Lymph heart

Last updated August 25, 2024

A lymph heart is an organ which pumps lymph in lungfishes, amphibians, reptiles, and flightless birds back into the circulatory system.^[1]^[2] In some amphibian species, lymph hearts are in pairs, and may number as many as 200 in one animal the size of a worm, while newts and salamanders have as many as 16 to 23 pairs of lymph hearts.^[2]^[3]

In frogs and other amphibians

The lymphatic system of a frog consists of lymph, lymph vessels, lymph heart, lymph spaces and spleen.

Lymphatics and lymph

As lymph is a filtrate of blood, it closely resembles the plasma in its water content. Lymph also contains a small amount of metabolic waste and a much smaller amount of protein than that of blood. Lymph vessels carry the lymph and, in the frog, open into the four lymph hearts. These lymph hearts are located on the dorsal side of frog's body. The front pair is situated below the shoulder blades. The posterior pair is on either side of a long, rod-like bone called a urostyle, formed by the fusion of the last few vertebrae. The anterior pair opens into the subclavian vein and the posterior pair into the femoral vein. The pair near the third vertebra pumps lymph into the jugular vein. The other pair at the end of the vertebral column pump lymph into the iliac vein in the legs.

The position of mammalian jugular lymph sacs coincide with that of amphibian anterior lymph hearts.^[2]

Mechanism of the lymph hearts

The lymph hearts rhythmically and slowly pump to drive the lymph into the veins.^[2] It is possible to see the lymph hearts beat by looking on the dorsal surface on either side of the urostyle. In the toad, the normal lymph heart rate is about 50 beats per minute. Thus the lymph emerging out of blood ultimately merges into the blood. It returns the proteins back to blood.

Amphibian lymph hearts are made up from three tissue layers analogous to the three layers of blood vessels. There are the tunica interna intima made up of endothelial cells, tunica media made up of muscle, and the tunica externa for anchor to organs. The MyoD-expressing muscle is developmentally more similar to skeletal muscle than to heart muscle.^[2]

In fish

There was great debate as to whether teleost fish have a lymphatic system. Current evidence shows that they likely have a "primitive" version. They do not seem to have lymph hearts, instead using blood pressure to move lymph.^[2]

Lungfish, which are more related to tetrapods, use many "micropumps" to move lymph around, reaching densities as high as 100 per cubic millimeter in the fins of South American lungfish.^[2]

In reptiles and birds

Lymph heart size and pump rate

These hearts vary in size from microscopic in lungfish to an estimated 20-liter capacity in some of the largest dinosaurs.^{[ citation needed ]} In newts, frogs and turtles they pump at rates higher than the blood heart and the volumes pumped are quite remarkable.^[1]^[3] In toads and frogs, this volume can amount to about 1/50 the output of blood from the heart. In amphibians, lymph hearts lie at vein junctions. Frogs and salamanders have 10 to 20 lymph hearts, while caecilians have more than 100. Conversely, reptiles have single pair of lymph hearts in the pelvic area.^{[ citation needed ]} In flightless (ratite) birds, the lymph heart function is less clear and the two almond-sized hearts located near the spinal column close to the hip joint are thought^{[ by whom? ]} to be involved in inflating and deflating the phallus with lymph, which is of a significant size in both sexes of emus and ostriches.^{[ clarification needed ]}^{[ citation needed ]}

Related Research Articles

Veins are blood vessels in the circulatory system of humans and most other animals that carry blood towards 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.

The circulatory system is a system of organs that includes the heart, blood vessels, and blood which is circulated throughout the entire body of a human or other vertebrate. It includes the cardiovascular system, or vascular system, that consists of the heart and blood vessels. The circulatory system has two divisions, a systemic circulation or circuit, and a pulmonary circulation or circuit. Some sources use the terms cardiovascular system and vascular system interchangeably with circulatory system.

