Acute Coronary Syndrome I

Question 1

Acute Coronary Syndromes

• aka
• Refers to…
• Result of…
• Associated w/…

Answer 1

• aka
  
  • ACS, syndromes of acute myocardial ischemia, or unstable coronary syndrome
• Refers to…
  
  • ST elevation myocaridal infarction (STEMI)
  • Non-ST segment myocardial infarction (STEMI)
  • Unstable angina pectoris (UA): syndrome of threatening MI
• Result of…
  
  • Tissue death
  • Necrosis
  • Hypoxia
• Associated w/…
  
  • Increased risk of systemic or pulmonary embolism
  • Supports role of anti-thrombotic therapy as part of therapy

Question 2

Plaque Disruption (“Unstable Plaque”) & the Pathophysiology of the ACS

• Acute myocardial ischemia in most cases is the result of…
• Underlying pathophysiology
• Plaque

Answer 2

• Acute myocardial ischemia in most cases is the result of…
  
  • Dynamic limitations in coronary blod flow (a “supply” problem)
    
    • Not a “demand” problem that causes chronic stable MI
  • Can occur at any time in the course of coronray atherosclerosis
• Underlying pathophysiology
  
  • Deterioration & disruption of an atherosclerotic plaque –> sudden occlusion of coronary artery
• Plaque
  
  • Mildly narrowing & flow-limiting
  • Porr in calcium & fibrous tissue
  • Rich in lipids
  • May become inflamed due to…
    
    • Attaining a certain threshold level of oxidized lipid
    • Infection of a plaque
    • Involvement in the plaque by a systemic inflammatory process

Question 3

Dynamic & Transient Limitations in Coronary Blood Flow & the Pathophysiology of the ACS

• Inflammation, “self-digestion,” & ateriosclerotic plaque disruption lead to…
• Transient limitations in coronary blood flow result in…
• Eventual outcome of this process determines…
• If this process is kept in check…

Answer 3

• Inflammation, “self-digestion,” & ateriosclerotic plaque disruption lead to…
  
  • Varying degrees of plaque disruption (prothrombotic)
  • Endothelial cell dysfunction
  • Abnormal vasoconstriction in the region of the deteriorating plaque
• Transient limitations in coronary blood flow result in…
  
  • Clot & abnormal vasoconstriction wax & wane in the coronary vessel
  • Can occur for hours, days, or weeks
  • Accounts for the development of MI following unstable angina
• Eventual outcome of this process determines…
  
  • The worst clinical syndrome that will afflict the patient (UA, NSTEMI, or STEMI)
• If this process is kept in check…
  
  • By the normal governing process of thrombosis & thrombolysis
  • Total or near-total occlusion of the involved coronary doesn’t occur or is brief
  • Unstable plaque may heal

Question 4

Clots, Occlusion, & MI Timing

• White clots (platelet plugs) vs. red clots
• Partial / short duration total vs. long duration total occlusion
• Timing of acute MIs

Answer 4

• White clots (platelet plugs) vs. red clots
  
  • White clots
    
    • –> unstable angina
    • Prone to dispersal in the arteries
  • Red clots
    
    • –> MI
    • More stable & less prone to dispersal
• Partial vs. total occlusion
  
  • Partial occlusion w/ thrombus or total occlusion for a short time (<20 mins)
    
    • –> NSTEMI
  • Total & persistent occlusion (>20 mins)
    
    • –> STEMI
• Timing of acute MIs
  
  • >1/2 of acute MIs occur during sleep or during mild to moderate physical activity
  • Circadian rhythm to time of acute MIs –> greatest frequency b/n 6am & noon

Question 5

Less Common Causes of ACS

Answer 5

• Thrombus downstream of a chronic high-grade stenosis (~10%)
  
  • Rheological factors associated w/ abnormal blood flow –> thrombosis at site of chornically & critically stenosed coronary artery –> MI
• Greatly increased myocardial oxygen demand
• Hyperadrenergic state
• Acute plaque disruption
  
