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==Parts==
==Parts==
[[File:Relations of the aorta, trachea, esophagus and other heart structures.png|thumb|right|250px| Course of the aorta in the thorax (anterior view), starting posterior to the [[main pulmonary artery]], then anterior to the right [[pulmonary arteries]], the [[human trachea|trachea]] and the [[esophagus]], then turning posteriorly to course dorsally to these structures.]]
[[File:Relations of the aorta, trachea, esophagus and other heart structures.png|thumb|right|250px| Course of the aorta in the thorax (anterior view), starting posterior to the [[main pulmonary artery]], then anterior to the right [[pulmonary arteries]], the [[human trachea|trachea]] and the [[esophagus]], then turning posteriorly to course dorsally to these structures.]]
In anatomical sources, the aorta is usually divided into sections. <ref>Tortora, Gerard J: "Principles of Human W. & Karen A. Koos: ''Human Anatomy, second edition'', page 479. Wm. C. Brown Publishing, 1994. (ISBN 0-697-12252-2)</ref><ref>De Graaff, Van: "Human Anatomy, fifth edition", pages 548-549. WCB McGraw-Hill, 1998. (ISBN 0-697-28413-1)</ref>
In anatomical sources, the aorta is usually divided into sections. <ref>Tortora, Gerard J: "Principles of Human W. & Karen A. Koos: ''Human Anatomy, second edition'', page 479. Wm. C. Brown Publishing, 1994. ({{ISBN|0-697-12252-2}})</ref><ref>De Graaff, Van: "Human Anatomy, fifth edition", pages 548-549. WCB McGraw-Hill, 1998. ({{ISBN|0-697-28413-1}})</ref>


One way of classifying a part of the aorta is by ''course and the direction of blood flow''. In this system, the aorta starts as the ''[[ascending aorta]]'' (or ascending part of the aorta), taking a [[Anatomical terms of location#Superior and inferior|superior]] course from the heart, but then making a hairpin turn, the ''[[aortic arch]]'' or arch of aorta. The part after this hairpin turn takes an [[Anatomical terms of location#Superior and inferior|inferior]] course and is known as the ''descending aorta''. The descending aorta is divided into two parts. The aorta begins to descend in the thoraic cavity, and consequently is known as the ''thoracic aorta''. After the aorta passes through the [[Thoracic diaphragm|diaphragm]], it is known as the ''abdominal aorta''. The aorta ends by dividing into two major blood vessels, the [[common iliac artery|common iliac arteries]] and a smaller midline vessel, the [[median sacral artery]].
One way of classifying a part of the aorta is by ''course and the direction of blood flow''. In this system, the aorta starts as the ''[[ascending aorta]]'' (or ascending part of the aorta), taking a [[Anatomical terms of location#Superior and inferior|superior]] course from the heart, but then making a hairpin turn, the ''[[aortic arch]]'' or arch of aorta. The part after this hairpin turn takes an [[Anatomical terms of location#Superior and inferior|inferior]] course and is known as the ''descending aorta''. The descending aorta is divided into two parts. The aorta begins to descend in the thoraic cavity, and consequently is known as the ''thoracic aorta''. After the aorta passes through the [[Thoracic diaphragm|diaphragm]], it is known as the ''abdominal aorta''. The aorta ends by dividing into two major blood vessels, the [[common iliac artery|common iliac arteries]] and a smaller midline vessel, the [[median sacral artery]].
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==Histology==
==Histology==
[[File:An opened aorta.jpg|thumb|250px|left|<center>A pig's aorta cut open showing also some leaving arteries.</center>]]
[[File:An opened aorta.jpg|thumb|250px|left|<center>A pig's aorta cut open showing also some leaving arteries.</center>]]
The aorta is an [[elastic artery]], and as such is quite stretchable. This is needed because [[blood pressure|Mean arterial blood pressure]] is the highest in the aorta due to it being the first artery where blood flows out from the heart. When the left ventricle contracts to force blood into the aorta, the aorta expands. This stretching gives the potential energy that will help maintain blood pressure during [[diastole]], as during this time the aorta contracts passively. This is called the [[Windkessel effect]]. Mean arterial pressure diminishes across the circulation; from aorta to [[arteries]] to [[arterioles]] to [[capillaries]] to [[veins]] back to the atrium.<ref>Nichols WW, O'Rourke MF. McDonald's Blood Flow in Arteries: Theoretical, Experimental and Clinical Principles. 4th ed. London, UK: Edward Arnold; 1998</ref>

