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Evaluation
Clinical
Evaluation
A reasonable clinical suspicion is required to avoid
missing the diagnosis of pulmonary embolism. Evaluating the likelihood of pulmonary
embolism in an individual patient according to the clinical presentation is of
utmost importance in the interpretation of diagnostic test results and the
selection of an appropriate diagnostic strategy. A bedside transthoracic
echocardiogram may be done in patients who are hemodynamically unstable to
differentiate suspected high-risk pulmonary embolism from other acute
life-threatening conditions. Patients should also be evaluated for risk factors
for venous thromboembolism.
It is recommended to perform initial risk
stratification in hemodynamically unstable patients with suspected or confirmed
pulmonary embolism to identify those with a high risk of early mortality. Acute
pulmonary embolism severity may be stratified using validated scores from
combined clinical, laboratory, and imaging prognostic factors in patients who
are hemodynamically stable. The Pulmonary Embolism Severity Index (PESI)
identifies the patient's overall mortality risk using pulmonary embolism severity
and comorbidity. A score of ≥1 indicates a 30-day mortality risk of 10.9% in
the simplified version of PESI.
Absolute Contraindications to
Thrombolysis
The following are absolute contraindications to thrombolysis:
- Hemorrhagic stroke or stroke of unknown origin at any time
- Major trauma, surgery, or head injury in the past 3 weeks
- Ischemic stroke within the past 6 months
- Central nervous system (CNS) damage or tumors
- Severe coagulation disorders
- Active bleeding
- Known increased risk for bleeding (bleeding diathesis)
Relative Contraindications to Thrombolysis
The following are relative contraindications to thrombolysis:
- Transient ischemic attack within the past 6 months
- Puncture of a non-compressible vessel
- Uncontrolled severe hypertension (systolic blood pressure of >180 mmHg, diastolic blood pressure [DBP] of >100 mmHg)
- Neurosurgery or ophthalmologic surgery within the last 1 month
- Ischemic stroke within the last 2 months
- Gastrointestinal bleeding within the last 10 days
- Active peptic ulcer disease
- Recent traumatic cardiopulmonary resuscitation (CPR)
- Pregnancy or within 1 week postpartum
- Infective endocarditis
- Oral anticoagulant therapy
- Advanced liver disease
Prompt Management of
Clinical Instability
Oxygen (O2)
Supplementation
Oxygen supplementation may be necessary in patients
with hypoxemia. Hypoxemia can usually be reversed with nasal oxygen so
mechanical ventilation is rarely necessary.
Mechanical Ventilation
Mechanical ventilation may be needed temporarily in
patients who appear toxic and hypoxic. Care should be taken to limit its
hemodynamic adverse effects. Positive intrathoracic pressures induced by
mechanical ventilation may reduce venous return and worsen right ventricular
failure. Low tidal volumes of approximately 6 mL/kg body weight are recommended.
Hemodynamic Support
Fluid Loading
Fluids may be administered initially and cautiously,
but other vasoactive therapies should promptly follow. The usefulness of fluid
challenge is controversial and should not exceed 500 mL over 15 to 30 minutes.
It may be harmful when systemic hypotension is present.
Adrenergic Agonists
Adrenergic agonists should be considered for
patients with low cardiac index and normal blood pressure or with impending
hypotension. In high-risk pulmonary embolism patients, Dobutamine and/or
Norepinephrine should be considered.
Please
see Adrenergic Agonists
under Pharmacological
Therapy: Prompt Management of Clinical Instability
for further information.
Nitric Oxide Inhalation
Nitric oxide inhalation may be indicated in patients with pulmonary
hypertension and a patent foramen ovale. It may improve the hemodynamic status and
gas exchange in patients with pulmonary embolism.
Principles of therapy
Phases of Anticoagulation in Deep
Vein Thrombosis
The initial treatment phase is given up to 10 days with
the aim of rapidly initiating anticoagulation to prevent the progression of deep
vein thrombosis and pulmonary embolism.
The principal treatment phase is given during the first
3 months to maintain therapeutic levels of anticoagulation to prevent deep vein
thrombosis progression and pulmonary embolism and reduce the risk of early
recurrent venous thromboembolism. Anticoagulation for 3 months is recommended
in patients with provoked proximal deep vein thrombosis with a major transient
risk factor.
