Browse the corpus

A deep-vein thrombosis (DVT) is a blood clot that forms within the deep veins, usually of the leg, but can occur in the arms and the mesenteric and cerebral veins. Deep-vein thrombosis is a common and important disease. It is part of the venous thromboembolism disorders, representing the third most common cause of death from cardiovascular disease after heart attacks and stroke. Even in patients who do not get pulmonary emboli, recurrent thrombosis and "post-thrombotic syndrome" are major causes of morbidity. This activity reviews the etiology, presentation, evaluation, and management of deep vein thrombosis and reviews the role of the interprofessional team in evaluating, diagnosing, and managing the condition. Objectives: Discuss the risk factors for developing deep vein thrombosis. Describe the examination findings and evaluation process of a patient with suspected deep vein thrombosis, including indicated laboratory analysis. Summarize the treatment and management strategies for deep vein thrombosis, including preventative measures. Outline the evaluation and management of deep vein thrombosis and the role of interprofessional team members in collaborating to provide well-coordinated care and enhance patient outcomes. Access free multiple choice questions on this topic.

Deep vein thrombosis (DVT) is an obstructive disease with a hindering venous reflux mechanism.[1] DVT usually involves the lower limb venous system, with clot formation originating in a deep calf vein and propagating proximally.[2] See Image. Deep Vein Thrombosis. It is a common venous thromboembolic (VTE) disorder with an incidence of 1.6 per 1000 annually.[3] The rate of particular site involvement depends on the anatomical location as follows, distal veins 40%, popliteal 16%, femoral 20%, common femoral 20%, and iliac veins 4%.[4] A deep-vein thrombosis (DVT) is a blood clot that forms within the deep veins, usually of the leg, but can occur in the arms and the mesenteric and cerebral veins. Deep-vein thrombosis is a common and important disease. It is part of the venous thromboembolism disorders, representing the third most common cause of death from cardiovascular disease after heart attacks and stroke. Even in patients who do not get pulmonary emboli, recurrent thrombosis and "post-thrombotic syndrome" are major causes of morbidity.[5][6][7] Deep-vein thrombosis is a major medical problem accounting for most cases of pulmonary embolism. Only through early diagnosis and treatment can the morbidity be reduced.

Risk Factors Following are the risk factors that are considered causes of deep venous thrombosis: Reduced blood flow: Immobility (bed rest, general anesthesia, operations, stroke, long flights)[8][9] Increased venous pressure: Mechanical compression or functional impairment leading to reduced flow in the veins (neoplasm, pregnancy, stenosis, or congenital anomaly which increases outflow resistance)[10] Mechanical injury to the vein: Trauma, surgery, peripherally inserted venous catheters, previous DVT, intravenous drug abuse [11][12][11] Increased blood viscosity: Polycythaemia rubra vera, thrombocytosis, dehydration [13] Anatomic variations in venous anatomy can contribute to thrombosis Increased Risk of Coagulation Genetic deficiencies: Anticoagulation proteins C and S, antithrombin III deficiency, factor V Leiden mutation [14][15][16] Acquired: Cancer, sepsis, myocardial infarction, heart failure, vasculitis, systemic lupus erythematosus and lupus anticoagulant, inflammatory bowel disease, nephrotic syndrome, burns, oral estrogens, smoking, hypertension, diabetes [12][17] Constitutional Factors Obesity, pregnancy, the advanced age of older than 60, surgery, critical care admission, dehydration, and cancer are the established causalities of DVT and VTE.[18][19][20][21] Obesity is associated with a hypercoagulability status via two mechanisms, 1. increased fibrinogen levels that may even surpass twofold the normal value, and 2. slower venous circulation flow in the infra diaphragmatic and especially in the lower limbs.[20] Both factors, associated with disorders in several coagulation factors, favor the appearance of venous thrombosis, thrombophlebitis, and thromboembolic events, and mostly fatal pulmonary thromboembolisms (PE), which are the primary cause of mortality in obese patients.[20]