The aorta consists of a heterogeneous mixture of [[smooth muscle]], nerves, intimal cells, endothelial cells, fibroblast-like cells, and a complex extracellular matrix. The vascular wall consists of several layers known as the [[tunica adventitia]], [[tunica media]], and [[tunica intima]]. The thickness of the aorta encourages an extensive network of tiny blood vessels called [[vasa vasorum]], which feed the outer layers of the aorta. The aortic arch contains [[baroreceptors]] and [[chemoreceptors]] that relay information concerning blood pressure, blood pH and carbon dioxide levels to the medulla oblongata of the brain. This information is processed by the brain and the [[autonomic nervous system]] mediates the homeostatic responses.
The aorta consists of a heterogeneous mixture of [[smooth muscle]], nerves, intimal cells, endothelial cells, fibroblast-like cells, and a complex extracellular matrix. The vascular wall consists of several layers known as the [[tunica adventitia]], [[tunica media]], and [[tunica intima]]. The thickness of the aorta encourages an extensive network of tiny blood vessels called [[vasa vasorum]], which feed the outer layers of the aorta. The aortic arch contains [[baroreceptors]] and [[chemoreceptors]] that relay information concerning blood pressure, blood pH and carbon dioxide levels to the medulla oblongata of the brain. This information is processed by the brain and the [[autonomic nervous system]] mediates the homeostatic responses.


Within the ''tunica media'', smooth muscle and the extracellular matrix are quantitatively the largest components of the aortic vascular wall. This layer of the aorta consist of concentric musculoelastic layers (the elastic lamella) in mammals. The smooth muscle component does not dramatically alter the diameter of the aorta but rather serves to increase the stiffness and viscoelasticity of the aortic wall when activated. The elastic matrix dominates the biomechanical properties of the aorta. The elastic matrix forms lamella, consisting of [[elastic fibers]], [[collagens]](predominately type III), [[proteoglycans]], and [[glycoaminoglycans]].
Within the ''tunica media'', smooth muscle and the extracellular matrix are quantitatively the largest components of the aortic vascular wall. This layer of the aorta consist of concentric musculoelastic layers (the elastic lamella) in mammals. The smooth muscle component does not dramatically alter the diameter of the aorta but rather serves to increase the stiffness and viscoelasticity of the aortic wall when activated. The elastic matrix dominates the biomechanical properties of the aorta. The elastic matrix forms lamella, consisting of [[elastic fibers]], [[collagens]](predominately type III), [[proteoglycans]], and [[glycoaminoglycans]].

'''NEEDS TO BE PUT UNDER FUNCTION'''

The aorta is an [[elastic artery]], and as such is quite stretchable. This is needed because [[blood pressure|Mean arterial blood pressure]] is the highest in the aorta due to it being the first artery where blood flows out from the heart. When the left ventricle contracts to force blood into the aorta, the aorta expands. This stretching gives the potential energy that will help maintain blood pressure during [[diastole]], as during this time the aorta contracts passively. This is called the [[Windkessel effect]]. Mean arterial pressure diminishes across the circulation; from aorta to [[arteries]] to [[arterioles]] to [[capillaries]] to [[veins]] back to the atrium.<ref>Nichols WW, O'Rourke MF. McDonald's Blood Flow in Arteries: Theoretical, Experimental and Clinical Principles. 4th ed. London, UK: Edward Arnold; 1998</ref>

'''TILL HERE'''


==Variations==
==Variations==
Line 168: Line 160:


