Lecture 2-Antihypertensives, Negative Inotropes, Negative Chronotropes Flashcards
This type of hypertension is related to overactivity of the ANS and an interaction with the renin-angiotensin system, along with factors related to sodium homeostasis and intravascular volume
Idiopathic hypertension
Primary cause of perioperative hypertension is increased ___ (sympathetic/parasympathetic) discharge with systemic vaso___
Increased sympathetic discharge with systemic vasoconstriction
Potential complications related to perioperative hypertension include CVA, MI, ischemia, LV dysfunction, arrhythmias, increased suture tension, hemorrhage, pulmonary edema, cognitive dysfunction—T/F?
True
Vasodilators are classified according to their predominate effect on the circulation—arterial dilators reduce ___
Afterload
Most vasodilators are arterial vasodilators
Vasodilators are classified according to their predominate effect on the circulation—venodilators reduce ___
Preload
Vasodilators act primarily to cause systemic vasodilation—T/F?
True
Pure arteriole dilators cause minimal effect on preload—T/F?
True—arteriole dilators affect afterload
“Pure” venodilators are not available—T/F?
True—NTG acts primarily on the venous circulation but also affects arterioles
Balanced vasodilators (i.e.: SNP) decrease afterload and preload—T/F?
True
Hemodynamic effects of vasodilators—reflex increase in ___
Heart rate—baroreceptors pick up on vasodilation in the periphery, resulting in a reflex tachycardia
Hemodynamic effects of vasodilators—redistribution of ___ blood flow; NTG may improve ___ circulation; other vasodilators may cause coronary ___
Coronary blood flow; NTG may improve collateral circulation; other vasodilators may cause coronary steal
What is coronary steal?
Stealing blood flow away from ischemic areas, making coronary artery disease/ischemia even worse. Can occur with use of vasodilators
70-90% of coronary artery perfusion to the LV occurs during ___ (systole/diastole)
Diastole
Aortic ___ (systolic/diastolic) pressure governs perfusion
Aortic diastolic pressure
In the presence of ischemic heart disease, collateral arteries are maximally dilated and coronary perfusion is largely pressure dependent—T/F?
True
Beta blockers/calcium channel blockers reduce myocardial oxygen demand and improve myocardial oxygen use—T/F?
True
What is this phenomenon?—narrowed coronary arteries are always maximally dilated to compensate for the decreased blood supply; dilating the other arterioles causes blood to be shunted away from the coronary vessels
Coronary steal
Vasodilators and coronary perfusion pressure—in the myocardium, ___ (what vasodilator?) dilates both epicardial conductance and intramyocardial resistance vessels; in the presence of CAD, this vasodilator shunts blood away from ischemic zones
SNP—sodium nitroprusside
This increases coronary steal and makes ischemia even worse
Vasodilators and coronary perfusion pressure—___ (what vasodilator?) preferentially dilates conductance vessels and directs more blood toward ischemic zones
NTG
(3) vasodilator medications that we use:
- Hydralazine
- Nitroglycerine (NTG)
- Sodium nitroprusside (SNP)
Hydralazine is a direct acting ___ (arterial/venous) vasodilator; it alters ___ metabolism and movement
Arterial vasodilator; it alters calcium metabolism and movement
Hydralazine ___ (increases/decreases) HR, contractility, renin activity, fluid retention, CO, and SV
Increases
Reflex tachycardia results from drops in BP
Stimulates the RAAS system as pressures begin to drop, leading to increased renin activity/fluid retention
Hydralazine ___ (increases/decreases) BP—it decreases ___ BP more than ___ BP; ___ (increases/decreases) SVR
Decreases BP—it decreases diastolic BP more than systolic BP; decreases SVR
Hydralazine acts on a specific receptor—T/F?
False—does not act on a specific receptor
Hydralazine acts through a second messenger pathway with cyclic GMP as the second messenger protein; results in an increase in cyclic GMP which reduces afterload (arterial vasodilator)
Hydralazine ___ (increases/decreases) myocardial oxygen demand, leading to ischemia
Increases myocardial oxygen demand
Hydralazine should be avoided in patients with ___, increased ___, and ___…why?
