The Spleen
Introduction
Introduction
The spleen is a relatively small organ which is located behind
the stomach (see figure above) and is usually around 5 inches wide. It can be divided into two
sections; the red pulp and the white pulp. The red pulp is used to filter blood
and the white pulp is used for antigen detection and elimination.
The spleen itself contains a lot of vessel tissues and can be used to store significant amounts of blood which is useful to help counter act loss of blood trauma (Cesta 2006).This allows a large amount of blood flow to the organ which will help it complete its already mentioned functions. This blog will discuss the tissues in the spleen which allow it to be such a spleen-did organ.
The spleen itself contains a lot of vessel tissues and can be used to store significant amounts of blood which is useful to help counter act loss of blood trauma (Cesta 2006).This allows a large amount of blood flow to the organ which will help it complete its already mentioned functions. This blog will discuss the tissues in the spleen which allow it to be such a spleen-did organ.
General Structure
The spleen can be divided into several sections.
Capsule: Is the outer layer of the spleen. It is mostly dense
fibrous, elastic fibres and smooth muscle.
Trabeculae: Smooth muscle and fibroelastic tissue that
spread from the capsule inward in an irregular shape. Trabeculae also contain
blood and lymph vessels and nerves. Aids in structure, helps with movement of blood to the parts of the spleen.
Red Pulp
The red pulp is used to filter the blood removing old red blood
cells and reuse their valuable iron for production of new erythrocytes and other
metabolic processes. This is accomplished
when the blood enters the cords(shown in the picture below).
Cords: The structure is most fibroblasts and
reticular fibres which house a lot of macrophages. Macrophages here are what breaks down the old red blood cells. The cords act as an open circulatory system which lack endothelial lining (Mebius and Kraal 2005).
Venous sinuses penetrate the cords and regulate the
passage of erythrocytes into them and thus back into the blood. These vessels have a specialised structure which is shown below. It involves
endothelial cells that have stress fibres connecting throughout them parallel. Contraction of the stress fibres
creates small slits that allow the red blood cells to enter the venous sinuses (Mebius and Kraal 2005).
Older red blood cells have more rigid cell membranes and have more trouble
moving through these slits. This leaves them in the cords with the large amount
of macrophages. The red blood cells are
targeted by the macrophages and are ingested in phagolysosomes. This will hydrolyse
the cell and destroy the hemoglobin proteins releasing Iron. Iron can be a dangerous molecule in biological
systems, and is kept in proteins called ferritin, or in larger quantities the
transporter protein transferrin(Mebius and Kraal 2005).
Haemolytic bacteria can pose a big threat here in the
spleen. Haemolytic bacteria break down red blood cells for iron and other
nutrients, so the spleen has ways to deal with these bacteria. Many of these
bacteria for example will secrete molecules known as siderophores which bind iron
and using specific transport proteins on the bacteria membrane will take in the
siderophore (which have now have iron). The macrophages of the spleen can be
easily induced to secrete the protein lipocalin-2 which binds the siderophores
and will prevent bacteria from taking the iron.(Ratledge and Dover 2000)
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White Pulp
The figure below shows the white pulp organisation in which
you have a central arteriole enter the white pulp nodule which is composed of B
cell zone(also called follicle), marginal zone and the T-cell zone(sometimes
referred to as the PALS which stands for periarteriolar lymphoid sheath). This actually is a very similar arrangement as
the lymph node(Cesta 2006).
A little reminder of
the function of immune cells!
T-cells are immune cells that come in several types. T helper cells which help other cells
recognise, mature or activate. Cytotoxic T-cells which kill “bad” host cells
which will be recognise for cancer patterns, intracellular bacteria or viruses.
(Other sometimes cause problems with autoimmune problems, transplant rejections etc). Regulatory T
cells which help control immune response to desired levels. Natural killer
t-cells which help the innate response trigger the adaptive responses of the
immune system. Rely on cell surface receptors of other immune cells to
activate.
B Cells are function to produce specific antibodies which
will bind to antigens. Binding to antigen allow them to be identified by other
immune processes and to cause agglutination. (Basically bridge a large amount
of antigens together to make an insoluble clump which prevent antigen from
doing certain things and allow easy identification.) B cells often come from clones and antigen
specific recognition needs to be effective.