The extended treatment phase after 3 months of
primary treatment is given to reduce the long-term risk of recurrent venous
thromboembolism. It is recommended for patients with second or subsequent
unprovoked deep vein thrombosis. Indefinite anticoagulation is recommended in
patients with a high risk of recurrence unless the patient is with a high risk
of bleeding, including patients with active cancer or persistent major risk factors
(eg rheumatic disorder, severe thrombophilia). Extended anticoagulation is
recommended in patients with a medium risk of recurrence which includes
patients with recurrent venous thromboembolism, unprovoked event, minor, soft
transient risk factors (eg travel), obesity, heart failure, chronic obstructive
pulmonary disease (COPD), and male gender.
General Therapy Principles
Regarding Heparin
Anticoagulation should be administered without delay
in patients with intermediate or high clinical probability of pulmonary
embolism during diagnostic workup and in low probability patients once pulmonary
embolism is confirmed.
If pulmonary embolism occurs postoperatively,
Heparin therapy should be started after consultation with the surgeon and at 12
to 24 hours after major surgery. Treatment could be delayed even longer if
there is any evidence of bleeding from the surgical site.
Similar initial and long-term treatment is
recommended for asymptomatic deep vein thrombosis. Protamine sulfate may be used for the reversal
of anticoagulation.
General Therapy Principles Regarding Anticoagulant Therapy
For patients with deep vein thrombosis or pulmonary embolism, the primary treatment of 3 months duration is recommended:
- Proximal deep vein thrombosis or pulmonary embolism provoked by major surgery or trauma that is transient: Treatment is stopped after 3 months
- Proximal deep vein thrombosis or pulmonary embolism which is unprovoked or associated with a non-surgical transient risk factor: Treat for 3 to 6 months
- Proximal deep vein thrombosis or pulmonary embolism which is recurrent unprovoked, provoked by active cancer or antiphospholipid antibody syndrome or by a chronic risk factor: Treat with extended anticoagulation
- Distal deep vein thrombosis provoked by a transient risk factor: Treat for 6 weeks
- Distal deep vein thrombosis which is unprovoked or with persisting risk factors: Treatment is stopped after 3 months
Thrombus Removal
Early thrombus removal strategies may be considered
in patients with symptomatic iliofemoral deep vein thrombosis.
Thrombolysis in Massive or
Sub-Massive Pulmonary Embolism
High-risk pulmonary embolism patients are
recommended to receive systemic thrombolytic therapy. Patients with hemodynamic
deterioration on anticoagulation therapy are recommended to undergo rescue
thrombolytic treatment. Studies have shown a more rapid improvement in
radiographic and hemodynamic abnormalities in acute massive pulmonary embolism
patients who received thrombolytic agents followed by anticoagulant agents over
conventional anticoagulant agents alone. There were no clinically relevant
outcomes for death rate or for the resolution of symptoms.
Treatment started within 48 hours of symptom onset
provides the most benefit, though thrombolysis can still be used in those who
are symptomatic for 6 to 14 days. Catheter-directed thrombolytic therapy may
also be considered in patients with massive iliofemoral deep vein thrombosis
(weigh risk vs benefit) with symptoms of <14 days, limb-threatening deep
vein thrombosis (phlegmasia cerulea dolens), good functional status, low risk
of bleeding, and ≥1-year life expectancy.
Massive Pulmonary Embolism
The use of thrombolytic therapy in pulmonary
embolism should be individualized. Patients with hemodynamically unstable pulmonary
embolism who are at low risk of bleeding are the most appropriate candidates.
Thrombolytic therapy may also be considered in
patients with compromised oxygenation; free-floating right ventricular thrombus
or patent foramen ovale documented by echocardiography; and massive
hemodynamically significant pulmonary embolism without systemic hypotension or
profound hypoxemia.
Sub-massive Pulmonary Embolism
The use of thrombolytics in patients with
sub-massive pulmonary embolism (hemodynamically stable patients with echocardiographic
and/or biomarker evidence of right ventricular dysfunction) is controversial.
Further studies are needed to show a clinically relevant improvement in the
benefit-risk ratio of thrombolytic treatment over traditional anticoagulant
therapy in these patients.
Thrombolysis may be reasonably considered in select
younger patients with sub-massive pulmonary embolism at low bleeding risk or
for those with high decompensation risk because of concomitant cardiopulmonary
disease.
Please
see Thrombolytic Agents
under Pharmacological Therapy: Thrombolysis
in Massive or Sub-massive Pulmonary Embolism
for further information.
Pharmacological therapy
Parenteral Anticoagulants in the Management of Deep Vein
Thrombosis and Non-massive Pulmonary Embolism
Unfractionated Heparin (UFH) and
Low-Molecular-Weight Heparin (LMWH)
Both subcutaneous LMWH and intravenous UFH short-course
treatments are recommended for objectively confirmed non-massive pulmonary
embolism. Either LMWH or UFH is appropriate for the initial treatment of pulmonary
embolism. It is not recommended to give UFH or LMWH monotherapy in patients with
severe renal impairment (Creatinine Clearance [CrCl] of <30 mL/min).
