p. 131.
  5. ^ a b Maton, Anthea; Jean Hopkins; Charles William McLaughlin; Alexandra Senckowski; Susan Johnson; Maryanna Quon Warner; David LaHart; Jill D. Wright (1993). Human Biology and Health. Englewood Cliffs, New Jersey: Prentice Hall. ISBN 978-0-13-981176-0.
  6. ^ Kienle A, Lilge L, Vitkin IA, Patterson MS, Wilson BC, Hibst R, Steiner R (March 1996). (PDF). Applied Optics. 35 (7): 1151. Bibcode:1996ApOpt..35.1151K. doi:10.1364/AO.35.001151. PMID 21085227. Archived from the original (PDF) on 10 February 2012.
  7. ^ a b Zivadinov, Robert; Chung, Chih-Ping (17 December 2013). "Potential involvement of the extracranial venous system in central nervous system disorders and aging". BMC Medicine. 11: 260. doi:10.1186/1741-7015-11-260. PMC 3866257. PMID 24344742.
  8. ^ a b c d e f Moore, Keith L. (2018). Clinically oriented anatomy (Eighth ed.). Philadelphia. pp. 38–41. ISBN 9781496347213.{{cite book}}: CS1 maint: location missing publisher (link)
  9. ^ a b GRAYS 2016, p. 134.
  10. ^ a b c d GRAYS 2016, p. 130.
  11. ^ a b GRAYS 2016, p. 127.
  12. ^ GRAYS 2016, p. 41.
  13. ^ a b c Saladin, Kenneth S. (2011). Human anatomy (3rd ed.). New York: McGraw-Hill. pp. 570–571. ISBN 9780071222075.
  14. ^ a b c GRAYS 2016, p. 135.
  15. ^ Baliyan V, Tajmir S, Hedgire SS, Ganguli S, Prabhakar AM (December 2016). "Lower extremity venous reflux". Cardiovasc Diagn Ther. 6 (6): 533–543. doi:10.21037/cdt.2016.11.14. PMC 5220199. PMID 28123974.
  16. ^ Albert, consultants Daniel (2012). Dorland's illustrated medical dictionary (32nd ed.). Philadelphia, PA: Saunders/Elsevier. p. 2042. ISBN 978-1-4160-6257-8.
  17. ^ Sureka, Binit (15 September 2015). "Portal vein variations in 1000 patients: surgical and radiological importance". British Journal of Radiology. 88 (1055): 1055. doi:10.1259/bjr.20150326. PMC 4743455. PMID 26283261.
  18. ^ Radhakrishnan N, George D, Jayakrishnan R, Sumi S, Kartha CC (December 2018). "Vein Size and Disease Severity in Chronic Venous Diseases". Int J Angiol. 27 (4): 185–189. doi:10.1055/s-0038-1639355. PMC 6221802. PMID 30410288.
  19. ^ a b Hall, John E. (2011). Guyton and Hall textbook of medical physiology (Twelfth ed.). Philadelphia, Pa. p. 868. ISBN 9781416045748.{{cite book}}: CS1 maint: location missing publisher (link)
  20. ^ a b c d e Publishing, Licorn (9 April 2013). "The venous valves of the lower limbs". Servier - Phlebolymphology. Retrieved 11 March 2023.
  21. ^ a b "20.1 Structure and Function of Blood Vessels - Anatomy and Physiology 2e | OpenStax". openstax.org. 20 April 2022. Retrieved 17 March 2023.
  22. ^ a b Bazigou E, Makinen T (March 2013). "Flow control in our vessels: vascular valves make sure there is no way back". Cell Mol Life Sci. 70 (6): 1055–66. doi:10.1007/s00018-012-1110-6. PMC 3578722. PMID 22922986.
  23. ^ Rajeeva Pandian NK, Jain A (2022). "In silico analyses of blood flow and oxygen transport in human micro-veins and valves". Clin Hemorheol Microcirc. 81 (1): 81–96. doi:10.3233/CH-211345. PMC 9307074. PMID 35034895.
  24. ^ Meissner MH (September 2005). "Lower extremity venous anatomy". Semin Intervent Radiol. 22 (3): 147–56. doi:10.1055/s-2005-921948. PMC 3036282. PMID 21326687.
  25. ^ "Veins: Anatomy and Function". Cleveland Clinic. Retrieved 16 March 2023.
  26. ^ Cai Q, Ahmad M (June 2020). "Eustachian valve, interatrial shunt, and paradoxical embolism". Echocardiography. 37 (6): 939–944. doi:10.1111/echo.14682. PMID 32426851.
  27. ^ Adams, Matt; Morgan, Matt A.; et al. "Coronary veins". Radiopaedia.org.
  28. ^ Weinberger, Steven E. (2019). Principles of pulmonary medicine (Seventh ed.). Philadelphia, PA. p. 178. ISBN 9780323523714.{{cite book}}: CS1 maint: location missing publisher (link)
  29. ^ "AVM" (PDF). Retrieved 5 February 2023.
  30. ^ GRAYS 2016, p. 132–134.
  31. ^ a b Brozovich FV, Nicholson CJ, Degen CV, Gao YZ, Aggarwal M, Morgan KG (April 2016). "Mechanisms of Vascular Smooth Muscle Contraction and the Basis for Pharmacologic Treatment of Smooth Muscle Disorders". Pharmacol Rev. 68 (2): 476–532. doi:10.1124/pr.115.010652. PMC 4819215. PMID 27037223.
  32. ^ Tousoulis D, Kampoli AM, Tentolouris C, Papageorgiou N, Stefanadis C (January 2012). "The role of nitric oxide on endothelial function". Curr Vasc Pharmacol. 10 (1): 4–18. doi:10.2174/157016112798829760. PMID 22112350.
  33. ^ Donovan, Mary F.; Arbor, Tafline C.; Bordoni, Bruno (2023). "Embryology, Yolk Sac". StatPearls. StatPearls Publishing. PMID 32310425. Retrieved 22 March 2023.
