How Blood Clots

An injured blood vessel constricts so that blood flows out more slowly and clotting can start. At the same time, the accumulating pool of blood outside the blood vessel (a hematoma) presses against the vessel, helping prevent further bleeding.

As soon as a blood vessel wall is damaged, a series of reactions activates platelets so that they stick to the injured area. The "glue" that holds platelets to the blood vessel wall is von Willebrand factor, a large protein produced by the cells of the vessel wall. The proteins collagen and thrombin act at the site of the injury to induce platelets to stick together. As platelets accumulate at the site, they form a mesh that plugs the injury. The platelets change shape from round to spiny, and they release proteins and other substances that entrap more platelets and clotting proteins in the enlarging plug that becomes a blood clot.

Formation of a clot also involves activation of a sequence of blood clotting factors, which are proteins produced mainly by the liver. There are over a dozen blood clotting factors. They interact in a complicated series of chemical reactions that ultimately generate thrombin. Thrombin converts fibrinogen, a blood clotting factor that is normally dissolved in blood, into long strands of fibrin that radiate from the clumped platelets and form a net that entraps more platelets and blood cells. The fibrin strands add bulk to the developing clot and help hold it in place to keep the vessel wall plugged.

Severe liver disease (such as cirrhosis or liver failure) can reduce production of clotting factors and increase risk of excessive bleeding. Because the liver needs vitamin K to make some of the clotting factors, vitamin K deficiency can cause excessive bleeding.

The reactions that result in the formation of a blood clot are balanced by other reactions that stop the clotting process and dissolve clots after the blood vessel has healed. Without this control system, minor blood vessel injuries could trigger widespread clotting throughout the body—which actually happens in some diseases (see Bruising and Bleeding).

The relationship between medications and the body's ability to control bleeding (hemostasis) is complicated. The body's ability to form blood clots is vital to hemostasis, but too much clotting increases the risk of a heart attack, stroke, or pulmonary embolism. Many medications, either intentionally or unintentionally, affect the body's ability to form blood clots.

Other people at risk of forming blood clots may be given an anticoagulantthrombin or activated factor X

People who take warfarin or heparin must be under close medical supervision. Doctors monitor the effects of these medications with blood tests that measure the time it takes for a clot to form, and they adjust the dose on the basis of test results. Doses that are too low may not prevent clots, while doses that are too high may cause severe bleeding. Other types of anticoagulants, such as a class of medications called low-molecular-weight heparins

If a person already has a blood clot, a thrombolytic (fibrinolytic) medication can be given to help dissolve the clot. Thrombolytic medications, which include streptokinase and tissue plasminogen activators, are sometimes used to treat heart attacks and strokes caused by blood clots. These medications may save lives, but they can also put the person at risk of severe bleeding. Heparin, a medication given to reduce the risk of clot formation, sometimes has an unintended, paradoxical activating effect on platelets that increases the risk of clotting (heparin-induced thrombocytopenia-thrombosis).

Estrogen, alone or in oral contraceptives, can have the unintended effect of causing excessive clot formation. Certain medications used to treat cancer (chemotherapy drugs), such as asparaginase, can also increase the risk of clotting.