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The spleen, similar in structure to a large lymph node, acts as a blood filter. Current knowledge of its purpose includes the removal of old red blood cells and platelets, and the detection and fight against certain bacteria. It is also known to function as a site for the development of new red blood cells from their hematopoietic stem cell precursors, and particularly in situations in which the bone marrow, the normal site for this process, has been compromised by a disorder such as leukemia. The spleen is enlarged in a variety of conditions such as malaria, mononucleosis and most commonly in cancers of the lymphatics, such as lymphomas or leukemia.
It is removed under the following circumstances:
- When it becomes very large such that it becomes destructive to platelets/red blood cells
- For diagnosing certain lymphomas
- Certain cases of splenic abscess
- Certain cases of wandering spleen
- Splenic vein thrombosis with bleeding Gastric varices
- When platelets are destroyed in the spleen as a result of an auto-immune condition, such as idiopathic thrombocytopenic purpura.
- When the spleen bleeds following physical trauma
- Following spontaneous rupture
- For long-term treatment of congenital erythropoietic porphyria (CEP) if severe hemolytic anemia develops
- The spread of gastric cancer to splenic tissue
- When using the splenic artery for kidney revascularisation in renovascular hypertension.
- For long-term treatment of congenital pyruvate kinase (PK) deficiency
The classical cause of traumatic damage to the spleen is a blow to the abdomen during a sporting event. In cases where the spleen is enlarged due to illness (mononucleosis), trivial activities, such as leaning over a counter or straining while defecating, can cause a rupture.
Laparoscopy is the preferred procedure in cases where the spleen is not too large and when the procedure is elective. Open surgery is performed in trauma cases or if the spleen is enlarged. Either method is major surgery and is performed under general anesthesia. Vaccination for pneumococcus, H. influenza and meningococcus should be given pre-operatively if possible to minimize the chance of overwhelming post-splenectomy infection (OPSI), a rapid-developing and potentially fatal type of septicaemia. The spleen is located and disconnected from its arteries. The ligaments holding the spleen in place, gastrosplenic ligament, splenorenal ligament and splenocolic ligament, are dissected and the organ is removed. In some cases, one or more accessory spleens are discovered and also removed during surgery. The incisions are closed and when indicated, a drain is left. If necessary, tissue samples are sent to a laboratory for analysis.
Splenectomy causes an increased risk of sepsis due to encapsulated organisms (such as S. pneumoniae and Haemophilus influenzae). It has been found that the risk of acquiring sepsis is 10 to 20 times higher in a splenectomized patient compared to a non-splenectomized patient, which can result in death, especially in young children. Therefore, patients are administered the pneumococcal conjugate vaccine (Prevnar), Hib vaccine, and the meningococcal vaccine post-operatively (see asplenia). These bacteria often cause a sore throat under normal circumstances but after splenectomy, when infecting bacteria cannot be adequately opsonized, the infection becomes more severe.
An increase in blood leukocytes can occur following a splenectomy. The post-splenectomy platelet count may rise to abnormally high levels (thrombocytosis), leading to an increased risk of potentially fatal clot formation. Mild thrombocytosis may be observed after a splenectomy due to the lack of sequestering and destruction of platelets that would normally be carried out by the spleen. In addition, the splenectomy may result in a slight increase in the production of platelets within the bone marrow. Normally, erythrocytes are stored and removed from the circulating blood by the spleen, including the removal of damaged erythrocytes. However, after a splenectomy the lack of presence of the spleen means this function cannot be carried out so damaged erythrocytes will continue to circulate in the blood and can release substances into the blood. If these damaged erythrocytes have a procoagulant activity then the substances they release can lead to the development of a procoagulant state and this can cause thromboembolic events e.g. pulmonary embolism, portal vein thrombosis and deep vein thrombosis. There also is some conjecture that post-splenectomy patients may be at elevated risk of subsequently developing diabetes. Splenectomy may also lead to chronic neutrophilia. Splenectomy patients typically have Howell-Jolly bodies and less commonly Heinz bodies in their blood smears. Heinz bodies are usually found in cases of G6PD (Glucose-6-Phosphate Dehydrogenase) and chronic liver disease.
A splenectomy also results in a greatly diminished frequency of memory B cells. A 28-year follow-up of 740 World War II veterans who had their spleens removed on the battlefield showed a significant increase in the usual death from pneumonia (6 deaths rather than the expected 1.74) and an increase in the deaths from ischemic heart disease (41 deaths rather than the expected 30.26) but not from other conditions.
Much of the spleen's protective roles can be maintained if a small amount of spleen can be left behind. Where clinically appropriate, attempts are now often made to perform either surgical subtotal (partial) splenectomy, or partial splenic embolization. In particular, whilst vaccination and antibiotics provide good protection against the risks of asplenia, this is not always available in poorer countries. However, as it may take some time for the preserved splenic tissue to provide the full protection, it has been advised that preoperative vaccination still be given.
The Austrian surgeon Hermann Schloffer performed the first splenectomy in 1916.
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