  34. ^ Schoenwolf, Gary C. (2015). Larsen's human embryology (Fifth ed.). Philadelphia, PA. p. 304. ISBN 9781455706846.{{cite book}}: CS1 maint: location missing publisher (link)
  35. ^ a b Schoenwolf, Gary C. (2015). Larsen's human embryology (Fifth ed.). Philadelphia, PA. p. 306. ISBN 9781455706846.{{cite book}}: CS1 maint: location missing publisher (link)
  36. ^ Schoenwolf, Gary C. (2015). Larsen's human embryology (Fifth ed.). Philadelphia, PA. p. 279. ISBN 9781455706846.{{cite book}}: CS1 maint: location missing publisher (link)
  37. ^ Goel, RR; Hardy, SC; Brown, T (30 September 2021). "Surgery for deep venous insufficiency". The Cochrane Database of Systematic Reviews. 2021 (9): CD001097. doi:10.1002/14651858.CD001097.pub4. PMC 8483065. PMID 34591328.
  38. ^ Molnár AÁ, Nádasy GL, Dörnyei G, Patai BB, Delfavero J, Fülöp GÁ, Kirkpatrick AC, Ungvári Z, Merkely B (December 2021). "The aging venous system: from varicosities to vascular cognitive impairment". Geroscience. 43 (6): 2761–2784. doi:10.1007/s11357-021-00475-2. PMC 8602591. PMID 34762274.
  39. ^ "Phlebology". Retrieved 9 January 2023.
  40. ^ Kahn SR (August 2006). "The post-thrombotic syndrome: progress and pitfalls". British Journal of Haematology. 134 (4): 357–65. doi:10.1111/j.1365-2141.2006.06200.x. PMID 16822286. S2CID 19715556.
  41. ^ Heil, J; Miesbach, W; Vogl, T; Bechstein, WO; Reinisch, A (7 April 2017). "Deep Vein Thrombosis of the Upper Extremity". Deutsches Ärzteblatt International. 114 (14): 244–249. doi:10.3238/arztebl.2017.0244. PMC 5415909. PMID 28446351.
  42. ^ a b Cosmi, B. (July 2015). "Management of superficial vein thrombosis". Journal of Thrombosis and Haemostasis. 13 (7): 1175–1183. doi:10.1111/jth.12986. PMID 25903684. S2CID 5276848.
  43. ^ Di Nisio M, Wichers IM, Middeldorp S (February 2018). "Treatment for superficial thrombophlebitis of the leg". Cochrane Database Syst Rev. 2018 (2): CD004982. doi:10.1002/14651858.CD004982.pub6. PMC 6953389. PMID 29478266.
  44. ^ Nickloes TA, Lopez Rowe V, Kallab AM, Dunlap AB (8 March 2022). "Superior Vena Cava Syndrome". Medscape. WebMD LLC. Retrieved 13 March 2023.
  45. ^ Steiner, JE; Drolet, BA (September 2017). "Classification of Vascular Anomalies: An Update". Seminars in Interventional Radiology. 34 (3): 225–232. doi:10.1055/s-0037-1604295. PMC 5615389. PMID 28955111.
  46. ^ a b c Chim, H; Drolet, B; Duffy, K; Koshima, I; Gosain, AK (August 2010). "Vascular anomalies and lymphedema". Plastic and Reconstructive Surgery. 126 (2): 55e–69e. doi:10.1097/PRS.0b013e3181df803d. PMID 20679788. S2CID 30865392.
  47. ^ Chen, RJ; Vrazas, JI; Penington, AJ (January 2021). "Surgical Management of Intramuscular Venous Malformations". Journal of Pediatric Orthopedics. 41 (1): e67–e73. doi:10.1097/BPO.0000000000001667. PMID 32815867. S2CID 221199574.
  48. ^ Markovic, JN; Shortell, CK (October 2021). "Venous malformations". The Journal of Cardiovascular Surgery. 62 (5): 456–466. doi:10.23736/S0021-9509.21.11911-1. PMID 34105926. S2CID 261366559.
  49. ^ Lee DK, Ahn KS, Kang CH, Cho SB (April 2017). "Ultrasonography of the lower extremity veins: anatomy and basic approach". Ultrasonography. 36 (2): 120–130. doi:10.14366/usg.17001. PMC 5381851. PMID 28260355.
  50. ^ Garcia R, Labropoulos N (April 2018). "Duplex Ultrasound for the Diagnosis of Acute and Chronic Venous Diseases". Surg Clin North Am. 98 (2): 201–218. doi:10.1016/j.suc.2017.11.007. PMID 29502767.
  51. ^ Miyake RK, et al. (2006). "Vein imaging: a new method of near infrared imaging, where a processed image is projected onto the skin for the enhancement of vein treatment". Dermatol Surg. 32 (8): 1031–8. doi:10.1111/j.1524-4725.2006.32226.x. PMID 16918565. S2CID 8872471.
  52. ^ Zhang Z, Wang M (March 2022). "A Simple and Efficient Method for Finger Vein Recognition". Sensors. 22 (6): 2234. Bibcode:2022Senso..22.2234Z. doi:10.3390/s22062234. PMC 8949429. PMID 35336406.
  53. ^ Anatomy – History of anatomy. Scienceclarified.com. Retrieved 2013-09-15.
  54. ^ West, J. B. (2008). "Ibn al-Nafis, the pulmonary circulation, and the Islamic Golden Age". Journal of Applied Physiology. 105 (6): 1877–1880. doi:10.1152/japplphysiol.91171.2008. PMC 2612469. PMID 18845773.
  55. ^ Pormann, Peter E. and Smith, E. Savage (2007) Medieval Islamic medicine Georgetown University, Washington DC, p. 48, ISBN 1589011619.
  56. ^ Romero Reverón, Rafael (June 2011). "Marcello Malpighi (1628-1694), Founder of Microanatomy". International Journal of Morphology. 29 (2): 399–402. doi:10.4067/S0717-95022011000200015. Retrieved 8 February 2023.

Bibliography Edit

  • Standring, Susan, ed. (2016). Gray's Anatomy: The Anatomical Basis of Clinical Practice (Forty first ed.). [Philadelphia]: Churchill Livingstone. ISBN 978-0-7020-5230-9.

