Phys 21
During strenuous exercise, cardiac output must usually:
A. Fall below resting levels
B. Stay near baseline
C.
Increase markedly
D. Become preload-independent
C. Increase markedly
During rhythmic exercise, muscle blood flow typically:
A. Remains constant each beat
B. Falls progressively
C. Rises progressively
D. Oscillates with contraction
D. Oscillates with contraction
During the contraction phase of normal exercise, muscle blood flow falls mainly because:
A. Venous PO2 rises
B. Arterioles fully dilate
C.
Contracted fibers compress vessels
D. Lymphatic drainage increases
C. Contracted fibers compress vessels
During a strong tetanic contraction, muscle blood flow can be almost abolished because of:
A. Sustained vascular compression
B. Arteriolar beta
activation
C. Venous valve closure
D. Reduced metabolic demand
A. Sustained vascular compression
A sustained tetanic contraction rapidly weakens primarily because:
A. Lactic acid disappears
B. Blood flow is nearly
stopped
C. Sympathetic tone is lost
D. Calcium entry is blocked
B. Blood flow is nearly stopped
At rest, many skeletal muscle capillaries:
A. Have maximal flow
B. Are structurally collapsed
C.
Carry little or no flow
D. Only drain venous blood
C. Carry little or no flow
During exercise, effective muscle capillary surface area usually increases by about:
A. 25%
B. 50%
C. Two- to threefold
D. Five- to sixfold
C. Two- to threefold
A fall in interstitial oxygen concentration in active muscle has what direct vascular effect?
A. Local arteriolar vasodilation
B. Local venular
constriction
C. Capillary sphincter closure
D. Sympathetic
alpha activation
A. Local arteriolar vasodilation
Which local change most strongly enhances muscle blood flow during exercise?
A. Increased tissue oxygen
B. Decreased tissue oxygen
C. Decreased carbon dioxide
D. Increased venous pressure
B. Decreased tissue oxygen
Which set best sustains exercise hyperemia in active muscle?
A. K+, ATP, lactate, CO2
B. Calcium, renin, serotonin,
ADH
C. Albumin, chloride, bicarbonate, urea
D. Histamine,
bradykinin, angiotensin, insulin
A. K+, ATP, lactate, CO2
Sympathetic vasoconstrictor nerve endings in muscle chiefly release:
A. Epinephrine
B. Dopamine
C. Acetylcholine
D. Norepinephrine
D. Norepinephrine
Maximal sympathetic stimulation of skeletal muscle vessels can reduce blood flow to about:
A. One half to one third
B. Three fourths to full
C.
One tenth to zero
D. Two thirds above baseline
A. One half to one third
Circulating epinephrine causes slight skeletal muscle vasodilation mainly by stimulating:
A. Alpha receptors
B. Beta receptors
C. Muscarinic
receptors
D. Nicotinic receptors
B. Beta receptors
Alpha vasoconstrictor receptors are excited especially by:
A. Norepinephrine
B. Epinephrine
C. ATP
D. Adenosine
A. Norepinephrine
Under resting conditions, the heart is normally restrained mainly by:
A. Sympathetic inhibition
B. Alpha receptor blockade
C.
Parasympathetic inhibition
D. Reduced venous return
C. Parasympathetic inhibition
At exercise onset, the rise in heart rate and contractility occurs first because of:
A. Increased vagal discharge
B. Removal of vagal
inhibition
C. Decreased adrenal output
D. Loss of beta receptors
B. Removal of vagal inhibition
During heavy exercise, most peripheral arterioles are:
A. Dilated, including inactive beds
B. Constricted, except
active muscle
C. Unchanged throughout body
D. Collapsed by
low pressure
B. Constricted, except active muscle
Despite high sympathetic tone, active skeletal muscle still receives increased flow because:
A. Venous pressure exceeds arterial
B. Local metabolites
override constriction
C. Capillaries generate pressure
D.
