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MARYVILLE NURS 620 ADVANCED PATHOPHYSIOLOGY EXAM 3 2026/2027 | Complete Solution | A+ Certified | DNP Program | Pass Guaranteed - A+ Graded

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Pass the Maryville NURS 620 Advanced Pathophysiology Exam 3 on your first attempt with this latest 2026/2027 complete solution that is A+ certified. This A+ Graded resource contains complete exam questions and verified solutions covering all key advanced pathophysiology content areas for Exam 3 including **cardiovascular disorders (hypertension pathophysiology: essential/primary hypertension, secondary causes, vascular remodeling, endothelial dysfunction; atherosclerosis pathophysiology: plaque formation, foam cells, fatty streak, fibrous cap, vulnerable plaque, inflammatory mechanisms; coronary artery disease: chronic stable angina vs acute coronary syndrome (unstable angina, NSTEMI, STEMI); myocardial infarction pathophysiology: myocardial stunning, hibernation, remodeling, complications (papillary muscle rupture, ventricular septal defect, free wall rupture, pericarditis, Dressler syndrome); heart failure pathophysiology: left vs right, systolic vs diastolic heart failure, reduced vs preserved ejection fraction (HFrEF vs HFpEF), Frank-Starling mechanism, neurohormonal activation (RAAS, SNS), natriuretic peptides (BNP, NT-proBNP); valvular heart disease: aortic stenosis pathophysiology (calcific, bicuspid valve, rheumatic), aortic regurgitation, mitral stenosis (rheumatic heart disease), mitral regurgitation (myxomatous degeneration, prolapse, chordae rupture), mitral valve prolapse pathophysiology; endocarditis: infective vs non-bacterial thrombotic, vegetation formation; cardiomyopathies: dilated, hypertrophic, restrictive pathophysiology; pericardial disorders: pericarditis, pericardial effusion, cardiac tamponade pathophysiology (Beck's triad, pulsus paradoxus); dysrhythmias pathophysiology: bradyarrhythmias (sinus bradycardia, heart blocks: first-degree, second-degree type I/Mobitz I/Wenckebach, second-degree type II/Mobitz II, third-degree/complete heart block), tachyarrhythmias (supraventricular: atrial fibrillation, atrial flutter, AV nodal reentrant tachycardia, AV reentrant tachycardia/Wolff-Parkinson-White syndrome; ventricular: premature ventricular complexes, ventricular tachycardia, ventricular fibrillation, torsade de pointes); long QT syndrome pathophysiology; shock pathophysiology: hypovolemic, cardiogenic, distributive (septic, anaphylactic, neurogenic), obstructive shock; vascular disorders: abdominal aortic aneurysm pathophysiology, thoracic aortic aneurysm, aortic dissection (Stanford type A vs B, DeBakey classification), peripheral artery disease, chronic venous insufficiency, and deep vein thrombosis pathophysiology (Virchow's triad)), **respiratory disorders (obstructive lung diseases: COPD pathophysiology: chronic bronchitis (mucus hypersecretion, goblet cell hyperplasia, ciliary dysfunction) vs emphysema (alveolar destruction, loss of elastic recoil, alpha-1 antitrypsin deficiency); asthma pathophysiology: chronic airway inflammation, airway hyperresponsiveness, bronchoconstriction, eosinophilic inflammation, mast cell activation, Th2-mediated immune response; acute exacerbation triggers; restrictive lung diseases: interstitial lung disease (idiopathic pulmonary fibrosis, sarcoidosis, hypersensitivity pneumonitis), pulmonary fibrosis pathophysiology; pneumonia pathophysiology: community-acquired, hospital-acquired, ventilator-associated, aspiration pneumonia; pulmonary embolism pathophysiology: deep vein thrombosis, fat embolism, air embolism, amniotic fluid embolism; acute respiratory distress syndrome (ARDS) pathophysiology: exudative, proliferative, fibrotic phases, diffuse alveolar damage, hyaline membranes, surfactant dysfunction; pulmonary hypertension pathophysiology (Group 1 pulmonary arterial hypertension, Group 2 left heart disease, Group 3 lung disease/hypoxia, Group 4 chronic thromboembolic, Group 5 multifactorial); respiratory failure pathophysiology: hypoxemic (Type I) vs hypercapnic (Type II), ventilation-perfusion mismatch, shunt, diffusion limitation; tuberculosis pathophysiology: primary vs reactivation, Ghon focus, Ghon complex, cavitation, miliary TB, and lung cancer pathophysiology: small cell vs non-small cell (adenocarcinoma, squamous cell, large cell)), and **hematologic disorders (anemias pathophysiology: microcytic iron deficiency anemia (hepcidin, ferroportin), anemia of chronic disease, thalassemia (alpha vs beta), sideroblastic anemia; macrocytic megaloblastic anemia (B12 deficiency pernicious anemia, folate deficiency), normocytic anemia (hemolytic anemia: autoimmune, hereditary spherocytosis, G6PD deficiency, sickle cell disease (HbS polymerization, vaso-occlusion); aplastic anemia pathophysiology; polycythemias: primary polycythemia vera (JAK2 mutation) vs secondary polycythemia; thrombocytopenia pathophysiology: immune thrombocytopenic purpura (ITP), thrombotic thrombocytopenic purpura (TTP, ADAMTS13 deficiency), heparin-induced thrombocytopenia (HIT type II); platelet disorders (Bernard-Soulier, Glanzmann thrombasthenia); coagulopathies: hemophilia A (factor VIII deficiency), hemophilia B (factor IX deficiency), von Willebrand disease, disseminated intravascular coagulation (DIC) pathophysiology; hypercoagulable states: factor V Leiden, prothrombin gene mutation, antiphospholipid syndrome; leukemia pathophysiology: acute myeloid leukemia (AML), acute lymphoblastic leukemia (ALL), chronic myeloid leukemia (CML, Philadelphia chromosome BCR-ABL), chronic lymphocytic leukemia (CLL); lymphoma: Hodgkin lymphoma (Reed-Sternberg cells) vs non-Hodgkin lymphoma; multiple myeloma pathophysiology (plasma cell dyscrasia, M protein, CRAB criteria: hypercalcemia, renal failure, anemia, bone lesions); and myelodysplastic syndromes). Each answer includes clear rationales to reinforce advanced pathophysiologic reasoning at the DNP level. Perfect for DNP students preparing for NURS 620 Exam 3. With our Pass Guarantee, you can confidently prepare for your Advanced Pathophysiology exam. Download your complete Maryville NURS 620 Exam 3 complete solution A+ certified guide instantly!