The lymphatic system, or lymphoid system, is an organ system in vertebrates that is part of the immune system, and complementary to the circulatory system. It consists of a large network of lymphatic vessels, lymph nodes, lymphoid organs, lymphatic tissue and lymph. Lymph is a clear fluid carried by the lymphatic vessels back to the heart for re-circulation. The Latin word for lymph, lympha, refers to the deity of fresh water, "Lympha".

Articles related to anatomy include:

In human anatomy, the thoracic duct is the larger of the two lymph ducts of the lymphatic system. The thoracic duct usually begins from the upper aspect of the cisterna chyli, passing out of the abdomen through the aortic hiatus into first the posterior mediastinum and then the superior mediastinum, extending as high up as the root of the neck before descending to drain into the systemic (blood) circulation at the venous angle.

Lymph is the fluid that flows through the lymphatic system, a system composed of lymph vessels (channels) and intervening lymph nodes whose function, like the venous system, is to return fluid from the tissues to be recirculated. At the origin of the fluid-return process, interstitial fluid—the fluid between the cells in all body tissues—enters the lymph capillaries. This lymphatic fluid is then transported via progressively larger lymphatic vessels through lymph nodes, where substances are removed by tissue lymphocytes and circulating lymphocytes are added to the fluid, before emptying ultimately into the right or the left subclavian vein, where it mixes with central venous blood.

The scalp is the area of the head where head hair grows. It is made up of skin, layers of connective and fibrous tissues, and the membrane of the skull. Anatomically, the scalp is part of the epicranium, a collection of structures covering the cranium. The scalp is bordered by the face at the front, and by the neck at the sides and back. The scientific study of hair and scalp is called trichology.

<span class="mw-page-title-main">Subclavian vein</span> Blood vessel that drains the arm

The subclavian vein is a paired large vein, one on either side of the body, that is responsible for draining blood from the upper extremities, allowing this blood to return to the heart. The left subclavian vein plays a key role in the absorption of lipids, by allowing products that have been carried by lymph in the thoracic duct to enter the bloodstream. The diameter of the subclavian veins is approximately 1–2 cm, depending on the individual.

<span class="mw-page-title-main">Superior thoracic aperture</span> Opening at the top of the thoracic cavity (area enclosed by the ribcage)

The superior thoracic aperture, also known as the thoracic outlet, or thoracic inlet refers to the opening at the top of the thoracic cavity. It is also clinically referred to as the thoracic outlet, in the case of thoracic outlet syndrome. A lower thoracic opening is the inferior thoracic aperture.

The cisterna chyli or receptaculum chyli is a dilated sac at the lower end of the thoracic duct in most mammals into which lymph from the intestinal trunk and two lumbar lymphatic trunks flow. It receives fatty chyle from the intestines and thus acts as a conduit for the lipid products of digestion. It is the most common drainage trunk of most of the body's lymphatics. The cisterna chyli is a retroperitoneal structure.

<span class="mw-page-title-main">Femoral sheath</span> Anatomical structure of the upper thigh

The femoral sheath is a funnel-shaped downward extension of abdominal fascia within which the femoral artery and femoral vein pass between the abdomen and the thigh. The femoral sheath is subdivided by two vertical partitions to form three compartments ; the medial compartment is known as the femoral canal and contains lymphatic vessels and a lymph node, whereas the intermediate canal and the lateral canal accommodate the femoral vein and the femoral artery (respectively). Some neurovascular structures perforate the femoral sheath. Topographically, the femoral sheath is contained within the femoral triangle.

This article describes the anatomy of the head and neck of the human body, including the brain, bones, muscles, blood vessels, nerves, glands, nose, mouth, teeth, tongue, and throat.

Cervical lymph nodes are lymph nodes found in the neck. Of the 800 lymph nodes in the human body, 300 are in the neck. Cervical lymph nodes are subject to a number of different pathological conditions including tumours, infection and inflammation.

<span class="mw-page-title-main">Popliteal lymph nodes</span>

The popliteal lymph nodes, small in size and some six or seven in number, are embedded in the fat contained in the popliteal fossa, sometimes referred to as the 'knee pit'. One lies immediately beneath the popliteal fascia, near the terminal part of the small saphenous vein, and drains the region from which this vein derives its tributaries, such as superficial regions of the posterolateral aspect of the leg and the plantar aspect of the foot.

