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5/16/06

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Question
Answer
Antihypertensives   Captopril, Clonidine, Enalapril, Furosemide, Hydralazine, Hydrochlorothiazide, Losartan, Metoprolol, Nifedipine, Nitroglycerin, Prazosin, Propranolol, Verapamil  
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Antianginal   Diltiazem, Nefedipine, Nitroglycerin, Propranolol  
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Class IA Antiarrhythmics (Na and K blocker; Inc QRS and QT); dec myocardial excitability, conduction velocity, contractility and automaticity; prolong refractory period and block vagal stimulation of AV node   Amiodarone, Procainamide, Quinidine, Disopyramide  
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Class 1B Antiarrhythmics (Activates K channels; Dec QT only); suppress SA and AV nodal conduction to improve resting potential duration   Lidocaine, Phenytoin, Mexiletine, Tocainide  
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Class IC Antiarrhythmics (Strong Na blocker; Inc QRS only)   Encainide, Propafenone, Flecainide  
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Class II Antiarrhythmics (B-blockers; Inc PR interval; neg chronotrope, dec sinus rhythm)   Esmolol, Atenolol, Propranol, Sotalol, Metoprolol  
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Class III Antiarrhythmics (K channel blockers; Inc QT only)   Amiodarone, Ibutilide, Sotalol  
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Class IV Antiarrhythmics (Ca channel blockers; Inc PR interval; Dec sinus and AV rhythm)   Verapamil, Diltiazam  
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Class I Side Effects   Torsade's (Inc QT; IA only); Dec Force (neg inotropic); Proarrhythmic; Do NOT give to CHF patients  
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Class II/IV Side Effects   Dec force (neg inotropic); Dec Rate (neg chronotropic)  
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Class III Antiarrhythmics Side Effects   Torsade's (Inc QT); Dec Rate (neg chronotropic); Proarrhythmic; Do NOT give if pt is Bradycardic  
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Antihhyperlipidemic   Cholestyramine, Clofibrate, Gemfibrozil, Lovastatin, Nicotinic Acid  
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Antimicrobials   Aminoglycoside, Ampicilin, Chloramphenicol, Methicilin, Penicilin, Tetracycline, Vancomycin  
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Cyclosporin in cardiac pt   used to prevent acute rejection of heart and renal transplants by inhibiting T-helper cell activation (via inhibition of IL-2)  
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Immunosuppressives   Glucocorticoids, Cyclosporine  
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Inotropic drugs (increase cardiac output)   Digoxin, Digitalis, Dobutamine, Dopamine  
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Myocardial Infarction drugs   Aspirin, Ticlopidine  
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Where do B-blockers work in CV system?   they inhibit renin release  
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Where do ACE inhibitors work?   they inhibit renin's ability to convert angiotensin I to angiotensin II  
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What do ARBs do?   they prevent antiotensin II from increasing preload, afterload and remodeling of the heart  
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What do diuretics and vasodilators do in the CV system?   inhibit increased preload and afterload of heart by lowering blood volume and pressure  
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Antihypertensive drug categories   Diuretics (Hydrochlorothiazide, Loops), Sympathohplegics (Clonidine, Methyldopa, Hexamethonium, Reserpine, Guanethidine, Prozasin, b-blockers), Vasodilators (Hydralazine, minoxidin, nifedipine, verapamil, nitroprusside), ACE-i (captopril), ARBs (losartan)  
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Antihypertensive diuretics   Hydrochlorothiazide; (adverse effects: hypoK, hyperLipidemia, hyperUricemia, lassitude, hyperCa, hyperGlycemia)  
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Antihypertensive diuretics   loop diuretics; (adverse effects: K+ wasting, metabolic alkalosis, hypotension, OTOTOXICITY)  
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Antihypertensive sympathoplegic   Clonidine; (adverse effects: dry mouth, sedation, severe rebound HTN)  
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Antihypertensive sympathoplegic   Methyldopa; (adverse effects: sedation, positive Coomb's test)  
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Antihypertensive sympathoplegic   Hexamethonium; (adverse effects; severe orthostatic hypotension, blurred vision, constipation, sexual dysfxn)  
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Antihypertensive sympathoplegic   Reserpine; (adverse effects: sedation, depression, nasal stuffiness, diarrhea)  
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Antihypertensive sympathoplegic   Guanethidine; (adverse effects: orthostatic and exercise hypotension, sexual dysfxn, diarrhea)  
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Antihypertensive sympathoplegic   Prozasin; (adverse effects: 1st dose orthostatic hypotension, dizziness, HA)  
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Antihypertensive sympathoplegic   b-blockers; (adverse effects: impotence, asthma, CV effects (bradycardia, CHF, AV block), CNS effects (sedation, sleep alterations))  
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Antihypertensive Vasodilator   Hydralazine; (adverse effects: nausea, HA, lupus-like syndrome, reflex tachycardia, angina, salt retention); *use with b-blockers to prevent reflex tachy and a diuretic to block salt retention*  
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Antihypertensive Vasodilator   Minoxidil; (adverse effects: hypertrichosis (hair growth), pericardial effusion, reflex tachycardia, angina, salt retention); *use with b-blockers to prevent reflex tachy and a diuretic to block salt retention*  
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Antihypertensive Vasodilator   Nifedipine, Verapamil; (adverse effects: dizziness, flushing, constipation (verapamil), nausea)  
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Antihypertensive Vasodilator   Nitroprusside; (adverse effects: cyanide toxicity d/t CN release)  
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Antihypertensive ACE inhibitor   "Captopril"; (adverse effects: HyperKalemia; Cough, Angioedema, Proteinuria, Taste changes, hypOtension, Pregnancy probs (fetal renal damage), Rash, Inc renin, Lower angiotensin II)  
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Antihypertensive ARB   Losartan; (adverse effects: fetal renal toxicity, hyperKalemia)  
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Acetazolamide site of action   prox tubule; carbonic anhydrase-i; self-limited NaHCO3 diuresis/depletion of HCO3- stores; Uses: Glaucoma, urinary alkalization, metabolic alkalosis, altitude sickness; (Toxcitiy: hyperChloremic metabolic ACIDosis, neuropathy, NH3 toxicity, sulfa allergy  
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Mannitol (Osmotic) Diuretic site of action   proximal tubule and descending loop of Henle and collecting duct  
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Furosemide (Loop) diuretic site of action   thick ascending loop; inhibit cotransport of Na/K/2Cl; no urine [ ]; LOSE Ca; Uses: Edema (CHF, cirrhosis, neprhotic syndrome, pulm edema), HTN, hyperCa; (Toxicity = "OH DANG;" ototoxicity, hypokalemia, dehydration, allergy (sulfa), nephritis, gout)  
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Thiazide (hydrochlorothiazide) diuretic site of action   distal tubule; inhibits NaCl reabsorption; DEC Ca excretion (opp loops); Uses: HTN, CHF, hypercalciuria, nephrogenic diabetes insipidus; (Toxicity: hypoKalemic met alkalosis; hyponatremia; HyperGLUC = hyperGlycemia, -Lipidemia, -Uricemia, -Calcemia; sulfa  
