Anticoagulants

د. قاسم ادوية 18\3\2018

عدد الاوراق ( 6 ) م\3\موصل lec:8
Anticoagulants
Thrombus VS. Embolus
A clot that adheres to a vessel wall is called a thrombus, whereas an intravascular clot that floats in the blood is termed an embolus. Thus, a detached thrombus becomes an embolus. Both thrombi and emboli are dangerous, because they may occlude blood vessels.
Inhibitors of coagulation
Endogenously, there are several inhibitors of coagulation factors, including protein C, protein S, antithrombin III, and tissue factor pathway inhibitor. The mechanism of action of several anticoagulant agents, including heparin and heparin-related products, involves activation of these endogenous inhibitors (primarily antithrombin III).
Anticoagulants
The anticoagulant drugs either inhibit the action of the coagulation factors (the thrombin inhibitors, such as heparin and heparin-related agents) or interfere with the synthesis of the coagulation factors (the vitamin K antagonists, such as warfarin).
A. Thrombin inhibitors: heparin
Heparin normally occurs as a macromolecule in mast cells, It is extracted commercially from porcine intestine.

Mechanism of action:

Heparin molecules bind antithrombin III inducing a conformational change that accelerates its rate of action about 1000-fold, with the subsequent rapid inactivation of coagulation factors(most importantly, thrombin (Factor IIa) and Factor Xa . Heparin serves as a true catalyst, allowing antithrombin III to rapidly combine with and inhibit circulating thrombin and Factor Xa .
Pharmacokinetics: Absorption: the anticoagulant effect with heparin occurs within minutes of intravenous administration (or 1 to 2 hours after subcutaneous injection), (This is in comparison to the vitamin K antagonist anticoagulants, such as warfarin, the activity of which requires 8 to 12 hours.)
Heparin must be given parenterally, either in a deep subcutaneous site or intravenously. [Note: Intramuscular administration is contraindicated because of hematoma formation.] Heparin is often administered intravenously in a bolus to achieve immediate anticoagulation. This is followed by lower doses or continuous infusion of heparin for 7 to 10 days, titrating the dose so that the activated partial thromboplastin time (aPTT) is 1.5- to 2.5-fold that of the normal control.
Metabolism : In the blood, heparin binds to many proteins that neutralize its activity, it is taken up by the monocyte/macrophage system, and it undergoes metabolism in liver to inactive products. [Note: Heparin therefore has a longer half-life in patients with hepatic cirrhosis.] The inactive metabolites are excreted into the urine. Therefore, renal insufficiency also prolongs the half-life. The half-life of heparin is approximately 1.5 hours. Heparin has the advantage of speedy onset of action, which is rapidly terminated on suspension of therapy.
Therapeutic uses. Heparin has been the major antithrombotic drug for the treatment of:
1) Acute deep-vein thrombosis and pulmonary embolism. The incidence of recurrent thromboembolic episodes is also decreased.
2) Clinically, heparin is used prophylactically to prevent postoperative venous thrombosis in patients undergoing elective surgery (for example, hip replacement).
3) In patients with acute phase of myocardial infarction.
4) Coronary artery rethrombosis after thrombolytic treatment is reduced with heparin.
5) The drug is also used in extracorporeal devices (for example, dialysis machines) to prevent thrombosis.
6) Because do not cross the placenta (due to their large size and negative charge), heparin is the anticoagulant of choice for treating pregnant women with prosthetic heart valves or venous thromboembolism.
Adverse effects :-
1-Bleeding complications: The major one is haemorrage ( urinary , GIT, adrenal, haemoarthrosis, echymosis , , and acute hemoragic pancreatitis . Careful monitoring of the bleeding time is required to minimize this problem. Excessive bleeding may be managed by ceasing administration of the drug or by treating with protamine sulfate. Infused slowly, the latter combines ionically with heparin to form a stable, 1:1 inactive complex. It is very important that the dosage of protamine sulfate is carefully titrated (1 mg. for every 100 units of heparin administered).
2-Hypersensitivity reactions: Heparin preparations are obtained from porcine sources and, therefore, may be antigenic. Possible adverse reactions include chills, fever, urticaria, or anaphylactic shock.
3-Thrombosis: Chronic or intermittent administration of heparin can lead to a reduction in antithrombin III activity, thus decreasing the inactivation of coagulation factors and, thereby, increasing the risk of thrombosis. To minimize this risk, low-dose heparin therapy is usually employed.


