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Thrombus

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Thrombus
Other namesBlood clot
Diagram of a thrombus (blood clot) that has blocked a vein valve
SpecialtyVascular surgery
Symptomsabrupt change in mental status, chest pain, cramp-like feeling, fatigue, passing out (syncope), and swelling in the arm and/or leg
Complicationsbleeding risks from taking anticoagulants, breathing problems, heart attacks, stroke
Durationc. 3–6 months
TypesSuperficial thrombophlebitis and thrombophlebitis migrans
Causesinjury to the artery, sepsis or viral infection, immobility
Risk factorshospitalization, immobility, obesity, pregnancy, physical trauma
Diagnostic methodmagnetic resonance angiography, ultrasound, and venography
Preventionsmoking cessation, regular exercise, improved blood flow, management of comorbidities
TreatmentAnticoagulants: edoxaban, tinzaparin, unfractionated heparin
Medicationapixaban, edoxaban, and rivaroxaban
Deaths100,000–300,000 each year

A thrombus (pl. thrombi), colloquially called a blood clot, is the final product of the blood coagulation step in hemostasis. There are two components to a thrombus: aggregated platelets and red blood cells that form a plug, and a mesh of cross-linked fibrin protein. The substance making up a thrombus is sometimes called cruor. A thrombus is a healthy response to injury intended to stop and prevent further bleeding, but can be harmful in thrombosis, when a clot obstructs blood flow through a healthy blood vessel in the circulatory system.

In the microcirculation consisting of the very small and smallest blood vessels the capillaries, tiny thrombi known as microclots can obstruct the flow of blood in the capillaries. This can cause a number of problems particularly affecting the alveoli in the lungs of the respiratory system resulting from reduced oxygen supply. Microclots have been found to be a characteristic feature in severe cases of COVID-19 and in long COVID.[1]

Mural thrombi are thrombi that adhere to the wall of a large blood vessel or heart chamber.[2] They are most commonly found in the aorta, the largest artery in the body, more often in the descending aorta, and less often in the aortic arch or abdominal aorta.[2] They can restrict blood flow but usually do not block it entirely. They appear grey-red along with alternating light and dark lines (known as lines of Zahn) which represent bands of white blood cells and red blood cells (darker) entrapped in layers of fibrin.[3]

Classification

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Thrombi are classified into two major groups depending on their location and the relative amount of platelets and red blood cells.[4] The two major groups are:

  1. Arterial or white thrombi (characterized by predominance of platelets)
  2. Venous or red thrombi (characterized by predominance of red blood cells).

Microclots

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In the microcirculation consisting of the very small and smallest blood vessels, the capillaries, tiny thrombi (microthrombi)[5] known as microclots can obstruct the flow of blood in the capillaries. Microclots are small clumps of blood that form within the circulation, usually as a result of a larger thrombus breaking down into smaller pieces. They can be a cause for concern as they can lead to blockages in small vessels and restrict blood flow, leading to tissue damage and potentially causing ischemic events.[citation needed]

Microclots can cause a number of problems particularly affecting the alveoli in the lungs of the respiratory system, resulting from reduced oxygen supply. Microclots have been found to be a characteristic feature in severe cases of COVID-19, and in long COVID.[1][6]

Mural thrombi

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Mural thrombi form and adhere on the inner wall of a large blood vessel or heart chamber, often as a result of blood stasis.[2] They are most commonly found in the aorta, the largest artery in the body, more often in the descending aorta, and less often in the aortic arch or abdominal aorta.[2] They can restrict blood flow but usually do not block it entirely. Mural thrombi are usually found in vessels already damaged by atherosclerosis.[3]

A mural thrombus can affect any heart chamber. When found in the left ventricle it is often a result of a heart attack complication. The thrombus in this case can separate from the chamber, be carried through arteries and block a blood vessel.[2] They appear grey-red with alternating light and dark lines (known as lines of Zahn) which represent bands of white blood cells and red blood cells (darker) entrapped in layers of fibrin.[citation needed]

Cause

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Illustration comparing normal artery with diseased artery with a blood clot.

