Difference between revisions of "Lymphatic System Overview - Anatomy & Physiology"

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|thispagetable = Lymphatic System (Table) - Anatomy & Physiology
 
|thispagemap = Lymphatic System (Content Map) - Anatomy & Physiology
 
|pagetype =Anatomy
 
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[[Image:Deep Lymphatic Drainage Diagram.jpg|right|thumb|200px|Deep Lymphatic drainage - Copyright B.Catchpole RVC]]
 
[[Image:Deep Lymphatic Drainage Diagram.jpg|right|thumb|200px|Deep Lymphatic drainage - Copyright B.Catchpole RVC]]
 
==Introduction==
 
==Introduction==
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==Lymphatic Vessels and Lymph==
 
==Lymphatic Vessels and Lymph==
Due to their structure lymphatic capillaries are more permeable than vascular capillaries which  means that not only can they remove fluid more effectively from tissues but they can also take up large molecules as well as chylomicrons. Chylomicrons transport fats and enter the [[Lymph - Anatomy & Physiology|lymph]] to eventually join the circulatory system via the thoracic duct; this enables the lipid soluble [[Small Intestine - Anatomy & Physiology#Triacylglycerol Digestion and Absorption |triacylglycerol (TAG)]] to be transported into the bloodstream. The interstitial fluid or lymph within the lymphatic vessels passes through lymph nodes where it is surveyed by [[Immunology|immune cells]] before returning to the circulation, ensuring that tissue pathogens are removed.
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Due to their structure lymphatic capillaries are more permeable than vascular capillaries which  means that not only can they remove fluid more effectively from tissues but they can also take up large molecules as well as chylomicrons. Chylomicrons transport fats and enter the [[Lymph - Anatomy & Physiology|lymph]] to eventually join the circulatory system via the thoracic duct; this enables the lipid soluble [[Small Intestine Overview - Anatomy & Physiology#Triacylglycerol Digestion and Absorption |triacylglycerols (TAGs)]] to be transported into the bloodstream. The interstitial fluid or lymph within the lymphatic vessels passes through lymph nodes where it is surveyed by [[Immunology|immune cells]] before returning to the circulation, ensuring that tissue pathogens are removed.
  
==Lymphoreticular system==
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==[[:Category:Lymphoreticular System|Lymphoreticular system]]==
 
The lymphoreticular system produces [[Immunology|immune cells]] and removes senescent cells.
 
The lymphoreticular system produces [[Immunology|immune cells]] and removes senescent cells.
Primary (or central) lymphoid tissues can also be referred to as primary lymphoid organs. Maturation of [[Lymphocytes|lymphocytes]] and [[Leukopoiesis#Lymphopoiesis|lymphopoiesis]] occurs in the primary lymphoid tissues, with different tissues responsible for maturing different types of lymphocyte. The primary lymphoid tissues are:
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Primary (or central) lymphoid tissues can also be referred to as primary lymphoid organs. Maturation of [[Lymphocytes - Introduction|lymphocytes]] and [[Leukopoiesis#Lymphopoiesis|lymphopoiesis]] occurs in the primary lymphoid tissues, with different tissues responsible for maturing different types of lymphocyte. The primary lymphoid tissues are:
 
*[[Bone Marrow - Anatomy & Physiology|Bone marrow]]
 
*[[Bone Marrow - Anatomy & Physiology|Bone marrow]]
 
*[[Bursa of Fabricius - Anatomy & Physiology|The Bursa of Fabricius]]
 
*[[Bursa of Fabricius - Anatomy & Physiology|The Bursa of Fabricius]]
 
*[[Thymus - Anatomy & Physiology|The Thymus]]
 
*[[Thymus - Anatomy & Physiology|The Thymus]]
*[[Haematopoiesis#Hepatic Phase|The Foetal Liver]]
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*[[Haematopoiesis - Overview#Hepatic Phase|The Foetal Liver]]
  
 
Secondary (or peripheral) lymphoid tissues or secondary lymphoid organs provide a site for immune responses to occur and are populated by relatively mature [[Lymphocytes#T cells|T cells]] and [[Lymphocytes#B cells|B cells]], [[Macrophages|macrophages]] and dendritic cells; each tissue seems to be preferentially populated by lymphocyte types that specialise in the antigens that are most likely to be presented at that site. The secondary lymphoid tissues are:
 
Secondary (or peripheral) lymphoid tissues or secondary lymphoid organs provide a site for immune responses to occur and are populated by relatively mature [[Lymphocytes#T cells|T cells]] and [[Lymphocytes#B cells|B cells]], [[Macrophages|macrophages]] and dendritic cells; each tissue seems to be preferentially populated by lymphocyte types that specialise in the antigens that are most likely to be presented at that site. The secondary lymphoid tissues are:
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*[[Regional Lymphoid Tissue - Anatomy & Physiology|Regional lymphoid tissue]]
 
*[[Regional Lymphoid Tissue - Anatomy & Physiology|Regional lymphoid tissue]]
  