  • In the presence of fixed & stable atherosclerotic coronary narrowing
• Coronary spasm
  
  • Spontaneous (Prinzmetal’s angina) or due to drugs
  • W/ or w/o atherosclerotic coronary heart disease
• Embolism to a coronary artery

Question 6

Non Q Wave vs. Q Wave Infarction & the Wave Front of Myocardial Necrosis

• Tissue most at risk when myocardial blood flow is limited: subendocardial tissue
• Transmural vs. subendocardial infarction
• 2 categoreis of patients in the 1st hours of acute coronary syndromes
• Coronary vessel occlusion +
  
  • Artery isn’t opened
  • Artery is opened within an hour of occlusion
  • Artery isn’t opened within 6-12 hours
  • 3-4 hours of occlusion
• Factors in necrosis that speed propagation of the wave front

Answer 6

• Tissue most at risk when myocardial blood flow is limited: subendocardial tissue
  
  • Large epicardial vessels give off nutirent mycoardial branches directly from subenpicardial to subendocardial tissue
  • Vessel is constricted during systole by the tension from the contracting myocardium
• Transmural vs. subendocardial infarction
  
  • Transmural: necrosis reaches epicardium, Q wave devlops
  • Subendocardial: necrosis doesn’t reach epicardium, Q wave doesn’t develop
• 2 categoreis of patients in the 1st hours of acute coronary syndromes
  
  • STEMI
  • UA / NSTEMI
• Coronary vessel occlusion +
  
  • Artery isn’t opened
    
    • Tissue in jeopardy gradually undergoes irreversible damage in a wave front fashion moving from endocardium to epicardium
    • Irreversible injury begins within 20 mins
  • Artery is opened within an hour of occlusion
    
    • Much of the muscle will survive
  • Artery isn’t opened within 6-12 hours
    
    • Little to none of the myocardium will survive
  • 3-4 hours of occlusion
    
    • About half of the jeopardized myocardium will be irreversibly damaged
• Factors in necrosis that speed propagation of the wave front
  
  • Presence & magnitude of coronray collateral vessels to the involved vessel
  • Metabolic state of the myocardium
  • Presence of anti-thrombotic therapy

Question 7

Normal Hemostasis & Control of Hemostasis

• Blood clot formation
• Hemostasis
• Too much vs. too little hemostasis (clot control)
• Following successful clotting…
• 2 essential elements for hemostasis

Answer 7

• Blood clot formation
  
  • Occurs at the site of an injured vessel
• Hemostasis
  
  • Must occur rapidly
  • Limited to the local site of disruption / thrombus formation
  • Must be under good control
• Too much vs. too little hemostasis (clot control)
  
  • Too much –> severe hemorrhage
  • Too little –> occlude
• Following successful clotting…
  
  • The clot must be removed by thrombolysis (fribrinolysis) & the damaged tissue must be healed
• 2 essential elements for hemostasis
  
  • Platelet plug
  • Fibrin formation

Question 8

Platelet Plug Formation

Answer 8

• Platelets: small, plate-like codies that aren’t adherent
• Platelets are activated by thrombin or exposed to collagen
• –> change from a rounded to plate-like shape w/ multiple sticky pseudopods
• –> adhere to the subendothelial matrix
• –> secrete platelet granule products
• –> enhance thrombin generation
• –> activate other platelets
  
  • Feed back loop involving platelet ADP release & platelet generation of thromboxane A-2
• –> aggregate w/ other platelets into a platelet plug
• –> expose the platelet glycoprotein IIb/IIia complex (integrin)
  
  • Site of fibrinogen & fibrin binding at the platelet surface

Question 9

Fibrin Formation

Answer 9

• Activated factor II (IIa) –> thrombin
• Thrombin releases tissue factor
• Tissue factor + activated coagulation factor VII (VIIa) –> activated factor X (Xa)
• Xa: prothrombin (II) –> thrombin (IIa)
• Thrombin (IIa): fibrinogen (soluble) –> fibrin (insoluble)
  
