Continuing Education Activity

Tissue plasminogen activator (tPA) is classified as a serine protease (enzymes that cleave peptide bonds in proteins). It is thus one of the essential components of the dissolution of blood clots. Its primary function includes catalyzing the conversion of plasminogen to plasmin, the primary enzyme involved in dissolving blood clots. Examples of these drugs include alteplase, reteplase, and tenecteplase. Indications for the use of tPA include ischemic stroke (most common) in patients presenting to treating facility within 3 hours (4.5 hours in certain, eligible patients) after the onset of symptoms, myocardial Infarction if there would be a delay of more than 1 to 2 hours before percutaneous transluminal coronary angioplasty, pulmonary embolism in massive pulmonary embolisms, causing severe instability due to high pressure on the heart, and thrombolysis (e.g., deep vein thrombosis). This activity outlines the indications, mechanism of action, methods of administration, significant adverse effects, contraindications, toxicity, and monitoring of tPA agents so providers can direct patient therapy where they are indicated as part of the interprofessional team.

Objectives:

• Assess the mechanism of action of tissue plasminogen activators.
• Identify the indications for initiating therapy with a tPA agent, differentiating between individual agents where appropriate.
• Evaluate the contraindications of tPA medications.
• Communicate interprofessional team strategies for improving care coordination to properly use tPA agents to improve patient outcomes in varied scenarios where they can be effective.

Indications

Tissue plasminogen activator (tPA) is classified as a serine protease (an enzyme that cleaves peptide bonds in proteins). It is thus 1 of the essential components of blood clot dissolution. Its primary function includes catalyzing the conversion of plasminogen to plasmin, the primary enzyme involved in dissolving blood clots. Recombinant biotechnology has allowed tPA to be manufactured in labs, and these synthetic products are called recombinant tissue plasminogen activators (tPA). These drugs have undergone various modifications to amplify their pharmacokinetics and pharmacodynamics, especially prolonging their short half-life in circulation and increasing their fibrin specificity to prevent an unwanted fibrinolytic state. Examples of these drugs include alteplase, reteplase, and tenecteplase. Indications for the use of tPA include the following:

1. Ischemic stroke (most common) in patients presenting to the treating facility within 3 hours (4.5 hours in certain, eligible people) after the onset of symptoms.[1][2]
2. Myocardial infarction would be a delay of more than 1 to 2 hours before percutaneous transluminal coronary angioplasty.[3] 
3. Pulmonary embolism in massive pulmonary embolisms causes severe instability due to high pressure on the heart.[4] 
4. Thrombolysis (eg, deep vein thrombosis).[5]

Definitions

• Alteplase is the normal human plasminogen activator and is FDA-approved for managing patients with ischemic stroke, myocardial infarction with ST-elevation, acute massive pulmonary embolism, and those with central venous access devices.[6][7]  
• Reteplase is a modified form of human tPA with similar effects but a faster onset and longer duration of action. It is currently FDA-approved for the management of acute myocardial infarction. It is preferred over alteplase due to its longer half-life, allowing it to be given as a bolus injection rather than through an infusion like alteplase.[8][9]
• Tenecteplase is another modified version of tPA with a longer half-life. Its indication is the management of acute myocardial infarction.[10]

Mechanism of Action

tPA is a thrombolytic (ie, it breaks up blood clots) formed by aggregating activated platelets into fibrin meshes by activating plasminogen. More specifically, it cleaves the zymogen plasminogen at its Arg561-Val562 peptide bond to form plasmin, a serine protease. Plasmin, an endogenous fibrinolytic enzyme, breaks the cross-links between fibrin molecules, which are the structural support of the blood clot, and its activity is extremely short-lived. This short duration is because alpha 2-antiplasmin, an abundant inhibitor of plasmin, quickly inactivates it and restricts the action of plasmin to the vicinity of the clot.[11] The following sequence summarizes the action of tPA:

1. tPA attaches to the fibrin on the clot surface.
2. It activates the fibrin-bound plasminogen.
3. Plasmin is subsequently cleaved from the plasminogen affiliated with the fibrin.
4. The plasmin breaks up the molecules of fibrin, and the clot dissolves.

Plasminogen activator inhibitor 1 (PAI 1) eventually terminates the catalytic activity of tPA by binding to it, and this inactive complex (PAI 1-bound tPA) is removed from the circulation by the liver via the scavenger receptor, LDL receptor-related protein 1 (LRRP1). In the nervous system, a neuronal-specific inhibitor of tPA, neuroserpin, acts similarly to PAI 1, and the LRRP1 internalizes the inactive tPA-neuroserpin complexes for removal from circulation.[12][13]

Administration

Alteplase

Alteplase administration is via the intravenous route. However, for catheter clearance, it is administered directly into the catheter.

Acute Myocardial Infarction

To manage acute myocardial infarction in adults, administer alteplase as soon as possible after the onset of symptoms. The patient's weight determines the dose to be administered, which does not exceed 100 mg irrespective of the selected administration method (accelerated infusion preferred by the AHA/ACCA or slower, 3-hour infusion as per manufacturer's labeling). 

