B Pharmacy Sem 4: Pathophysiology
Subject 5. Pathophysiology
1. Cell Injury, Adaptation & Death (Hypoxia, Free Radicals, Apoptosis)
2. Inflammation & Repair (Acute & Chronic; Mediators; Wound Healing)
3. Cardiovascular Disorders (Atherosclerosis, Hypertension, Heart Failure)
4. Respiratory Disorders (COPD, Asthma, Pneumonia)
5. Gastrointestinal Disorders (Peptic Ulcer, Hepatitis, IBD)
6. Renal & Hepatic Disorders (Glomerulonephritis, Cirrhosis)
7. Endocrine & Metabolic Disorders (Diabetes Mellitus, Thyroid Diseases)
Unit 1: Cell Injury, Adaptation & Death (Hypoxia, Free Radicals, Apoptosis)
A detailed exploration of how cells respond to stress and damage—covering reversible and irreversible injury, adaptive changes, mechanisms of hypoxic and oxidative damage, programmed cell death, and their implications in disease.
1.1 Definitions & Concepts
1.1.1 Cell Injury
Reversible Injury: Cellular dysfunction without structural disruption; removal of stress restores normal function.
Irreversible Injury: Structural damage beyond recovery, culminating in cell death.
1.1.2 Cellular Adaptations
Hypertrophy: Increase in cell size (e.g., cardiac myocytes in hypertension).
Hyperplasia: Increase in cell number (e.g., endometrial proliferation under estrogen).
Atrophy: Reduction in size and function (e.g., muscle wasting in disuse).
Metaplasia: Replacement of one differentiated cell type with another (e.g., Barrett’s esophagus: squamous → columnar epithelium).
1.2 Mechanisms of Hypoxic Injury
1.2.1 Definition of Hypoxia
Insufficient O₂ to meet cellular metabolic demands; common causes include ischemia, anemia, and respiratory failure.
1.2.2 Pathophysiology
ATP Depletion
Impaired oxidative phosphorylation → drop in ATP → failure of Na⁺/K⁺‐ATPase → cellular swelling.
Ion Homeostasis Disruption
Na⁺ and Ca²⁺ influx; K⁺ efflux; ER and mitochondrial swelling.
Anaerobic Glycolysis
Lactic acid accumulation → intracellular acidosis → ribosomal detachment and reduced protein synthesis.
Membrane Damage
Increased cytosolic Ca²⁺ activates phospholipases and proteases.
1.2.3 Morphological Features
Reversible: Cellular swelling, plasma membrane blebs, mitochondrial swelling.
Irreversible: Dense mitochondrial matrix, rupture of lysosomes, nuclear chromatin clumping (pyknosis), karyorrhexis, karyolysis.
1.3 Free Radical–Mediated Injury
1.3.1 Reactive Oxygen Species (ROS)
Examples: Superoxide (O₂·⁻), hydrogen peroxide (H₂O₂), hydroxyl radical (·OH).
1.3.2 Sources
Endogenous: Mitochondrial electron transport leakage, NADPH oxidases, peroxisomal fatty acid oxidation.
Exogenous: Ionizing radiation, xenobiotics (e.g., CCl₄ metabolism), inflammation (neutrophil respiratory burst).
1.3.3 Mechanisms of Damage
Lipid Peroxidation of membranes → loss of integrity.
Protein Oxidation → enzyme inactivation, structural protein damage.
DNA Damage → strand breaks, base modifications, mutagenesis.
1.3.4 Antioxidant Defenses
Enzymatic: Superoxide dismutase (SOD), catalase, glutathione peroxidase.
Non‑Enzymatic: Glutathione, vitamins C and E, ceruloplasmin.
1.4 Cell Death Pathways
1.4.1 Necrosis
Definition: Passive, uncontrolled cell death with inflammation.
Features: Cell swelling, plasma membrane rupture, enzymatic digestion, inflammatory response.
Patterns: Coagulative (ischemia in heart/kidney), liquefactive (brain infarcts, abscesses), caseous (tuberculosis), fat necrosis (pancreatitis), fibrinoid (immune vascular injury).
1.4.2 Apoptosis
Definition: Active, regulated “programmed” cell death without inflammation.
Morphology: Cell shrinkage, chromatin condensation, membrane blebbing, formation of apoptotic bodies, phagocytosis by macrophages.
Pathways:
Intrinsic (Mitochondrial): Stress → Bcl‑2 family regulation → cytochrome c release → caspase‑9 activation.
Extrinsic (Death Receptor): Fas/FasL or TNF receptor engagement → caspase‑8 activation.
Execution: Caspase‑3 cleaves cellular substrates (e.g., ICAD), leading to DNA fragmentation (180–200 bp ladders).
1.5 Integration in Disease
1.5.1 Hypoxic Injury in Myocardial Infarction
Prolonged ischemia → irreversible necrosis of cardiomyocytes → loss of contractile tissue.
1.5.2 Oxidative Stress in Liver Injury
CCl₄ metabolism → ·CCl₃ radicals → lipid peroxidation → centrilobular necrosis.
1.5.3 Apoptosis in Chronic Disease
Excessive apoptosis in neurodegenerative disorders (e.g., Parkinson’s).
Insufficient apoptosis in cancer leading to uncontrolled proliferation.
1.6 Key Points for Exams
Define & Differentiate: Reversible vs. irreversible injury; necrosis vs. apoptosis.
Mechanism Sketch: Draw steps of intrinsic apoptotic pathway, labeling mitochondrial events and caspases.
Clinical Correlation: Explain cellular changes in early and late myocardial ischemia.
Free Radical Defense: List enzymatic and non‑enzymatic antioxidants and their roles.