Lymphatics pump arterial blood
B. Local metabolites override constriction
As blood flow to active muscle rises, flow to many nonmuscular tissues:
A. Also rises equally
B. Falls because of
redistribution
C. Remains unchanged
D. Becomes entirely capillary
B. Falls because of redistribution
During exercise, which two vascular beds are relatively spared from the generalized vasoconstriction affecting nonactive tissues?
A. Renal and splanchnic
B. Coronary and cerebral
C.
Cutaneous and renal
D. Pulmonary and hepatic
B. Coronary and cerebral
Coronary and cerebral vessels are relatively spared during exercise mainly because they:
A. Have high alpha tone
B. Are nonessential to exercise
C. Need preserved perfusion
D. Lack local metabolites
C. Need preserved perfusion
Compared with many inactive vascular beds, coronary and cerebral circulations have relatively:
A. Poor vasoconstrictor innervation
B. Dense venous
plexuses
C. High resting compliance
D. Minimal endothelial function
A. Poor vasoconstrictor innervation
During exercise, sympathetic stimulation causes venous walls to:
A. Relax diffusely
B. Contract powerfully
C. Become
metabolically inactive
D. Dilate in active muscle
B. Contract powerfully
Venoconstriction during exercise most directly increases:
A. Pulmonary vascular resistance
B. Mean systemic filling
pressure
C. Left atrial compliance
D. Coronary sinus pressure
B. Mean systemic filling pressure
The major hemodynamic importance of exercise-induced venoconstriction is to increase:
A. Capillary hydrostatic pressure
B. Venous return and
cardiac output
C. Coronary autoregulation
D. Systolic
ejection time
B. Venous return and cardiac output
In active skeletal muscle during exercise, arterioles are predominantly:
A. Vasoconstricted
B. Collapsed
C. Vasodilated
D. Unresponsive
C. Vasodilated
In most nonactive tissues during exercise, the dominant arteriolar effect is:
A. Vasodilation
B. Vasoconstriction
C. No tone
change
D. Passive collapse
B. Vasoconstriction
The relatively modest pressure rise during massive whole-body exercise is best explained by:
A. Global vagal dominance
B. Widespread muscle
vasodilation
C. Coronary vasoconstriction
D. Reduced
venous return
B. Widespread muscle vasodilation
Compared with an untrained runner, a trained marathon runner can increase cardiac output during maximal exercise:
A. Less
B. Equally
C. More
D. Not at all
C. More
Raising the entire venous return curve during exercise requires:
A. Lower MSFP, higher resistance
B. Higher MSFP, lower
resistance
C. Higher RAP, higher resistance
D. Lower
contractility, lower resistance
B. Higher MSFP, lower resistance
In a person with a very strong heart during heavy exercise, right atrial pressure often:
A. Rises above normal
B. Falls below normal
C. Remains
fixed
D. Equals arterial pressure
B. Falls below normal
Exercise → ↑ sympathetic stimulation → ↑ heart contractility + ↑ heart rate → right heart empties faster → ↓ blood left in right atrium → ↓ RAP
The left coronary artery mainly supplies the:
A. Right ventricle and septum
B. Anterior and left lateral
LV
C. Posterior RV and septum
D. Both atria equally
B. Anterior and left lateral LV
The right coronary artery supplies most of the right ventricle and the:
A. Anterior left ventricle
B. Lateral left ventricle
C.
Posterior left ventricle
D. Apical septum only
C. Posterior left ventricle
Most venous blood from the left ventricular myocardium returns to the right atrium through the:
A. Great cardiac vein
B. Small cardiac vein
C.
Coronary sinus
D. Thebesian plexus
C. Coronary sinus
Approximately what fraction of total coronary flow returns via the coronary sinus?