Further reading Edit

  • Shoja, M. M.; Tubbs, R. S.; Loukas, M.; Khalili, M.; Alakbarli, F.; Cohen-Gadol, A. A. (2009). "Vasovagal syncope in the Canon of Avicenna: The first mention of carotid artery hypersensitivity". International Journal of Cardiology. 134 (3): 297–301. doi:10.1016/j.ijcard.2009.02.035. PMID 19332359.

External links Edit

 
Look up vein in Wiktionary, the free dictionary.
  • Merck Manual article on veins
  • A lecture on YouTube on the veins' and lymphatic systems of the upper limb

October 10, 2023
vein, other, uses, disambiguation, blood, vessels, circulatory, system, humans, most, other, animals, that, carry, blood, toward, heart, most, veins, carry, deoxygenated, blood, from, tissues, back, heart, exceptions, those, pulmonary, fetal, circulations, whi. For other uses see Vein disambiguation Veins v eɪ n are blood vessels in the circulatory system of humans and most other animals that carry blood toward the heart Most veins carry deoxygenated blood from the tissues back to the heart exceptions are those of the pulmonary and fetal circulations which carry oxygenated blood to the heart In the systemic circulation arteries carry oxygenated blood away from the heart and veins return deoxygenated blood to the heart in the deep veins 1 VeinStructure of a vein which consists of three main layers an outer layer of connective tissue a middle layer of smooth muscle and an inner layer lined with endothelium DetailsSystemCirculatory systemIdentifiersLatinvenaMeSHD014680TA98A12 0 00 030 A12 3 00 001TA23904FMA50723Anatomical terminology edit on Wikidata There are three sizes of veins large medium and small Smaller veins are called venules and the smallest the post capillary venules are microscopic that make up the veins of the microcirculation 2 Veins are often closer to the skin than arteries Veins have less smooth muscle and connective tissue and wider internal diameters than arteries Because of their thinner walls and wider lumens they are able to expand and hold more blood This greater capacity gives them the term of capacitance vessels At any time nearly 70 of the total volume of blood in the human body is in the veins 3 In medium and large sized veins the flow of blood is maintained by one way unidirectional venous valves to prevent backflow 3 1 In the lower limbs this is also aided by muscle pumps also known as venous pumps that exert pressure on intramuscular veins when they contract and drive blood back to the heart 4 Contents 1 Structure 2 Venous system 2 1 Venous valves 2 2 Circulatory routes 3 Microanatomy 4 Development 5 Function 6 Clinical significance 6 1 Venous insufficiency 6 2 Venous thrombosis 6 2 1 Deep vein thrombosis 6 2 2 Superficial vein thrombosis 6 3 Portal hypertension 6 4 Phlebitis 6 5 Compression 6 6 Vascular anomalies 6 7 Venous access 6 8 Imaging 6 8 1 Recognition techniques 7 History 8 See also 9 References 10 Bibliography 11 Further reading 12 External linksStructure Edit nbsp Layers of vein wall shown in comparison to arterial wallThere are three sizes of vein large medium and small Smaller veins are called venules The smallest veins are the post capillary venules Veins have a similar three layered structure to arteries The layers known as tunicae have a concentric arrangement that forms the wall of the vessel The outer layer is a thick layer of connective tissue called the tunica externa or adventitia this layer is absent in the post capillary venules 4 The middle layer consists of bands of smooth muscle and is known as the tunica media The inner layer is a thin lining of endothelium known as the tunica intima The tunica media in the veins is much thinner than that in the arteries as the veins are not subject to the high systolic pressures that the arteries are There are valves present in many veins that maintain unidirectional flow Unlike arteries the precise location of veins varies among individuals 5 Veins close to the surface of the skin appear blue for a variety of reasons The factors that contribute to this alteration of color perception are related to the light scattering properties of the skin and the processing of visual input by the visual cortex rather than the actual colour of the venous blood which is dark red 6 Venous system EditSee also List of veins of the human body Veins of the human body nbsp Main veins of the systemic circulation nbsp Veins of the circulatory system The venous system is the system of veins in the systemic and pulmonary circulations that return blood to the heart In the systemic circulation the return is of deoxygenated blood from the organs and tissues of the body and in the pulmonary circulation the pulmonary veins return oxygenated blood from the lungs to the heart Almost 70 of the blood in the body is in the veins and almost 75 of this blood is in the small veins and venules 7 All of the systemic veins are tributaries of the largest veins the superior and inferior vena cava which empty the oxygen depleted blood into the right atrium of the heart 8 The thin walls of the veins and their greater internal diameters lumens enable them to hold a greater volume of blood and this greater capacitance gives them the term of capacitance vessels 4 This characteristic also allows for the accommodation of pressure changes in the system The whole of the venous system bar the post capillary venules is a large volume low pressure system 9 The venous system is often asymmetric and whilst the main veins hold a relatively constant position unlike arteries the precise location of veins varies among individuals 5 7 nbsp Positions of venae cavae and vessels of the pulmonary circulationVeins vary in size from the smallest post capillary venules and more muscular venules to small veins medium veins and large veins The thickness of the walls of the veins varies as to their location in the legs the vein walls are much thicker than those in the arms 10 In the circulatory system blood first enters the venous system from capillary beds where arterial blood changes to venous blood Large arteries such as the thoracic aorta subclavian femoral and popliteal arteries lie close to a single vein that drains the same region Other arteries are often accompanied by a pair of veins held in a connective tissue sheath The accompanying veins are known as venae comitantes or satellite veins and they run on either side of the artery When an associated nerve is also enclosed the sheath is known as a neurovascular bundle 11 This close proximity of the artery to the veins helps in venous return due to the pulsations in the artery 12 It also allows for the promotion of heat transfer from the larger arteries to the veins in a counterflow exchange that helps to preserve normal body heat 11 