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Potassium sparing diuretic site of action   The K STAys (spironolactone, triamterene, amiloride, eperlone); junction of distal tubule and collecting tubule; Uses: hyperaldosteronism, K+ depletion, CHF; (Toxicity: hyperKalemia, endocrine effects (spironolactone = gynecomastia/antiandrogen effects)  
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ADH antagonist diuretic site of action   collecting duct  
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Spironolactone   competitive aldosterone receptor antagonist  
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Diuretics that increase Urine NaCL   all types: carbonic anhydrase inhibitors, loop diuretics, thiazides, K-sparing  
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Diuretics that increase Urine K+   all types except K-sparing  
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Diuretics that decrease blood pH, causing metabolic acidosis   carbonic anhydrase inhibitors, K-sparing  
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Diuretics that increase blood pH, causing metabolic alkalosis   loop diuretics, thiazides  
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Diuretics that increase Urinary Ca   loop diuretics  
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Diuretics that decrease Urinary Ca   thiazides  
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Hydralazine   antihypertensive; inc cGMP to relax smooth m (vasodilates arterioles > vv); reduces afterload; Uses: severe HTN, CHF; (Toxicity: compensatory tachy, fluid retention, lupus-like syndrome)  
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Nifedipine, verapamil, diltiazam   CCBs; block voltage-dep channels on cardiac/smooth muscle to reduce contractility; Uses: HTN, angina, arrhythmias; (Toxicity: cardiac depression, peripheral edema, flushing, dizziness, constipation)  
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Verapamil   CCB that has greatest effect on decreasing cardiac muscle contracility  
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Nifedipine   CCB that has greatest effect on decreasing smooth muscle contracility; does NOT cause arrhythmias  
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Captopril, Enalapril, Lisinopril   ACE-i; dec AT-II (No bradykinin inactivation = vasodilation); inc renin d/t loss of feedback inhib; Uses: HTN, CHF, diabetic renal dz; (Toxicity: "CAPTOPRIL" = cough, angioedema, proteinuria, taste change, hypOtension, Pregnancy (fetal renal damage), rash  
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Losartan   ARB; does not cause cough; use when pt cannot stand ACE-i  
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Nitroglycerin, Isosorbide dinitrate   vasodilators (vv >> aa; inc NO and cGMP for smooth m relaxation; Uses: angina, pulmonary edema; (Toxicity: tachycardia, hypotension, HA, "monday dz")  
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Goal of antianginal therapy   reduce myocardial O2 consumption by decreasing 1 or more of the following: end diastolic vol, BP, HR, contractility, ejection time; the use of nitrates + b-blockers has greatest effect overall on dec BP, HR and O2 consumption  
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Nifedipine, Verapamil   CCBs; N is similar to nitrates (dec end diastolic vol, BP, ejection time, but reflexes inc contractility and HR) and V is similar to b-blockers in effect (inc end diastolic vol and ejection time, dec BP, contractility, HR)  
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Digitalis, Digoxin (cardiac glycosides)   inhibits Na/K ATPase = inc in intracellular Na and Ca = Positive inotropy; Inc PR, Dec QT, Scooping of ST segment, T-wave inversion; Uses: CHF (inc contractility) and Atrial Fib (dec AV node conduction); (Toxicity: N/V/D, blurry yellow vision, arrhythmias  
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CCBs   inhibit voltage-gated Ca channels  
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B-agonists   activate voltage-gated Ca channels  
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Digoxin   75% bioavailability; urinary excretion; (Toxicity: renal failure (dec excretion), hypokalemia, quinidine (dec clearance); ANTIDOTE = slowly normalize K+, Lidocaine, Cardiac pacer, Anti-dig Fab fragments  
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LDL Lowering drugs   HMG-CoA reductase inhibitors ("statins") >> Niacin = Bile Resins (Cholestyramine, Colestipol), Cholesterol absorption blocker (Ezetimibe) > Fibrates (Gemfibrozil, Clofibrate, etc)  
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TG lowering drugs   Fibrates >>> Niacin = HMG-CoA Reductase Inhibitors  
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HDL Raising Drugs   Niacin > HMG-CoA Reductase Inhib = Fibrates  
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Side effects of Niacin   red, flushed face (can be dec w/aspirin or long-term use); try to get pt to tolerate b/c it can raise HDL and lower LDL  
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Lipid lowering drugs that cause Elevated LFTs   HMG-CoA red inhib, Fibrates, rarely cholesterol absorption blocker (ezetimibe)  
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HMG-CoA Reductase Inhibitors MOA   prevent conversion of HMG-CoA to cholesterol in hepatocytes  
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Niacine MOA   Inhibits cholesterol conversion to VLDL in hepatocytes; less circulates in blood  
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Resins MOA   prevents reabsorptionof bile acids from GI into hepatocytes; pts hate tase and have GI discomfort  
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Gemfibrozil MOA   activates Lipoprotein lipase to convert VLDL into IDL; can cause myositis  
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Heart development   mesoderm; paired endocardial tubes; lateral and cephalic folding; primitive heart dilates in 5 areas (truncus arteriosus, bulbus cordis, primitive ventricle, primitive atrium, sinus venosus)  
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Truncus arteriosus   ascending aorta, pulmonary trunk/artery; divided by aorticopulonary septum  
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Bulbus cordis   smooth parts of R ventricle (conus arteriosus) and L ventricles  
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Primitive ventricle   R and L ventricles (trabeculated)  
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Primitive atrium   R and L atria (trabeculated)  
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Sinus venosus   R horn = smooth part of R atrium; L horn = coronary sinus; oblique vein  
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R common and anterior cardinal veins   superior vena cava  
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Septum primum, septum secundum, AV cushion form the:   atrial septum  
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Foramen ovale   communication btw R and L atria formed by walls of septum primum and septum secundum; Persistance/patency = mc atrial septal defect  
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Aberrant development of aorticopulmonary septum causes:   Tetralogy of Fallot  
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Aorticupulmonary septum, R and L bulbar ridges, atrioventricular cushion form the:   Interventricular septum  
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Aortic arch 3   forms bilateral common carotid arteries  
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Aortic arch 4   forms aorta on left and proximal subclavian artery on right  
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Aortic arch 6   forms ductus arteriosus and part of pulmonary trunk  
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Paired dorsal aortae that run on ventral surface of embryo form:   descending aorta when they coalesce  
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Vitelline veins   ductus venosus, hepatic sinusoids, IVF, portal vein, superior and inferior mesenteric vv  
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Umbilical veins   no adult vascular structures; L vein connects to ductus venosus & carries O2-blood (80% sat) from placenta to fetus; L vein = ligamentum teres hepatis  