External gills are the gills of an animal, most typically an amphibian, that are exposed to the environment, rather than set inside the pharynx and covered by gill slits, as they are in most fishes. Instead, the respiratory organs are set on a frill of stalks protruding from the sides of an animal's head.

<span class="mw-page-title-main">Bronchomediastinal lymph trunk</span> Lymph node

The bronchomediastinal lymph trunks are essential components of the human lymphatic system, tasked with draining lymph from the tracheobronchial, internal mammary, and anterior mediastinal lymph nodes.

The following outline is provided as an overview of and topical guide to human anatomy:

Lymph sacs are a part of the development of the lymphatic system, known as lymphangiogenesis. The lymph sacs are precursors of the lymph vessels. These sacs develop through the processes of vasculogenesis and angiogenesis. However, there is evidence of both of these processes in different organisms. In mice, it is thought that the lymphatic components form through an angiogenic process. But, there is evidence from bird embryos that gives rise to the idea that lymphatic vessels arise in the embryos through a vasculogenesis-like process from the lymphangioblastic endothelial precursor cells.

The cheek constitutes the facial periphery and plays a key role in the maintenance of oral competence and mastication. It is also involved in the facial manifestation of human emotion and supports neighboring primary structures.

References

1 2 Martin, Feder (15 Oct 1992). Environmental Physiology of the Amphibians. University of Chicago Press. p. 115. ISBN 9780226239446 . Retrieved 6 January 2015.
1 2 3 4 5 6 7 8 Hedrick, Michael S.; Hillman, Stanley S.; Drewes, Robert C.; Withers, Philip C. (1 July 2013). "Lymphatic regulation in nonmammalian vertebrates". Journal of Applied Physiology. 115 (3): 297–308. doi:10.1152/japplphysiol.00201.2013. ISSN 8750-7587. PMID 23640588.
1 2 Banda, Chihena H.; Shiraishi, Makoto; Mitsui, Kohei; Okada, Yoshimoto; Danno, Kanako; Ishiura, Ryohei; Maemura, Kaho; Chiba, Chikafumi; Mizoguchi, Akira; Imanaka-Yoshida, Kyoko; Maruyama, Kazuaki; Narushima, Mitsunaga (2023-04-27). "Structural and functional analysis of the newt lymphatic system". Scientific Reports. 13 (1): 6902. Bibcode:2023NatSR..13.6902B. doi:10.1038/s41598-023-34169-w. ISSN 2045-2322. PMC 10140069 . PMID 37106059.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[martin-1] 1 2 Martin, Feder (15 Oct 1992). Environmental Physiology of the Amphibians. University of Chicago Press. p. 115. ISBN 9780226239446 . Retrieved 6 January 2015.

[Hedrick-2] 1 2 3 4 5 6 7 8 Hedrick, Michael S.; Hillman, Stanley S.; Drewes, Robert C.; Withers, Philip C. (1 July 2013). "Lymphatic regulation in nonmammalian vertebrates". Journal of Applied Physiology. 115 (3): 297–308. doi:10.1152/japplphysiol.00201.2013. ISSN 8750-7587. PMID 23640588.

[:0-3] 1 2 Banda, Chihena H.; Shiraishi, Makoto; Mitsui, Kohei; Okada, Yoshimoto; Danno, Kanako; Ishiura, Ryohei; Maemura, Kaho; Chiba, Chikafumi; Mizoguchi, Akira; Imanaka-Yoshida, Kyoko; Maruyama, Kazuaki; Narushima, Mitsunaga (2023-04-27). "Structural and functional analysis of the newt lymphatic system". Scientific Reports. 13 (1): 6902. Bibcode:2023NatSR..13.6902B. doi:10.1038/s41598-023-34169-w. ISSN 2045-2322. PMC 10140069 . PMID 37106059.

[1]

[2]

[3]