It was suggested over 150 years ago that thrombus formation is a result of abnormalities in blood flow, vessel wall, and blood components. This concept is now known as Virchow's triad. The three factors have been further refined to include circulatory stasis, vascular wall injury, and hypercoagulable state, all of which contribute to increased risk for venous thromboembolism and other cardiovascular diseases.[4]

Virchow's triad describes the pathogenesis of thrombus formation:[7][8]

  1. Endothelial injury: Injury to the endothelium (interior surface of blood vessel), causing platelet activation and aggregation;
  2. Hemodynamic changes (stasis, turbulence): Blood stasis promotes greater contact between platelets/coagulative factors with vascular endothelium. If rapid blood circulation (e.g., because of tachycardia) occurs within vessels that have endothelial injuries, that creates disordered flow (turbulence) that can lead to the formation of thrombosis;[9]
    • Common causes of stasis include anything that leads to prolonged immobility and reduced blood flow such as: trauma/broken bones and extended air travel.
  3. Hypercoagulability (also called thrombophilia; any disorder of the blood that predisposes to thrombosis);[10]
    • Common causes include: cancer (leukaemia), factor V mutation (Leiden) – prevents Factor V inactivation leading to increased coagulability.

Disseminated intravascular coagulation (DIC) involves widespread microthrombi formation throughout the majority of the blood vessels. This is due to excessive consumption of coagulation factors and subsequent activation of fibrinolysis using all of the body's available platelets and clotting factors. The result is hemorrhaging and ischemic necrosis of tissue/organs. Causes are septicaemia, acute leukaemia, shock, snake bites, fat emboli from broken bones, or other severe traumas. DIC may also be seen in pregnant females. Treatment involves the use of fresh frozen plasma to restore the level of clotting factors in the blood, as well as platelets and heparin to prevent further thrombi formation.[citation needed]

Pathophysiology

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Animation of the formation of an occlusive thrombus in a vein. A few platelets attach themselves to the valve lips, constricting the opening and causing more platelets and red blood cells to aggregate and coagulate. Coagulation of unmoving blood on both sides of the blockage may propagate a clot in both directions.

A thrombus occurs when the hemostatic process, which normally occurs in response to injury, becomes activated in an uninjured or slightly injured vessel. A thrombus in a large blood vessel will decrease blood flow through that vessel (termed a mural thrombus). In a small blood vessel, blood flow may be completely cut off (termed an occlusive thrombus), resulting in death of tissue supplied by that vessel. If a thrombus dislodges and becomes free-floating, it is considered an embolus.[citation needed] If an embolus becomes trapped within a blood vessel, it blocks blood flow and is termed as an embolism. Embolisms, depending on their specific location, can cause more significant effects like strokes, heart attacks, or even death.[11]

Mechanism of blood clotting

Some of the conditions which increase the risk of blood clots developing include atrial fibrillation (a form of cardiac arrhythmia), heart valve replacement, a recent heart attack (also known as a myocardial infarction), extended periods of inactivity (see deep venous thrombosis), and genetic or disease-related deficiencies in the blood's clotting abilities.[citation needed]

Formation

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Platelet activation occurs through injuries that damage the endothelium of the blood vessels, exposing the enzyme called factor VII, a protein normally circulating within the vessels, to the tissue factor, which is a protein encoded by the F3 gene. The platelet activation can potentially cause a cascade, eventually leading to the formation of the thrombus.[12] This process is regulated through thromboregulation.