CAD, increased ICP, and lupus
Avoid in CAD because Hydralazine can cause reflex tachycardia, resulting in ischemia
Avoid with increased ICP d/t fluid shifts (stimulates RAAS system, leading to increased renin/fluid retention)
Avoid in lupus—interesting side effect with lupus—will see positive ANA [antinuclear antibody] titers in 5-10% of patients treated with Hydralazine; patients won’t get butterfly rash or organ damage but will get arthralgias and painful components of lupus from hydralazine
Hydralazine CNS side effects—___ache, ___ness, ___ from increased ICP
Headache, dizziness, tremor from increased ICP
Hydralazine CV side effects—___tations, ___ina, ___cardia, ___ from vasodilation
Palpitations, angina, tachycardia, flushing from vasodilation
Hydralazine GI side effects—___xia, ___/___, ___ pain, paralytic ___
Anorexia, nausea/vomiting, abdominal pain, paralytic ileus
Hydralazine other side effects—___ia, ___osis, ___ congestion, muscle ___, ___ from activation of RAAS system
Anemia, agranulocytosis, nasal congestion, muscle cramps, edema from activation of RAAS system
Hydralazine pharmacokinetics—onset ___ mins (IV and PO); peak ___-___ mins (IV and PO); duration ___-___ hours (PO), ___-___ hours (IV); half life ___-___ hours (IV and PO); metabolized in ___, excreted by ___; highly ___ bound
Onset 30-60 mins (IV and PO); peak 30-60 mins (IV and PO); duration 4-6 hours (PO), 2-6 hours (IV); half life 3-7 hours (IV and PO); metabolized in liver, excreted by kidney; highly protein bound
Hydralazine is good for acute BP management—T/F?
False—not good for acute BP management because it takes ~30 mins to kick in, peak effect in 60 mins
Pros = lasts longer
Cons = tachycardia and fluid shifts
Nitroglycerine causes a release of ___ for ___ (specific/non-specific) relaxation of vascular smooth muscle
Causes a release of nitric oxide for non-specific relaxation of vascular smooth muscle
Nitroglycerine dilates ___ > ___
Veins > arteries
Nitroglycerine ___ (increases/decreases) PVR, venous return, and myocardial oxygen consumption
Decreases
Venous dilation = decreased venous return, reducing preload
Decreased venous return = pooling of blood/edema in lower extremities
Nitroglycerine relaxes ___ vessels and relieves ___ spasms
Relaxes coronary vessels and relieves coronary spasms
What is an advantage of using nitroglycerine?
It preferentially shifts blood flow to areas that need it—don’t have coronary steal like you do with SNP
NTG non-cardiac effects—dilates ___ vessels (caution in patients with increased ___); decreased ___ blood flow with decreased BP; dilates ___ vessels and reduces ___ vascular resistance
Dilates meningeal vessels (caution in patients with increased ICP); decreased renal blood flow with decreased BP; dilates pulmonary vessels and reduces pulmonary vascular resistance
Pharmacokinetics of NTG—onset ___ min; duration ___-___ min; half life ___-___ min
Onset 1 min; duration 3-5 min; half life 1-4 min
Much faster onset than hydralazine, much shorter duration
Nitroglycerine/SNP are good for acute BP management, unlike hydralazine—T/F?
True
Metabolism of NTG—metabolized by ___ in the ___
Glutathione nitrate reductase in the liver
Metabolism of NTG—nitrite ion oxidizes ___ to ___
Hemoglobin to methemoglobin
What is a risk of using nitroglycerin in patients at risk for developing anemia? (i.e.: patients with CKD or CLD)
If you have a patient at risk for developing anemia (i.e.: patients with CKD or CLD), the more the methemoglobin builds up from NTG metabolism into nitrite ions, the less O2 delivery and higher risk for ischemia
Tolerance with NTG—tolerance in ___ (arterial/venous) vessels can occur with chronic NTG administration
Tolerance in arterial vessels can occur with chronic NTG administration, but not in the venous vessels
Tachyphylaxis can occur with NTG over time—T/F?