A. About 25%
B. About 50%
C. About 75%
D. About 95%
C. About 75%
Most venous blood from the right ventricular myocardium returns directly to the right atrium through:
A. Coronary sinus tributaries
B. Small anterior cardiac
veins
C. Middle cardiac veins
D. Posterior septal veins
B. Small anterior cardiac veins
A tiny amount of coronary venous blood enters all chambers directly through:
A. Vasa vasorum
B. Anterior cardiac veins
C. Coronary
sinusoids
D. Thebesian veins
D. Thebesian veins
During strenuous exercise, myocardial work rises more than cardiac output because the heart also pumps against:
A. Lower venous pressure
B. Higher arterial pressure
C.
Lower coronary resistance
D. Higher pulmonary compliance
B. Higher arterial pressure
A lifter performing intense arm exercise develops a marked rise in mean arterial pressure. Which pattern best explains this?
A. Local vasoconstriction, systemic dilation
B. Local
dilation, systemic constriction
C. Global dilation, low venous
tone
D. Global constriction, fixed venous return
B. Local dilation, systemic constriction
In the left ventricular myocardium, coronary capillary blood flow during systole normally:
A. Decreases
B. Increases
C. Reverses
D. Plateaus
A. Decreases
The fall in left ventricular coronary capillary flow during systole occurs mainly because:
A. Aortic pressure collapses
B. Vagal tone rises
sharply
C. Myocardial contraction compresses vessels
D.
Coronary sinus pressure falls
C. Myocardial contraction compresses vessels
In the left ventricle, coronary capillary blood flow is greatest during:
A. Isovolumic contraction
B. Ventricular systole
C.
Early ejection only
D. Diastole
D. Diastole
Compared with most other vascular beds, left ventricular coronary flow is unusual because it:
A. Falls during systole
B. Stops during diastole
C.
Ignores metabolic demand
D. Depends only on nerves
A. Falls during systole
The coronary arteries on the outer surface of the heart are the:
A. Septal arteries
B. Thebesian arteries
C. Epicardial
arteries
D. Subendocardial arteries
C. Epicardial arteries
Immediately beneath the endocardium lies a plexus of:
A. Subendocardial arteries
B. Epicardial arteries
C.
Atrial venules
D. Coronary sinusoids
A. Subendocardial arteries
Whenever cardiac contractile vigor increases, coronary blood flow generally:
A. Falls slightly
B. Also increases
C. Becomes
fixed
D. Depends on venous return
B. Also increases
Coronary blood flow rises almost in what relationship to myocardial oxygen consumption?
A. Inverse
B. Biphasic
C. Direct
D. Unrelated
C. Direct
Very low intracellular oxygen causes breakdown of ATP first to:
A. Creatine
B. ADP
C. Lactate
D. Acetylcholine
B. ADP
After ATP falls to ADP and then AMP, the next major breakdown product is:
A. Adenosine
B. Inosine
C. Pyruvate
D. NADH
A. Adenosine
Very low myocardial oxygen levels promote local coronary vasodilation mainly through release of:
A. Potassium
B. Bradykinin
C. Norepinephrine
D. Adenosine
D. Adenosine
The oxygen level that most strongly triggers adenosine release is:
A. Very low
B. Very high
C. Mildly high
D. Oscillating
A. Very low
Coronary vasodilation from adenosine is most directly a response to:
A. Increased venous pressure
B. Myocardial hypoxia
C.
High arterial oxygen
D. Vagal discharge
B. Myocardial hypoxia
Sympathetic stimulation of the heart generally:
A. Decreases metabolism
B. Prevents coronary dilation
C. Increases metabolism
D. Stops local control
C. Increases metabolism
During sympathetic activation, coronary vessels dilate mainly because increased cardiac metabolism triggers:
A. Local flow regulation
B. Direct alpha constriction
C.
Thebesian drainage
D. Venous pooling
A. Local flow regulation
So even though sympathetic nerves can cause some direct vasoconstriction, the main effect in coronary vessels is metabolic vasodilation → more coronary blood flow.