Venules nbsp Deep and superficial veins of the arm and near thoraxThe first entry of venous blood is from the convergence of two or more capillaries into a microscopic post capillary venule 13 Post capillary venules have a diameter of between 10 and 30 micrometres mm and are part of the microcirculation Their endothelium is of flattened oval or polygon shaped cells surrounded by a basal lamina Post capillary venules are too small to have a smooth muscle layer and are instead supported by pericytes that wrap around them 14 Post capillary venules become muscular venules when they reach a diameter of 50 mm 10 and can reach a diameter of 1 mm 13 These larger venules feed into small veins Small medium and large veinsThe small veins merge to feed as tributaries into medium sized veins The medium veins feed into the large veins which include the internal jugular and renal veins and the venae cavae that carry the blood directly into the heart 13 The venae cavae enter the right atrium of the heart from above and below From above the superior vena cava carries blood from the arms head and chest to the right atrium of the heart and from below the inferior vena cava carries blood from the legs and abdomen to the right atrium The inferior vena cava is the larger of the two The inferior vena cava is retroperitoneal and runs to the right and roughly parallel to the abdominal aorta along the spine Deep superficial and perforator veinsThe three main compartments of the venous system are the deep veins the superficial veins and the perforator veins 15 Superficial veins are those closer to the surface of the body and have no corresponding arteries Deep veins are deeper in the body and have corresponding arteries Perforator veins drain from the superficial to the deep veins 16 These are usually referred to in the lower limbs and feet 17 Superficial veins include the very small spider veins of between 0 5 and 1 mm diameter and reticular or feeder veins 18 Venous plexusesThere are a number of venous plexuses where veins are grouped or sometimes combined in networks at certain body sites The Batson venous plexus runs through the inner vertebral column connecting the thoracic and pelvic veins These veins are noted for being valveless believed to be the reason for metastasis of certain cancers A subcutaneous venous plexus is continuous and a high rate of flow is supplied by small arteriovenous anastomoses The high rate of flow ensures heat transfer to the vein wall 19 Venous valves Edit nbsp Video of valve in popliteal vein nbsp Venous valve stopping backflowBlood flows back to the heart in the systemic deep veins with the flow of blood maintained by one way valves in the deep veins superficial veins and in the perforator veins 20 The venous valves serve to prevent regurgitation backflow due to the low pressure of veins and the pull of gravity 1 They also serve to prevent the over widening of the vein 20 21 A venous valve is bicuspid having two leaflets and is formed by an infolding of part of the tunica intima on either side of the lumen of the veins The leaflets are strengthened with collagen and elastic fibres and covered with endothelium 10 The endothelial cells on the surfaces of the leaflets facing the vein wall are arranged transversely On the leaflet surfaces that open to let the blood flow the cells are arranged longitudinally in the direction of the flow The leaflets are attached to the venous wall at their convex edges Their margins are concave and are directed with the flow lying against the wall 4 As the valve forms the vein wall where the leaflets attach becomes dilated on each side These widenings form the pockets hollow cup shaped regions on the cardial side known as the valvular sinuses 22 The endothelial cells in the sinuses are able to stretch twice as much as those in areas without valves 22 When the blood tries to reverse its direction due to low venous pressure and the pull of gravity the sinuses fill first closing the leaflets and keeping them together 4 8 Approximately 95 of the venous valves are in the small veins of less than 300 micrometres 23 The deep veins of the lower limb include the common femoral vein femoral vein and the deep femoral vein the popliteal vein the tibial and fibular veins In the common femoral vein one valve is located above the saphenofemoral junction called the suprasaphenic valve There are sometimes two valves in the same tract In the femoral vein there are often three valves the most constantly found valve is just below the joining of the deep femoral vein The deep femoral vein and its perforators have valves In the popliteal veins there are between one and three valves in each posterior tibial vein there are between 8 and 19 valves and in the anterior tibial veins there are between 8 and 11 valves 20 In the superficial veins there are between one and seven valves along the thigh portion of the great saphenous vein GSV two to six below the knee and one to four in the marginal veins of the foot There is a valve at the termination of the GSV known as the terminal valve to prevent reflux from the femoral vein A preterminal valve is located just below the openings of the tributaries to prevent reflux form these into the GSV 20 Incompetence of the GSV is a common cause of varicose veins The valves also divide the column of blood into segments which helps move the blood unidirectionally to the heart 24 Their action is supported by the action of skeletal muscle pumps that contract and compress the veins A skeletal muscle is confined in its fascia and contraction of the muscle which makes it wider results In compression on the vein that pushes the blood forward 8 Valves in the perforating veins close when a calf muscle contracts to prevent backflow from the deep veins to the superficial 25 There are more valves in the lower leg due to increased gravitational pull with the number decreasing as the veins travel to the hip There are no valves in the veins of the thorax or abdomen 4 There is a valve at the junction of the inferior vena cava one of the great vessels and the right atrium known as the valve of inferior vena cava also known as the eustachian valve This valve is an embryological remnant and is insignificant in the adult However when persistent it can cause problems 26 Circulatory routes Edit nbsp Diagram showing venous blood flow from capillary beds in some specific locations including the lungs liver and kidneysThere are some separate parallel systemic circulatory routes that supply specific regions and organs 8 They include the coronary circulation the cerebral circulation the bronchial circulation and the renal circulation Coronary circulationIn the coronary circulation the blood supply to the