===Blood flow and velocity===
===Blood flow and velocity===
The [[Pulsatile flow|pulsatile]] nature of blood flow creates a pulse wave that is propagated down the [[arterial tree]], and at [[Aortic bifurcation|bifurcations]] reflected waves rebound to return to semilunar valves and the origin of the aorta. These return waves create the [[Dicrotic_notch#Ventricular_systole|dicrotic notch]] displayed in the aortic pressure curve during the [[cardiac cycle]] as these reflected waves push on the [[heart valve|aortic semilunar valve]].<ref name="sestta">{{cite book |last1=Seeley |first1=Rod |last2=Stephens |first2=Trent |coauthors=Philip Tate |editor1-first=Deborah |editor1-last=Allen |title=Anatomy and physiology |format= |edition=2 |year=1992 |publisher=Mosby-Year Book, Inc |isbn=0-8016-4832-7 |page=631 |chapter=20}}</ref> With age, the aorta stiffens such that the pulse wave is propagated faster and reflected waves return to the heart faster before the semilunar valve closes, which raises the blood pressure. The stiffness of the aorta is associated with a number of diseases and pathologies, and noninvasive measures of the pulse wave [[Aorta#Blood_flow_and_velocity|velocity]] are an independent indicator of [[hypertension]]. Measuring the pulse wave velocity (invasively and non-invasively) is a means of determining [[arterial stiffness]]. Maximum aortic velocity may be noted as '''V<sub>max</sub>''' or less commonly as '''AoV<sub>max</sub>'''.
The aorta is an [[elastic artery]], and as such is quite stretchable. This is needed because [[blood pressure|Mean arterial blood pressure]] is the highest in the aorta. When the left ventricle contracts to force blood into the aorta, the aorta expands. This stretching gives the potential energy that will help maintain blood pressure during [[diastole]], as during this time the aorta contracts passively. This is called the [[Windkessel effect]]. Mean arterial pressure diminishes across the circulation; from aorta to [[arteries]] to [[arterioles]] to [[capillaries]] to [[veins]] back to the atrium.<ref>Nichols WW, O'Rourke MF. McDonald's Blood Flow in Arteries: Theoretical, Experimental and Clinical Principles. 4th ed. London, UK: Edward Arnold; 1998</ref>
The [[Pulsatile flow|pulsatile]] nature of blood flow (caused by a beat of the heart) also creates a pulse wave that is propagated down the [[arterial tree]]. At the [[Aortic bifurcation|bifurcations]] reflected waves rebound to return to semilunar valves at the heart. These return waves create the [[Dicrotic_notch#Ventricular_systole|dicrotic notch]] displayed in the aortic pressure curve during the [[cardiac cycle]] as these reflected waves push on the [[heart valve|aortic semilunar valve]].<ref name="sestta">{{cite book |last1=Seeley |first1=Rod |last2=Stephens |first2=Trent |coauthors=Philip Tate |editor1-first=Deborah |editor1-last=Allen |title=Anatomy and physiology |format= |edition=2 |year=1992 |publisher=Mosby-Year Book, Inc |isbn=0-8016-4832-7 |page=631 |chapter=20}}</ref> With age, the aorta stiffens such that the pulse wave is propagated faster and reflected waves return to the heart faster before the semilunar valve closes, which raises the blood pressure. The stiffness of the aorta is associated with a number of diseases and pathologies, and noninvasive measures of the pulse wave [[Aorta#Blood_flow_and_velocity|velocity]] are an independent indicator of [[hypertension]]. Measuring the pulse wave velocity (invasively and non-invasively) is a means of determining [[arterial stiffness]]. Maximum aortic velocity may be noted as '''V<sub>max</sub>''' or less commonly as '''AoV<sub>max</sub>'''.