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Anterior Cardinal veins   forms internal jugular vein and superior vena cava  
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Posterior Cardinal veins   form IVC, common iliac vv, azygos v, and renal vv  
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The umbilical ciruculation   the only other place besides lungs where artery carries deO2 blood; the paired arteries carry deO2 to placenta and single vein brings O2-blood to fetus  
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1st aortic arch   part of maxillary artery  
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2nd aortic arch   stapedial and hyoid arteries  
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Umbilical arteries   MEDIAL umbilical ligaments  
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Ductus arteriosus   ligamentum arteriosum  
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Ductus venosus   ligamentum venosum  
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Foramen ovale   fossa ovalis  
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Allantois   urachus; MEDIAN umbilical ligament (urachal cyst or sinus permits urine to drain from bladder)  
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Notochord   nucleus pulposus  
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Fetal blood flow: oxygenated blood   the majority reaches heart via IVC and is diverted thru foramen ovale and pumped out aorta towards head  
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Fetal blood flow: deoxygenated blood   arrives in the SVC and is expelled thru pulmonary artery and ductus arteriosus to lower body of fetus  
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Fetal circulation: changes at birth   deep breath = dec pumonary resistance and inc L atrial pressure (versus R atrial pressure); foramen ovale closes; Inc in O2 inhibits prostaglandins, causing closure of ductus arteriosus w/in first days of life  
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Indomethacin Therapy   closes patent ductus arteriosus  
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Alprostadil (PGE1) Prostaglandin Therapy   keeps an patent ductus arteriosus open (in case of a heart defect)  
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Down syndrome heart defects   endocardial cushion defects can manifest as atrial septal or ventricular septal defects  
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Atrial septal defect   90% are d/t septum secundum; L to R shunt; asymptomatic until 30s; murmur, R ventricular hypertrophy; female  
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Coarctation of aorta   infantile (proximal to PDA) versus Adult (constriction at closed ductus arteriosus, distal to origin of L subclavian v); weak pulses in lower limbs; males and females with Turner's syndrome  
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Paradoxical emboli   originate in venous circulation, pass thru patent foramen ovale or ASD to produce symptoms on arterial side  
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Patent ductus arteriosus   may be d/t premature birth w/hypoxemia or structural defects; continuous MACHINERY murmur; 2nd mc CHD  
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Tetralogy of Fallot   overriding aorta, VSD, pulmonary stenosis, hypertrophy of R ventricle; possible cyanosis, R to L shunt, boot-shaped heart; pt "squats" to relieve symptoms; can survive to adulthood  
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Transposition of great arteries   separate pulmonary and systemic circuits = incompatible with life unless a shunt exists; cyanosis at birth; a/w diabetic mothers  
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Ventricular septal defect   mc CHD; membranous (90%) or muscular; L to R shunt; LOUD HOLOSYSTOLIC murmur means small defect (can close spontaneously); large = heart failure at birth  
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Dextrocardia   heart is on R side of thorax; isolated cases a/w other organ anomalies  
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Situs Inversus   transposition of al organs; a/w "Kartagener's Syndrome" w/immotile cilia d/t dynein arm defect (lung dz and sterility); heart is usu normal  
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Eisenmenger's syndrome   the change from a L to R shunt to a R to L shunt secondary to increasing pulmonary HTN; usu d/t chronic adaptive response to pre-existing L to R shunt such as VSD  
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Right coronary artery   supplies SA and AV nodes and inferior portion of left ventricle via posterior descending artery (right dominant heart)  
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Coronary artery occlusion   most commonly occurs in left anterior descending artery, which supplies anterior IV septum  
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Coronary artery dilation   occurs during diastole  
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Left atrium of heart   the most posterior portion of the heart; enlargement can cause dysphagia  
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Depolarization of nodal tissues versus muscular cardiac tissue   Ca2+ versus Na+; Ca channels are slower allowing for prolongation of AV transmission btw atria and ventricles  
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Drugs that treat arrhythmias can also cause them   digoxin, class Ia (quinidine, disopyramide), Class Ic (propafenone, flecainide, ecainide) and Class II (propranolol)  
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Sympathetic CHOLINERGICS   mediate vasodilation in skin vessels; activated in response to inc body temp or alcohol (vessels dilate, AV anastomoses close and heat is lost to atmosphere); the opposite occurs w/dec core body temp  
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Increased intracellular Ca (drug-mediated or d/t sympathetic b-receptor stimulation)   allows for increased INOTROPIC effects of heart; greater contractility  
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Greater preload (inc filling of ventricles)   stretches myocytes and induces stronger contraction  
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Afterload (aortic pressure)   influenced by total peripheral resistance of body; heart must work harder if afterload is high otherwise cardiac output falls  
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Renin-Angiotensin-Aldosterone System   responds to changes in arterial pressure by altering salt and water retention by kidneys; low bp inc renin release (converts angiotensinogen to AT1 in liver, AT1 --> AT2 in lungs via ACE; AT2 constricts arterioles and inc release of aldosterone (Na/Water)  
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Atrial natriuretic peptide   responds to bp changes; Inc BP = Inc stretch in Atrial Myocytes which releases ANP; ANP inhibits contraction of smooth muscle, inc Na and water excretion and inhibits renin release  
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Antidiuretic hormone/ADH/AVP   responds to rapid blood loss; released from pituitary to work on kidney to dec urine output and retain water; also constricts arterioles to inc peripheral vascular resistance  
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Baroreceptor reflex   affects total vascular resistance; carotid bodies (sense arterial pressure) send afferent signals via CNIX to induce efferent signals via CNX to influence HR; inc BP = inc vagal output and dec HR; Dec in BP = Dec in vagal output and inc HR  
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Layers of a muscular coronary artery   adventitia, vasa vasorum, external elastic lamina, media, internal elastic lamina, endothelium  
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Anastamoses between R and L coronary arteries   Septal branch and Apex  
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P wave   atrial depolarization  