  • Feedback loop creates more thrombin
• Thrombin (IIa) –> activated factor XIII (XIIIa)
  
  • Aids in crosslinking & stabliizing fibrin into a web

Question 10

Formation & Propagation of Thrombus

Answer 10

• Fibrin web attach to & stabilize platelet plugs at the glycoprotein (BP) IIb/IIIa complex
• Incorporation fo platelet plug into fibrin –> stabilization of fibrin web –> traps RBCs & WBCs
• Platelet plugs (white clots) quickly convert into propagating, resilient red clots

Question 11

Control of Platelet Activation & Fibrin Formation

• Platelet activation & aggregation are inhibited locally by…
• Antithrombin/heparin system

Answer 11

• Platelet activation & aggregation are inhibited locally by…
  
  • Local endotehlial production of prostacyclin
  • NO (EDRF)
• Antithrombin/heparin system
  
  • Controls fibrin formation
  • Antithrombin (AT)
    
    • Circulating plasma protease inhibitor
    • Inhibits thrombin, Xa, & 3 other coagulation factors
  • AT binds w/ endogenous heparin, polymeric chains of monosaccarides, & endothelial heparin sulfate moities –> enhances inactivation
  • Heparin binds to thrombin & AT simultaneously –> inactivates thrombin
    
    • Only occurs when heparin contains _>_18 monosaccharide units
      
      • Shorter units inactivate Xa
    • Heparins have a pentasaccharide unit important in AT binding

Question 12

Thrombolysis

• Controlled vs. uncontrolled
• Controlled by…
• Caused by…
• Tissue-type plasminogen activator (t-PA)

Answer 12

• Controlled vs. uncontrolled
  
  • Controlled: removes clots
  • Uncontrolled: hemorrhage
• Controlled by…
  
  • Thrombolytic inhibitors (local process)
  • 4 inhibitory mechanisms
• Caused by…
  
  • t-PA activation of circulating plasminogen to plasmin
• Tissue-type plasminogen activator (t-PA)
  
  • One of two native plasminogen activators in circulation
  • Product of endothelium
  • Binds to fibrin to maximally activate plasminogen

Question 13

Anti-thrombotic Drugs

• Treats…
• Categories

Answer 13

• Treat ACS
  
  • Open acutely closed coronary arteries
  • Prevent further thrombosis
  • Prevent thrombotic & thromboembolic complications
• Categories
  
  • Anti-platelet agents
  • Anti-thrombin agents (“anticoagulatns”)
    
    • Local & systemic effects
    • Problem: bleeding
  • Thrombolytic (fibrinolytic) agents (plasminogen activates)
    
    • Local & systemic effects
    • Problem: bleeding

Question 14

Anti-platelet Agents

Answer 14

• Anti-thrombotic drugs
• 4 types
  
  • Aspirin
  • Platelet P2Y₁₂ protein (ADP binding) inhibitors
    
    • Thienopyridines
    • Cyclo-pentyl-triazolo-pyrimidines (CPTPs)
  • Platelet GPIIb/IIIa blockers
  • Protease-activated receptor-1 (PAR-1), thrombin-binding inhibitors

Question 15

Aspirin

• Type
• General
• Low dose

Answer 15

• Type
  
  • Anti-thrombotic anti-platelet agents
• General
  
  • Irreversible COX-1 inhibitor for the anuclear platelet
  • Permanently decreases thromboxane A2 synthesis in the affected platelet
  • Decreases teh positive feedbacl loop of thromboxane A2 in recruiting more activated platelets
• Low dose
  
  • Max inhibition of thromboxane production
  • Min decrease on prostacyclin production by endothelial cells
    
    • Endothelial cells have nuclei & can make new COX-1 molecules

Question 16

Platelet P2Y12 Inhibitors

• Type
• General
• Thienopyridines
  
  • General
  • Ticlopidine
  • Clopidogrel
  • Pasulgrel
• Cyclo-pentyl-triazolo-pyrimidines
  