Prevention

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Anticoagulants are drugs used to prevent the formation of blood clots, reducing the risk of stroke, heart attack and pulmonary embolism. Heparin and warfarin are used to inhibit the formation and growth of existing thrombi, with the former used for acute anticoagulation while the latter is used for long-term anticoagulation.[8] The mechanism of action of heparin and warfarin are different as they work on different pathways of the coagulation cascade.[13]

Heparin works by binding to and activating the enzyme inhibitor antithrombin III, an enzyme that acts by inactivating thrombin and factor Xa.[13] In contrast, warfarin works by inhibiting vitamin K epoxide reductase, an enzyme needed to synthesize vitamin K dependent clotting factors II, VII, IX, and X.[13][14] Bleeding time with heparin and warfarin therapy can be measured with the partial thromboplastin time (PTT) and prothrombin time (PT), respectively.[14]

Treatment

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Once clots have formed, other drugs can be used to promote thrombolysis or clot breakdown. Streptokinase, an enzyme produced by streptococcal bacteria, is one of the oldest thrombolytic drugs.[14] This drug can be administered intravenously to dissolve blood clots in coronary vessels. However, streptokinase causes systemic fibrinolytic state and can lead to bleeding problems. Tissue plasminogen activator (tPA) is a different enzyme that promotes the degradation of fibrin in clots but not free fibrinogen.[14] This drug is made by transgenic bacteria and converts plasminogen into the clot-dissolving enzyme, plasmin.[15] Recent research indicates that tPA could have toxic effects in the central nervous system. In cases of severe stroke, tPA can cross the blood–brain barrier and enter interstitial fluid, where it then increases excitotoxicity, potentially affecting permeability of the blood–brain barrier,[16] and causing cerebral hemorrhage.[17]

There are also some anticoagulants that come from animals that work by dissolving fibrin. For example, Haementeria ghilianii, an Amazon leech, produces an enzyme called hementin from its salivary glands.[18]

Prognosis

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Thrombus formation can have one of four outcomes: propagation, embolization, dissolution, and organization and recanalization.[19]

  1. Propagation of a thrombus occurs towards the direction of the heart and involves the accumulation of additional platelets and fibrin. This means that it is anterograde in veins or retrograde in arteries.
  2. Embolization occurs when the thrombus breaks free from the vascular wall and becomes mobile, thereby traveling to other sites in the vasculature. A venous embolus (mostly from deep vein thrombosis in the lower limbs) will travel through the systemic circulation, reach the right side of the heart, and travel through the pulmonary artery, resulting in a pulmonary embolism. Arterial thrombosis resulting from hypertension or atherosclerosis can become mobile and the resulting emboli can occlude any artery or arteriole downstream of the thrombus formation. This means that cerebral stroke, myocardial infarction, or any other organ can be affected.
  3. Dissolution occurs when the fibrinolytic mechanisms break up the thrombus and blood flow is restored to the vessel. This may be aided by fibrinolytic drugs such as Tissue Plasminogen Activator (tPA) in instances of coronary artery occlusion. The best response to fibrinolytic drugs is within a couple of hours, before the fibrin meshwork of the thrombus has been fully developed.
  4. Organization and recanalization involves the ingrowth of smooth muscle cells, fibroblasts and endothelium into the fibrin-rich thrombus. If recanalization proceeds it provides capillary-sized channels through the thrombus for continuity of blood flow through the entire thrombus but may not restore sufficient blood flow for the metabolic needs of the downstream tissue.[7]