heart is drained by cardiac veins or coronary veins that remove the deoxygenated blood from the heart muscle These include the great cardiac vein the middle cardiac vein the small cardiac vein the smallest cardiac veins and the anterior cardiac veins Cardiac veins carry blood with a poor level of oxygen from the heart muscle to the right atrium Most of the blood of the cardiac veins returns through the coronary sinus The anatomy of the veins of the heart is very variable but generally it is formed by the following veins heart veins that go into the coronary sinus the great cardiac vein the middle cardiac vein the small cardiac vein the posterior vein of the left ventricle and the oblique vein of the left atrium oblique vein of Marshall Heart veins that go directly to the right atrium the anterior cardiac veins and the smallest cardiac veins Thebesian veins 27 Bronchial circulationIn the bronchial circulation that supplies blood to the lung tissues bronchial veins drain venous blood from the large main bronchi into the azygous vein and ultimately the right atrium Venous blood from the bronchi inside the lungs drains into the pulmonary veins and empties into the left atrium since this blood never went through a capillary bed it was never oxygenated and so provides a small amount of shunted deoxygenated blood into the systemic circulation 28 Cerebral circulationIn the cerebral circulation supplying the cerebrum the venous drainage can be separated into two subdivisions superficial and deep The superficial system is composed of dural venous sinuses which have walls composed of dura mater as opposed to a traditional vein The dural sinuses are therefore located on the surface of the cerebrum The most prominent of these sinuses is the superior sagittal sinus which flows in the sagittal plane under the midline of the cerebral vault posteriorly and inferiorly to the confluence of sinuses where the superficial drainage joins with the sinus that primarily drains the deep venous system From here two transverse sinuses bifurcate and travel laterally and inferiorly in an S shaped curve that forms the sigmoid sinuses which go on to form the two jugular veins In the neck the jugular veins parallel the upward course of the carotid arteries and drain blood into the superior vena cava The deep venous drainage is primarily composed of traditional veins inside the deep structures of the brain which join behind the midbrain to form the vein of Galen This vein merges with the inferior sagittal sinus to form the straight sinus which then joins the superficial venous system mentioned above at the confluence of sinuses Portal venous systemsA portal venous system is a series of veins or venules that directly connect two capillary beds The two systems in verebrates are the hepatic portal system and the hypophyseal portal system AnastomosesAn anastomosis is a joining of two structures such as blood vessels In the circulation these are called circulatory anastomoses one of which is the join between an artery with a vein known as an arteriovenous anastomosis This connection which is highly muscular enables venous blood to travel directly from an artery into a vein without having passed from a capillary bed 19 14 Abnormal connections can be present known as arteriovenous malformations These are usually congenital and the connections are made from a tangle of capillaries 29 A cerebral arteriovenous malformation is one that is located in the brain An irregular connection between an artery and a vein is known as arteriovenous fistula A small specialised arteriovenous anastomosis known as a glomus body or organ serves to transfer heat in the fingers and toes The small connection is surrounded by a capsule of thickened connective tissue In the hands and feet there are a great number of glomera 14 Vascular shuntA vascular shunt can also bypass the capillary bed and provide a route for blood supply directly to a collecting venule This is achieved by a metarteriole that supplies around a hundred capillaries At their junctions are precapillary sphincters that tightly regulate the flow of blood into the capillary bed When all of the sphincters are closed blood can flow from a metarteriole into a thoroughfare channel and into a collecting venule bypassing the capillary bed 21 4 OtherA communicating vein directly connects two parts of the same system such as the Giacomini vein that connects the superficial small saphenous vein with the superficial great saphenous vein Peripheral veins carry blood from the limbs and hands and feet Microanatomy Edit nbsp Diagram of different sized veins with differing component proportionsThe three layers of the vein wall are the outer tunica externa the middle tunica media and the inner tunica intima There are also numerous valves present in many of the veins The outer tunica externa also known as the tunica adventitia is a sheath of thick connective tissue This layer is absent in the post capillary venules 8 The middle tunica media is mainly of vascular smooth muscle cells elastic fibers and collagen This layer is much thinner than that in arteries 30 Vascular smooth muscle cells control the size of the vein lumens and thereby help to regulate blood pressure 31 The inner tunica intima is a lining of endothelium comprising a single layer of extremely flattened epithelial cells supported by delicate connective tissue 8 This subendothelium is a thin but variable connective tissue 4 The tunica intima has the most variation in blood vessels in terms of their wall thickness and relative size of their lumen The endothelial cells continuously produce nitric oxide a soluble gas to the cells of the adjacent smooth muscle layer This constant synthesis is carried out by the enzyme endothelial nitric oxide synthase eNOS 32 Other endothelial secretions are endothelin and thromboxane vasoconstrictors and prostacyclin a vasodilator 9 Development EditThe development of the embryo is completely reliant on the vitelline circulation the bidirectional flow of blood between the yolk sac and the embryo The yolk sac is the first extraembryonic structure to appear This circulation is critical in allowing the exchange of nutrients prior to the full development of the placenta 33 By day 17 vessels begin to form in the yolk sac arising from the splanchnic mesoderm of the yolk sac wall 34 The capillaries are formed during vasculogenesis and they lengthen and interconnect to form an extensive primitive vascular network 35 Blood is supplied from the primitive aorta and drained by vitelline veins from the yolk sac to the embryo By the end of the third week the yolk sac connecting stalk and chorionic villi are entirely vascularised 35 In the middle of the fourth week the