Obesity, pregnancy, the advanced age of older than 60, surgery, critical care admission, dehydration, and cancer are the established causalities of DVT and VTE.[18][19][20][21] Obesity is associated with a hypercoagulability status via two mechanisms, 1. increased fibrinogen levels that may even surpass twofold the normal value, and 2. slower venous circulation flow in the infra diaphragmatic and especially in the lower limbs.[20] Both factors, associated with disorders in several coagulation factors, favor the appearance of venous thrombosis, thrombophlebitis, and thromboembolic events, and mostly fatal pulmonary thromboembolisms (PE), which are the primary cause of mortality in obese patients.[20] Potential risk factors of deep vein thrombosis might be categorized according to the transient, persistent, or unprovoked criteria. Accordingly, transient risk factors are as follows: 1. surgery with general anesthetics, 2. hospitalization, 3. Cesarean section, 4. hormone replacement therapy, 5. pregnancy and peripartum period, 6. lower extremity injury with limited mobility for more than 72 hours.[4] It should be noted that general anesthesia for longer than 30 minutes and hospitalization for longer than 72 hours are considered the transient risk factors of DVT.[4] However, active cancers and specific medical conditions that increase the risk of venous thromboembolism are categorized as persistent risk factors. Systemic lupus erythematosus and inflammatory bowel disease are among the predisposing medical conditions.[4] Any further etiological risk factors not categorized among either transient or persistent subgroups should be labeled as unprovoked VTE.[4][1] For instance, a recent cohort study, including 500 participants evaluating the association of blood lipid levels and lower extremity DVT (LEDVT), demonstrated that higher total cholesterol levels, high-density lipoprotein (HDL-C), and apolipoprotein A1 (ApoA1) were associated with a decreased risk of lower extremity DVT (LEDVT). However, higher triglyceride levels (TG) were associated with a greater risk of LEDVT.[1]

Incidence and prevalence: Deep-vein thrombosis and pulmonary emboli are common and often "silent" and thus go undiagnosed or are only picked up at autopsy. Therefore, the incidence and prevalence are often underestimated. It is thought the annual incidence of DVT is 80 cases per 100,000, with a prevalence of lower limb DVT of 1 case per 1000 population.[1] Annually in the United States, more than 200,000 people develop venous thrombosis; of those, 50,000 cases are complicated by pulmonary embolism.[22][23][24] Age: Deep-vein thrombosis is rare in children, and the risk increases with age, most occurring in the over-40 age group.[1] Gender: There is no consensus about whether there is a sex bias in the incidence of DVT. Ethnicity: There is evidence from the United States that there is an increased incidence of DVT and an increased risk of complications in African Americans and white people compared to Hispanic and Asian populations. Associated diseases: In the hospital, the most commonly associated conditions are malignancy, congestive heart failure, obstructive airway disease, and patients undergoing surgery.

According to the Virchow triad, the following are the main pathophysiological mechanisms involved in DVT: Damage to the vessel wall Blood flow turbulence Hypercoagulability Thrombosis is a protective mechanism that prevents the loss of blood and seals off damaged blood vessels. Fibrinolysis counteracts or stabilizes thrombosis. The triggers of venous thrombosis are frequently multifactorial, with the different parts of the triad of Virchow contributing in varying degrees in each patient, but all result in early thrombus interaction with the endothelium. This stimulates local cytokine production and causes leukocyte adhesion to the endothelium, promoting venous thrombosis. Depending on the relative balance between the coagulation and thrombolytic pathways, thrombus propagation occurs. DVT is commonest in the lower limb below the knee and starts at low-flow sites, such as the soleal sinuses, behind venous valve pockets.[25][26][27] A potential correlation between DVT and atherosclerosis (AS) has been proposed.[1] The endothelial dysfunction involved in the pathophysiological mechanism of DVT would potentially result in AS. Accordingly, a greater risk of subsequent AS in patients with DVT is predicted.[1]

In the venous system following acute thrombosis formation, an extensive remodeling process occurs. Neutrophils and macrophages infiltrate the fibrin clot from within the lumen of the vessel over weeks leading to cytokine release and, eventually, fibroblast and collagen replacement of fibrin. This remodeling and fibrosis can result in diminished blood flow long after the acute thrombosis resolves.[28]