==Clinical relevance==
==Clinical relevance==
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==History==
==History==
The word 'Aorta' stems from the [[Late Latin]] ''{{lang-la|aorta}}'' from ''aortē'' ({{lang-el|ἀορτή}}), from ''aeirō'', "I lift, raise" ({{lang-el|ἀείρω}})<ref>Illustrated Steadman's Dictionary, 24th ed.</ref> This term was first applied by Aristotle when describing the aorta.<ref>{{cite web|last=Harper|first=Douglas|title=Aorta|url=http://www.etymonline.com/index.php?term=aorta|work=Online Etymology Dictionary|accessdate=5 January 2014}}</ref>
The word 'Aorta' stems from the [[Late Latin]] ''{{langx|la|aorta}}'' from ''aortē'' ({{langx|el|ἀορτή}}), from ''aeirō'', "I lift, raise" ({{langx|el|ἀείρω}})<ref>Illustrated Steadman's Dictionary, 24th ed.</ref> This term was first applied by Aristotle when describing the aorta.<ref>{{cite web|last=Harper|first=Douglas|title=Aorta|url=http://www.etymonline.com/index.php?term=aorta|work=Online Etymology Dictionary|accessdate=5 January 2014}}</ref>


==See also==
==See also==
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{{wiktionary}}
{{wiktionary}}
{{Commons category}}
{{Commons category}}
* {{GraySubject|153}} - Descending aorta
* {{GraySubject|154}} - Abdominal aorta


{{Cardiovascular system}}
{{Cardiovascular system}}

Latest revision as of 12:18, 31 October 2024

Aorta
Schematic view of the aorta and a number of its most important branches
Details
PrecursorTruncus arteriosus

Fourth left branchial artery

Paired dorsal aortae (combine into the single descending aorta)
SourceLeft ventricle
BranchesAscending aorta:
Right and left coronary arteries.

Arch of aorta (supra-aortic vessels):

Brachiocephalic trunk
Left common carotid artery
Left subclavian artery

Descending aorta, thoracic part:

Left bronchial arteries
Oesophageal arteries to the thoracic part of the Oesophagus
Third to eleventh Posterior intercostal arteries, and the Subcostal arteries

Descending aorta, abdominal part:

Parietal branches:
Inferior phrenic arteries
Lumbar arteries
Median sacral artery
Visceral branches:
Celiac trunk
Middle suprarenal arteries
Superior mesenteric artery
Renal arteries
Gonadal arteries testicular in males, ovarian in females
Inferior mesenteric artery

Terminal branches:

Common iliac arteries
Median sacral artery
VeinCombination of coronary sinus, superior vena cava and inferior vena cava
SuppliesThe systemic circulation
(entire body with exception of the respiratory zone of the lung which is supplied by the pulmonary circulation)
Identifiers
LatinAorta, arteria maxima
Anatomical terminology

The aorta (/ˈɔːrtə/) is the largest artery in the human body, it receives all the oxygen-rich blood that is pumped from the left chamber (or ventricle) of the heart and extends down to the abdomen. From the aorta blood is distributed to every organ, with the exception of the lungs. Just like a big river with tributaries, the aorta splits multiple times. [1] [2]

Parts

[edit]
Course of the aorta in the thorax (anterior view), starting posterior to the main pulmonary artery, then anterior to the right pulmonary arteries, the trachea and the esophagus, then turning posteriorly to course dorsally to these structures.

In anatomical sources, the aorta is usually divided into sections. [3][4]

One way of classifying a part of the aorta is by course and the direction of blood flow. In this system, the aorta starts as the ascending aorta (or ascending part of the aorta), taking a superior course from the heart, but then making a hairpin turn, the aortic arch or arch of aorta. The part after this hairpin turn takes an inferior course and is known as the descending aorta. The descending aorta is divided into two parts. The aorta begins to descend in the thoraic cavity, and consequently is known as the thoracic aorta. After the aorta passes through the diaphragm, it is known as the abdominal aorta. The aorta ends by dividing into two major blood vessels, the common iliac arteries and a smaller midline vessel, the median sacral artery.