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MARYVILLE NURS 620 ADVANCED
PATHOPHYSIOLOGY EXAM 3 2026/2027 | Complete
Solution | A+ Certified | DNP Program | Pass
Guaranteed - A+ Graded

Section 1: Cardiovascular Pathophysiology - Heart Failure, Valvular Disease &
CAD (Q1-18)

Q1. A 72-year-old female with long-standing hypertension presents with exertional
dyspnea, fatigue, and bilateral pulmonary crackles. Echocardiography reveals an
ejection fraction of 58% and markedly elevated left ventricular end-diastolic pressure
with abnormal tissue Doppler imaging. This presentation is most consistent with:

A. Heart failure with reduced ejection fraction (HFrEF)
B. Heart failure with preserved ejection fraction (HFpEF)
C. Dilated cardiomyopathy
D. Hypertrophic obstructive cardiomyopathy

Correct Answer: B. Heart failure with preserved ejection fraction (HFpEF) [CORRECT]

Rationale: HFpEF is characterized by preserved systolic function (EF ≥50%) with
impaired diastolic filling and elevated filling pressures, commonly associated with
chronic hypertension and ventricular stiffness. HFrEF (A) requires reduced EF, dilated
cardiomyopathy (C) presents with systolic dysfunction and chamber dilation, and
HOCM (D) causes dynamic outflow obstruction.




Q2. In HFrEF, sustained activation of the renin-angiotensin-aldosterone system
(RAAS) produces which pathophysiologic consequence that perpetuates cardiac
remodeling?

A. Vasodilation and natriuresis
B. Vasoconstriction, sodium retention, and myocardial fibrosis
C. Decreased sympathetic nervous system activity
D. Increased nitric oxide bioavailability

,Correct Answer: B. Vasoconstriction, sodium retention, and myocardial fibrosis
[CORRECT]

Rationale: RAAS activation in HFrEF promotes maladaptive vasoconstriction, volume
overload, and collagen deposition, worsening afterload and ventricular stiffness.
Options A, C, and D describe compensatory or therapeutic mechanisms, not the
pathophysiologic consequences of RAAS overactivity.