True—can start to lose effect in arterial vessels
NTG CNS side effects—___ache, appre___, ___ vision, ___go, ___ness, ___ness
Headache, apprehension, blurred vision, vertigo, dizziness, faintness
NTG CV side effects—___ hypotension d/t vaso___ and ___ of blood in the periphery, ___tations, ___ (increased/decreased) heart rate, ___cope
Postural hypotension d/t vasodilation and pooling of blood in the periphery, palpitations, increased heart rate, syncope
NTG GI side effects—___/___, ___ pain, ___ mouth
Nausea/vomiting, abdominal pain, dry mouth
NTG other side effects—___hemoglobinemia, ___ from vasodilation, ___, ana___, ___ and ___ edema (potentially d/t fluid shifts)
Methemoglobinemia, flushing from vasodilation, rash, anaphylaxis, oral and conjunctival edema (potentially d/t fluid shifts)
Warnings/contraindications with NTG—___ inhibitors; ___ glaucoma; ___ trauma, cerebral ___; severe ___; ___tension
PDE5 inhibitors (used to treat erectile dysfunction/pulmonary HTN); narrow angle glaucoma; head trauma, cerebral hemorrhage; severe anemia; hypotension
If you give NTG with PDE5 inhibitors, it can lead to fatal ___
Fatal hypotension
Advantages of NTG—___ (rapid/slow) onset; ___ (short/long) duration; coronary vaso___; ___ (increased/decreased) myocardial O2 consumption; no major ___; no coronary ___; reduced ___ vascular resistance
Rapid onset; short duration; coronary vasodilation; decreased myocardial O2 consumption; no major toxicities; no coronary steal; reduced pulmonary vascular resistance
Disadvantages of NTG—decreased ___ (systolic/diastolic) BP; reflex ___cardia; possible ___tension; variable efficacy; ___phylaxis
Decreased diastolic BP; reflex tachycardia; possible hypotension; variable efficacy; tachyphylaxis
Within 3-5 days of NTG use—___hemoglobinemia; intrapulmonary ___; prolonged ___ time
Methemoglobinemia; intrapulmonary shunting; prolonged bleeding time
NTG is best used to treat ___
Emergent HTN—fast onset, short duration, and easy to titrate
SNP directly vasodilates ___ and ___
Arteries and veins
SNP ___ (increases/decreases) BP with slight ___ (increase/decrease) in HR; ___ (increases/decreases) cerebral blood flow and ICP; ___ (increases/decreases/maintains) renal blood flow; ___ (increases/decreases) myocardial O2 demand
SNP decreases BP with slight increase in HR; increases cerebral blood flow and ICP; maintains renal blood flow, slight reduction; decreases myocardial O2 demand
What occurs with abrupt discontinuation of SNP?—___cardia and ___tension
Reflex tachycardia and hypertension
SNP pharmacokinetics—onset less than ___; peak ___-___ min; duration ___-___ min; half life ___ to ___ days
Onset less than 1 min; peak 2-3 min; duration 5-10 min; half life 2.7 to 7 days
Even though SNP has a much longer half life than NTG, the risk of toxicity is low because it doesn’t actually exert its effects for a full 7 days—T/F?
True
Half life of NTG = 1-4 min
Half life of SNP = 2.7 to 7 days
SNP CNS side effects—___lessness, appre___, muscle ___, ___ache, ___ness
Restlessness, apprehension, muscle twitching, headache, dizziness
SNP CV side effects—profound ___tension, ___tations, fluctuations in ___, ___ discomfort
Profound hypotension, palpitations, fluctuations in heart rate, retrosternal discomfort
SNP GI side effects—___/___, ___ pain
Nausea/vomiting, abdominal pain
SNP other side effects—nasal ___; ___ (increased/decreased) serum creatinine with ___/___ doses; ___/___ toxicity that can lead to ___ via ___
Nasal stuffiness, increased serum creatinine with higher/longer doses; thiocyanate/cyanide toxicity that can lead to end organ damage via hypoxia
SNP warnings/contraindications—congenital optic ___; ___volemia; compensatory ___tension (i.e.: AV shunting, aortic coarctation); ___ (increased/decreased) ICP; severe ___/___ impairment
Congenital optic atrophy; hypovolemia; compensatory hypertension (i.e.: AV shunting, aortic coarctation); increased ICP; severe renal/hepatic impairment
Why should SNP be avoided in severe renal/hepatic impairment?