  • General
  • Ticagrelor

Answer 16

• Type
  
  • Anti-thrombotic anti-platelet agents
• General
  
  • Block the binding of ADP to the adenosine binding protein P2Y₁₂
  • Decrease the positive feedback loop of ADP in recruiting more activated platelets
• Thienopyridines
  
  • Metabolites of these drugs irreversibly block the platelet protein P2Y₁₂
  • Ticlopidine
  • Clopidogrel
    
    • Fewer side effects
    • Used more frequently
  • Pasulgrel
    
    • More potent
    • Great bleeding risks
    • Superior to clonidine in early ACS
• Cyclo-pentyl-triazolo-pyrimidines
  
  • Bind directly to & reversible to P2Y₁₂ –> block ADP binding
  • Ticagrelor
    
    • Superior to clopidogrelin in early ACS but only at low doses

Question 17

Platelet GPIIb/IIIa Blockers

• Type
• General
  
  • Abciximab
  • Eptifibatide & tirofiban

Answer 17

• Type
  
  • Anti-thrombotic anti-platelet agents
• General
  
  • Given IV
  • Abciximab
    
    • Non-specific antibody that binds to many integrins
    • Long acting (up to 24-48 hours)
  • Eptifibatide & tirofiban
    
    • Small moleucles
    • Highly specific for GPIIb/IIIa
    • Short-acting (~4-6 hours)

Question 18

Protease-Activated Receptor-1 (PAR-1), Thrombin-Binding Inhibitors

• Type
• General
• Mechanism of action

Answer 18

• Type
  
  • Anti-thrombotic anti-platelet agents
• General
  
  • First agent: vorapaxar sulfate
  • For initial ACS recovery to prevent subsequent cardiac ischemic events
  • Potent, orally active, tricyclic himbacine-derived, selective PAR-1 antagonist
• Mechanism of action
  
  • Thrombon activates platelets by binding & activating PAR-1 & PAR-4 receptors
    
    • PAR-1 receptros are activated at lower thrombin concentrations & elicit a more rapid platelet response than PAR-4
  • PAR-1 inhibitors limit thrombin-activation of platelets
    
    • Competitively block PAR-1 –> inhibit thrombin-induced platelet aggregation

Question 19

Anti-thrombin Agents

Answer 19

• Anti-thrombotic drugs
• Block the formation of thrombin &/or inhibit thrombin action
• 3 types
  
  • Heparin (or heparin-like) agents
  • Direct thrombin inhibitors (hirudin-like agents)
  • Oral vitamin K antagonists (VKAs)

Question 20

Heparins

• Type
• Unfracitonated heparin
• Low-molecular weight heparins
• Fondaparinux

Answer 20

• Type
  
  • Anti-thrombotic anti-thrombin agents
• Unfractionated Heparin
  
  • Biological product
    
    • Ginds to antithrombin
    • –> makes antithrombin more active
    • –> inhibits thrombin , Xa, & other coagulaiton factors
  • Molecules > 18 polysaccharide units –> greater effect on thrombin
  • Given IV
  • Blood clot testing required
• Low-molecular weight heparins
  
  • Created by breaking down larger heparin chains into lower MW chains
    
    • –> inhibits thrombin & Xa
  • Molecules < 18 polysaccharide units –> greater effect on Xa
  • Given subcutaneously
  • Blood clot testing not required
• Fondaparinux
  
  • Pentasaccharide heparin analog
    
    • Effect in ACS but cost limits it to patients who can’t receive heparin
  • Blocks Xa w/ no effect on thrombin
  • Given subcutaneously
  • Blood clot testing not required

Question 21

Direct Thrombin Inhibitors (Hirudin-Like Agents)