heart begins to beat and the circulation of blood begins The primitive outflow tract is of three pairs of aortic arches The inflow tract is formed of six paired veins the vitelline veins umbilical veins and the cardinal veins 36 Function EditMain article Circulatory system In the systemic circulation veins serve to return oxygen depleted blood from organs and tissues to the right heart From here it passes to the pulmonary arteries for the pulmonary circulation to return oxygen rich blood to the left heart in the pulmonary veins to be pumped back into the systemic circulation to complete the cycle Veins have thinner walls than arteries and a wider diameter that allow them to expand and hold a greater volume of blood This gives them a functional role of capacitance that makes possible the accommodation of different pressures in the system The venous system apart from the post capillary venules is a high volume low pressure system Vascular smooth muscle cells control the size of the vein lumens and thereby help to regulate blood pressure 31 The post capillary venules are exchange vessels whose ultra thin walls allow the ready diffusion of molecules from the capillaries 10 The return of blood to the heart is assisted by the action of the muscle pump and by the thoracic pump action of breathing during respiration Standing or sitting for a prolonged period of time can cause low venous return from venous pooling vascular shock Fainting can occur but usually baroreceptors within the aortic sinuses initiate a baroreflex such that angiotensin II and norepinephrine stimulate vasoconstriction and heart rate increases to return blood flow Neurogenic and hypovolaemic shock can also cause fainting In these cases the smooth muscles surrounding the veins become slack and the veins fill with the majority of the blood in the body keeping blood away from the brain and causing unconsciousness Jet pilots wear pressurized suits to help maintain their venous return and blood pressure Clinical significance EditFurther information Vascular surgery Management of venous diseases Most venous diseases involve obstruction such as a thrombus or insufficiency of the valves or both of these 37 20 Other conditions may be due to inflammation or compression Ageing is a major independent risk factor for venous disorders 38 The medical speciality involved with the diagnosis and treatment of venous disorders is known as phlebology also venology and the specialist concerned is a phlebologist 39 There are a number of vascular surgeries and endovascular surgeries carried out by vascular surgeons to treat many venous diseases Venous insufficiency Edit Main article Chronic venous insufficiency Venous insufficiency is the most common disorder of the venous system and is usually manifested as either spider veins or varicose veins Several treatments are available including endovenous thermal ablation using radiofrequency or laser energy vein stripping ambulatory phlebectomy foam sclerotherapy laser or compression Postphlebitic syndrome is venous insufficiency that develops following deep vein thrombosis 40 Venous thrombosis Edit Further information Deep vein thrombosis Venous thrombosis is the formation of a thrombus blood clot in a vein This most commonly affects a deep vein known as deep vein thrombosis DVT but can also affect a superficial vein known as superficial vein thrombosis SVT Deep vein thrombosis Edit DVT usually occurs in the veins of the legs although it can also occur in the deep veins of the arms 41 Immobility active cancer obesity traumatic damage and congenital disorders that make clots more likely are all risk factors for deep vein thrombosis It can cause the affected limb to swell and cause pain and an overlying skin rash In the worst case a deep vein thrombosis can extend or a part of a clot can break off as an embolus and lodge in a pulmonary artery in the lungs known as a pulmonary embolism The decision to treat deep vein thrombosis depends on its size symptoms and their risk factors It generally involves anticoagulation to prevents clots or to reduce the size of the clot Intermittent pneumatic compression is a method used to improve venous circulation in cases of edema or in those at risk from a deep vein thrombosis Superficial vein thrombosis Edit SVT is the development of a thrombus in a superficial vein SVT is not normally clinically significant but the thrombus can migrate into the deep venous system where it can also give rise to a pulmonary embolism 42 The main risk factor for SVT in the lower limbs is varicose veins 42 Portal hypertension Edit The portal vein also known as the hepatic portal vein carries blood drained from most of the gastrointestinal tract to the liver Portal hypertension is mainly caused by cirrhosis of the liver Other causes can include an obstructing clot in a hepatic vein Budd Chiari syndrome or compression from tumors or tuberculosis lesions When the pressure increases in the portal vein a collateral circulation develops causing visible veins such as esophageal varices Phlebitis Edit Phlebitis is the inflammation of a vein It is usually accompanied by a blood clot when it is known as thrombophlebitis When the affected vein is a superficial vein in the leg it is known as superficial thrombophlebitis and unlike deep vein thrombosis there is little risk of the clot breaking off as an embolus 43 Compression Edit Some disorders as syndromes result from compression of a vein These include a venous type of thoracic outlet syndrome due to compression of a subclavian vein nutcracker syndrome most usually due to compression of the left renal vein and May Thurner syndrome associated with compression of the iliac vein which can lead to iliofemoral DVT Compression of the superior vena cava most usually by a malignant tumor can lead to superior vena cava syndrome 44 Vascular anomalies Edit A vascular anomaly can be either a vascular tumor or a birthmark or a vascular malformation 45 In a tumor such as infantile hemangioma the mass is soft and easily compressed and their coloring is due to the dilated anomalous involved veins 46 They are most commonly found in the head and neck Venous malformations are the type of vascular malformation that involves the veins They can often extend deeper from their surface appearance reaching underlying muscle or bone 47 In the neck they may extend into the lining of the mouth cavity or into the salivary glands 46 They are the most common of the vascular malformations 48 A severe venous malformation can involve the lymph vessels as a lymphaticovenous malformation 46 Venous access Edit See also Venipuncture Venous access is any method used to access the bloodstream through the veins either to administer