The follicle and T-cell are kept their organisation by specific
chemokines. The T-cells can interact with dendritic cells and passing B-cells.
The follicles are where clonal selection takes place for B-cells. The bulk of
blood travels through the white pulp upon entering the spleen. This allows a
good way to detect any pathogens or foreign material that may be in the blood.
Marginal Zone
This is a layer which separates the white and red pulp,
which is argued to be considered part of the white pulp or its own layer which
divides the red and white pulps. Its purpose is to screen the any viruses or
bacteria. There is a band of macrophages which separate the white pulp and the
marginal zone which are called as marginal zone metallophilic macrophages
characterised by their adhesion molecules. The marginal zone itself has layers
of reticular fibroblasts where more immune cells reside including specialised B
cells which can be differentiate by the types of antibodies the produced
compared to the follicle region.(Mebius and Kraal 2005)
Pathology
Pathology
The most common problem with the spleen is spleen is called splenomegaly which is easily noticed by enlargement of the spleen. This caused by a variety of conditions such as congestion, neoplasm, injection, hemolytic anemia, extramedullary hematoposis or trauma.
The genetic disorder Gaucher disease causes spleenic enlargement as well. This disease is categorised by macrophages carrying too much glycolipids. This disease effects many organs including the spleen. Shown below (Cox et al., 1997)
Cystic lymphangiomatosis is another rare disease which again effects several organs and is caused by the a development issue with lymphatic tissues which can again effect the spleen (Mohanana et al., 2009)
References
Cesta. M (2006) Normal structure, function and histology of the spleen. Toxicol Pathol 34:455-466
Ratledge C, Dover L (2000) Iron metabolism in pathogenic bacteria Annu. Rev.Microbiology 54: 881-941
Mebius R, Kraal 2005. Structure and Function of the spleen. Nature Vol 5 606-616
Cesta. M (2006) Normal structure, function and histology of the spleen. Toxicol Pathol 34:455-466
Ratledge C, Dover L (2000) Iron metabolism in pathogenic bacteria Annu. Rev.Microbiology 54: 881-941
Mebius R, Kraal 2005. Structure and Function of the spleen. Nature Vol 5 606-616
Wright,
Dennis Wilkins, Bridget , Illustrated
Pathology of the Spleen 03/2000
Cox T, Shcofield J, 1997. Gaucher's disease: Clinical features and natural historyBailli~re's Clinical Haematology-- 657 Vol. 10, No. 4, December 1997
S. Mohana, N.V. Seethalekshmy, K. Pavithran: Splenic Cystic lymphangiomatosis presenting with massive splenomegaly. The Internet Journal of Pathology. 2009 Volume 8 Number 1. DOI: 10.5580/21ca
http://instruction.cvhs.okstate.edu/histology/HistologyReference/hrlym.htm
http://www.deltagen.com/target/histologyatlas/atlas_files/hematopoietic/spleen_red_pulp_40x.htm
http://www.cell.com/immunity/image_resource-spleen
http://archive.ispub.com/journal/the-internet-journal-of-pathology/volume-8-number-1/splenic-cystic-lymphangiomatosis-presenting-with-massive-splenomegaly.html#sthash.PKWmivin.dpbs
Cox T, Shcofield J, 1997. Gaucher's disease: Clinical features and natural historyBailli~re's Clinical Haematology-- 657 Vol. 10, No. 4, December 1997
S. Mohana, N.V. Seethalekshmy, K. Pavithran: Splenic Cystic lymphangiomatosis presenting with massive splenomegaly. The Internet Journal of Pathology. 2009 Volume 8 Number 1. DOI: 10.5580/21ca
http://www.deltagen.com/target/histologyatlas/atlas_files/hematopoietic/spleen_red_pulp_40x.htm
http://www.cell.com/immunity/image_resource-spleen
http://archive.ispub.com/journal/the-internet-journal-of-pathology/volume-8-number-1/splenic-cystic-lymphangiomatosis-presenting-with-massive-splenomegaly.html#sthash.PKWmivin.dpbs