During sympathetic stimulation, coronary blood flow rises roughly in proportion to cardiac:
A. Heart rate only
B. Filling pressure
C. Venous
return
D. Metabolic needs
D. Metabolic needs
Vagal stimulation indirectly tends to constrict coronary arteries because it:
A. Raises oxygen demand
B. Increases ventricular
pressure
C. Lowers cardiac oxygen use
D. Stimulates alpha receptors
C. Lowers cardiac oxygen use
Despite that indirect effect, acetylcholine has what direct action on coronary arteries?
A. Dilates them
B. Constricts them
C. Occludes
them
D. No effect
A. Dilates them
In coronary vessels, constrictor receptors are predominantly:
A. Muscarinic
B. Beta
C. Nicotinic
D. Alpha
D. Alpha
In coronary vessels, dilator receptors are predominantly:
A. Alpha
B. Beta
C. H1
D. M2
B. Beta
Epicardial coronary vessels have a relative predominance of:
A. Alpha receptors
B. Beta receptors
C. M3
receptors
D. Dopamine receptors
A. Alpha receptors
Intramuscular coronary arteries may have a predominance of:
A. Alpha receptors
B. Nicotinic receptors
C. Beta
receptors
D. Opioid receptors
C. Beta receptors
The major controller of myocardial blood flow is:
A. Sympathetic tone
B. Myocardial oxygen consumption
C.
Coronary venous pressure
D. Right atrial pressure
B. Myocardial oxygen consumption
Under resting conditions, the heart obtains most of its energy from:
A. Glucose
B. Lactate
C. Ketones
D. Fatty acids
D. Fatty acids
Under ischemic or anaerobic conditions, cardiac muscle must rely more on:
A. Fat oxidation
B. Anaerobic glycolysis
C. Oxidative
phosphorylation
D. Beta-oxidation
B. Anaerobic glycolysis
During severe ischemia, chest pain is promoted partly by buildup of:
A. Uric acid
B. Carbonic acid
C. Lactic acid
D. Acetoacetate
C. Lactic acid
During coronary hypoxia, which metabolite is believed to dilate coronary arterioles?
A. Adenosine
B. Acetylcholine
C. Lactate
D. Norepinephrine
A. Adenosine
Why is prolonged coronary occlusion especially dangerous after 30 minutes?
A. Coronary veins thrombose completely
B. Adenine resynthesis
is very slow
C. Fibrosis is immediately complete
D. All
collateral flow stops
B. Adenine resynthesis is very slow
In atherosclerosis, the first major material deposited beneath the arterial endothelium is:
A. Calcium
B. Cholesterol
C. Fibrin
D. Hemosiderin
B. Cholesterol
As an atherosclerotic plaque matures, it is commonly invaded by:
A. Elastic lamellae
B. Lymphoid nodules
C. Fibrous
tissue
D. Smooth clot only
C. Fibrous tissue
Advanced atherosclerotic plaques frequently become:
A. Necrotic
B. Hemorrhagic
C. Ulcerated
D. Calcified
D. Calcified
Local muscular spasm of a coronary artery containing plaque may precipitate:
A. Primary fibrinolysis
B. Secondary thrombosis
C.
Valve rupture
D. Venous pooling
B. Secondary thrombosis
coronary spasm → narrowed lumen → plaque surface/endothelium gets disrupted → platelets stick → clot forms
Immediately after sudden occlusion of a large coronary artery, which vessels dilate first?