The clinical presentation of acute lower extremity DVT varies with the anatomic distribution, extent, and degree of occlusion of the thrombus. Symptoms may range from absence to massive swelling and cyanosis with impending venous gangrene. Three patterns of thrombosis are usually recognized: isolated calf vein (distal), femoropopliteal, and iliofemoral thrombosis, and symptoms tend to be more severe as thrombosis extends more proximally (see Video. Popliteal Deep Vein Thrombosis With Partial Color Flow, Video). However, up to 50% of patients with acute DVT may lack specific signs or symptoms. [5][6] Postoperative patients are, in particular, more likely to have small, asymptomatic, distal, non-occlusive thrombi. When present, signs and symptoms of acute lower extremity DVT may include pain, edema, erythema, tenderness, fever, prominent superficial veins, pain with passive dorsiflexion of the foot (Homan’s sign), and peripheral cyanosis. Phlegmasia cerulea dolens, characterized by the triad of massive swelling, cyanosis, and pain, is the most severe form of acute lower extremity DVT and results from complete thrombosis of an extremity’s venous outflow.[7] In advanced cases, it is marked by severe venous hypertension with collateral and microvascular thrombosis, leading to venous gangrene. Venous gangrene is particularly associated with warfarin-mediated protein C depletion in patients with cancer or heparin-induced thrombocytopenia.[8][9] Obtaining the diagnosis of DVT only based on clinical signs and symptoms is notoriously inaccurate. The signs and symptoms of DVT are generally non-specific. They may be associated and misdiagnosed with other lower extremity disorders. Accordingly, lymphedema, superficial venous thrombosis, and cellulitis should be excluded. However, the most common presenting symptoms with inconsistent sensitivity and specificity are calf pain and swelling. The former index has a sensitivity of 75% to 91% and a specificity of 3% to 87%, and the latter might have a sensitivity of up to 97% and a specificity of up to 88%.[29] None of the signs or symptoms is sufficiently sensitive or specific, either alone or in combination, to accurately diagnose or exclude thrombosis.[30] History Pain (50% of patients) Redness Swelling (70% of patients) Physical Examination Limb edema (may be unilateral or bilateral if the thrombus extends to pelvic veins)

Obtaining the diagnosis of DVT only based on clinical signs and symptoms is notoriously inaccurate. The signs and symptoms of DVT are generally non-specific. They may be associated and misdiagnosed with other lower extremity disorders. Accordingly, lymphedema, superficial venous thrombosis, and cellulitis should be excluded. However, the most common presenting symptoms with inconsistent sensitivity and specificity are calf pain and swelling. The former index has a sensitivity of 75% to 91% and a specificity of 3% to 87%, and the latter might have a sensitivity of up to 97% and a specificity of up to 88%.[29] None of the signs or symptoms is sufficiently sensitive or specific, either alone or in combination, to accurately diagnose or exclude thrombosis.[30] History Pain (50% of patients) Redness Swelling (70% of patients) Physical Examination Limb edema (may be unilateral or bilateral if the thrombus extends to pelvic veins) Red and hot skin with dilated veins Tenderness

The following veins are categorized as deep veins according to the Clinical-Etiology-Anatomy-Pathophysiology (CEAP) classification: 1. inferior vena cava, 2. common iliac, 3. internal and external iliac, 4. pelvic veins, including a. gonadal, and b. broad ligament veins, 5. common femoral, 6. deep femoral vein, 7. femoral, 8. popliteal, 9. paired crural veins of anterior and posterior tibial and peroneal, 10. muscular veins of gastrocnemial, and soleal.[31] As per the National Institute for Clinical Excellence guidelines following investigations are done: D-dimers (very sensitive but not very specific) Coagulation profile Proximal leg vein ultrasound, which, when positive, indicates that the patient should be treated as having a DVT Deciding how to investigate is determined by the risk of DVT. The first step is to assess the clinical probability of a DVT using the Wells scoring system. The clinical probability is low for patients with a score of 0 to 1, but for those with two or above, the clinical probability is high. If a patient scores 2 or above, either a proximal leg vein ultrasound scan should be done within 4 hours, and if the result is negative, a D-dimer test should be done. If imaging is not possible within 4 hours, a D-dimer test should be undertaken, and an interim 24-hour dose of a parenteral anticoagulant should be given. A proximal leg vein ultrasound scan should be carried out within 24 hours of being requested. In the case of a positive D-dimer test and a negative proximal leg vein ultrasound scan, the proximal leg vein ultrasound scan should be repeated 6 to 8 days later for all patients. If the patient does not score 2 on the DVT Wells score, but the D-dimer test is positive, the patient should have a proximal leg vein ultrasound scan within 4 hours, or if this is not possible, the patient should receive an interim 24-hour dose of a parenteral anticoagulant. A proximal leg vein ultrasound scan should be carried out within 24 hours of being requested. In all patients diagnosed with DVT, treat as if there is a positive proximal leg vein ultrasound scan.[32][33][34]