Because you need the liver to breakdown cyanide (byproduct of SNP)
Thiocyanate is a byproduct of cyanide metabolism and is broken down by the kidneys
Thiocyanate/cyanide toxicity presentation—___tension; ___ vision; ___gue; metabolic ___osis; ___ skin; absence of ___; ___ heart sounds
Hypotension; blurred vision; fatigue; metabolic acidosis; pink skin; absence of reflexes; faint heart sounds
Risk of thiocyanate/cyanide toxicity increases with doses over ___mcg/kg/min, > ___ days of therapy
Doses over 4 mcg/kg/min, > 2 days of therapy
Thiocyanate levels—therapeutic = ___-___ mcg/ml; toxic = ___-___ mcg/ml; fatal > ___ mcg/ml
Therapeutic = 6-29 mcg/ml
Toxic = 35-100 mcg/ml
Fatal > 200 mcg/ml
Cyanide levels—normal is < ___ mcg/ml, < ___ mcg/ml for smokers; toxic > ___ mcg/ml; fatal > ___ mcg/ml
Normal is < 0.2 mcg/ml, < 0.4 mcg/ml for smokers
Toxic > 2 mcg/ml
Fatal > 3 mcg/ml
Thiocyanate/cyanide toxicity—what happens? ___ binds to hemoglobin very quickly; iron in hemoglobin cannot bind to ___ when cyanide is bound; patients can die of ___ dysfunction because they are ___ and no ___ exchange is occurring
Cyanide binds to hemoglobin very quickly; iron in hemoglobin cannot bind to oxygen when cyanide is bound; patients can die of multiorgan dysfunction because they are hypoxic and no oxygen exchange is occurring
What is one distinct feature in patients with thiocyanate/cyanide toxicity?
Can smell almonds on patient’s breath
SNP—treatment of cyanide toxicity—___ infusion; administer ___; correct ___
Stop SNP infusion; administer 100% oxygen; correct metabolic acidosis
SNP—treatment of cyanide toxicity—sodium thiosulfate donates a ___ group to remove ___/___ molecules from hemoglobin so that hemoglobin can bind to ___
Sodium thiosulfate donates a sulfate group to remove thiocyanate/cyanide molecules from hemoglobin (they will bind to the sulfate instead) so that hemoglobin can bind to oxygen
SNP—treatment of cyanide toxicity—hydroxocobalamin is a precursor to vitamin ___; binds ___ molecules
Precursor to vitamin B12; binds cyanide molecules
Can consider Vitamin B12 for treatment of cyanide toxicity as well
SNP—treatment of cyanide toxicity—3% sodium nitrite has become a medication of last resort because it causes ___ and can worsen ___
Has become a medication of last resort because it causes anemia and can worsen ischemia
SNP advantages—___ onset, ___ (short/long) duration, ___ (increased/decreased) myocardial O2 demand
Immediate onset, short duration, decreased myocardial O2 demand
SNP disadvantages—reflex ___cardia; ___ toxicity; intrapulmonary ___; precipitous drop in ___ is possible; ___degradation; ___hemoglobinemia; coronary ___; enhanced ___; cerebral vaso___
Reflex tachycardia; cyanide toxicity; intrapulmonary shunting; precipitous drop in BP is possible; photodegradation; methemoglobinemia; coronary steal; enhanced bleeding; cerebral vasodilator
Always use ___ for CAD patients, not ___
NTG for CAD patients, not SNP
Because NTG does not cause coronary steal and SNP does, which further worsens ischemia
Alpha 1 receptor activation—increases intracellular ___; smooth muscle ___ (contraction/relaxation); peripheral vaso___; broncho___; ___ (inhibits/stimulates) insulin secretion; ___ (inhibits/stimulates) glycogenolysis and gluconeogenesis; ___ (mydriasis/miosis); GI ___ (contraction/relaxation)
Increases intracellular calcium; smooth muscle contraction; peripheral vasoconstriction; bronchoconstriction; inhibits insulin secretion; stimulates glycogenolysis and gluconeogenesis; mydriasis; GI relaxation
Alpha 2 receptor activation ___ (stimulates/inhibits) neuronal firing in the CNS and peripheral NS; results in ___tension, ___cardia, ___ation, ___gesia
Inhibits neuronal firing in the CNS and peripheral NS; results in hypotension, bradycardia, sedation, analgesia