UFH
Intravenous UFH treatment in pulmonary embolism is
well-established. UFH should be considered as a first-dose bolus; for massive
or sub-massive pulmonary embolism; without delay in suspected high-risk pulmonary
embolism patients with hemodynamic instability; and when rapid reversal of
effect may be required.
It may also be given to patients with high bleeding
risks, receiving thrombolysis, or undergoing invasive procedures. It is used
for the initial management of patients with phlegmasia cerulea dolens delivered
in combination with aggressive leg elevation and fluid resuscitation. Patients
with confirmed pulmonary embolism and hemodynamic instability may be given
continuous UFH infusion with thrombolytic therapy. UFH is preferred over LMWH in
patients with severe renal failure.
Intravenous UFH has been proven effective in the
therapy of pulmonary embolism and deep vein thrombosis. Studies have shown a
reduced mortality rate when UFH has been used to treat venous thromboembolism
disease. The recurrence of venous thromboembolism is unusual when UFH is
infused at a rate that prolongs the aPTT >1.5-2.5 times the control value and
when adequate levels are reached within 24 hours. Intravenous UFH typically requires hospitalization with
close laboratory monitoring and dose adjustment. The most common complication
is Heparin-induced thrombocytopenia.
LMWH
LMWH should be used whenever possible for the
initial inpatient treatment of deep vein thrombosis rather than UFH. LMWH is
superior to UFH for the initial treatment of deep vein thrombosis in terms of
reducing mortality and the risk of major bleeding during the initial therapy.
LMWH is now preferred over UFH in patients with acute
non-massive pulmonary embolism and it is also preferred over vitamin K
antagonists (VKA). LMWH or Fondaparinux is recommended over UFH for the
acute-phase treatment of low- or intermediate-risk pulmonary embolism.
It may be a treatment option for venous
thromboembolism in patients with brain tumors. It is also used for the initial management
of patients with phlegmasia cerulea dolens delivered in combination with aggressive
leg elevation and fluid resuscitation.
A number of studies have shown that LMWH has equal
efficacy to UFH in patients with non-massive pulmonary embolism. Patients with symptomatic pulmonary embolism
should initially be treated in the hospital because of decreased
cardiorespiratory reserve, complications, and for monitoring of International
Normalized Ratio (INR) to guide Warfarin therapy.
The use of LMWH is safe
and effective and may shorten hospital stay and improve the quality of life for
patients. Monotherapy with LMWH may be used in patients with active cancer or
established renal failure and considered in patients with liver disease and
coagulopathy. It may also be given concurrently with a vitamin K antagonist for
patients with active cancer or antiphospholipid syndrome. Outpatient management
of deep vein thrombosis should be extended to include stable patients with stable
pulmonary embolism who have been carefully screened for risk factors for
hemorrhage.
Laboratory monitoring is not required except for a
regular platelet count before treatment initiation and on the fifth day, then
every 2 to 3 days if LMWH treatment is continued.
Fondaparinux
Fondaparinux is also a preferred initial treatment
for deep vein thrombosis and pulmonary embolism. Heparin assay (anti-factor Xa)
has been used to monitor the effects of Fondaparinux. Warfarin is initiated
usually within 72 hours of therapy. A platelet count should be obtained prior
to the start of therapy.
Duration of Therapy
Treatment with UFH, LMWH, or Fondaparinux should be
continued for at least 5 to 7 days after the initiation of Warfarin and until
therapeutic INR is stable and ≥2.0 (range: 2.0 to 3.0) for 2 consecutive days.
Oral Anticoagulants in the Management of Deep Vein Thrombosis and
Non-massive Pulmonary Embolism
Non-Vitamin K Antagonist Oral
Anticoagulants (NOACs)
Example
drugs: Apixaban, Dabigatran, Edoxaban, Rivaroxaban
Non-vitamin K antagonist oral anticoagulants are also
known as direct oral anticoagulants (DOACs). They are the recommended
anticoagulant agents for patients with leg deep vein thrombosis or pulmonary
embolism during the first 3 months of therapy. They are preferred over vitamin
K antagonists in eligible pulmonary embolism patients for the acute-phase
treatment of low- or intermediate-risk pulmonary embolism.