If the patient does not score 2 on the DVT Wells score, but the D-dimer test is positive, the patient should have a proximal leg vein ultrasound scan within 4 hours, or if this is not possible, the patient should receive an interim 24-hour dose of a parenteral anticoagulant. A proximal leg vein ultrasound scan should be carried out within 24 hours of being requested. In all patients diagnosed with DVT, treat as if there is a positive proximal leg vein ultrasound scan.[32][33][34] Clinical decision rules such as the Pulmonary Embolism Rule-Out Criteria (PERC) and the Wells Criteria should be employed with the patient presenting with a possible DVT. Risk stratification is crucial in deciding diagnostic and management options. Patients who meet PERC criteria may need no further testing, whereas those who do not meet PERC criteria and are low probability based on the Wells criteria may be candidates for rule-out with a D-dimer. The D-dimer test is sensitive but not specific and should be used selectively in a low-probability patient who does not have other confounding diagnoses that could produce a false positive test. The test also should be used with caution, perhaps with different cut-off values in the elderly.[5][6][7][8] Imaging modalities available to evaluate for DVT include diagnostic ultrasound, vascular studies, CT venograms, and point-of-care ultrasound (POCUS). The POCUS exam is described below. Rapid diagnosis or rule-out by the emergency provider can expedite necessary treatment and reduce the length of stay, and it is particularly useful when access to 24-hour ultrasound is unavailable. There is evidence that emergency practitioners can perform a two-point compression exam at the two highest probability sites for identifying a DVT: femoral and popliteal veins. However, recent literature suggests a 2-region approach where clinicians do serial compression testing may significantly improve diagnostic sensitivity without greatly increasing diagnostic time. This point-of-care ultrasound exam should be used with other clinical decision rules and is perhaps most useful in those patients with high and low pre-test probability.

Imaging modalities available to evaluate for DVT include diagnostic ultrasound, vascular studies, CT venograms, and point-of-care ultrasound (POCUS). The POCUS exam is described below. Rapid diagnosis or rule-out by the emergency provider can expedite necessary treatment and reduce the length of stay, and it is particularly useful when access to 24-hour ultrasound is unavailable. There is evidence that emergency practitioners can perform a two-point compression exam at the two highest probability sites for identifying a DVT: femoral and popliteal veins. However, recent literature suggests a 2-region approach where clinicians do serial compression testing may significantly improve diagnostic sensitivity without greatly increasing diagnostic time. This point-of-care ultrasound exam should be used with other clinical decision rules and is perhaps most useful in those patients with high and low pre-test probability. With the patient supine in the frog-leg position, apply approximately 20 to 30 degrees of reverse Trendelenburg to increase venous distention. Place the high-frequency linear transducer (5 to 10 MHz) in the transverse plane at the anatomical location of the inguinal ligament. Just distal to the inguinal ligament, the common femoral vein can be visualized. Apply direct pressure to the vein. The complete collapse of the vein indicates there is no presence of a DVT. Continue distally along the femoral vein to where the greater saphenous vein and deep femoral vein deviate from the common femoral vein. Complete compression of all venous structures at these levels rules out a proximal DVT. Next, proceed to the popliteal region. Laterally rotate the leg, flex the knee, and place the high-frequency transducer transversely in the popliteal fossa. The popliteal vein typically resides just anterior to the popliteal artery. Apply a compressive force once again and observe for complete compression. Compress the areas just proximal and distal to the popliteal fossa as well to complete the two-region technique. If DVT studies are negative, repeat testing may be required in one to two weeks to rule out a propagating calf DVT further. Alternatively, sending a D-dimer test may be adequate in certain patient populations. Typical laboratory tests also should be sent to evaluate for coagulation status, blood count, and renal function.[9][10][35]