A. Small anastomoses
B. Coronary veins
C. Endocardial
lymphatics
D. Thebesian vessels
A. Small anastomoses
After acute coronary occlusion, collateral flow typically begins to rise and often doubles by:
A. 12 hours
B. Day 7
C. Days 2 to 3
D. Week 4
C. Days 2 to 3
With progressive collateral development after coronary occlusion, flow often becomes normal or nearly normal within about:
A. 24 hours
B. 1 month
C. 3 months
D. 6 months
B. 1 month
Immediately after acute coronary occlusion, myocardium with essentially no effective perfusion is said to be:
A. Stunned
B. Hibernating
C. Ischemic
D. Infarcted
D. Infarcted
Soon after infarction begins, the area may become overfilled with stagnant blood because of collateral seepage plus local vessel:
A. Dilation
B. Rupture
C. Collapse
D. Sclerosis
A. Dilation
As infarcted fibers consume the last available oxygen, hemoglobin in the area becomes:
A. Oxidized
B. Alkalinized
C. Deoxygenated
D. Fragmented
C. Deoxygenated
Grossly, an early infarcted region often appears:
A. Pale-white, collapsed vessels
B. Bluish-brown, engorged
vessels
C. Bright-red, empty vessels
D. Yellow-gray,
shrunken vessels
B. Bluish-brown, engorged vessels
When blood flow is compromised, myocardial injury usually begins in the:
A. Epicardial region
B. Midmyocardium
C. Papillary
muscles
D. Subendocardial region
D. Subendocardial region
Once ischemic injury begins in the ventricular wall, it typically spreads:
A. Toward the atria
B. Toward the septum
C. Toward the
epicardium
D. Toward the valves
C. Toward the epicardium
After acute coronary occlusion, overall cardiac output often falls more than expected because of:
A. Electrical alternans
B. Systolic stretch
C. Reflex
bradycardia
D. Diastolic collapse
B. Systolic stretch
In systolic stretch, the ischemic ventricular segment is forced:
A. Inward during systole
B. Downward in diastole
C.
Clockwise with torsion
D. Outward during systole
D. Outward during systole
Which statement best describes systolic stretch?
A. Infarcted muscle contracts too forcefully
B. Ischemic
segment actively shortens
C. Nonfunctional wall bulges
outward
D. Epicardium pulls septum inward
C. Nonfunctional wall bulges outward
A 72-year-old man has a massive anterior MI. Cardiogenic shock becomes highly likely when approximately what fraction of the left ventricle is infarcted?
A. More than 20%
B. More than 30%
C. More than
40%
D. More than 60%
C. More than 40%
Once cardiogenic shock develops after MI, mortality is approximately:
A. Over 70%
B. About 25%
C. About 40%
D. Under 10%
A. Over 70%
When the infarcted heart fails to pump blood forward, blood is primarily:
A. Diluted in capillaries
B. Dammed in atria and veins
C. Shunted through coronaries
D. Lost through lymphatics
B. Dammed in atria and veins
In the days after a large infarction, venous damming often worsens because diminished renal perfusion causes:
A. Osmotic diuresis
B. Excess natriuresis
C. Reduced
urine excretion
D. Increased aldosterone clearance
C. Reduced urine excretion
Failure of the kidneys to excrete enough urine after severe MI most directly predisposes to:
A. Acute pulmonary edema
B. Tension pneumothorax
C.
Massive hemoptysis
D. Pleural fibrosis
A. Acute pulmonary edema
After the first pulmonary symptoms from this post-MI fluid retention appear, death may occur within:
A. Several weeks
B. A few hours
C. Two days
D.
One month
B. A few hours
Ventricular fibrillation is especially likely after:
A. Small subendocardial infarcts
B. Right atrial
stretch
C. Large myocardial infarctions
D. Isolated
mitral regurgitation
C. Large myocardial infarctions
The first especially dangerous period for post-infarction fibrillation is approximately:
A. 10 minutes after infarction
B. 30 minutes after
infarction
C. 6 hours after infarction
D. 24 hours after infarction
A. 10 minutes after infarction
After a short safer interval, a second dangerous period for fibrillation begins about:
A. 10 minutes later
B. 1 hour later
C. 12 hours
later
D. 2 days later
B. 1 hour later
Which Elevated extracellular ion increases myocardial irritability and promotes fibrillation after infarction?
A. Sodium
B. Calcium
C. Chloride
D. Potassium
D. Potassium
Ischemic myocardium promotes fibrillation partly because it may fail to completely:
A. Depolarize
B. Repolarize
C. Contract
D. Relax
B. Repolarize
Simple idea:
So they fail to fully repolarize
Why that causes fibrillation
When ischemic muscle fails to fully recover electrically after a beat, its external surface remains relatively:
A. Positive
B. Neutral
C. Negative
D. Insulated
C. Negative
Which autonomic response after massive infarction further increases the risk of fibrillation?