Another way of classifying a part of the aorta is by anatomical compartment, where the thoracic aorta (or thoracic part of the aorta) runs from the heart to the thoracic diaphragm. The aorta then continues as the abdominal aorta (or abdominal part of the aorta) diaphragm to the aortic bifurcation. [5]: 18 

In the next section the course and the direction of blood flow method is used.

Ascending aorta

[edit]

The ascending aorta originates at the opening of the aortic valve at the heart. It runs in a common pericardial sheath with the pulmonary trunk. These two blood vessels twist around each other, causing the aorta to start out posterior to the pulmonary trunk, but ends by twisting to its right and anterior side. [6] : 191, 204  The transition from ascending aorta to aortic arch is at the pericardial reflection on the aorta. [7]: Plate 211 

At the root of the ascending aorta, the lumen has three little pockets between the cusps of the aortic valve and the wall of the aorta, named the aortic sinuses or sinuses of Valsalva. The left aortic sinus contains the origin of the left coronary artery and the right aortic sinus likewise gives rise to the right coronary artery. Together, these two arteries supply the heart. The posterior aortic sinus does not give rise to a coronary artery. For this reason the left, right and posterior aortic sinuses are also called left-coronary, right-coronary and non-coronary sinuses.[6]: 191 

Aortic arch

[edit]

The aortic arch loops over the right pulmonary artery and the bifurcation of the pulmonary trunk, with which it remains connected by the ligamentum arteriosum, a remnant of the fetal circulation that is obliterated a few days after birth. In addition to these blood vessels, the aortic arch crosses the left main bronchus. Between it and the pulmonary trunk is a network of autonomic nerve fibers, the cardiac or aortic plexus. The left vagus nerve, which passes anterior to the aortic arch, gives off a major branch, the recurrent laryngeal nerve, which loops under the aortic arch just lateral to the ligamentum arteriosum. It then runs back to the neck.

The aortic arch has three major branches: from proximal to distal they are the brachiocephalic trunk, which supplies the right side of the head and neck, as well as the right arm and chest wall, the left common carotid artery, and the left subclavian artery. The latter two together supply the left side of the same regions.

At the level of the intervertebral disc between the fourth and fifth thoracic vertebrae, the aortic arch ends and the descending aorta starts.[6]: 209 

Descending aorta

[edit]

The descending aorta is split up into two parts, the thoracic descending aorta and the abdominal aorta.

Thoracic descending aorta

[edit]

The thoracic descending aorta gives rise to the intercostal and subcostal arteries, as well as to the superior and inferior left bronchial arteries and variable branches to the oesophagus, mediastinum, and pericardium. Its lowest pair of branches are the superior phrenic arteries, which supply the diaphragm, and the subcostal arteries for the twelfth rib. [8]: 195 

Abdominal aorta

[edit]

The abdominal aorta gives rise to lumbar and musculophrenic arteries, renal and middle suprarenal arteries, and visceral arteries (the celiac trunk, the superior mesenteric artery and the inferior mesenteric artery). It ends in a bifurcation into the left and right common iliac arteries. At the point of the bifurcation, there also springs a smaller branch, the median sacral artery.[8]: 331 

Development

[edit]

At the start of embryological development in mammals and birds, the aorta is split up into multiple arteries called aortic arches. There are 6 aortic arches to start with, but after development only the third, the fourth and the sixth survive. The third aortic arch vessel persists as the brachiocephalic artery (also called the root of the internal carotid). The fourth aortic arch vessel becomes the arch of the aorta and the sixth arch contributes to the pulmonary arteries. All great arteries, including the aorta, are made out of smooth muscle cells. Usually the muscle cells are derived from the mesoderm, but these muscle cells are formed by Cardiac Neural Crest Cells (CNCCs). These CNCCs are temporary multipotent (can give rise to some other types of cells but not all) cells that are pinched off during the formation of the neural tube (precursor to the spinal cord and brain) that have migrated to the aortic arches. These cells also form the aorticopulmonary septum which separates the aorta and pulmonary artery. A failure of the aorticopulmonary septum to divide the great vessels results in persistent truncus arteriosus, a heart condition where the two chambers are connected.