Q3. A 68-year-old male with HFpEF is hospitalized with acute decompensation. The
primary hemodynamic defect in this condition is:

A. Reduced contractility and increased ventricular volumes
B. Impaired ventricular relaxation and increased passive stiffness
C. Severe mitral regurgitation with volume overload
D. High-output circulatory state

Correct Answer: B. Impaired ventricular relaxation and increased passive stiffness
[CORRECT]

Rationale: HFpEF is fundamentally a disorder of diastolic dysfunction where the
ventricle cannot relax or fill properly during diastole due to increased passive
stiffness. Reduced contractility (A) defines HFrEF, severe mitral regurgitation (C) is a
separate valvular problem, and high-output states (D) are unrelated.




Q4. A 75-year-old male reports syncope with exertion, angina, and progressive
dyspnea. Physical examination reveals a harsh crescendo-decrescendo systolic
murmur at the right upper sternal border radiating to the carotids. The underlying
pathophysiology involves:

A. Volume overload with eccentric left ventricular hypertrophy
B. Pressure overload with concentric left ventricular hypertrophy
C. Left ventricular dilation and reduced wall thickness
D. Right ventricular pressure overload from pulmonary hypertension

,Correct Answer: B. Pressure overload with concentric left ventricular hypertrophy
[CORRECT]

Rationale: Aortic stenosis creates a fixed outflow obstruction, generating pressure
overload that stimulates concentric LV hypertrophy to maintain wall stress. Volume
overload (A) occurs in regurgitant lesions, LV dilation (C) occurs in dilated
cardiomyopathy, and RV pressure overload (D) occurs in pulmonary hypertension.




Q5. A patient with chronic aortic regurgitation develops bounding pulses, a wide
pulse pressure, and Austin Flint murmur. The left ventricle undergoes:

A. Concentric hypertrophy without dilation
B. Eccentric hypertrophy with chamber dilation to accommodate regurgitant volume
C. Apical ballooning and akinesis
D. Right ventricular hypertrophy from pulmonary congestion

Correct Answer: B. Eccentric hypertrophy with chamber dilation to accommodate
regurgitant volume [CORRECT]

Rationale: Chronic volume overload from aortic regurgitation triggers eccentric
hypertrophy—sarcomeres added in series—producing a dilated, compliant ventricle
that handles increased preload. Concentric hypertrophy (A) responds to pressure
overload, apical ballooning (C) describes Takotsubo cardiomyopathy, and RV
hypertrophy (D) is not the primary adaptation.




Q6. A 45-year-old immigrant from Southeast Asia presents with dyspnea on exertion
and orthopnea. Echocardiography shows thickened, immobile mitral valve leaflets
with a "hockey stick" appearance of the anterior leaflet and a mitral valve area of 1.2
cm². The most likely etiology is:

A. Degenerative calcific mitral stenosis
B. Rheumatic heart disease
C. Mitral valve prolapse with chordal rupture
D. Infective endocarditis

, Correct Answer: B. Rheumatic heart disease [CORRECT]

Rationale: The commissural fusion, leaflet thickening, and hockey-stick deformity are
pathognomonic for rheumatic mitral stenosis, still prevalent in developing regions.
Degenerative calcification (A) typically affects the annulus in elderly patients, chordal
rupture (C) causes regurgitation, and endocarditis (D) produces vegetations and
regurgitation.




Q7. In severe mitral regurgitation, the left atrium and left ventricle dilate because:

A. Systolic ejection of blood into the aorta is obstructed
B. A portion of left ventricular stroke volume regurgitates into the low-pressure left
atrium during systole
C. Diastolic filling from the pulmonary veins is obstructed
D. Right ventricular output exceeds left ventricular output

Correct Answer: B. A portion of left ventricular stroke volume regurgitates into the
low-pressure left atrium during systole [CORRECT]

Rationale: In mitral regurgitation, the LV ejects blood retrograde into the compliant
LA during systole, creating volume overload that progressively dilates both
chambers. Obstruction (A, C) describes stenotic lesions, and RV output exceeding LV
output (D) is physiologically incorrect.




Q8. A 28-year-old female with a mid-systolic click and late systolic murmur that
worsens with Valsalva maneuver is diagnosed with mitral valve prolapse. The primary
structural abnormality is:

A. Commissural fusion and chordal shortening
B. Myxomatous degeneration with thickened, redundant valve leaflets
C. Bicuspid aortic valve with calcification
D. Papillary muscle rupture from ischemia

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