Treatment of DVT aims to prevent pulmonary embolism, reduce morbidity, and prevent or minimize the risk of developing post-thrombotic syndrome. The cornerstone of treatment is anticoagulation. NICE guidelines only recommend treating proximal DVT (not distal) and those with pulmonary emboli. In each patient, the risks of anticoagulation need to be weighed against the benefits.[36][37][38] Treatment for DVT should be addressed mainly according to the underlying causality of DVT as follows: The preferred anticoagulant to address DVT in cancer-associated thromboembolism is low molecular weight heparin and factor Xa inhibitors, including rivaroxaban.[39] However, in the following circumstances, the higher levels of anticoagulation should be considered: 1. recently diagnosed cancer, 2. extensive VTE circumstances, and 3. cancer treatment-related adverse effects, including vomiting.[40] In circumstances where once-daily oral therapy is the preferred management, the following options are viable; 1. rivaroxaban, 2. edoxaban, and 3. vitamin-K antagonist (VKA) In the context of liver disease, DVT should be managed with low-molecular-weight heparin.[41] Direct oral anticoagulants (DOACs) are contraindicated in raised INR levels. In patients with renal disease suppressed creatinine clearance to less than 30 ml/min, VKAs are recommended. DOACs and LMWH should be avoided in patients with end-stage renal disease. In patients with a remarkable past medical history of coronary artery disease, the following alternatives are recommended: 1. VKA, 2. rivaroxaban, 3. apixaban, and 4. edoxaban.[42] In patients with remarkable dyspepsia or any past medical history suggestive of gastrointestinal bleeding, VKA, and apixaban are the preferred treatments. It should be noted that DOCAs, eg, dabigatran, factor Xa inhibitors, eg, rivaroxaban, and selective factor Xa inhibitors, eg, edoxaban, might be associated with higher rates of gastrointestinal bleeding.[43][44][45] In the group of patients with a history compatible with poor compliance, VKA is preferred. However, it should be noted that some patients might still be highly compliant with other alternatives, including DOACs.[46] If thrombolytic therapy is indicated, unfractionated heparin is indicated.[47] In patients who might later be subjected to reversal of thrombolytic therapy, it should be noted that reversal agents for DOACs are not universally available.

In the group of patients with a history compatible with poor compliance, VKA is preferred. However, it should be noted that some patients might still be highly compliant with other alternatives, including DOACs.[46] If thrombolytic therapy is indicated, unfractionated heparin is indicated.[47] In patients who might later be subjected to reversal of thrombolytic therapy, it should be noted that reversal agents for DOACs are not universally available. Since most anticoagulants have the potential to cross the placenta, the preferred anticoagulation therapy during pregnancy is LMWH. Moreover, the following guidelines address the required duration of treatment. Prescribe low-molecular-weight heparin or fondaparinux for 5 days or until the international normalized ratio (INR) is greater than 2 for 24 hours (unfractionated heparin for patients with renal failure and increased risk of bleeding). Supplement with vitamin K antagonists for 3 months. In patients with cancer, consider anticoagulation for 6 months with low-molecular-weight heparin. In patients with unprovoked DVT, consider vitamin K antagonists beyond 3 months. Rivaroxaban is an oral factor Xa inhibitor that has recently been approved by the Food and Drug Administration and NICE and is attractive because there is no need for regular INR monitoring. If the platelet count drops to less than 75,000, switch from heparin to fondaparinux, which is not associated with heparin-induced thrombocytopenia. Thrombolysis: The indications for the use of thrombolytics include: Symptomatic iliofemoral DVT Symptoms of less than 14 days duration Good functional status A life expectancy of 1 year or more Low risk of bleeding The use of thrombolytic therapy can result in an intracranial bleed, and hence, careful patient selection is vital. Recently endovascular interventions like catheter-directed extraction, stenting, or mechanical thrombectomy have been tried with moderate success. Compression hosiery: Below-knee graduated compression stockings with an ankle pressure greater than 23 mm Hg for 2 years if there are no contraindications Inferior vena cava filters: If anticoagulation is contraindicated or if emboli are occurring despite adequate anticoagulation Newer Drugs

The use of thrombolytic therapy can result in an intracranial bleed, and hence, careful patient selection is vital. Recently endovascular interventions like catheter-directed extraction, stenting, or mechanical thrombectomy have been tried with moderate success. Compression hosiery: Below-knee graduated compression stockings with an ankle pressure greater than 23 mm Hg for 2 years if there are no contraindications Inferior vena cava filters: If anticoagulation is contraindicated or if emboli are occurring despite adequate anticoagulation Newer Drugs Rivaroxaban, apixaban, dabigatran, edoxaban, and betrixaban are relatively newer factor Xa inhibitors approved for prophylaxis of deep vein thrombosis. The duration of DVT treatment is 3 to 6 months, but recurrent episodes may require at least 12 months of treatment. Patients with cancer need long-term treatment. Inferior vena cava filters are not recommended in acute DVT. There are both permanent and temporary inferior vena cava filters available. These devices may decrease the rate of recurrent DVT but do not affect survival. Today, only patients with contraindications to anticoagulation with an increased risk of bleeding should have these filters inserted.