4- Thrombocytopenia: is a common abnormality associated with the use of heparin and is called heparin-induced thrombocytopenia (HIT), can be caused by a variety of factors. Two types of this abnormality have been identified. Type I is common and involves a mild decrease in platelet number due to nonimmunologic mechanisms. Type I usually occur within the first 5 days of treatment and is not serious. In Type II, platelets are activated by an immunoglobulin G, causing platelet aggregation and release of platelet contents. This can result in thrombocytopenia and thrombosis (dangerous complications of heparin therapy occurring between the fifth and fourteenth days of treatment) that range from mild to life-threatening. Platelet counts can drop 50 percent or more, and thromboembolic complications can develop. It is imperative that heparin therapy be discontinued in such patients.
5-Heparin may produce abnormal liver function tests, and osteoporosis has been observed in patients on long term heparin therapy.
Contraindications: ABSOLUTE: Serious or active bleeding, intracranial bleeding , recent surgery , dissecting aortic aneurism, malignant HT, known patients who are hypersensitive to it.
RELATIVE: active GIT bleeding, recent stroke, sever hypertension , bacterial endocarditis, threatened abortion, sever liver or renal disease , and alcoholics.
Oral anticoagulants
Vitamin K antagonists
The coumarin anticoagulants, which include warfarin , and dicumarol , their action is by their ability to antagonize the cofactor functions of vitamin K. Warfarin is now widely employed clinically as an oral anticoagulant. The potential morbidity associated with the use of warfarin makes it important to identify those patients who are truly at risk for thrombosis. Even careful monitoring to keep the prothrombin time at 1.5- to 2.5-fold longer than normal values does not prevent bleeding complications in about 20 percent of the patients.
Mechanism of action: Several of the protein coagulation factors (including Factors II, VII, IX, and X (1972), require vitamin K as a cofactor for their synthesis by the liver, therefore when the warfarin antagonize vitamin K, the synthesis of these factors are inhibited.
Pharmacokinetics: Absorption: Warfarin is rapidly absorbed after oral administration (100% bioavailability with little individual variation). Although food may delay absorption, it does not affect the extent of absorption of the drug. Warfarin is 99 percent bound to plasma albumin, which prevents its diffusion into the cerebrospinal fluid, urine, and breast milk. Warfarin readily crosses the placental barrier. The mean half life of warfarin is approximately 40 hours. Unlike heparin, the anticoagulant effects of warfarin are not observed until 8 to 12 hours after drug administration, but peak effects may be delayed for 72 to 96 hours(the time required to deplete the pool of circulating clotting factors. The anticoagulant effects of warfarin can be overcome by the administration of vitamin K. However, reversal following administration of vitamin K takes approximately 24 hours . Prothrombin time measurement , may be used to monitor warfarin therapy.
Fate: The products of warfarin metabolism are inactive. After conjugation to glucuronic acid, they are excreted in the urine and stool.
Therapeutic uses: Warfarin is used to prevent the progression or recurrence of acute deep-vein thrombosis or pulmonary embolism after initial heparin treatment. It is also used for the prevention of venous thromboembolism during orthopaedic or gynecologic surgery. Prophylactically, it is used in patients with acute myocardial infarction, prosthetic heart valves, or chronic atrial fibrillation.
Adverse effects:
Bleeding disorders: It is important to frequently monitor and adjust the anticoagulant effect. Minor bleeding may be treated by withdrawal of the drug and administration of oral vitamin. Whole blood, frozen plasma, or plasma concentrates of the blood factors may also be employed to arrest hemorrhage. Skin lesions and necrosis are rare complications of warfarin therapy and are observed primarily in women. Purple toe syndrome, a painful, blue-tinged discoloration of the toe caused by cholesterol emboli from plaques, has also been observed with warfarin therapy.
Drug interactions: Warfarin has numerous drug interactions that may potentiate or attenuate its anticoagulant effect. Contraindications: Warfarin should never be used during pregnancy, because it is teratogenic and can cause abortion as well as birth defects.
Thrombolytic Drugs
These drugs are plasminogen activator, cause lysis of formed clots in both arteries and veins and reestablish tissue perfusion
A-Streptokinase is an extracellular protein purified from culture broths of Group C-hemolytic streptococci.
Mechanism of action: Streptokinase forms an active one-to-one complex with plasminogen. This enzymatically active complex converts uncomplexed plasminogen to the active enzyme plasmin, which dissolves hemostatic plugs . In addition to the hydrolysis of fibrin plugs, the complex also catalyzes the degradation of fibrinogen as well as clotting Factors V and VII.
Pharmacokinetics: Streptokinase therapy is instituted within 4 hours of a myocardial infarction and is infused for 1 hour. Its half-life is less than half an hour. Thromboplastin time is monitored and maintained at two- to five-fold the control value. On discontinuation of treatment, either heparin or oral anticoagulants may be administered.
Clinical uses : Originally used for the treatment of deep-vein thrombosis, and serious acute myocardial infarction, arterial thrombosis, and occluded access shunts. Treatment is effective in acute and sub acute occlusion and effective in recanalization after MI.