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PR interval   0.12 - 0.2 seconds; measures time btw atrial and ventricular polarization  
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QRS interval   usu <0.1 second; reflects duration of ventricular depolarization  
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T wave   ventricular depolarization  
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Torsades des Pointes   ventricular tachycardia d/t anti-arrhythmic drugs, especially quinidine; long QT interval and "short-long-short" sequence prior to inception of tachycardia; ECG shows series of upward pointing QRS complexes followed by series of downward pointing complexe  
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Atrial Flutter   regular, saw-tooth pattern of back-to-back atrial depolarizations (P wave); usu near 300/min; QRS complexes are present  
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Atrial Fibrillation   chaotic, erratic baseline w/o discrete P waves in between irregularly spaced QRS complexes (AV node is bombarded by impulses; wide QRS complexes = abberent "Ashman" beats  
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Ventricular Fibrillation   completely irratic rhythm without any identifiable waves; fatal w/o immediate defibrillation; atria may be dissociated  
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Wolff-Parkinson-White Syndrome   accessory AV conductions (bundle of Kent) bypassing AV node; aterograde or retrograde - ventricles partially depolarize early producing blurred QRS slope (delta-waves); reentry currents lead to supraventricular tachycardia  
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Myocardial infarctions can cause   both second degree and third degree heart blocks  
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First degree heart block   long PR interval (>0.2 sec); AV nodal anomaly; b-blockers, digitalis, CCBs  
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Second degree heart block: Mobitz type 1, Wenckebach   Progressively increasing PR interval until QRS wave is lost; defective AV node; common; no Tx required  
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Second Degree Heart Block: Mobits type 2   defectiv His-Purkinje system; constant PR interval with random dropped QRS complexes; Tx = pacemaker  
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Third Degree Heart Block   Atria and ventricles contract independently; Rate of ventricular contraction is determined by His-Purkinje system; may need pacemaker  
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Ventricular action potentials   depolarized by Na, K+ efflux plateaus with Ca influx; Ca triggers SR to release more Ca and contract myocytes; Massive K efflux repolarizes as Ca channels close (Phases 0 thru 4)  
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Pacemaker (SA and AV nodes) Action Potentials   depolarization initiated by Ca (not Na), which is slower than myocytes to prolong transmission btw atria & ventricles; No plateau; slow diastolic depolarization; ACh decreases HR, Catecholamines (NE, E) inc HR (aka rate of diastolic depol of SA node)  
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Fick Equation   calculates either CO or oxygen consumption: CO = (O2 consumption)/([O2] in pulmonary v - pulmonary a)  
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Cardiac output   Stroke volume x HR; inc during exercise initially d/t inc in SV and d/t inc in HR after prolonged exercise; if HR is too high, diastolic filling is incomplete and CO decreases (ex: v-tach)  
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Mean arterial pressure   cardiac output x total peripheral resistance OR 1/3 systolic + 2/3 diastolic  
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Pulse pressure   systolic - diastolic; (approximates the stroke volume)  
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Stroke volume   Cardiac output / Heart rate OR End diastolic volume - End systolic volume  
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Ejection fraction   (Stroke Volume / End diastolic volume) x 100%; Normal >55%  
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Relationship between arteriolar diameter and systemic resistance   if radius is increased by 2, the resistance drops by 16 fold (R = 1/r^4)  
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What happens to blood flow resistence when vessels run parallel to each other? What affects viscosity?   It lowers total resistance (ex: capillary beds); inversely proportional to the radius^4; directly proportional to viscosity (ex: polycythemia, hyperproteinemia (multiple myeloma), hereditary spherocytosis)  
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Stroke volume is affected by (SV CAP)   contractility, afterload, and preload; it increases with elevated preload and contractility and decreases with decreased afterload  
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Contractility and SV increase with   Catecholamines (inc Ca pump in SR); Inc intracellular Ca; Dec extracellular Na; Digitalis (in intracellular Na and Ca); anxiety, exercise, pregnancy  
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Contractility and SV decrease with   b1 blockade; Heart failure; Acidosis; Hypoxemia/hypercapnea  
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Myocardial O2 demand increases with   inc Afterload, inc Contractility, inc HR, in Heart size (inc wall tension)  
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Preload   represents ventricular end diastolic volume; it increases w/exercise, overtransfusion, and excitement; It can be decreased by venous dilators (ex: Nitroglycerin); force of contraction is proportional to initial length of cardiac muscle fiber  
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Afterload   represents diastolic arterial pressure (proportional to peripheral resistance); It can be decreased by vasodilators (ex: hydralazine)  
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Isovolemic contraction   period btw mitral valve closure and aortic valve opening; period w/highest O2 consumption  
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Systolic ejection   period btw aortic valve opening and closing  
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Isovolemic relaxation   period btw aortic valve closing and mitral valve opening  
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Rapid filling   period just after mitral valve opening  
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Slow filling   period just before mitral valve closure  
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S1 sound   mitral and tricuspid valve closure  
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S2 sound   aortic and pulmonary valve closure  
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S3 sound   at end of rapid ventricular filling; a/w dilated CHF  
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S4 sound   "atrial kick;" high atrial pressure/stiff ventricle; a/w hypertrophic ventricle  
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S2 splitting   aortic valve closes before pulmonic; the difference is increased during inspiration  
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Normal S2 splitting   aortic closes before pulmonic valve  
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Paradoxical splitting   a/w aortic stenosis; pulmonic valve closes before aortic valve  
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Jugular venous distention   a/w right heart failure  
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Cardiac myocyte physiology in contrast to skeletal muscle   contraction relies on calcium-induced calcium release; cardiac myocyte APs have a plateau d/t Ca influx; cardiac nodal cells spontaneously depolarize, resulting in automaticity; cardiac myocytes are electrically coupled together via gap junctions  
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Smooth muscle contraction   AP depolarizes membrane, voltage-gated Ca channels open, inc intracellular Ca binds to Calmodulin; Calmodulin activates myosin light chain kinase; phosphorylation = relaxation, myosin light chain phosphatase permits x-bridging & contraction  