intravenous therapy such as medication or fluid parenteral nutrition to obtain blood for analysis or to provide an access point for blood based treatments such as dialysis or apheresis Access is most commonly achieved via the placement of a central venous catheter a Seldinger technique and guidance tools such as ultrasound and fluoroscopy can also be used to assist with access location Imaging Edit Ultrasound particularly duplex ultrasound is the most usual and widely used way of viewing veins in the diagnosis of venous disease 49 50 Venography is an invasive procedure that uses a catheter to deliver a contrast agent in giving an X ray of veins An augmented reality healthcare application is a near infrared vein finder that films subcutaneous veins and projects their image either onto a screen or onto the person s skin 51 Recognition techniques Edit Some imaging techniques using veins have been developed for identification purposes These vein matching technologies include finger vein recognition 52 and eye vein verification History EditFurther information Circulatory system History The Greek physician Herophilus born 335 BC distinguished veins from arteries noting the thicker walls of arteries but thought that the pulse was a property of arteries themselves Greek anatomist Erasistratus observed that arteries that were cut during life bleed He ascribed the fact to the phenomenon that air escaping from an artery is replaced with blood that entered by very small vessels between veins and arteries Thus he apparently postulated capillaries but with reversed flow of blood 53 In 2nd century AD Rome the Greek physician Galen knew that blood vessels carried blood and identified venous dark red and arterial brighter and thinner blood each with distinct and separate functions Growth and energy were derived from venous blood created in the liver from chyle while arterial blood gave vitality by containing pneuma air and originated in the heart Blood flowed from both creating organs to all parts of the body where it was consumed and there was no return of blood to the heart or liver The heart did not pump blood around the heart s motion sucked blood in during diastole and the blood moved by the pulsation of the arteries themselves nbsp Image of veins from William Harvey s Exercitatio Anatomica de Motu Cordis et Sanguinis in AnimalibusGalen believed that the arterial blood was created by venous blood passing from the left ventricle to the right by passing through pores in the interventricular septum air passed from the lungs via the pulmonary artery to the left side of the heart As the arterial blood was created sooty vapors were created and passed to the lungs also via the pulmonary artery to be exhaled In addition Ibn al Nafis had an insight into what would become a larger theory of the capillary circulation He stated that there must be small communications or pores manafidh in Arabic between the pulmonary artery and vein a prediction that preceded the discovery of the capillary system by more than 400 years 54 Ibn al Nafis theory however was confined to blood transit in the lungs and did not extend to the entire body Finally William Harvey a pupil of Hieronymus Fabricius who had earlier described the valves of the veins without recognizing their function performed a sequence of experiments and published Exercitatio Anatomica de Motu Cordis et Sanguinis in Animalibus in 1628 which demonstrated that there had to be a direct connection between the venous and arterial systems throughout the body and not just the lungs Most importantly he argued that the beat of the heart produced a continuous circulation of blood through minute connections at the extremities of the body This is a conceptual leap that was quite different from Ibn al Nafis refinement of the anatomy and bloodflow in the heart and lungs 55 This work with its essentially correct exposition slowly convinced the medical world However Harvey was not able to identify the capillary system connecting arteries and veins these were later discovered by Marcello Malpighi in 1661 56 See also EditCardiovascular disease Central venous pressure Compliance physiology References Edit a b c Moore HM Gohel M Davies AH October 2011 Number and location of venous valves within the popliteal and femoral veins a review of the literature J Anat 219 4 439 43 doi 10 1111 j 1469 7580 2011 01409 x PMC 3196749 PMID 21740424 Guven G Hilty MP Ince C 2020 Microcirculation Physiology Pathophysiology and Clinical Application Blood Purif 49 1 2 143 150 doi 10 1159 000503775 PMC 7114900 PMID 31851980 a b Classification amp Structure of Blood Vessels SEER Training training seer cancer gov Retrieved 29 January 2023 a b c d e f g h GRAYS 2016 p 131 a b Maton Anthea Jean Hopkins Charles William McLaughlin Alexandra Senckowski Susan Johnson Maryanna Quon Warner David LaHart Jill D Wright 1993 Human Biology and Health Englewood Cliffs New Jersey Prentice Hall ISBN 978 0 13 981176 0 Kienle A Lilge L Vitkin IA Patterson MS Wilson BC Hibst R Steiner R March 1996 Why do veins appear blue A new look at an old question PDF Applied Optics 35 7 1151 Bibcode 1996ApOpt 35 1151K doi 10 1364 AO 35 001151 PMID 21085227 Archived from the original PDF on 10 February 2012 a b Zivadinov Robert Chung Chih Ping 17 December 2013 Potential involvement of the extracranial venous system in central nervous system disorders and aging BMC Medicine 11 260 doi 10 1186 1741 7015 11 260 PMC 3866257 PMID 24344742 a b c d e f Moore Keith L 2018 Clinically oriented anatomy Eighth ed Philadelphia pp 38 41 ISBN 9781496347213 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link a b GRAYS 2016 p 134 a b c d GRAYS 2016 p 130 a b GRAYS 2016 p 127 GRAYS 2016 p 41 a b c Saladin Kenneth S 2011 Human anatomy 3rd ed New York McGraw Hill pp 570 571 ISBN 9780071222075 a b c GRAYS 2016 p 135 Baliyan V Tajmir S Hedgire SS Ganguli S Prabhakar AM December 2016 Lower extremity venous reflux Cardiovasc Diagn Ther 6 6 533 543 doi 10 21037 cdt 2016 11 14 PMC 5220199 PMID 28123974 Albert consultants Daniel 2012 Dorland s illustrated medical dictionary 32nd ed Philadelphia PA Saunders Elsevier p 2042 ISBN 978 1 4160 6257 8 Sureka Binit 15 September 2015 Portal vein variations in 1000 patients surgical and radiological importance British Journal of Radiology 88 1055 1055 doi 10 1259 bjr 20150326 PMC 4743455 PMID 26283261 Radhakrishnan N George D Jayakrishnan R Sumi S Kartha CC December 2018 Vein Size and Disease Severity in Chronic Venous Diseases Int J Angiol 27 4 185 189 doi 10 1055 s 0038 1639355 PMC 6221802 PMID 30410288 a b Hall John E 2011 Guyton and Hall textbook of medical physiology Twelfth ed Philadelphia Pa p 868 ISBN 9781416045748 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link