Thrombosis Information and Courses from MediaLab, Inc.
These are the MediaLab courses that cover Thrombosis and links to relevant pages within the course.
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| Fibrin/Fibrinogen Degradation Products and D-dimers The presence of D-dimers in plasma or whole blood indicates that fibrin has been formed and degraded (fibrinolysis). Plasmin can also degrade intact fibrinogen, generating fibrinogen degradation products that are detected in fibrin/fibrinogen degradation products (FDP) assays. D-dimers and FDP can become elevated whenever the coagulation and fibrinolytic systems are activated. The presence of D-dimer confirms that both thrombin and plasmin have been generated since it can only be produced as the result of the plasmin degradation of fibrin. This makes the test for D-dimers more specific for fibrinolysis than the FDP test that also detects the products of the direct proteolysis of fibrinogen (fibrinogenolysis).The D-dimer test can be useful in the diagnosis of deep venous thrombosis (DVT) or pulmonary embolism (PE), two forms of venous thromboembolism (VTE). When the test is being used for this purpose, it is important that D-dimer levels are accurately measured and accurately reported because of the serious nature of this clinical decision. If the test is positive in a patient suspected to have DVT or PE, clinicians proceed with further diagnostic tests. If the test is negative, depending on the clinical situation and the sensitivity of the D-dimer assay, DVT or PE is considered unlikely and further diagnostic tests for DVT or PE might not be pursued. D-dimer is a sensitive, but not specific, diagnostic test for disseminated intravascular coagulation, and an indicator of increased risk of future myocardial infarction in patients evaluated for chest pain. | View Page |
| Coagulation Disorders This course began with a discussion on homeostasis, the body’s desire to maintain a status of physiological equilibrium. Our inborn system of chemical checks and balances, activators and inhibitors, can be disrupted by numerous factors, two of the more common being acquired disease states and disorders passed on to offspring via inheritance. In regard to coagulation, both disease status and genetics can adversely affect the functionality of many hemostatic processes. Impaired hemostatic mechanisms, be it acquired in cases of disease or inherent, may result in situations of either hemorrhage or thrombosis. A situation of hemorrhage, or bleeding external to the vasculature, most often stems from physical vessel trauma, but may also arise from a wide variety of disease states. Thrombosis does not require physical trauma, and is the activation of hemostatic processes at an inappropriate time in an inappropriate place, and may arise from a number of inherited or acquired disease states. The following pages are intended to serve as an introduction to some of the more commonly encountered coagulation disorders. | View Page |
| Anticoagulation Therapy Anticoagulant therapy is employed in a number of clinical situations Some of these clinical situations include: After an episode of thrombosis, such as deep venous thrombosis (DVT) in the veins of the legs, to prevent reoccurrence. Prophylactically after some surgeries, especially those involving vascular repair such as coronary bypass surgery to prevent clots from blocking newly formed vasculature. In heart valve and chamber disorders where there is an increased risk of thrombosis occurring. | View Page |
| Anticoagulation Therapy - Oral Anticoagulant Therapy The therapeutic use of oral anticoagulants is typically the long-term solution for the patient in terms of managing situations of thrombosis. Warfarin, a dicumarol derivative, is one of the most popular oral anticoagulants used today. While heparin is administered intravenously and acts to inhibit thrombin, warfarin is given orally, taken in pill form, and functions as a Vitamin K antagonist. In earlier discussions, it was mentioned that certain clotting factors are considered to be vitamin K dependant. They require vitamin K molecules for their action to occur. Vitamin K dependant factors include factor II, VII, IX, and X. Vitamin K dependant metabolic processes involved with these coagulation factors are inhibited by drugs such as warfarin. The chemical structure of warfarin and similar anticoagulants enables them to bind competitively with free vitamin K. The prothrombin time (PT/INR) is used to monitor oral anticoagulant therapy. | View Page |
| Warfarin Metabolism The first specific PGx testing application most labs are likely to encounter is that used in patients taking warfarin. Recent studies have revealed that the variations seen in patients taking the anticoagulant warfarin are due to PGx factors. The consequences of incorrect warfarin dosing are obviously serious, with inadequate doses predisposing patients to thrombosis and higher doses placing them at risk for hemorrhage. The United States' Food and Drug Administration (FDA) recently approved updated labeling for Coumadin (warfarin sold by Bristol-Myers Squibb). The new labeling suggests that physicians incorporate PGx information into warfarin-dosing regimens for patients. Manufacturers of generic warfarin products are now adding similar labeling. | View Page |