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Conduction to contraction   depolarization - T tubule opens Ca channel and SR Ca release - binds troponin C & conformational change moves tropomyosin out of myosin binding groove on actin - myosin hydrolyzes ATP for power stroke with contracts "HIZ" bands (lenght stays constant)  
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Aortic arch baroreceptor   transmits via vagus nerve to medulla; responds ONLY to increased BP  
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Carotid sinus baroreceptor   transmits via glossopharyngeal nerve to medulla  
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Hypotension   low arterial pressure, low stretch, low afferent baroreceptor firing = INC efferent SYMP firing and dec parasymp stimulation = VASOCONSTRICTION, INC HR, contractility, INC BP; (important response to severe hemorrhage)  
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Carotid massage   by increasing pressure on the carotid artery, the vessels stretches and DECREASES HR  
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Peripheral chemoreceptors   carotid and aortic bodies respond to low PO2 (<60mmHg), high PCO2 and low pH  
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Central chemoreceptors   respond to pH and pCO2 changes in CSF which are influenced by arterial CO2. NO direct response to O2 levels; Responsible for Cushing's rxn to ICP (hypertension (symp response), bradycardia (parasymp response))  
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Circulation through liver   gets largest share of systemic cardiac output  
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Circulation through Kidney   gets highest blood flow per gram of tissue  
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Circulation through the heart   large arteriovenous O2 difference; Inc O2 demand is met by Inc coronary blood flow NOT by inc extraction of O2  
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Pulmonary capillary wedge pressure (PCWP)   is a good approximation of LEFT ATRIAL pressure; measured with Swan-Ganz catheter; usu <12mmHg  
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Right atrial pressure   <5mmHg  
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Right ventricle pressure   <25/<5mmHg  
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Pulmonary artery pressure   <25/10mmHg  
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Left atrial pressure   PCWP; <12mmHg  
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Left ventricular pressure   <130/10mmHg  
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Aortic pressure   <130/90mmHg  
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Autoregulation of blood flow   alterations meet demands of tissue  
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Factors determining autoregulation of Heart blood flow   local metabolites: O2, adenosine, NO  
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Factors determining autoregulation of Brain blood flow   Local metabolites: CO2 (pH)  
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Factors determining autoregulation of Kidney blood flow   Myogenic and tubuloglomerular feedback  
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Normal blood composition   8% of total body weight; 45% = hematocrit (formed elements: RBC, WBC, platelets); 55% = plasma (water, ptns, salts, fats, vitamins)  
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Serum   Plasma minus the clotting factors (ex: fibrinogen)  
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Starling forces   determine fluid movement by osmosis thru capillary membranes; Net filtration = the difference btw capillary fluid pressure and osmotic pressure  
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Pc = capillary pressure AND (pi)i = interstitial fluid colloid osmotic pressure   moves fluid out of capillary  
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Pi = interstitial fluid pressure AND (pi)c = plasma colloid osmotic pressure   tends to move fluid into capillary  
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Edema   excess fluid outflow into interstitium d/t: Inc capillary pressure (ex: HF); Dec plasma ptns (ex: nephrogenic dz or liver failure); Inc capillary permeability (ex: toxins, burns, infxn); Inc interstitial colloid osmotic pressure (ex: lymphatic blockage)  
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Atherosclerosis   the deposition of lipids into the INTIMA of elastic and lg/med muscular arteries leading to FIBROSIS and CALCIFICATION  
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Risk factors for Atherosclerosis   hyperlipidemia, DM, smoking, HTN, obesity, (family Hx, age, male, OCPs, elevated homocystein level)  
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Pathogenesis of Atheroma formation in Atherosclerosis   monocytes adhere to vessel wall, enter tissue, become MQs; transform into FOAM CELLS w/ingestion of oxidized LDL; accumulation in INTIMA w/release of factors to aggregate platelets, FGF (smooth muscle); plaque calcifies around central core of cholesterol  
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Complications of Atheroma in Atherosclerosis   plaque rupture, FATTY STREAKS, ischemic heart dz or MI; stroke; renal artery ischemia; death  
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Vitamin E   inhibits oxidation of LDL and its absorption by MQs  
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Superoxide, NO, Hydrogen peroxide   promote oxidation of LDL and blood vessel injury  
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HDL   works to remove cholesterol from tissues and plaques; exerts protective effect; levels are increased by EXERCISE  
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Familial Dyslipidemias   type IIb (combined hyperlipidemia) and IV (hypertriglyceridemia) are most common  
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Familial hypercholesterolemia (type IIa)   high LDL, elevated cholesterol, DEC LDL RECEPTORS; Xanthomas; (Tx = cholestyramine, lovastatin & niacin for homos)  
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Combined Hyperlipidemia (type IIb)   elevated LDL, VLDL, TG and Cholesterol; d/t hepatic overproduction of VLDL (Tx = cholestyramine, lovastatin & niacin for homos)  
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Hypertriglyceridemia (type IV)   elevated VLDL, TGs (cholesterol may be normal); d/t hepatic overproduction/dec clearance of VLDL; a/w diabetes, obesity, pregnancy, alcoholics; (Tx = wt loss, low fat diet, niacin, clofibrate or lovastatin)  
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Progression of atherosclerosis; and locations   fatty streaks --> proliferative plaque --> complex atheromas; abdominal aorta > coronary artery > popliteal artery > carotid artery  
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Symptoms and Complications of atherosclerosis   Angina, claudication, may be asymptomatic AND aneurysms, ischemia, infarcts, peripheral vascular dz, thrombus, emboli  
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Monckeberg Arteriosclerosis   calcification of arteries, especially radial or ulnar; usu benign  
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Arteriolosclerosis   HYALINE THICKENING of small arteries in ESSENTIAL HTN; hyperplastic "ONION SKINNING" in MALIGNANT HTN  
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Hypertension   age, obesity, diabetes, smoking, genetics, black, 90% essential d/t inc CO and TPR; 2* cases d/t renal dz; Malignant = severe/rapid progression  
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Characteristics of essential hypertension   BP >140/90 on 3 separate occasions; Hypertrophy of LV; Onion-skinning of vessel walls; Retinal hemorrhage; Predisposition to ischemic heart disease  
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Hypertrophy of left ventricle   a/w hypertension, left-sided valvular disease (ex: aortic stenosis or mitral regurgitation)  