The following are differential diagnoses of deep venous thrombosis: Cellulitis Post-thrombotic syndrome (especially venous eczema and lipodermatosclerosis) Ruptured Baker cyst Trauma Superficial thrombophlebitis Peripheral edema, heart failure, cirrhosis, nephrotic syndrome Venous or lymphatic obstruction Arteriovenous fistula and congenital vascular abnormalities Vasculitis [35]

Given the increased risk of thromboembolism, patients with clinically active malignancy would benefit from thromboprophylaxis. A meta-analysis looking at a total of 33 trials and 11,972 patients provided more evidence that thromboprophylaxis decreased the incidence of VTE in cancer patients who were undergoing chemotherapy or surgery, with no apparent increase in the incidence of significant bleeding.[7] Current guidelines from the National Comprehensive Cancer Network (NCCN) recommend anticoagulation with unfractionated heparin or low molecular weight heparin in hospitalized cancer patients as thromboprophylaxis. Mechanical prophylaxis should be used instead of anticoagulation therapy in patients experiencing active bleeding, thrombocytopenia (platelet count below 50,000/MCL), evidence of hemorrhagic coagulopathy, or having an indwelling neuraxial catheter. Contraindications to mechanical prophylaxis include acute deep venous thrombosis and severe arterial insufficiency. A recent meta-analysis addressed the question of the optimum duration of anticoagulation in cancer patients hospitalized with acute illnesses. This study looked at trials comparing standard-duration versus extended-duration anticoagulation prophylaxis. The risk of VTE was not significantly lower in the extended-duration prophylaxis group of patients, but the risk of bleeding was about 2-fold higher.[8] Regarding outpatient VTE prophylaxis, surgical pelvic or abdominal oncology patients would benefit from continuing VTE prophylaxis up to four weeks post-operation. The use of aspirin or anticoagulation therapy for patients with multiple myeloma on immunomodulatory medications is recommended based on risk stratification with the IMPEDE VTE score.[9][10] For patients with solid cancers on chemotherapy and high Khorana score, prophylactic anticoagulation with direct oral anticoagulation or low molecular weight heparin showed a decrease in the incidence of pulmonary embolism.[11]

A recent meta-analysis addressed the question of the optimum duration of anticoagulation in cancer patients hospitalized with acute illnesses. This study looked at trials comparing standard-duration versus extended-duration anticoagulation prophylaxis. The risk of VTE was not significantly lower in the extended-duration prophylaxis group of patients, but the risk of bleeding was about 2-fold higher.[8] Regarding outpatient VTE prophylaxis, surgical pelvic or abdominal oncology patients would benefit from continuing VTE prophylaxis up to four weeks post-operation. The use of aspirin or anticoagulation therapy for patients with multiple myeloma on immunomodulatory medications is recommended based on risk stratification with the IMPEDE VTE score.[9][10] For patients with solid cancers on chemotherapy and high Khorana score, prophylactic anticoagulation with direct oral anticoagulation or low molecular weight heparin showed a decrease in the incidence of pulmonary embolism.[11] Low molecular weight heparin (LMWH) remains the preferred anticoagulation option for managing cancer-associated thrombosis.[12] The dosage recommendation for LMWH is 1 mg/kg every 12 hours and 1 mg/kg once daily for patients with creatinine clearance of less than 30 mL/minute. Avoid the use of LMWH in patients on dialysis. Other treatment options include direct oral anticoagulants like apixaban, rivaroxaban, edoxaban, fondaparinux, and warfarin. In the Caravaggio trial, researchers found apixaban to be non-inferior to LMWH in treating cancer-associated VTE without an increased risk of significant bleeding.[13] Thrombolytic therapy can be used in patients with life or limb-threatening pulmonary embolism or acute deep vein thrombosis considering contraindications such as intracranial tumors or metastasis, active bleeding, and a history of intracranial hemorrhage. NCCN recommends a treatment duration minimum of 3 months or for the duration of active malignancy. For patients with non-catheter-related deep venous thrombosis or pulmonary embolism, indefinite anticoagulation is the recommendation.