a b c d e Publishing Licorn 9 April 2013 The venous valves of the lower limbs Servier Phlebolymphology Retrieved 11 March 2023 a b 20 1 Structure and Function of Blood Vessels Anatomy and Physiology 2e OpenStax openstax org 20 April 2022 Retrieved 17 March 2023 a b Bazigou E Makinen T March 2013 Flow control in our vessels vascular valves make sure there is no way back Cell Mol Life Sci 70 6 1055 66 doi 10 1007 s00018 012 1110 6 PMC 3578722 PMID 22922986 Rajeeva Pandian NK Jain A 2022 In silico analyses of blood flow and oxygen transport in human micro veins and valves Clin Hemorheol Microcirc 81 1 81 96 doi 10 3233 CH 211345 PMC 9307074 PMID 35034895 Meissner MH September 2005 Lower extremity venous anatomy Semin Intervent Radiol 22 3 147 56 doi 10 1055 s 2005 921948 PMC 3036282 PMID 21326687 Veins Anatomy and Function Cleveland Clinic Retrieved 16 March 2023 Cai Q Ahmad M June 2020 Eustachian valve interatrial shunt and paradoxical embolism Echocardiography 37 6 939 944 doi 10 1111 echo 14682 PMID 32426851 Adams Matt Morgan Matt A et al Coronary veins Radiopaedia org Weinberger Steven E 2019 Principles of pulmonary medicine Seventh ed Philadelphia PA p 178 ISBN 9780323523714 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link AVM PDF Retrieved 5 February 2023 GRAYS 2016 p 132 134 a b Brozovich FV Nicholson CJ Degen CV Gao YZ Aggarwal M Morgan KG April 2016 Mechanisms of Vascular Smooth Muscle Contraction and the Basis for Pharmacologic Treatment of Smooth Muscle Disorders Pharmacol Rev 68 2 476 532 doi 10 1124 pr 115 010652 PMC 4819215 PMID 27037223 Tousoulis D Kampoli AM Tentolouris C Papageorgiou N Stefanadis C January 2012 The role of nitric oxide on endothelial function Curr Vasc Pharmacol 10 1 4 18 doi 10 2174 157016112798829760 PMID 22112350 Donovan Mary F Arbor Tafline C Bordoni Bruno 2023 Embryology Yolk Sac StatPearls StatPearls Publishing PMID 32310425 Retrieved 22 March 2023 Schoenwolf Gary C 2015 Larsen s human embryology Fifth ed Philadelphia PA p 304 ISBN 9781455706846 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link a b Schoenwolf Gary C 2015 Larsen s human embryology Fifth ed Philadelphia PA p 306 ISBN 9781455706846 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link Schoenwolf Gary C 2015 Larsen s human embryology Fifth ed Philadelphia PA p 279 ISBN 9781455706846 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link Goel RR Hardy SC Brown T 30 September 2021 Surgery for deep venous insufficiency The Cochrane Database of Systematic Reviews 2021 9 CD001097 doi 10 1002 14651858 CD001097 pub4 PMC 8483065 PMID 34591328 Molnar AA Nadasy GL Dornyei G Patai BB Delfavero J Fulop GA Kirkpatrick AC Ungvari Z Merkely B December 2021 The aging venous system from varicosities to vascular cognitive impairment Geroscience 43 6 2761 2784 doi 10 1007 s11357 021 00475 2 PMC 8602591 PMID 34762274 Phlebology Retrieved 9 January 2023 Kahn SR August 2006 The post thrombotic syndrome progress and pitfalls British Journal of Haematology 134 4 357 65 doi 10 1111 j 1365 2141 2006 06200 x PMID 16822286 S2CID 19715556 Heil J Miesbach W Vogl T Bechstein WO Reinisch A 7 April 2017 Deep Vein Thrombosis of the Upper Extremity Deutsches Arzteblatt International 114 14 244 249 doi 10 3238 arztebl 2017 0244 PMC 5415909 PMID 28446351 a b Cosmi B July 2015 Management of superficial vein thrombosis Journal of Thrombosis and Haemostasis 13 7 1175 1183 doi 10 1111 jth 12986 PMID 25903684 S2CID 5276848 Di Nisio M Wichers IM Middeldorp S February 2018 Treatment for superficial thrombophlebitis of the leg Cochrane Database Syst Rev 2018 2 CD004982 doi 10 1002 14651858 CD004982 pub6 PMC 6953389 PMID 29478266 Nickloes TA Lopez Rowe V Kallab AM Dunlap AB 8 March 2022 Superior Vena Cava Syndrome Medscape WebMD LLC Retrieved 13 March 2023 Steiner JE Drolet BA September 2017 Classification of Vascular Anomalies An Update Seminars in Interventional Radiology 34 3 225 232 doi 10 1055 s 0037 1604295 PMC 5615389 PMID 28955111 a b c Chim H Drolet B Duffy K Koshima I Gosain AK August 2010 Vascular anomalies and lymphedema Plastic and Reconstructive Surgery 126 2 55e 69e doi 10 1097 PRS 0b013e3181df803d PMID 20679788 S2CID 30865392 Chen RJ Vrazas JI Penington AJ January 2021 Surgical Management of Intramuscular Venous Malformations Journal of Pediatric Orthopedics 41 1 e67 e73 doi 10 1097 BPO 0000000000001667 PMID 32815867 S2CID 221199574 Markovic JN Shortell CK October 2021 Venous malformations The Journal of Cardiovascular Surgery 62 5 456 466 doi 10 23736 S0021 9509 21 11911 1 PMID 34105926 S2CID 261366559 Lee DK Ahn KS Kang CH Cho SB April 2017 Ultrasonography of the lower extremity veins anatomy and basic approach Ultrasonography 36 2 120 130 doi 10 14366 usg 17001 PMC 5381851 PMID 28260355 Garcia R Labropoulos N April 2018 Duplex Ultrasound for the Diagnosis of Acute and Chronic Venous Diseases Surg Clin North Am 98 2 201 218 doi 10 1016 j suc 2017 11 007 PMID 29502767 Miyake RK et al 2006 Vein imaging a new method of near infrared imaging where a processed image is projected onto the skin for the enhancement of vein treatment Dermatol Surg 32 8 1031 8 doi 10 1111 j 1524 4725 2006 32226 x PMID 16918565 S2CID 8872471 Zhang Z Wang M March 2022 A Simple and Efficient Method for Finger Vein Recognition Sensors 22 6 2234 Bibcode 2022Senso 22 2234Z doi 10 3390 s22062234 PMC 8949429 PMID 35336406 Anatomy History of anatomy Scienceclarified com Retrieved 2013 09 15 West J B 2008 Ibn al Nafis the pulmonary circulation and the Islamic Golden Age Journal of Applied Physiology 105 6 1877 1880 doi 10 1152 japplphysiol 91171 2008 PMC 2612469 PMID 18845773 Pormann Peter E and Smith E Savage 2007 Medieval Islamic medicine Georgetown University Washington DC p 48 ISBN 1589011619 Romero Reveron Rafael June 2011 Marcello Malpighi 1628 1694 Founder of Microanatomy International Journal of Morphology 29 2 399 402 doi 10 4067 S0717 95022011000200015 Retrieved 8 February 2023 Bibliography EditStandring Susan ed 2016 Gray s Anatomy The Anatomical Basis of Clinical Practice Forty first ed Philadelphia Churchill Livingstone ISBN 978 0 7020 5230 9 Further reading EditShoja M M Tubbs R S Loukas M Khalili M Alakbarli F Cohen Gadol A A 2009 Vasovagal syncope in the Canon of Avicenna The first mention of carotid artery hypersensitivity International Journal of Cardiology 134 3 297 301 doi 10 1016 j ijcard 2009 02 035 PMID 19332359 External links Edit nbsp Look up vein in Wiktionary the free dictionary Merck Manual article on veins A lecture on YouTube on the veins and lymphatic systems of the upper limb Retrieved from https en wikipedia org w index php title Vein amp oldid 1177568434, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.