Adverse effects:
1-Bleeding disorders: Activation of circulating plasminogen by streptokinase leads to elevated levels of plasmin, which may precipitate bleeding by dissolving hemostatic plugs .
2-Hypersensitivity: Streptokinase is a foreign protein and is antigenic. Rashes, fever, and rarely, anaphylaxis occur. Because most individuals have had a streptococcal infection sometime in their lives, circulating antibodies against streptokinase are likely to be present in most patients. These antibodies can combine with streptokinase and neutralize its fibrinolytic properties. Therefore, sufficient quantities of streptokinase must be administered to overwhelm the antibodies and provide a therapeutic concentration of plasmin. Fever, allergic reactions, and therapeutic failure may be associated with the presence of antistreptococcal antibodies in the patient. The incidence of allergic reactions is approximately 3 percent.
Urokinaze : It is not antigenic in human , directly bound and activate both circulating fibrin and plasminogen , half life 10-20 min. , used for recent pulmonary emboli , and more effective than heparin in large pulmonary emboli.
B. Alteplase: (formerly known as tissue plasminogen activator, or tPA) is a serine protease originally derived from cultured human melanoma cells. It is now obtained as a product of recombinant DNA technology.
Mechanism of action: Alteplase has a low affinity for free plasminogen in the plasma, but it rapidly activates plasminogen that is bound to fibrin in a thrombus or a hemostatic plug. Thus, alteplase is said to be fibrin selective, and at low doses, it has the advantage of lysing only fibrin, without unwanted degradation of other proteins. This contrasts with streptokinase, which acts on free plasminogen and induces a general fibrinolytic state.
Pharmacokinetics: Alteplase has a very short half-life (about 5 minutes) and, therefore, is administered as a total dose equal to 0.9 mg/kg. Ten percent of the total dose injected intravenously as a bolus and the remaining drug is administered over 60 minutes.
Therapeutic uses: Alteplase is approved for the treatment of myocardial infarction, massive pulmonary embolism, and acute ischemic stroke. Alteplase seems to be superior to streptokinase in dissolving older clots and, ultimately, may be approved for other applications. Alteplase, administered within 3 hours of the onset of ischemic stroke, significantly improves clinical ouecome.
Adverse effects: Bleeding complications, including gastrointestinal and cerebral hemorrhages, may occur.
Platelet Aggregation Inhibitors
A. Aspirin : The platelet membrane phospholipases liberate arachidonic acid. Arachidonic acid is first converted to prostaglandin E2 by COX-1; prostaglandin E2 is further metabolized to thromboxane A2, Thromboxane A2 produced , promotes the clumping process that is essential to the rapid formation of a hemostatic plug. Aspirin inhibits thromboxane A2 synthesis from arachidonic acid in platelets irreversibley , The inhibitory effect is rapid, and last for the life of the anucleate platelet(approximately 7 to 10 days). Aspirin is currently employed in the prophylactic treatment of transient cerebral ischemia, to reduce the incidence of recurrent myocardial infarction, and to decrease mortality in pre and post(myocardial infarct patients). The recommended dose of aspirin ranges from 81 to 325 mg, with side effects determining the dose chosen. . Aspirin is frequently used in combination with other drugs having anticlotting properties for example, heparin or clopidogrel.
B. Ticlopidine and clopidogrel: Ticlopidine and clopidogrel are closely related thienopyridines that also block platelet aggregation, but by a mechanism different from that of aspirin.
Mechanism of action: These drugs irreversibly inhibit the binding of adenosine diphosphate (ADP) to its receptors on platelets and, thus, inhibit the activation of the GP IIb/IIIa receptors required for platelets to bind to fibrinogen and to each other.
Therapeutic use: Although ticlopidine and clopidogrel are similar in both structure and mechanism of action, their therapeutic uses are different.
Ticlopidine is approved for the prevention of transient ischemic attacks and strokes for patients with prior cerebral thrombotic event. It is also used as adjunct therapy with aspirin following coronary stent implantation to decrease the incidence of stent thrombosis. However, due to its life threatening hematologic adverse reactions, including neutropenia/agranulocytosis, thrombotic thrombocytopenic purpura (TTP), and aplastic anemia, it is generally reserved for patients who are intolerant to other therapies.
