Several anticoagulants are available. Warfarin, other coumarins, and heparins have long been used. Since the 2000s, several agents have been introduced that are collectively referred to as direct oral anticoagulants (DOACs).
Coumarins (vitamin K antagonists) These oral anticoagulants are derived from
coumarin found in many plants. A prominent member of this class,
warfarin (Coumadin), was found to be the anticoagulant most prescribed in a large multispecialty practice. The anticoagulant effect takes at least 48 to 72 hours to develop. Where an immediate effect is required,
heparin is given concomitantly. These anticoagulants are used to treat patients with
deep-vein thrombosis (DVT) and
pulmonary embolism (PE) and to prevent emboli in patients with
atrial fibrillation (AF), and mechanical
prosthetic heart valves. Other examples are
acenocoumarol,
phenprocoumon,
atromentin, and
phenindione. The coumarins
brodifacoum and
difenacoum are used as mammalicides (particularly as
rodenticides) but are not used medically.
Heparin and derivative substances Heparin is the most widely used intravenous clinical anticoagulant worldwide.
Heparin is a naturally occurring
glycosaminoglycan. There are three major categories of heparin: unfractionated heparin (UFH), low molecular weight heparin (LMWH), and ultra-low-molecular weight heparin (ULMWH). Unfractionated heparin is usually derived from
pig intestines and bovine lungs. UFH binds to the enzyme inhibitor
antithrombin III (AT), causing a conformational change that results in its activation. The activated AT then inactivates
factor Xa,
thrombin, and other coagulation factors. Heparin can be used
in vivo (by injection), and also
in vitro to prevent blood or plasma clotting in or on medical devices. In
venipuncture,
Vacutainer brand blood collecting tubes containing heparin usually have a green cap.
Low molecular weight heparin (LMWH) Low molecular weight heparin (LMWH) is produced through a controlled depolymerization of unfractionated heparin. These agents include
direct thrombin inhibitors, such as
dabigatran, and
direct factor Xa inhibitors including
rivaroxaban,
apixaban,
betrixaban and
edoxaban. DOACs have been shown to be as good or possibly better than the coumarins with less serious side effects. The newer anticoagulants (NOACs/DOACs) are more expensive than the traditional ones and should be used in caring for patients with kidney problems. Compared to warfarin, DOACs have a rapid onset action and relatively short half-lives; hence, they carry out their function more rapidly and effectively, allowing drugs to reduce their anticoagulation effects quickly. Routine monitoring and dose adjustments of DOACs are less important than for warfarin, as they have better predictable anticoagulation activity. Both DOACs and warfarin are equivalently effective, but compared to warfarin, DOACs have fewer drug interactions, no known dietary interactions, a wider therapeutic index, and have conventional dosing that does not require dose adjustments with constant monitoring. However, there is no countermeasure for most DOACs, unlike for warfarin; nonetheless, the short half-lives of DOACs will allow their effects to recede swiftly. A reversal agent for dabigatran,
idarucizumab, is currently available and approved for use by the FDA. Rates of adherence to DOACs are only modestly higher than adherence to warfarin among patients prescribed these drugs. Thus, adherence to anticoagulation is often poor despite hopes that DOACs would lead to higher adherence rates. DOACs are significantly more expensive than warfarin, but the patients on DOACs may experience reduced lab costs as they do not need to monitor their INR. Darexaban development was discontinued in September 2011; in a trial for prevention of recurrences of myocardial infarction in addition to dual antiplatelet therapy (DAPT), the drug did not demonstrate effectiveness, and the risk of bleeding was increased by approximately 300%. The development of letaxaban for acute coronary syndrome was discontinued in May 2011 following negative results from a Phase II study.
Direct thrombin inhibitors Another type of anticoagulant is the
direct thrombin inhibitor. Current members of this class include the bivalent drugs
hirudin,
lepirudin, and
bivalirudin and the monovalent drugs
argatroban and
dabigatran. An oral direct thrombin inhibitor,
ximelagatran (Exanta), was denied approval by the
Food and Drug Administration (FDA) in September 2004 and was pulled from the market entirely in February 2006 after reports of severe liver damage and heart attacks. In November 2010,
dabigatran etexilate was approved by the FDA to prevent thrombosis in
atrial fibrillation.
Relevance to dental treatments As in any invasive procedure, patients on anticoagulation therapy have an increased risk for bleeding, and caution should be used along with local
hemostatic methods to minimize bleeding risk during the operation as well as postoperatively. However, with regards to DOACs and invasive dental treatments, there has not been enough clinical evidence and experience to prove any reliable adverse effects, relevance or interaction between these two. Further clinical prospective studies on DOACs are required to investigate the bleeding risk and hemostasis associated with surgical and dental procedures. Recommendations of modifications to the usage/dosage of DOACs before dental treatments are made based on the balance of the bleeding risk of each procedure and also the individual's own bleeding risks and renal functionality. With low-bleeding-risk dental procedures, it is recommended that DOACs be continued by the patient to avoid any increase in the risk of a thromboembolic event. For dental procedures with a higher risk of bleeding complications (i.e. complex extractions, adjacent extractions leading to a large wound, or more than three extractions), the recommended practice is for the patient to miss or delay a dose of their DOAC before such procedures to minimize the effect on bleeding risk.
Antithrombin protein therapeutics The antithrombin protein is used as a
protein therapeutic that can be purified from human plasma or produced recombinantly (for example, Atryn, produced in the milk of
genetically modified goats). The FDA approves Antithrombin as an anticoagulant for preventing clots before, during, or after surgery or birthing in patients with hereditary antithrombin deficiency.
Other Many other anticoagulants exist in
research and development,
diagnostics, or as drug candidates. •
Batroxobin, a
toxin from
snake venom, clots platelet-rich plasma without affecting
platelet functions (cleaves
fibrinogen). •
Hementin is an anticoagulant protease from the salivary glands of the giant Amazon leech,
Haementeria ghilianii. •
Vitamin E •
Alcoholic beverage ==Reversal agents==