Accelerated infusion (1 to 1/2 hr):

• For patients who weigh less than or equal to 67 kg: 15 mg IVP bolus is administered over 1 to 2 minutes, followed by 0.75 mg/kg intravenous infusion given over 30 minutes (not to exceed 50 mg), followed by 0.5 mg/kg intravenously over the following 60 minutes (not to exceed 35 mg over 1 hour).

• For patients who weigh greater than 67 kg: (A total of 100 mg is infused over 1.5 hours) 15 mg intravenous pyelogram (IVP) bolus is administered over 1 to 2 minutes, followed by 50 mg intravenous infusion during the next 30 minutes, and then the remaining 35 mg over the following 60 minutes. 

 3-hour infusion:

• For patients who weigh less than 65 kg: A dose of 0.075 mg/kg IVP bolus is administered over 1 to 2 minutes, followed by a 0.675 mg/kg infusion over the rest of the first hour, and, lastly, 0.25 mg/kg intravenously over the next 2 hours. 

• Patients weighing 65 kg or more: A 100 mg total dose is infused over 3 hours. Six to 10 mg IVP bolus is given over 1 to 2 minutes, followed by 50 to 54 mg over the rest of the first hour (ie, 60 mg in the first hour including 6 to 10 mg bolus), and then 20 mg/hr over the next 2 hours.

Pulmonary Embolism

• Infuse 100 mg intravenously over 2 hours. Institute parenteral anticoagulation towards the end of or immediately following the alteplase infusion when the thrombin time or PTT returns to less than 2 times the reference range.

Acute Ischemic Stroke

• A dose of 0.9 mg/kg is given through intravenous infusion, not to exceed 90 mg total dose. Ten percent of the total dose is administered as an intravenous bolus over 1 minute, and the remaining is gradually infused over 60 minutes.[14]

  Dosing considerations for acute ischemic stroke:

1. Intracranial hemorrhage should be excluded as the primary cause of stroke before initiation of treatment.
2. Administer alteplase as soon as possible but ideally within 3 hours after onset of symptoms.
3. Monitor and control the blood pressure during and after administration.
4. In patients who have not recently used oral anticoagulants or heparin, treatment can start before the coagulation study test results are available.
5. Discontinue if the pretreatment INR exceeds 1.7 or the aPTT is elevated.

Arterial Thrombosis and Embolism

• 0.05 to 0.1 mg/kg/hr is given by transcatheter intra-arterial infusion for about 1 to 8 hours or until the lysis of the thrombus.

Central Venous Catheter Occlusion 

• 1 mg/mL, intracatheter
• Adult patients who weigh less than 30 kg: Administer 110% of the lumen volume of the catheter (intracatheter), not exceeding 2 mg/2 mL; then retain in the catheter for around 0.5 to 2 hours; can instill a second dose if the catheter remains occluded.
• Patients who weigh more than or equal to 30 kg: Administer 2 mg/2 mL, which should be retained in the catheter for around 0.5 to 2 hours. If the catheter remains occluded, a second dose can be instilled. 
• Pediatric patients who weigh less than 30 kg: Administer 110% of the measured internal lumen volume of the catheter with alteplase, not exceeding 2 mg/2 mL.
• Pediatric patients who weigh 30 kg or more: Instill 2 mg of alteplase into the occluded catheter.

After 30 minutes of dwell time, assess the catheter's function by attempting to aspirate blood; if blood cannot be aspirated 120 minutes after dwell time, a second dose may be administered, and the process repeated. If catheter function is restored, aspirate 4 to 5 mL of blood in patients who weigh 10 kg or more (aspirate around 3 mL if the patient weighs less than 10 kg) to remove the drug and the residual clot. Then, gently irrigate with 0.9% NaCl. 

Pleural Catheter or Chest Tube Drainage

• Concurrent TPA and human deoxyribonuclease (DNAse) can be administered intrapleurally through the chest tube or pleural catheters. It has been shown to assist with better drainage of thick, loculated effusions like empyema. 

Reteplase

• Reteplase is administered intravenously as soon as possible after the onset of symptoms.[15]
• Adult patients: Initially, administer 10 units of intravenous bolus (over 2 minutes), with the second dose given 30 minutes after the first (for a total cumulative dose of 20 units). An intravenous line is used to administer the bolus injection, and no other medication should be simultaneously injected or infused through this intravenous line.
• Pediatric patient safety and efficacy are not established.

Tenecteplase

• Tenecteplase is administered intravenously as soon as possible after the onset of symptoms.[16]
• In adult patients, administer a 30 to 50 mg intravenous bolus over 5 seconds 1 time (based on weight): 30 mg for patients weighing less than 60 kg; 35 mg for patients weighing 60 to 70 kg; 40 mg for patients weighing 70-80 kg; 45 mg for patients weighing 80 to 90 kg; 50 mg for patients weighing more than 90 kg.
• Pediatric patient safety and efficacy not established.