A. Vagal withdrawal
B. Parasympathetic surge
C.
Baroreceptor silence
D. Powerful sympathetic reflexes
D. Powerful sympathetic reflexes
Massive MI → strong sympathetic activation → ↑ heart irritability/automaticity → ↑ risk of ventricular fibrillation
After MI, marked ventricular dilation promotes fibrillation mainly by:
A. Shortening all conduction loops
B. Blocking AV nodal
conduction
C. Prolonging reentry pathways
D. Eliminating
refractory tissue
C. Prolonging reentry pathways
A nonfunctional ischemic ventricle dilates, allowing impulses to re-enter partly recovered myocardium. This initiates a:
A. Wenckebach sequence
B. Circus movement cycle
C.
Escape rhythm focus
D. Junctional pause loop
B. Circus movement cycle
Impulse loops around → re-excites heart tissue → rapid abnormal rhythm
A patient collapses several days after transmural MI when the ventricular free wall ruptures. The immediate lethal event is usually:
A. Aortic dissection
B. Pulmonary embolism
C. Tension
pneumothorax
D. Cardiac tamponade
D. Cardiac tamponade
Free wall rupture → blood around heart → heart gets squeezed → cardiac tamponade
In cardiac tamponade after ventricular rupture, blood most directly cannot flow into the:
A. Left ventricle
B. Right atrium
C. Coronary
sinus
D. Pulmonary veins
B. Right atrium
Death in acute tamponade occurs because cardiac output suddenly:
A. Increases excessively
B. Becomes fixed high
C.
Decreases sharply
D. Equals venous return
C. Decreases sharply
After infarction, necrotic myocardium is gradually replaced by:
A. Granulation myocardium
B. Purulent debris
C. Elastic
lamellae
D. Fibrous scar tissue
D. Fibrous scar tissue
Surviving normal myocardium compensates after infarction mainly by:
A. Atrophy
B. Calcification
C. Hypertrophy
D. Fragmentation
C. Hypertrophy
Because of scar formation plus compensatory hypertrophy, cardiac function may recover:
A. Only if no necrosis occurred
B. Partially or almost
completely
C. Only with valve replacement
D. Fully within hours
B. Partially or almost completely
During early recovery from MI, excessive cardiac activity can worsen ischemia because normal vessels dilate and divert blood away from ischemic tissue. This is called:
A. Reverse splitting
B. Ventricular stunning
C.
Coronary steal
D. Hibernating myocardium
C. Coronary steal
Coronary steal worsens ischemia mainly because blood preferentially flows through:
A. Fibrotic infarct tissue
B. Dilated normal
musculature
C. Occluded epicardial arteries
D. Thebesian
drainage channels
B. Dilated normal musculature
The concept of coronary steal explains why the recovering infarcted heart benefits from:
A. Vigorous exercise
B. High-dose vasodilators
C.
Repeated tachycardia
D. Rest
D. Rest
After MI, pumping ability is more often permanently:
A. Increased above normal
B. Unchanged from baseline
C.
Decreased below healthy levels
D. Limited only at night
C. Decreased below healthy levels
The ability of the normal heart to increase output 300 to 400% above resting requirement is called:
A. Ejection reserve
B. Cardiac reserve
C. Coronary
reserve
D. Preload reserve
B. Cardiac reserve
Which set best represents the pain-producing substances released by ischemic myocardium?