See also

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References

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  1. ^ a b Pretorius E, Vlok M, Venter C, Bezuidenhout JA, Laubscher GJ, Steenkamp J, Kell DB (August 2021). "Persistent clotting protein pathology in Long COVID/Post-Acute Sequelae of COVID-19 (PASC) is accompanied by increased levels of antiplasmin". Cardiovasc Diabetol. 20 (1): 172. doi:10.1186/s12933-021-01359-7. PMC 8381139. PMID 34425843.
  2. ^ a b c d e Singh, Davinder P.; Basit, Hajira; Malik, Ahmad; Mahajan, Kunal (5 November 2021). "Mural Thrombi". PMID 30484999. Retrieved 11 February 2022.
  3. ^ a b Karaolanis G, Moris D, Bakoyiannis C, Tsilimigras DI, Palla VV, Spartalis E, Schizas D, Georgopoulos S (August 2017). "A critical reappraisal of the treatment modalities of normal appearing thoracic aorta mural thrombi". Ann Transl Med. 5 (15): 306. doi:10.21037/atm.2017.05.15. PMC 5555985. PMID 28856146.
  4. ^ a b "Thrombus Formation – Virchow's triad & Types of Thrombi". Thrombosis Adviser. Bayer AG. Retrieved 20 March 2020.
  5. ^ "Medical Definition of micro thrombus". www.merriam-webster.com. Retrieved 22 February 2023.
  6. ^ Chen W, Pan JY (January 2021). "Anatomical and Pathological Observation and Analysis of SARS and COVID-19: Microthrombosis Is the Main Cause of Death". Biological Procedures Online. 23 (1): 4. doi:10.1186/s12575-021-00142-y. PMC 7816139. PMID 33472576. S2CID 255608747.
  7. ^ a b Kumar, Vinay; Abbas, Abul; Aster, Jon (2014). Robbins & Cotran Pathologic Basis of Disease (9th ed.). Philadelphia: Elsevier. ISBN 9781455726134. OCLC 879416939.
  8. ^ a b "Venous thromboembolism (VTE) | McMaster Pathophysiology Review". www.pathophys.org. 26 September 2012. Retrieved 2018-11-03.
  9. ^ Kushner, Abigail; West, William P.; Pillarisetty, Leela Sharath (2020), "Virchow Triad", StatPearls, Treasure Island (FL): StatPearls Publishing, PMID 30969519, retrieved 2020-06-18
  10. ^ Ataga KI (10 May 2020). "Hypercoagulability and thrombotic complications in hemolytic anemias". Haematologica. 94 (11): 1481–1484. doi:10.3324/haematol.2009.013672. PMC 2770956. PMID 19880774.
  11. ^ Marieb, Elaina N. Human Anatomy and Physiology (11th ed.). Pearson.
  12. ^ Furie, Bruce; Furie, Barbara (2008). "Mechanisms of Thrombus Formation". The New England Journal of Medicine. 359 (9): 938–49. doi:10.1056/NEJMra0801082. PMID 18753650.
  13. ^ a b c Harter, K.; Levine, M.; Henderson, S. O. (2015). "Anticoagulation Drug Therapy: A Review". The Western Journal of Emergency Medicine. 16 (1): 11–17. doi:10.5811/westjem.2014.12.22933. PMC 4307693. PMID 25671002.
  14. ^ a b c d Whalen, Karen; Finkel, Richard S.; Panavelil, Thomas A. (2015). Lippincott Illustrated Reviews: Pharmacology (6th ed.). Philadelphia: Wolters Kluwer. ISBN 9781451191776. OCLC 881019575.
  15. ^ Saladin, Kenneth S. (2012). Anatomy & Physiology: The Unity of Form and Function (6th ed.). New York: McGraw-Hill. p. 710. ISBN 978-0-07-337825-1.
  16. ^ Fredriksson, L.; Lawrence, D. A.; Medcalf, R. L. (2016). "TPA modulation of the blood–brain barrier: A unifying explanation for the pleiotropic effects of tPA in the CNS?". Seminars in Thrombosis and Hemostasis. 43 (2): 154–168. doi:10.1055/s-0036-1586229. PMC 5848490. PMID 27677179.
  17. ^ Medcalf, R. (2011). "Plasminogen activation-based thrombolysis for ischaemic stroke: the diversity of targets may demand new approaches". Current Drug Targets. 12 (12): 1772–1781. doi:10.2174/138945011797635885. PMID 21707475.
  18. ^ Budzynski, A. Z. (1991). "Interaction of hementin with fibrinogen and fibrin". Blood Coagulation & Fibrinolysis. 2 (1): 149–52. doi:10.1097/00001721-199102000-00022. PMID 1772982.
  19. ^ Kumar, Vinay; et al. (2007). Robbins Basic Pathology (8th ed.). Philadelphia: Saunders/Elsevier. ISBN 978-1-4160-2973-1.
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