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Secondary hypertension   a/w Renal Diseases (MCC; Parenchyma, Renal a. stenosis (atherosclerosis in black males, fibromuscular dysplasia in white females), activated RAAS) AND Endocrine dzs (1* Aldosteronism, Pheochromocytoma, Hyperthyroidism)  
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Fibromuscular dysplasia of renal artery   "beads on a string" sign on radiograph; common in white females; cause of secondary HTN  
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Malignant Hypertension   rapid course; results in end organ damage (CV - vascular damage, aortic dissection; Pulmonary - edema; Renal - "flea-bitten kidneys," azotemia; Ocular - fundal hemorrhage, papilledema; CNS - encephalopathy, seizure, coma); Death d/t CVA; Young Black Males  
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Arteriovenous fistula aneurysm   d/t trauma; causes high output cardiac failure  
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Atherosclerotic aneurysm   d/t atherosclerotic or coronary artery dz; usu in DESCENDING AORTA btw renal aa and iliac bifurcation  
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Berry aneurysm   congenital weakness at cerebral bifurcations esp Circle of Willis; usu hemorrhage into SUBARACHNOID SPACE; a/w polycystic kidney dz (AD dz on Chrom 16)  
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Dissecting aneurysm   a/w HTN, Marfan's, cystic medial necrosis; Tearing pain (separation of tunica media from aortic wall)  
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Syphilitic aneurysm   tertiary syphilis obiliteration of vaso vasorum w/necrosis of media; ASCENDING AORTA w/ aortic valve insufficiency;  
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Mycotic (infectious) aneurysm   inflammation usu d/t salmonella; ABDOMINAL AORTA  
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Syphilis   STD caused by Treponema pallidum (spirochete); painless hard chancre; if untreated, it causes rashes, lymphadenopathy, condyloma lata, Argyll Robertson pupils (accommodation, but no constriction) and aneuyrisms  
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Ischemic heart disease   inadequate supply of O2 relative to demand of heart, resulting in damage to cardiac tissue; most often caused by atherosclerosis; Exercise tolerance testing is good way to diagnose subacute coronary occlusion  
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4 types of ischemic heart disease   Angina Pectoris, Myocardial Infarction, Chronic Ischemic Heart Disease, Sudden Cardiac Death  
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Angina pectoris   paroxysmal attacks of retrosternal pain that may radiate to face/arms; a/w diaphoresis & nausea; CAD narrowing >75%; Three types: Stable, Prinzmetal's (Variant) and Unstable  
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Stable Angina   mc; induced by exercise, relieved by rest, d/t stenosis of coronary arteries  
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Prinzmetal's (variant) angina   episodic pain at rest; attacks are unrelated to activity, BP, or HR, but are d/t coronary vessel VASOSPAM; significant artery stenosis is present  
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Cocaine use   can cause coronary vasospasm and myocardial ischemia; it stimulates release of endogenous catecholamines (dopamine, NE, E)  
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Amphetamine use   prevents the reuptake of endogenous catecholamines  
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Unstable angina   occurs at rest or with increasing frequency, severity or duration; d/t RUPTURED atherosclerotic PLAQUE w/subsequent thrombosis and embolization; Activated platelets help thrombosis and vasospasm; Microinfarcts may occur  
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Myocardial infarction   tissue death d/t lack of perfusion; mc d/t atherosclerosis, plaque rupture, thrombosis; Endocardium is most vulnerable; can be: Non-transmural and Transmural; cardiac enzymes are released by damaged myocytes  
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Non-transmural (non-Q-wave) Infarct   diffuse coronary atherosclerosis w/dec coronary flow; Rupture/thrombosis is followed by clot lysis and loss of perfusion to inner 1/3 of muscular wall; ST segment DEPRESSION on ECG  
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Transmural Infarct   Atherosclerotic plaques rupture; Platelet-mediated thrombosis OCCLUDES vessel and blood flow is lost to entire muscular wall; ST segment ELEVATION on ECG  
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Left anterior descending coronary artery   mc artery involved in acute MI; infarcts affect LV near apex or anterior part of intraventricular septum  
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ST elevation is pathognomonic for:   Transmural (Q-wave) infarcts  
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ST depression   is not pathognomonic for non-transmural infarcts, it can also be produced by digitalis drugs  
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Red versus Pale Infarcts   Red (hemorrhagic) = occur in loose tissues w/collaterals (ex: lungs, intestines, or following reperfusion); Pale Infarcts = solid tissues w/single blood supply (ex: brain, heart, kidney, spleen)  
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Evolution of MI   Coronary artery occlusion: LAD > RCA > Circumflex; Day 1 (coagulative necrosis, dark, PMN recruitment); Days 2-4 (inflammation, hyperemia, PMN emigration, necrosis, yellow & soft); Days 5-10 (granulation tissue, MQ, PMNs); 7wks (Gray/white scar tissue)  
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Acute MI Symptoms and Diagnosis   Severe retrosternal pain, L arm/jaw pain, SOB, fatigue, adrenergic sx; ECG w/in 6hrs; later - troponin-I, CK-MB, LDH1, AST, ECG changes  
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Cardiac troponin I for diagnosis of MI   rises after 4hrs; stays elevated for 7-10days; Most SPECIFIC marker  
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CK-MB for diagnosis of MI   Test of choice w/in 1st 24hrs  
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LDH1 for diagnosis of MI   former test of choice; stays elevated for 2-7 days post-MI  
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AST for diagnosis of MI   nonspecific; can be found in liver, cardiac and skeletal muscle cells  
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ECG changes a/w MI   ST elevation (transmural), ST depression (subendocardial infarct), Q waves (transmural infarct)  
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MI Complications   Arrhythmia (early); LV failure/pulmonary edema; Cardiogenic shock (high mortality); Rupture of ventricular free wall, septum, papillary m (day 4-10) w/cardiac tamponade; Thromboembolism (mural); Fibrinous pericarditis (day 3-5); Dressler's syndrome (wks)  
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Dressler's Syndrome   autoimmune phenomenon a/w MI, resulting from fibrinous pericarditis (friction rub) several wks post-MI  
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Greatest danger of sudden cardiac death d/t arrhythmias   w/in 1-3hrs post-MI  
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Greatest danger of left ventricular free wall rupture   w/in 4-8 days post-MI (heart has yellow infarct w/red border and angiogenic/fibroblastic proliferation)  
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Chronic Ischemic Heart Disease   d/t Congestive heart failure; hypertrophy of heart and cardiac decompensation occur d/t infarction; usu in ELDERLY  
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Sudden Cardiac Death   unexpected death from cardiac failure w/in 2hrs of MI; a/w marked atherosclerosis and d/t arrhythmias  
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What is the most common cause of post-MI arrhythmias?   re-entry circuits, refractory tissue (unidirectional block), slow conduction velocity and an initiating event (premature beat)  
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Congestive heart failure   a clinical dz where heart can't pump enough blood to meet metabolic needs of body; hormonal changes (RAA and sympathetic activation), peripheral vasoconstriction and myocardial dysfunction all play a role  