A. Glucose, insulin, glycogen, pyruvate
B. Creatine, ADH,
albumin, serotonin
C. Lactate, histamine, kinins, enzymes
D. Cholesterol, calcium, fibrin, collagen
C. Lactate, histamine, kinins, enzymes
These ischemic products accumulate mainly because coronary blood flow is:
A. Too slow for clearance
B. Entirely absent
chronically
C. Rapid but turbulent
D. Preferentially venous
A. Too slow for clearance
Lactic acid, histamine, kinins, and proteolytic enzymes cause cardiac pain mainly by stimulating:
A. Baroreceptors in carotid sinus
B. Stretch receptors in
pericardium
C. Chemoreceptors in aorta
D. Pain endings in myocardium
D. Pain endings in myocardium
Progressive cardiac pain from ongoing coronary constriction is called:
A. Pleuritic syndrome
B. Angina pectoris
C. Cardiac
tamponade
D. Dressler syndrome
B. Angina pectoris
Typical anginal pain is usually first felt beneath the:
A. Upper sternum
B. Right scapula
C. Left flank
D. Lower abdomen
A. Upper sternum
Classic referred pain of angina often involves the:
A. Right leg and groin
B. Epigastrium and back
C. Left
arm and shoulder
D. Left hip and thigh
C. Left arm and shoulder
Anginal pain may also radiate to the:
A. Right jaw and axilla
B. Abdomen and flank
C. Back
and sacrum
D. Neck and face
D. Neck and face
A patient with chronic stable angina most often develops pain during:
A. Deep sleep or physical stress
B. Exercise or emotional
stress
C. Quiet sitting or physical stress
D. After
urination or emotional stress
B. Exercise or emotional stress
Cold weather or a large meal can worsen angina mainly by increasing cardiac:
A. Workload
B. Chronotropy alone
C. Venous
capacitance
D. Oxygen extraction
A. Workload
For an acute anginal attack, the best immediate drug is:
A. Metoprolol
B. Lisinopril
C. Ranolazine
D. Nitroglycerin
D. Nitroglycerin
Nitroglycerin belongs to which drug class?
A. Beta blockers
B. Calcium blockers
C. Nitrate
vasodilators
D. Angiotensin blockers
C. Nitrate vasodilators
Which drug may help chronic stable angina?
A. Digoxin
B. Ranolazine
C. Epinephrine
D. Mannitol
B. Ranolazine
During stress, beta blockers reduce angina mainly by lowering myocardial:
A. Glucose uptake
B. Coronary spasm
C. Stroke work
only
D. Oxygen demand
D. Oxygen demand
Harvesting a leg vein and grafting from the aorta to a coronary artery beyond a blockage describes:
A. CABG
B. Angioplasty
C. Valvuloplasty
D. Atherectomy
A. CABG
The usual symptomatic result of CABG is:
A. Immediate infarct extension
B. Relief in most
patients
C. Permanent arrhythmia risk
D. No flow improvement
B. Relief in most patients
A balloon-tipped catheter or stent used to open a partially blocked coronary artery is:
A. Coronary endarterectomy
B. Aortic valvotomy
C.
Coronary angioplasty
D. Ventricular remodeling
C. Coronary angioplasty
In exercising muscle, deficiency of what triggers vasodilator release?
A. Carbon dioxide
B. Oxygen
C. ATP
D. Sodium
B. Oxygen
Which statement best describes emotionally triggered angina?
A. Pain follows vagal bradycardia
B. It improves sympathetic
tone
C. It reflects pleural inflammation
D. Stress can
transiently constrict coronaries
D. Stress can transiently constrict coronaries
The trigger for angina is best described as:
A. Coronary flow exceeding demand
B. Cardiac load exceeding
coronary flow
C. Venous return exceeding preload
D.
Afterload falling below baseline
B. Cardiac load exceeding coronary flow
A patient describes chest pain as “hot, pressing, and constricting,” provoked by exertion and stress. The best diagnosis is:
A. Acute pericarditis
B. Aortic dissection
C. Angina
pectoris
D. Pulmonary embolism
C. Angina pectoris
Ischemia stimulates growth of:
A. Myocytes
B. Fibroblasts
C. Neutrophils
D.
Endothelial valves
B. Fibroblasts