• Type
• General
• Bivalarudin
• Argatraban

Answer 21

• Type
  
  • Anti-thrombotic anti-thrombin agents
• General
  
  • Modeled after hirudin (anti-thrombin found in saliva of leaches)
  • Act directly on thrombin
  • Given IV
  • Require blood clot testing
  • Used as alternatives to vitamin K antagonists in longer-term management of ACS patients w/ AFib
• Bivalarudin
  
  • Derived from the hirudin molecule
  • Used in ACS…
    
    • To replace heparin & IIb/IIIa during angioplasty procedures
    • W/ known or suspected heparin-induced thrombocytopenia (HIT)
• Argatraban
  
  • Small molecule that contains part of the hirudin molecule that blocks the thrombin active site
  • Used in ACS w/ known or suspected HIT

Question 22

Oral Vitamin K Antagonitsts (VKAs)

• Type
• General

Answer 22

• Type
  
  • Anti-thrombotic anti-thrombin agents
• General
  
  • Warfarin (a coumarin)
  • Blocks terminal gamma carboxylation of clotting factor II (prothrombin) & 3 other coagulation factors
    
    • Decreases normally functioning thrombin & fibrin formation
  • Given orally
  • Slow onset & cessation
  • Blood clot testing required

Question 23

Thrombolytic (Fibrinolytic) Agents (Plasminogen Activators)

Answer 23

• Anti-thrombotic drugs
• Available drugs
  
  • Alteplase (recombinant form of t-PA)
  • Tenecteplase & reteplase (alteplase analogs)
    
    • Derived to allow solely bolus adminstration IV
• Moderatley selective for fibrinolysis at the site of a clot
• Little action on fibrinogen

Question 24

Opening Acutely Thrombosed Coronary Arteries: Emergency Reperfusion Therapy for STEMI w/ Thrombolysis (Fibrinolysis)

• Thrombolytic therapy
  
  • Restricted to patients w/…
  • STEMI
  • UA/NSTEMI
  • Effectiveness
  • Adverse effects
  • Contraindications
• Emergency angioplasty & stenting

Answer 24

• Thrombolytic therapy
  
  • Restricted to patients w/ high risk for adverse outcome & can’t undergo emergency angioplasty & stenting within 90 mins
  • STEMI
    
    • Within 30 mins of admission
    • Within 6 hours of MI
    • Small benefit b/n 6-12 hours of MI
    • Benefit after 12 hours only w/ recurrent or ongoing ischemia
  • UA/NSTEMI
    
    • Not beneficial b/c coronary arteyr isn’t totally occluded
    • Risk : benefit ratio isn’t favorable
  • Effectiveness: 50-60%
  • Adverse effects: bleeding (intracranial or other hemorrhage)
  • Contraindications
    
    • High risk of bleeding & intracranial hemorrhage
    • Elderly, female, small body size, HTN, recent neurosurgery, prior intracranial hemorrhage, vascular risks
• Emergency angioplasty & stenting
  
  • Superior to thrombolytic therapy if within 90 mins of admission

Question 25

Aspirin Therapy for ACS

Answer 25

• Antiplatelet w/ low dose following an initial high dose
• Moderate reduction in 1 month mortality from STEMI & recurrent MI / sudden death when given long-term
• Marked reduction in death, progression to MI, & recurrent MI in patients w/ UA/NSTEMI

Question 26

Platelet P2Y₁₂ (ADP Binding) Inhibitior Therapy for ACS

• Use
• This vs. aspirin
• Clopidogrel vs. pasugrel & ticagrelor
• Duration

Answer 26

• Use
  
  • Adjunctive therapy to aspirin
  • Alternative to aspirin w/ aspirin allergy
  • Small additional benefit to aspirin in UA, NSTEMI, & STEMi w/o angioplasty / stenting procedures
• This vs. aspirin
  
  • Mildly effective alone
  • Moderately effective in addition to aspirin
• Clopidogrel vs. pasugrel & ticagrelor
  
  • Pasugrel & ticagrelor > clopidogrel in early ACS
  • Clopidogrel used after 1 month for cost
  • Aspirin dose must be < 100 mg when used w/ ticagrelor
• Duration
  