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Cor pulmonale   right heart failure secondary to lung disorders which leads to pulmonary arterial hypertension  
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Left-sided CHF   Pulmonary edema/Paroxysmal Nocturnal dyspnea (pulm venous pressure; hemosiderin MQs), Orthopnea (can't be supine), S3 sound; d/t ischemia (CAD), HTN, valvular dz, myocarditis, cardiomyopathy, congenital heart dz, pericardial dz  
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Right-sided CHF   Nutmeg liver (central venous pressure; hepatomegaly/ascites), Peripheral Edema (pitting in ankles), Distention of neck vv; d/t Cor pulmonale  
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Myocarditis   inflammation of cardiac muscle; MCC is Coxsackie B virus (toxoplasmosis, S. aureus, C. diptheriae, Chaga's dz, Lyme dz, hypersensitivity rxns); Muffled S1, Audible S3, Mitral Regurgitation, Cardiomegaly  
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Trypanosoma cruzi   causes Chagas dz; transmitted by Reduvid bug; can cause myocarditis  
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Borrelia burgorferi   a spirochete that causes Lyme dz; Stage 1 = erythema chronicum migrans; Stage 2 = cardiac (myocarditis) and neurogenic probs; Stage 3 = arthritis  
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Causes of irreversible, dose-dependent cardiotoxicity   Doxorubicin, daunorubicin, anthracylines (used to tx breast cancer, lung cancer and ALL)  
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Endocarditis   inflammation of heart lining/CT; d/t Rheumatic heart dz (or rheumatic fever) OR Infectious causes (bacteria, damage, vegetative growth)  
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Characteristics of Endocarditis   Janeway lesions (peripheral nodular hemorrhages); Osler's Nodes (tender on fingers/toe pads); Splinter hemorrhages (finger nails), roth spots (retina), splenomegaly, petechiae; Commonly Mitral or Aortic valve (tricuspid = IVDA)  
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Acute Endocarditis   d/t Staph aureus; rapid onset; fever, anemia, embolic events, murmur  
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Subacute Endocarditis   d/t Strep viridans; poor dentition or oral surgery in pt w/preexisting heart dz; Onset over 6mo; Tx = IV Abx  
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Nonbacterial (marantic) endocarditis   a/w metastatic cancer; sterile fibrin deposits on heart valves; can cause cerebral infarct  
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Libman-Sacks endocarditis   a/w SLE; auto-antibody damage/vegetations to both sides of valve; no embolisms  
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Culture negative endocarditis   a/w HACEK organisms (Haemophilus, Actinobacillus, Cardiobacterium, Eikenella, Kingella)  
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Prosthetic valves predispose pts to   endocarditis caused by Staph epidermitis  
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Tumors of heart   Metastatic (2*) are most common; Primary tumors are very rare; Atrial myxomas are the most common 1* tumor in adults; Rhabdomyomas are mc primary tumor in children (a/w tuberus sclerosis)  
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Antiphospholipid syndrome   common in SLE; d/t Abs to phopsholipids that produces a hypercoagulable state leading to thrombotic disorders and multiple spontaneous abortions  
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Rheumatic Fever and Heart Disease   a/w pharyngitis w/GAS (b-hemolytic; S pyogenes); w/o Tx (PCN), Abs form via antigenic mimicry & fibrous bridges in hi pressure valves (MITRAL > aortic >>tricuspid); Aschoff bodies (granuloma in giant cell), polyarteritis, Erythema marginatum, hi ESO titer  
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Rheumatic Fever: FEVERSS   kids 5-15yo; fever, erythema marginatum, valvular damage, elevated ESR, Red-hot joints (polyarteritis), Subcutaneous nodules, St. Vitus' dance (chorea); myocarditis can cause heart failure and death  
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Bacterial Endocarditis: From Jane   Fever, Roth's spots, Oslers nodes, Murmur, Janeway lesions, Anemia, Nail-bed hemorrhage, Emboli  
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Cardiac Tamponade   compression of heart by fluid (ex: blood) in pericardium, leads to dec cardiac output; pressure in all 4 chambers equilibrates; Pulsus paradoxus; ECG - electrical alternans (beat-to-beat alterations in height of QRS)  
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Dilated cardiomyopathy   mc type; dilated "balloon" ventricles; idiopathic, a/w coxsackie B, alcoholics, Chagas, lithium, doxorubicin; Decreased Ejection Fraction and PVCs (systolic dysfxn)  
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Hypertrophic cardiomyopathy (aka: idiopathic hypertrophic subaortic stenosis)   AD seen in Young Athletes; asymmetric, involves IV septum; Mitral Regurgitation; S4, cardiomegaly, dyspnea, syncope, murmur; Relieved by Squatting and worsened w/activity  
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Restrictive cardiomyopathy   Stiffenen heart muscle (a/w sarcoidosis, amyloidosis); Peripheral Edema, ascites, JVD; (differentiate from constrictive)  
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Idioapthic dilated cardiomyopathy (mc cause), Tx =   Digitalis, ACE inhibitors, Heart Transplant, Chronic Anticoagulation  
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Senile Amyloidosis is derived from   tranthyretin  
🗑
Primary amyloidosis is d/t   amyloid light chain (AL) ptn from immunoglobulin light chains; seen in plasma cell disorders  
🗑
Mitral Stenosis   usu d/t Rheumatic Heart Disease; Opening Snap  
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Mitral Regurgitation   50% d/t Rheumatic Heart Disease; S3; Holosystolic Murmur loudest at apex  
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Aortic Stenosis   Calcification/thick valve; Crescendo-Decrescendo Systolic Ejection Murmur (do NOT give b-blockers)  
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Aortic Regurgitation   S3, High pitched Blowing Decrescendo Diastolic Murmur; wide pulse pressure  
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Mitral Valve Prolapse   mc valvular lesion; Late Systolic Murmur w/midsystolic click; found in young women or Marfan's pts; d/t tissue laxity; Murmur is exagerated by Valsalva and reduced by sqatting; Require endocardial prophylaxis prior to dental procedures  
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Ventricular Septal Defect   holosystolic murmur  
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Patent ductus arteriosus   Continuous machine-like murmur; Loudest at S2  
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Systolic Ejection Murmurs   Aortic or Pulmonic valve stenosis, Hypertrophic Cardiomyopathy  
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Holosystolic Murmur   Mitral or Tricuspid Regurgitation, Ventricular Septal Defect  
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Late Systolic Murmur   Mitral Valve Prolapse  
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Early Diastolic Murmur   Aortic or Pulmonoic Valve Regurgitation  
🗑
Mid-to-late Diastolic Murmur   Mitral Stenosis  
🗑
Continous Diastolic Murmur   Patent Ductus Arteriosus  
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Churg-Strauss Peripheral vascular dz   Granulomatous inflammation; a/w ASTHMA, EOSINOPHILIA  
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Henoch-Schonlein Purpura vascular dz   IgA immune complex mediated; Atopic (allergic) pt; URTI in KIDS; renal deposits, PALPABLE PURPURA  
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Kaposi's Sarcoma vascular dz   AIDS; malignant vascular tumor in HOMOSEXUALS; a/w HHV-8  
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Kawasaki's Disease vascular dz   Acute necrotizing; YOUNG KIDS  