Alpha 2 receptor activation—effects on other organs—___ (increased/decreased) salivation and secretions; ___ (increased/decreased) GI motility; ___ (stimulates/inhibits) renin release; ___ (increases/decreases) GFR; ___ (increases/decreases) sodium and water secretion; ___ (increased/decreased) insulin release
Decreased salivation and secretions; decreased GI motility; inhibits renin release; increases GFR; increases sodium and water secretion; decreased insulin release
Phenoxybenzamine (Dibenzyline) is a ___
Nonselective alpha antagonist—it irreversibly binds to alpha 1 and alpha 2 receptors
Main use of phenoxybenzamine (dibenzyline)—long-term preoperative treatment to control the effects of ___
Pheochromocytoma
“Chemical sympathectomy”
Other uses of phenoxybenzamine (dibenzyline)—relieve ischemia in ___; ___ to improve flow
Relieve ischemia in PVD; BPH to improve flow (was used before flomax, rapaflo, and hytrin came around)
Effects of phenoxybenzamine (dibenzyline)—reduced ___ to reduced ___; secondary increases in ___ due to ___ blockade can increase ___ and ___
Reduced peripheral vascular resistance (PVR) to reduced BP; secondary increases in NE due to alpha 2 blockade can increase HR and CO (beta 1 effects)
Phenoxybenzamine (dibenzyline) does not cross the BBB—T/F?
False—crosses the BBB
Phenoxybenzamine (dibenzyline) CNS side effects—___ation, ___ssion, ___ness, ___gy, ___ache
Sedation, depression, tiredness, lethargy, headache
Phenoxybenzamine (dibenzyline) GI side effects—___/___
Nausea/vomiting
Phenoxybenzamine (dibenzyline) CV side effects—___tension, ___cardia, ___mias
Postural hypotension, tachycardia, arrhythmias
Phenoxybenzamine (dibenzyline) pharmacokinetics—half life ___ hours; duration of action ___ days; route of administration ___
Half life 24 hours; duration of action 4 days; route of administration PO
May see up regulation of alpha receptors with phenoxybenzamine (dibenzyline)—T/F?
True—because it is a nonselective alpha antagonist—blocks alpha 1 and alpha 2 receptors
Phentolamine is a ___
Nonselective alpha antagonist—blocks alpha 1 and alpha 2 receptors just like phenoxybenzamine
Phentolamine uses—hypertension secondary to ___; ___ withdrawal hypertension; ___ dysfunction; ___ of catecholamines
Hypertension secondary to pheochromocytoma; clonidine withdrawal hypertension; erectile dysfunction; extravasation of catecholamines
Phentolamine pharmacokinetics—half life ___ minutes; onset ___-___ minutes IM, ___ IV
Half life 19 minutes; onset 15-20 minutes IM, immediate IV
Oral alpha 1 antagonists are ___ (selective/non-selective)
Selective
Alpha 1 antagonists end in -___
-zosin or -osin
Examples = prazosin (minipres); terazosin (hytrin); doxazosin (cardura); tamsulosin (flomax); silodosin (rapaflo); afluzosin (uroxatral)
What did Cochrane review demonstrate about the use of Alpha 2 agonists and risk of cardiac complications after surgery?
Alpha 2 agonists had no effect on reducing cardiac complications after surgery—specifically, they had no effect on overall mortality, cardiac mortality, and prevention of MI
Alpha 2 agonists and cardiac complications—monitor patients for excessive ___ and ___
Excessive hypotension and bradycardia
Clonidine is a ___ (central/peripheral) acting alpha-___ ___ that leads to inhibition of ___ (sympathetic/parasympathetic) outflow
Clonidine is a central acting alpha-2 agonist that leads to inhibition of sympathetic outflow
Clonidine affinity for alpha 2 over alpha 1 receptors is ___:___
220:1
Clonidine ___ (increases/decreases) the release of sympathetic neurotransmitters, ___ (stimulates/inhibits) renin release
Decreases the release of sympathetic neurotransmitters, inhibits renin release
Clonidine can be administered orally and by patch, as well as by IV, intrathecal, and epidural—T/F?
True
Clonidine actions/effects—___ (increases/decreases) HR, BP, CO, and SVR
Decreases