Adverse Effects

Alteplase: Adverse effects occur in 1% to 10% of the people who receive alteplase. The most common adverse effect is bleeding, and the most serious is a stroke. Other side effects include bruising, pulmonary edema, arterial embolism, deep vein thrombosis, orolingual angioedema, intracranial hemorrhage, shock, hypersensitivity, nausea/vomiting, seizure, ischemic stroke, thromboembolism, and sepsis.[17][18]

Tenecteplase: Adverse effects occur in more than 10% of patients receiving tenecteplase. The most common is minor bleeding. Other adverse effects include fever, myocardial infarction, reperfusion arrhythmias, nausea/vomiting, edema, allergic reaction, and cholesterol embolization.[17][18][19]

Reteplase: As with other tPAs, the most common adverse effect seen with reteplase is bleeding. Other observed adverse effects include reperfusion arrhythmias, hypotension, nausea/vomiting, cardiogenic shock, muscle pain, allergic reaction, a reaction at the injection site, anemia, gastrointestinal/urogenital bleeding, intracranial hemorrhage, and cholesterol embolization.[18][20]

Contraindications

Do not administer tPA for the treatment of acute ischemic stroke in the following scenarios:

• If the risk of bleeding and serious complications are greater than the potential benefit of tPA therapy. These include patients with current intracranial hemorrhage, subarachnoid hemorrhage, and those who have active internal bleeding. 
• If the patient underwent recent (less than 3 months ago) intracranial or intraspinal surgery or suffered a serious head trauma 
• Evidence of intracranial conditions that may increase the risk of bleeding
• Bleeding diathesis (hemorrhagic diathesis)
• Patients with severe uncontrolled hypertension[21][22][23]

Do not administer tPA in the management of acute myocardial infarction or pulmonary embolism in the following:

• If the risk of bleeding is greater than any potential benefit. This risk includes active internal bleeding or patients with a recent history of stroke. 
• Recent (within 3 months) intracranial or intraspinal surgery or serious head trauma
• Presence of intracranial pathologies that may increase the risk of bleeding
• Bleeding diathesis (hemorrhagic diathesis)
• Current severe uncontrolled hypertension[21]

Do not administer tPA in any patient who had a hypersensitivity reaction to a previous dose of tPA (urticarial or anaphylactic reactions)[21][24]

Monitoring

Monitoring During Therapy With tPA

• Perform a regular neurologic assessment on the patient.
• Check thoroughly for major or minor bleeding.
• Continuously monitor the blood pressure of the patient.
• Check for the signs and symptoms of intracranial hemorrhage.
• Check for the signs of orolingual angioedema.
• Discontinue tPA infusion and order an emergency computed tomography scan if the patient develops a severe headache, severe hypertension, nausea/vomiting, or a worsening neurologic examination.
• If a hypersensitivity reaction occurs in the patient, stop the tPA administration and immediately initiate supportive therapy with antihistamines and corticosteroids.[25][26]

Monitoring After Therapy With tPA

• Follow the patient to monitor for any neurologic deterioration.
• Check for any major or minor bleeding.
• Monitor and strictly control blood pressure.
• Order a follow-up computed tomography scan or MRI at least 24 hours before initiating anticoagulants or antiplatelet agents.
• Continue to monitor for hypersensitivity and signs of orolingual angioedema.[25][26][27]

Toxicity

Aminocaproic acid is the drug used to reverse tPA toxicity, an FDA-approved drug for managing acute bleeding caused by increased fibrinolytic activity. It acts as an effective inhibitor for proteolytic enzymes like plasmin, the primary enzyme responsible for fibrinolysis.[28][29]

Drug Interactions

Monitor closely with any drug that causes anticoagulation as there is an increased risk of bleeding.

• Defibrotide: Through pharmacodynamic synergism, defibrotide increases the effects of tPA drugs and is thus contraindicated.
• Prothrombin complex concentrate, human: This can cause pharmacodynamic antagonism of the tPA drugs.
• Apixaban: Apixaban and tPA drugs increase anticoagulation and can lead to an increased bleeding risk.
• Nitroglycerin: This could decrease the serum concentration of tPA drugs.
• Salicylates: These could enhance the toxic effects of thrombolytic drugs. Monitor therapy, as there is an increased risk of bleeding.

Enhancing Healthcare Team Outcomes

tPA has a significant risk of causing complications as well as helping the patient. An interprofessional medical team consisting of clinicians (MDs, DOs, NPs, and PAs), specialists, nurses, pharmacists, and clinicians exercising open lines of communication should monitor patients receiving this drug to provide the safest care and best patient outcome. Interprofessional collaboration and open communication can improve patient outcomes with fewer adverse effects.

Review Questions

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• Comment on this article.

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Disclosure: Talha Jilani declares no relevant financial relationships with ineligible companies.

Disclosure: Abdul Siddiqui declares no relevant financial relationships with ineligible companies.