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Rendu-Osler-Weber Syndrome vascular dz   AD hemorrhagic telangiectasia; MORMONS  
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Polyarteritis nodosa vascular dz   p-ANCA necrotizing degeneration of media; a/w HEPATITIS B infxn  
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Takayasu's Arteritis   "pulseless dz;" damage of AORTIC ARCH; loss of carotid, radial and ulnar pulses; Young ASIAN FEMALES  
🗑
Temporal Arteritis   nodular inflammation of branches of carotid; HA, VISUAL deficits; elevated ESR, ELDERLY; mc vasculitis in US  
🗑
Thromboangiitis Obliterans (Buerger's dz) vascular dz   full thickness vessel inflammation, extends to nerves w/ occlusive lesions in extremities; Raynaud's Phenomenon; young JEWISH MALE SMOKER; may lead to gangrene  
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Von Hippel-Lindau vascular Dz   AD (chrom 3); Hemangioblastomas of cerebellum; inc risk of RENAL CELL CARCINOMA  
🗑
Wegener's Granulomatosis vascular dz   c-ANCA: necrotizing Granulomatous lesions in KIDNEY and LUNG; ulcers in NASAL SEPTUM  
🗑
Serum sickness   generalized deposition of immune complexes (TYPE III HYPERSENSITIVITY); more rare now d/t less frequent use of animal serum  
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Details about Cardiac Tamponade   fluid in pericardial sac (mc d/t neoplasms, pericarditis, uremia); Ventricular filling is limited & CO is low; Tx = Pericardiocentesis  
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Pericarditis   d/t idiopathic or Coxsackie A or B; JVD, inc Jugular venous pressure w/inspiration (Kussmaul's Sign); Pericardial Friction Rub, Distant heart sounds; ST ELEVATION; can lead to constrictive pericarditis  
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Differences btw ST elevation in MI and Pericarditis   in MI, the ST elevation is followed by a depression of the ST segment and QRS changes  
🗑
Shock   a metabolic state where O2 delivery doesn't match O2 demand; tachycardia, hypotension, oliguria, mental changes, weak pulses, cool extremities  
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Autoregulation of heart is altered to meet demands of tissues via   Nitric oxide and Adenosine  
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Cardiogenic shock   d/t pump failure; arrhythmias, HF, intracardiac obstruction or MI  
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Hypovolemic shock   d/t volume loss; blood, E-lyte, fluid or plasma loss; burns, severe vomiting or diarrhea  
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Obstructive shock   extracardiac obstruction of blood flow; d/t aortic dissection, cardiac tamponade, pulmonary embolism  
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Septic shock   d/t inc venous capacitance; from G(-) endotoxemia, direct toxic injury or DIC; a/w Vasodilation, Hypotension, and WARM EXTREMITIES  
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Neurogenic shock   d/t massive peripheral vasodilation; from severe cerebral, brain stem or spinal cord injury  
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Clinical Manifestations of Shock   acute tubular necrosis, necrosis of brain, fatty change in liver/heart, patchy hemorrhages in colon, pulmonary edema  
🗑
CV Manifestations of DM   large vessel ATHEROSCLEROSIS, MIs, CAD, Restrictive cardiomyopathy; Transposition of great arteries in fetus  
🗑
Hyperthyroidism effects on CV System   Palpitations, Systolic HTN, Fatigue, Sinus Tachycardia  
🗑
Hypothyroidism effects on CV System   Decreased CO, HR, BP, pulse pressure; Cardiomegaly, Bradycardia  
🗑
Kwashiorkor effects on CV System   Thin, pale, flabby heart; Low Cardiac Output and low Systolic Pressure  
🗑
Malignant Carcinoid effects on CV System   Right-sided heart lesions; Coronary artery spasm (angina)  
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Obesity effects on CV System   Inc total blood volume; Inc Cardiac Output; HTN; CAD, Cardiac Hypertrophy  
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Pheochromocytoma effects on CV System   HTN, myocardial necrosis, LV hypertrophy  
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Rheumatoid Athritis effects on CV Stystem   Pericarditis, Coronary Arteritis  
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SLE effects on CV Systems   Pericarditis, Libman-Sacks endocarditis, Anti-phospholipid syndrome  
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Thiamine Deficiency effects on CV System   High output cardiac failure; Tachycardia, S3, Systolic Murmur  
🗑
leukocytoclastic angiitis   hypersensitivity vasculitis w/fragmented neutrophils; PCN may be an antigenic trigger  
🗑
acebutolol and pindolol   not recommended in angina patients b/c they can exacerbate sx; these have intrinsic sympathomimetic properties  
🗑
beta-blockers in general   are the only drugs that are proven to prolong a pt's life w/ coronary dz and are a first line agent in chronic angina (except acebutolol and pindolol)  
🗑
Treatment of atrial fibrillation and flutter   digoxin  
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Treatment of supraventricular tachycardias   adenosine, amiodarone, disopyramide, quinidine  
🗑
thiazide diuretics decrease the excretion of Ca   indapamide, hydrochlorothiazide, metolazone (can treat edema and hypertension)  
🗑
congenital arteriovenous fistulas in limbs   pathognomonic = increased O2 content; warmth, swelling  
🗑
Symptoms of complete heart block   HR around 40bpm b/c ventricles are controlling rhythm; pulse pressure is high (normal is 30-50); elevated stroke volume causes a larger rise and fall in pressure btw systole and diastole  
🗑
Marfan's syndrome   fibrillin mutation  
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Amlopidine   CCB; used to treat mild/moderate HTN and angina  
🗑
Terazosin   alpha-1 adrenergic receptor blocking agent; used to treat HTN and BPH  
🗑
Enalapril   ACE-i; used to treat HTN and CHF  
🗑
Propranolol   non-selective b-1 (neg inotropic/neg chronotropic) and b-2 (bronchoconstriction) receptor blocker; used to treat HTN  
🗑
Cardiac defect most commonly a/w Down Syndrome   endocardial cushion defect (MR, duodenal atresia "double bubble," simian crease)  
🗑
22q11 cardiac defects   truncus arteriosus, tetralogy of fallot  
🗑
congenital rubella cardiac defects   Septal defects, PDA  
🗑
Infantile coarctation of the aorta   aortic stenosis proximal to insertion of ductus arteriosus (preductal); check for weak or absent femoral pulses  
🗑
Adult type coarctation of the aorta   stenosis DISTAL to ductus arteriosus (postductal); a/w notching of ribs, HTN in upper extremities and weak pulses in lower extremities;  
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Right to left shunts (early cyanosis) = "Blue Baby" syndrome   3 Ts = Tetralogy, Transposition, Truncus; children may squat to increase venous return  
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Left to right shunts (late cyanosis) = "Blue Kids"   VSD (mc congenital cardiac anomaly) > ASD (loud S1, fixed split S2) > PDA (close w/indomethacin); Inc pulmonary resistance d/t arteriolar thickening, progressive pulmonary HTN can reverse shunt (Eisenmenger's)  
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Common congenital malformations   heart defects, hypospadias, cleft lip (w/ or w/o palate), congenital hip dislocation, spina bifida, anencephaly, pyloric stenosis w/projectile vomiting  
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Carotid Sheath Structures   VAN = Internal jugular VEIN (lateral), Common carotid ARTERY (medial), VAGUS nerve (posterior)  
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Recurrent laryngeal nerve supplies all intrinsic muscles of larynx except:   cricothyroid; it is a branch of CNX  
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The left recurrent laryngeal nerve wraps around the:   arch of the aorta and ligamentum arteriosum; damage results in hoarseness (complication of thyroid surgery)  
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The right recurrent laryngeal nerve wraps around the:   right subclavian artery; damage results in hoarseness (complication of thyroid surgery)  
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