Drug interactions are few, bleeding risk is low, and
routine monitoring is not required. Studies suggest that non-vitamin K
antagonist oral anticoagulants have a safety advantage over conventional
therapy for venous thromboembolism treatment in Asian patients. They may be
given to patients with renal impairment or active cancer. They may also be a
treatment option for venous thromboembolism in patients with brain tumor.
Apixaban and Rivaroxaban are given according to the
single-drug approach (monotherapy) while Dabigatran and Edoxaban should be
given after initial treatment with Heparin (dual therapy). For the reversal of
anticoagulation, Idarucizumab may be used for patients taking Dabigatran while
Andexanet alfa may be used for patients taking Apixaban or Rivaroxaban.
Ciraparantag is an investigational agent that can bind and inhibit factor Xa
inhibitors, UFH, LMWH, and Fondaparinux.
Apixaban
When Apixaban is given, prior Heparin treatment is
not necessary, though short courses of Heparin should be given when there is a treatment
delay. Apixaban is considered an alternative agent to LMWH for patients with cancer-associated
thrombosis without high risk for gastrointestinal or genitourinary bleeding.
Dabigatran etexilate
Dabigatran etexilate is approved for the management
of deep vein thrombosis and pulmonary embolism in patients who have been
treated with parenteral anticoagulant for 5 to 10 days, and to reduce the risk
of recurrent deep vein thrombosis and pulmonary embolism in patients who have
been previously treated.
Edoxaban
Edoxaban may be used for the treatment of deep vein
thrombosis and pulmonary embolism in patients who have been treated with parenteral
anticoagulant for 5 to 10 days. It is considered an alternative agent to LMWH for
pulmonary embolism patients with cancer (except gastrointestinal cancer).
Rivaroxaban
Rivaroxaban is an initial treatment for both pulmonary
embolism and deep vein thrombosis without additional anticoagulation. A direct
factor Xa inhibitor that is non-inferior to Warfarin in the management of acute
venous thromboembolism. It is considered an alternative agent to LMWH for
pulmonary embolism patients with cancer (except gastrointestinal cancer).
Warfarin
Warfarin is a vitamin K antagonist and is used to
reduce the risk of venous thromboembolism recurrence and complications. It should
only be started once venous thromboembolism has been reliably confirmed. It is
started on day 1 of Heparin therapy.
Bolus dose is not effective; therefore, it requires
at least 5 days to achieve its full effects. Thus, it is recommended that
Warfarin therapy overlap with parenteral anticoagulation for at least 4 to 5
days until therapeutic INR is stable and >2.0 (range: 2.0 to 3.0) in 2
consecutive readings.
A high-loading dose
(>10 mg) of Warfarin is not recommended as it has no clinical use, and it
predisposes patients to hemorrhage at the start of therapy. Overdose may be
reversed easily with vitamin K administration.
Warfarin overlapping with UFH, LMWH, or dose-reduced
Enoxaparin may be considered in patients with severe renal impairment,
established renal failure or increased risk of bleeding. Patients with
antiphospholipid antibody syndrome are recommended to undergo indefinite vitamin
K antagonist treatment.
Prompt
Management of Clinical Instability
Adrenergic Agonists
Dobutamine
Dobutamine is considered a first-line agent to treat
right-sided heart failure and cardiogenic shock. It affects vasodilatation of
both systemic and pulmonary vascular beds and increases myocardial
contractility while decreasing right-sided filling pressures.
Dopamine
Dopamine has also been used for hemodynamic support
in pulmonary embolism patients. Its use may be limited by the development of
tachycardia.
Epinephrine
Epinephrine may be effective when shock complicates
acute pulmonary embolism. Its vasoconstrictor effect is similar to
Norepinephrine. Its inotropic effect is more due to potent β1
stimulation rather than the β2 effect, accounting for improved
pulmonary vascular resistance.
Norepinephrine
Norepinephrine may be appropriate in acute massive pulmonary
embolism when there is profound hypertension (eg cardiogenic shock).
Norepinephrine stimulates both α-adrenergic (inducing vasoconstriction) and β1-adrenergic
receptors (augmenting cardiac contractility) resulting in improved systemic blood
pressure, cardiac output, pulmonary vascular resistance, and right ventricular
pressure. A combination with other vasoactive agents (eg Dobutamine) needs
further evaluation.
Thrombolysis in Massive or
Sub-Massive Pulmonary Embolism
Thrombolytic
Agents
Alteplase (Recombinant Tissue Plasminogen Activator [rt-PA])
Alteplase has comparable thrombolytic capacity to
Streptokinase and Urokinase but can be administered for a shorter duration (2
hours). It is the preferred thrombolytic agent because of its shorter
administration time.