Histology

[edit]
A pig's aorta cut open showing also some leaving arteries.

The aorta consists of a heterogeneous mixture of smooth muscle, nerves, intimal cells, endothelial cells, fibroblast-like cells, and a complex extracellular matrix. The vascular wall consists of several layers known as the tunica adventitia, tunica media, and tunica intima. The thickness of the aorta encourages an extensive network of tiny blood vessels called vasa vasorum, which feed the outer layers of the aorta. The aortic arch contains baroreceptors and chemoreceptors that relay information concerning blood pressure, blood pH and carbon dioxide levels to the medulla oblongata of the brain. This information is processed by the brain and the autonomic nervous system mediates the homeostatic responses.

Within the tunica media, smooth muscle and the extracellular matrix are quantitatively the largest components of the aortic vascular wall. This layer of the aorta consist of concentric musculoelastic layers (the elastic lamella) in mammals. The smooth muscle component does not dramatically alter the diameter of the aorta but rather serves to increase the stiffness and viscoelasticity of the aortic wall when activated. The elastic matrix dominates the biomechanical properties of the aorta. The elastic matrix forms lamella, consisting of elastic fibers, collagens(predominately type III), proteoglycans, and glycoaminoglycans.

Variations

[edit]

Variations may occur in the location of the aorta, and the way in which arteries branch off the aorta. The aorta, normally on the left side of the body, may be found on the right in dextrocardia, in which the heart is found on the right, or situs inversus, in which the location of all organs are flipped.[8]: 188 

Variations in the branching of individual arteries may also occur. For example, the left vertebral artery may arise from the aorta, instead of the left common carotid.[8]: 188 

Function

[edit]
Major Aorta anatomy displaying Ascending Aorta, Brachiocephalic trunk, Left Common Carotid Artery, Left Subclavian Artery, Aortic Isthmus, Aortic Arch and Descending Thoracic Aorta

The aorta supplies all of the systemic circulation, which means that the entire body, except for the respiratory zone of the lung gets its blood from the aorta. Broadly speaking, branches from the ascending aorta supply the heart, branches from the aortic arch supply the head, neck and arms, branches from the thoracic descending aorta supply the chest (excluding the heart and the respiratory zone of the lung) and branches from the abdominal aorta supply the abdomen. The pelvis and legs get their blood from the common iliac arteries.

Blood flow and velocity

[edit]

The aorta is an elastic artery, and as such is quite stretchable. This is needed because Mean arterial blood pressure is the highest in the aorta. When the left ventricle contracts to force blood into the aorta, the aorta expands. This stretching gives the potential energy that will help maintain blood pressure during diastole, as during this time the aorta contracts passively. This is called the Windkessel effect. Mean arterial pressure diminishes across the circulation; from aorta to arteries to arterioles to capillaries to veins back to the atrium.[9] The pulsatile nature of blood flow (caused by a beat of the heart) also creates a pulse wave that is propagated down the arterial tree. At the bifurcations reflected waves rebound to return to semilunar valves at the heart. These return waves create the dicrotic notch displayed in the aortic pressure curve during the cardiac cycle as these reflected waves push on the aortic semilunar valve.[10] With age, the aorta stiffens such that the pulse wave is propagated faster and reflected waves return to the heart faster before the semilunar valve closes, which raises the blood pressure. The stiffness of the aorta is associated with a number of diseases and pathologies, and noninvasive measures of the pulse wave velocity are an independent indicator of hypertension. Measuring the pulse wave velocity (invasively and non-invasively) is a means of determining arterial stiffness. Maximum aortic velocity may be noted as Vmax or less commonly as AoVmax.