Clopidogrel is approved for prevention of atherosclerotic events following recent myocardial infarction, stroke, or established peripheral arterial disease. It is also approved for prophylaxis of thrombotic events in acute unstable angina . Additionally, clopidogrel is used to prevent thrombotic events associated with percutaneous coronary intervention with or without coronary stent. Compared to ticlopidine, clopidogrel has a better overall side-effect profile, although TTP may also occur with this agent.
Pharmacokinetics: Food interferes with the absorption of ticlopidine but not with clopidogrel. After oral ingestion, both drugs are extensively bound to plasma proteins. They undergo hepatic metabolism to active metabolites. The maximum effect is achieved in 3 to 5 days; when treatment is suspended, the platelet system requires time to recover. Elimination of the drugs and metabolites occurs by both the renal and fecal routes. Both drugs can cause prolonged bleeding for which there is no antidote. Serious adverse effects of ticlopidine include neutropenia, TTP, and aplastic anemia requiring frequent blood monitoring, especially during the first 3 months of treatment. Clopidogrel causes fewer adverse reactions, and the incidence of neutropenia is lower. However, TTP has been reported as an adverse effect for both drugs. Because these drugs can inhibit cytochrome P450, they may interfere with the metabolism of drugs such as phenytoin, tolbutamide, warfarin, fluvastatin, and tamoxifen if taken concomitantly. Indeed, phenytoin toxicity has been reported when taken with ticlopidine.
C. Abciximab The platelet GP IIb/IIIa receptor stimulate platelet aggregation , abciximab is a chimeric monoclonal antibody, By binding to GP IIb/IIIa, the antibody blocks the binding of fibrinogen and von Willebrand factor; consequently, aggregation does not occur. Abciximab is given intravenously along with heparin or aspirin as an adjunct to percutaneous coronary intervention for the prevention of cardiac ischemic complications. After cessation of infusion, platelet function gradually returns to normal, with the antiplatelet effect persisting for 24 to 48 hours. The major adverse effect of abciximab therapy is the potential for bleeding, especially if the drug is used with anticoagulants or if the patient has a clinical hemorrhagic condition. Abciximab is expensive, limiting its use in some setting.
D . Dipyridamole
Dipyridamole , a coronary vasodilator, is employed prophylactically to treat angina pectoris. It is usually given in combination with aspirin or warfarin; it is ineffective when used alone. Dipyridamole increases intracellular levels of cAMP by inhibiting cyclic nucleotide phosphodiesterase, resulting in decreased thromboxane A2 synthesis. It may potentiate the effect of prostacyclin to antagonize platelet stickiness and, therefore, decrease platelet adhesion to thrombogenic surfaces .
Drugs Used to Treat Bleeding
Bleeding problems may have their origin in naturally occurring pathologic conditions, such as hemophilia, or as a result of fibrinolytic states that may arise after gastrointestinal surgery or prostatectomy. The use of anticoagulants may also give rise to hemorrhage. Certain natural proteins and vitamin K, as well as synthetic antagonists, are effective in controlling this bleeding. For example, hemophilia is a consequence of a deficiency in plasma coagulation factors, most frequently Factors VIII and IX. Concentrated preparations of these factors are available from human donors. Blood transfusion is also an option for treating severe hemorrhage.
A. Aminocaproic acid and tranexamic acid
Fibrinolytic states can be controlled by the administration of aminocaproic acid or tranexamic acid. Both agents are synthetic, inhibit plasminogen activation, are orally active, and are excreted in the urine. A potential side effect of treatment is intravascular thrombosis.
B. Protamine sulfate : antagonizes the anticoagulant effects of heparin. This protein is derived from fish sperm , and is high in arginine content, which explains its basicity. The positively charged protamine interacts with the negatively charged heparin, forming a stable complex without anticoagulant activity. Adverse effects of drug administration include hypersensitivity as well as dyspnea, flushing, bradycardia, and hypotension when rapidly injected.
C. Vitamin K
That vitamin K1 (phytonadione) administration can stem bleeding problems due to the oral anticoagulants is not surprising, because those substances act by interfering with the action of the vitamin. The response to vitamin K is slow, requiring about 24 hours (time to synthesize new coagulation factors). Thus, if immediate hemostasis is required, fresh-frozen plasma should be infused.









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