Thrombolytic therapy can be used in patients with life or limb-threatening pulmonary embolism or acute deep vein thrombosis considering contraindications such as intracranial tumors or metastasis, active bleeding, and a history of intracranial hemorrhage. NCCN recommends a treatment duration minimum of 3 months or for the duration of active malignancy. For patients with non-catheter-related deep venous thrombosis or pulmonary embolism, indefinite anticoagulation is the recommendation. Continuing to assess for benefits vs. risks, as well as monitoring for complications, is essential. In patients with DVT located in the inferior vena cava, iliac, femoral, and popliteal veins, in addition to a contraindication to therapeutic anticoagulation, placement of retrievable vena cava filters can prevent pulmonary embolism. Once placed, it is important to periodically assess patients for resolution of contraindications, removal of the vena cava filters, and switching to therapeutic anticoagulation. For patients with catheter-associated thrombosis, treatment consists of removing the catheter or anticoagulation if the catheter remains.[10]

The severity of the disease is classified as follows: Provoked: Due to acquired states (surgery, oral contraceptives, trauma, immobility, obesity, cancer) Unprovoked: Due to idiopathic or endogenous reasons; more likely to suffer recurrence if anticoagulation is discontinued Proximal: Above the knee, affecting the femoral or iliofemoral veins; much more likely to lead to complications such as pulmonary emboli Distal: Below the knee

The prognosis for DVT includes the following: Many DVTs will resolve with no complications. Post-thrombotic syndrome occurs in 43% of patients 2 years post-DVT (30% mild, 10% moderate, and severe 3%). The risk of recurrence of DVT is high (up to 25%). Death occurs in approximately 6% of DVT cases and 12% of pulmonary embolism cases within one month of diagnosis. Early mortality after venous thromboembolism is strongly associated with the presentation of pulmonary embolism, advanced age, cancer, and underlying cardiovascular disease.

Deep-vein thromboses can occur in many settings and almost every medical specialty; failing to diagnose DVT can result in a pulmonary embolus, which can be fatal. DVTs also result in more prolonged admission to the hospital and drug treatment that can last 3 to 9 months, all of which add to the cost of healthcare. Thus its diagnosis and management are best made with an interprofessional healthcare team consisting of clinicians, specialists, nurses, physical therapists, vascular technicians, and pharmacists. The focus is on the prevention of DVT. In addition to clinicians, both nurses and pharmacists are vital in educating patients about DVT prophylaxis. Nurses are the first professionals to encounter patients being admitted to the hospital, and it is here that the prevention of DVT starts. Nurses must educate the patients on the importance of ambulation, complying with compression stockings, and taking the prescribed anticoagulation medications. In both the operating room and post-surgery, nurses play a key role in reminding physicians of the need for DVT prophylaxis. Each hospital has guidelines on DVT prophylaxis and treatment, and all healthcare workers should follow them. Once a DVT has developed, the pharmacist should be familiar with the current anticoagulants and their indications. They can consult with the prescribing/ordering clinician and perform medication reconciliation. Plus, the pharmacist must educate the patients on the need for treatment compliance and the need to undergo regular testing to ensure that the INR is therapeutic.[37][52] Once DVT is diagnosed, the treatment is with an anticoagulant for 3 to 6 months, and again, monitoring of the INR by a hematology nurse or pharmacist is necessary. Further, these patients need to be monitored for bleeding. Open communication between the interprofessional team is the only way to treat DVT and lower the morbidity of the drugs safely. Outcomes

Once a DVT has developed, the pharmacist should be familiar with the current anticoagulants and their indications. They can consult with the prescribing/ordering clinician and perform medication reconciliation. Plus, the pharmacist must educate the patients on the need for treatment compliance and the need to undergo regular testing to ensure that the INR is therapeutic.[37][52] Once DVT is diagnosed, the treatment is with an anticoagulant for 3 to 6 months, and again, monitoring of the INR by a hematology nurse or pharmacist is necessary. Further, these patients need to be monitored for bleeding. Open communication between the interprofessional team is the only way to treat DVT and lower the morbidity of the drugs safely. Outcomes Nearly 300,000 patients die from a pulmonary embolus yearly in the US alone. Despite countless guidelines and education of healthcare workers, DVT prophylaxis is often not done. The fact is that DVT is preventable in the majority of patients, and the onus is on healthcare workers to be aware of the condition. For those who develop a DVT and survive, post-thrombotic phlebitis is a lifelong sequela with no ideal treatment.[53][54] This is why interprofessional care coordination and open communication is crucial to managing these patients long-term.