Clinical relevance

[edit]

In other animals

[edit]

All amniotes have a broadly similar arrangement to that of humans, albeit with a number of individual variations. In fish, however, there are two separate vessels referred to as aortas. The ventral aorta carries de-oxygenated blood from the heart to the gills; part of this vessel forms the ascending aorta in tetrapods (the remainder forms the pulmonary artery). A second, dorsal aorta carries oxygenated blood from the gills to the rest of the body, and is homologous with the descending aorta of tetrapods. The two aortas are connected by a number of vessels, one passing through each of the gills. Amphibians also retain the fifth connecting vessel, so that the aorta has two parallel arches.[13]

History

[edit]

The word 'Aorta' stems from the Late Latin Latin: aorta from aortē (Greek: ἀορτή), from aeirō, "I lift, raise" (Greek: ἀείρω)[14] This term was first applied by Aristotle when describing the aorta.[15]

See also

[edit]

References

[edit]
  1. ^ Maton, Anthea; Jean Hopkins; Charles William McLaughlin; Susan Johnson; Maryanna Quon Warner; David LaHart; Jill D. Wright (1995). Human Biology Health. Englewood Cliffs, New Jersey: Prentice Hall. ISBN 0-13-981176-1.
  2. ^ Drs. A.M.M. van den Eerenbeemt (2000). Merck Manual - Medisch Handboek. Het spoor 2, Houten: Bohn Stafleu van Loghem. ISBN 90-313-3069-8.{{cite book}}: CS1 maint: location (link)
  3. ^ Tortora, Gerard J: "Principles of Human W. & Karen A. Koos: Human Anatomy, second edition, page 479. Wm. C. Brown Publishing, 1994. (ISBN 0-697-12252-2)
  4. ^ De Graaff, Van: "Human Anatomy, fifth edition", pages 548-549. WCB McGraw-Hill, 1998. (ISBN 0-697-28413-1)
  5. ^ Putz, R.; Pabst, R., eds. (2006). Atlas van de menselijke anatomie (in Dutch and translated from German (Atlas der Anatomie des Menschen)) (3rd ed.). Bohn Stafleu van Loghum. ISBN 90-313-4712-4.{{cite book}}: CS1 maint: unrecognized language (link)
  6. ^ a b c Drake, Richard L.; Vogl, Wayn A.; Mitchell, Adam W. M. (2010). Gray's Anatomy for Students (2nd ed.). Churchill Livingstone (Elsevier). ISBN 978-0-443-06952-9.
  7. ^ Netter, Frank H. (2003). Atlas of Human Anatomy (3rd ed.). ICON Learning Systems. ISBN 1-929007-21-3.
  8. ^ a b c d Drake, Richard L. (2005). Gray's anatomy for students. Philadelphia: Elsevier/Churchill Livingstone. ISBN 978-0-8089-2306-0. {{cite book}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  9. ^ Nichols WW, O'Rourke MF. McDonald's Blood Flow in Arteries: Theoretical, Experimental and Clinical Principles. 4th ed. London, UK: Edward Arnold; 1998
  10. ^ Seeley, Rod; Stephens, Trent (1992). "20". In Allen, Deborah (ed.). Anatomy and physiology (2 ed.). Mosby-Year Book, Inc. p. 631. ISBN 0-8016-4832-7. {{cite book}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  11. ^ Samett EJ. http://www.emedicine.com/radio/topic44.htm Aorta, Trauma. eMedicine.com. Accessed on: April 24, 2007.
  12. ^ Tambyraja, A; Scollay, JM; Beard, D; Henry, JM; Murie, JA; Chalmers, RT (2006). "Aortic Trauma in Scotland - A Population Based Study". European Journal of Vascular and Endovascular Surgery. 32 (6): 686–689. doi:10.1016/j.ejvs.2006.04.006. PMID 16750920.
  13. ^ Romer, Alfred Sherwood; Parsons, Thomas S. (1977). The Vertebrate Body. Philadelphia, PA: Holt-Saunders International. pp. 419–421. ISBN 0-03-910284-X.
  14. ^ Illustrated Steadman's Dictionary, 24th ed.
  15. ^ Harper, Douglas. "Aorta". Online Etymology Dictionary. Retrieved 5 January 2014.
[edit]

Category:Arteries of the thorax Category:Arteries of the abdomen