==Test yourself on the lymphoreticular flash cards==
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==Functions==
[[Lymphoreticular System Flashcards - Wikiblood|Lymphoreticular Flashcards]]
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<p>The lymphatic system has three functions:
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#'''Immune defence''': This is a broad topic area.</p><p>Immune functions are covered broadly under the [[:Category:Primary Lymphoid Tissue|primary]] and [[:Category:Secondary Lymphoid Tissue|secondary]] lymphoid tissues of the [[Lymphoreticular System - Anatomy & Physiology|lymphoreticular system]] with further information under the [[Immunology|immunology]] section.
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#'''Removal of interstitial fluid from tissue''': Details can be found at [[Lymphatic Vessels - Anatomy & Physiology#Function|lymphatic vessel function]].
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#'''Transport of fat''': Chylomicrons transport digested lipids, however these are too large to enter the blood stream directly and thus enter the lymphatic system before being released into the blood stream. Further details can be found at [[Small Intestine Overview - Anatomy & Physiology#Triacylglycerol Digestion and Absorption|Triacylglycerol Digestion and Absorption]].
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{{Learning
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|flashcards = [[:Category:Lymphoreticular System Anatomy & Physiology Flashcards|Lymphoreticular Flashcards]]
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|Vetstream = [https://www.vetstream.com/canis/search?s=lymphatic+ Lymphatic diseases]
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}}
  
 
==References==
 
==References==
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*<div id="Nance">{{citation|initiallast = Nance|initialfirst = D.M|finallast = Sanders|finalfirst = V.M|year = 2007|jtitle = Autonomic innervation and regulation of the immune system (1987-2007)|jor = Brain, Behavior, and Immunity|vol = 21(6)|range = 736-745}}</div>
 
*<div id="Nance">{{citation|initiallast = Nance|initialfirst = D.M|finallast = Sanders|finalfirst = V.M|year = 2007|jtitle = Autonomic innervation and regulation of the immune system (1987-2007)|jor = Brain, Behavior, and Immunity|vol = 21(6)|range = 736-745}}</div>
  
==Creator==
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<br><br>
[[Asher Allison]]
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{{Jim Bee 2007}}
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==Webinars==
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<rss max="10" highlight="none">https://www.thewebinarvet.com/clinical-pathology/webinars/feed</rss>
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[[Category:Lymphoreticular System]]

Latest revision as of 16:06, 3 January 2023


Deep Lymphatic drainage - Copyright B.Catchpole RVC

Introduction

The lymphatic system can be divided into two anatomical and functional subsets: lymphatic vessels that carry lymph around the body, and the lymphoreticular system which describes the lymphoid tissues. The lymphatic system has three functions - immune defence, removal of interstitial fluid from tissues and the transport of fats.

Lymphatic Vessels and Lymph

Due to their structure lymphatic capillaries are more permeable than vascular capillaries which means that not only can they remove fluid more effectively from tissues but they can also take up large molecules as well as chylomicrons. Chylomicrons transport fats and enter the lymph to eventually join the circulatory system via the thoracic duct; this enables the lipid soluble triacylglycerols (TAGs) to be transported into the bloodstream. The interstitial fluid or lymph within the lymphatic vessels passes through lymph nodes where it is surveyed by immune cells before returning to the circulation, ensuring that tissue pathogens are removed.

Lymphoreticular system

The lymphoreticular system produces immune cells and removes senescent cells. Primary (or central) lymphoid tissues can also be referred to as primary lymphoid organs. Maturation of lymphocytes and lymphopoiesis occurs in the primary lymphoid tissues, with different tissues responsible for maturing different types of lymphocyte. The primary lymphoid tissues are:

Secondary (or peripheral) lymphoid tissues or secondary lymphoid organs provide a site for immune responses to occur and are populated by relatively mature T cells and B cells, macrophages and dendritic cells; each tissue seems to be preferentially populated by lymphocyte types that specialise in the antigens that are most likely to be presented at that site. The secondary lymphoid tissues are:

Functions

The lymphatic system has three functions:

  1. Immune defence: This is a broad topic area.

    Immune functions are covered broadly under the primary and secondary lymphoid tissues of the lymphoreticular system with further information under the immunology section.

  2. Removal of interstitial fluid from tissue: Details can be found at lymphatic vessel function.
  3. Transport of fat: Chylomicrons transport digested lipids, however these are too large to enter the blood stream directly and thus enter the lymphatic system before being released into the blood stream. Further details can be found at Triacylglycerol Digestion and Absorption.


Lymphatic System Overview - Anatomy & Physiology Learning Resources
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Lymphoreticular Flashcards


References

Texts:

  • Dyce, K.M., Sack, W.O. and Wensing, C.J.G. (2002) Textbook of Veterinary Anatomy. 3rd ed. Philadelphia: Saunders.
  • Janeway, C.A., Travers, P., Walport, M. and Shlomchik, M.J. (2005) Immunobiology: The immune system in health and disease. 6th ed. New York: Garland Science Publishing.
  • McGeady, T.A., Quinn, P.J., FitzPatrick, E.S. and Ryan, M.T. (2006) Veterinary Embryology. Oxford: Blackwell Publishing.
  • Ross, M.H. and Pawlina, W. (2006) Histology: A text and atlas. 5th ed. Baltimore: Lippincott Williams & Wilkins.
  • Sjaastad, O.V., Hove, K. and Sand, O. (2004) Physiology of Domestic Animals. Oslo: Scandinavian Veterinary Press.
  • Tizard, I.R. (2004) Veterinary Immunology: An Introduction. 7th ed. Philadelphia: Saunders.

Literature:

  • Dasso, J.F., Obiakor, H., Bach, H., Anderson, and Mage, R.G. (2000) A morphological and immunohistological study of the human and rabbit appendix for comparison with the avian bursa. Developmental & Comparative Immunology 24(8): pp.797-814.
  • Metcalfe, D.D., Baram, D. and Mekori, Y. (1997) Mast Cells. Physiological Reviews 77(4): pp.1033-1064.
  • Nance, D.M. and Sanders, V.M. (2007) Autonomic innervation and regulation of the immune system (1987-2007). Brain, Behavior, and Immunity 21(6): pp.736-745.



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