  • Use for > 3-12 months in patient sw/ coronary angioplasty & stent placement
  • Use > 12 months in patients w/ drug-eluting stent b/c this slows endothelium recovery time
  • Therapy decreases risk of in-stent thrombosis

Question 27

GP IIb/IIIa Blocker Therapy for ACS

• Abciximab & eptifibatide
• Bivalirudin
• Tirofiban & eptifibatide

Answer 27

• Abciximab & eptifibatide
  
  • Moderate benefit in patients w/ SteMi undergoing emergency coronary angioplasty procedures (before platelet P2Y₁₂s)
  • Primraily used as an additional anti-platelet agent in high risk patients (coronray dilation & stenting procedures in clot-burdened vessels)
• Bivalirudin
  
  • Direc trhombin inhibitor
  • Substitute for both GP IIb/IIIa blocker & heparin for emerggency, high-risk angioplasty procedures
• Tirofiban & eptifibatide
  
  • Small molecule glycoprotein IIb/IIIa blockers
  • High benefit in addition to other drug therapy in UA/NSTEMI w/ cardiac cath & angioplasty/stenting therapy (before platelet P2Y₁₂s)
    
    • Reduce death, MI, & need for urgent repeat vascular procedures
  • If used in UA/NSTEMI, limit to high risk patients w/o cardiac cath & w/ planned angioplsaty /stenting procedures
    
    • Provide therapy in 12-24 hours b/n initial eval & coronary arteriography
    • Provide therapy in cath lab before dilation or stenting of the coronary arteries

Question 28

PAR-1 Inhibition of Platelets (Vorapaxar) Therapy for ACS

• Use during active ACS
• Use > 2 months after ACS
• Contraindications

Answer 28

• Use during active ACS
  
  • Unacceptable increased risk of hemorrhage
• Use > 2 months after ACS + aspirin + P2Y₁₂ inhibitors
  
  • Mildly further decreaes risk of additional cardiac ischemic episodes, esp recurrent MI
  • Risk fo hemorrhage
• Contraindications
  
  • Post-ACS patients w/ a history of stroke or transient cerebrovascular ischemia or other conditoins w/ increased bleeding risk

Question 29

Heparin Therapy for ACS

• Short term (1-2 day) heparin
• Low dose heparin
• In UA/NSTEMI
• Bivalirudin

Answer 29

• Short term (1-2 day) heparin
  
  • STEMI: small additional benefits in addition to aspirin & fibrin-selective thrombolytic therapy
  • Necessary for max benefit w/ fibrin-selective thrombolytic agents & emergency angioplasty procedures
• Low dose heparin
  
  • Subcutaneous for all MI patients until fully ambulatory
  • Prevent DVT & pulmonary embolism
• In UA/NSTEMI
  
  • Unfracitonated heparin, low MW heparin, or fondaprinux + aspirin –> additional protection against death & progression to MI
  • Therapy given for 2 days or until cath & revascularization procedures are complete
• Bivalirudin
  
  • Replaces GP IIb/IIia blocker & heparin in STEMI + primary angioplasty procedures

Question 30

Vitamin K Inhibitor Therapy for ACS

Answer 30

• Vitamin K inhibitors vs. aspirin
  
  • Prevent sudden death & recurrent MI w/o aspirin
  • Additional benefit when added to aspirin
    
    • But increases hemorrhage risk
  • Prefer aspirin b/c easier, cheaper, & safer longterm
    
    • Except in patients w/ high risk for peripheral or pulmonary thromboembolism
• Reduces stroke risk in patients w/ AMI or apical infarctions & persistent wall motion abnormalities
  
  • 3 months anti-thrombin therapy + shrot-term heparin –> intensive warfarin + low dose aspirin
• High risk patients after MI
  
  • Given warfarin to prevent stroke + intensive regimen + low dose aspirin
  • Patients: AFib, large dialted ventricles, prior thromboembolic episodes