Streptokinase or Urokinase
Streptokinase and Urokinase have similar
thrombolytic effects in pulmonary embolism and have been shown to resolve pulmonary
embolism comparatively at 24 hours and 3x that as seen with Heparin alone. 12
hours of Urokinase has equivalent thrombolytic efficacy to 24 hours of
Streptokinase.
Nonpharmacological: Patient Education
Patient Education
Educate patients and their families about deep vein
thrombosis or pulmonary embolism, especially its signs and symptoms, risk of
recurrence of disease, risk of long-term disability, and the possibility of
genetic predisposition. Explain the treatment options to patients and discuss
the benefits, risks, and side effects of anticoagulation therapy. Discuss
lifestyle issues with patients and advise patients to drink plenty of fluids. The
lay public may not be familiar with pulmonary embolism and discussing it may
assuage their emotional burden.
Bed Rest and Leg Elevation
The affected extremity should be elevated above the
level of the heart until edema and tenderness subside.
Early Ambulation
Early ambulation is preferred over bed rest when
feasible in patients with acute deep vein thrombosis.
Exercise
Encourage patients confined to a chair or bed to
perform regular leg exercises.
Graduated Elastic Compression
Stockings (GECS)
Graduated elastic compression stockings provide
continuous stimulation of blood flow and prevent dilation of the venous system
in the legs. It counteracts increased venous pressure and improves venous flow
leading to the reduction of edema and optimal calf muscle function.
Graduated elastic
compression stockings combined with early ambulation do not increase the
chances of developing pulmonary embolism and provide faster resolution of pain and
swelling. It is recommended to start at 1 month of diagnosis of proximal deep
vein thrombosis until a minimum of 2 years to prevent post-thrombotic syndrome.
Graduated compression, knee-high, custom-fitted stockings with at least 30 to 40
mmHg on the affected leg may be used. Use may be limited to 6 to 12 months in
patients with proximal deep vein thrombosis and with limited signs and symptoms.
It should be used with caution in patients with post-thrombotic syndrome.
It is contraindicated in patients with peripheral artery disease or severe CHF.
Some studies show the ineffectiveness of graduated elastic compression
stockings for prophylaxis and they also cause lower extremity skin damage;
thus, routine use of compression stockings is not recommended in patients with
deep vein thrombosis, with or without an increased risk of post-thrombotic
syndrome.
Invasive Procedures
In patients with cardiac arrest or refractory
circulatory collapse, extracorporeal membrane oxygenation (ECMO) may be considered
in combination with a catheter-directed treatment or surgical embolectomy.
Catheter Extraction
Catheter extraction involves the suction extraction
of pulmonary embolism under fluoroscopy with ECG monitoring. This approach
should be reserved for highly compromised patients who cannot receive
thrombolytic therapy or whose status is so critical that it does not allow time
to infuse thrombolytic therapy.
Pulmonary Embolectomy
Pulmonary embolectomy is performed in emergency situations when more conservative measures have failed. It should be reserved for the following patients:
- Massive pulmonary embolism (preferably angiographically documented)
- Hemodynamic instability despite Heparin and resuscitation
- High-risk pulmonary embolism or hemodynamically deteriorating patients with failure of thrombolytic therapy or contraindication to its use
Thrombectomy
Percutaneous Venous Thrombectomy
Patients with acute deep vein thrombosis should not
be treated with percutaneous thrombectomy alone.
Surgical Venous Thrombectomy
Surgical venous thrombectomy reduces acute symptoms and
post-thrombotic morbidity in patients with acute iliofemoral deep vein
thrombosis. These patients have extensive venous thrombosis and have
contraindications for anticoagulation and thrombolytic therapy.
Vena Caval Interruption
Inferior Vena Caval (IVC)
Filters
Inferior vena caval filters should be considered in deep
vein thrombosis or pulmonary embolism patients with contraindication or
complication of anticoagulant therapy and in patients with large, free-floating
iliocaval thrombus or with a pulmonary embolism that developed during
anticoagulation therapy. Consider removing the inferior vena caval filter if
anticoagulation has been established and is no longer contraindicated.
Inferior vena caval may also be considered in
patients who suffer from recurrent venous thromboembolism despite adequate
anticoagulant therapy and patients with chronic recurrent embolism with pulmonary
hypertension. It may be indicated after surgical embolectomy or pulmonary
thromboendarterectomy.
It is preferable in patients with proximal deep vein thrombosis with
active hemorrhage, platelet count <50,000 x 109/L, or previous
intracerebral hemorrhage. It should not be used routinely in patients with deep
vein thrombosis who are also being treated with anticoagulants.