Adaptive Change: Provide one example each of hypertrophy, hyperplasia, atrophy, and metaplasia, with underlying stimulus.
Unit 2: Inflammation & Repair (Acute & Chronic; Mediators; Wound Healing)
An exhaustive exploration of the body’s response to injury—including the cellular and molecular events of acute and chronic inflammation, the principal mediators involved, and the stages and regulation of tissue repair and wound healing.
2.1 Inflammation: Purpose & Types
2.1.1 Definition
Inflammation: Complex tissue reaction to harmful stimuli (infection, necrosis, foreign bodies) intended to eliminate the cause, clear debris, and initiate repair.
2.1.2 Classification
| Type | Onset | Duration | Key Features |
|---|---|---|---|
| Acute | Minutes–hours | Days | Vascular changes, neutrophil influx, exudation |
| Chronic | Days–months | Months–years | Mononuclear cell infiltration, tissue destruction, fibrosis |
2.2 Acute Inflammation
2.2.1 Vascular Events
Vasoconstriction (brief) → Vasodilation (increased blood flow; heat/redness)
Increased Vascular Permeability → plasma exudation (swelling/pain)
2.2.2 Cellular Events
Leukocyte (Neutrophil) Recruitment
Margination & Rolling: Selectin‑mediated transient binding on endothelium
Adhesion: Integrin–ICAM/VCAM interactions
Transmigration (Diapedesis): PECAM‑1–mediated passage between endothelial cells
Leukocyte Activation & Phagocytosis
Recognition & Attachment: Opsonins (C3b, IgG)
Engulfment: Pseudopod formation, phagosome
Killing & Degradation:
Oxygen‑dependent: NADPH oxidase → superoxide → MPO halide system → HOCl
Oxygen‑independent: Lysozyme, major basic protein, defensins
2.2.3 Exudate Types
| Type | Protein Content | Appearance | Examples |
|---|---|---|---|
| Serous | Low | Clear, straw‑colored | Blister, pleural effusion |
| Fibrinous | High | Thick, fibrin mesh | Pericarditis |
| Purulent (Suppurative) | High (neutrophils) | Pus | Abscess, empyema |
| Hemorrhagic | High (RBCs) | Blood‑tinged | Severe vascular injury |
2.3 Mediators of Inflammation
2.3.1 Plasma‑Derived Mediators
| Mediator | Source | Function |
|---|---|---|
| Complement (C3a, C5a) | Liver (cascade activation) | Chemotaxis, vasodilation, increased permeability |
| Kinins (Bradykinin) | HMWK via kallikrein | Pain, vasodilation, permeability |
| Coagulation Factors | Liver | Thrombin generates fibrinopeptides; PAR activation |
2.3.2 Cell‑Derived Mediators
| Mediator | Source | Function |
|---|---|---|
| Histamine | Mast cells, basophils, platelets | Vasodilation, permeability |
| Prostaglandins (PGI₂, PGE₂) | Leukocytes, endothelium | Vasodilation, pain, fever |
| Leukotrienes (LTB₄, LTC₄) | Leukocytes | Chemotaxis (LTB₄), bronchospasm (LTC₄) |
| Platelet‑activating factor (PAF) | Many cells | Vasodilation, permeability, leukocyte activation |
| Cytokines (TNF, IL‑1, IL‑6) | Macrophages, endothelial | Fever, adhesion molecule upregulation, acute phase proteins |
| Reactive Oxygen Species (ROS) | Neutrophils, macrophages | Microbial killing, tissue injury |
| Nitric Oxide (NO) | Endothelium, macrophages | Vasodilation, microbial killing |
2.4 Chronic Inflammation
2.4.1 Cellular Infiltrate & Features
Mononuclear Cells: Macrophages, lymphocytes, plasma cells
Tissue Destruction: Persistent injury by cytokines and enzymes
Repair: Simultaneous angiogenesis and fibrosis
2.4.2 Granulomatous Inflammation
Definition: Aggregates of activated macrophages (epithelioid cells) often with multinucleated giant cells.
Etiologies: Mycobacterium tuberculosis, schistosomiasis, sarcoidosis.
Morphology: Central caseation (tuberculous) vs. non‑caseating (sarcoid).
2.5 Tissue Repair & Wound Healing
2.5.1 Regeneration vs. Repair
Regeneration: Restoration of normal architecture by proliferation of residual cells and stem cells (e.g., liver).
Repair (Scar Formation): Replacement with connective tissue when regeneration impossible.
2.5.2 Phases of Wound Healing
Hemostasis & Inflammation (Days 0–3)
Vasoconstriction, platelet plug, clot formation releasing PDGF, TGF‑β
Neutrophils → macrophages clear debris
Proliferative Phase (Days 3–14)
Angiogenesis: VEGF‑driven new capillaries
Fibroplasia & ECM Deposition: TGF‑β stimulates collagen (Type III) and proteoglycan synthesis
Re‑epithelialization: Keratinocyte migration over granulation tissue
Maturation & Remodeling (Weeks 2–months)
Collagen Remodeling: Type III replaced by stronger Type I collagen; crosslinking increases tensile strength
Scar Maturation: Decreased vascularity, myofibroblast‑mediated wound contraction
2.5.3 Factors Influencing Healing
Local: Infection, ischemia, mechanical stress
Systemic: Nutrition (vitamin C, protein), diabetes, corticosteroids, age
2.6 Clinical Correlations
2.6.1 Chronic Ulcer Formation
Defective proliferation or excessive protease activity impedes granulation → non‑healing ulcers.
2.6.2 Fibrosis in Chronic Disease
Liver cirrhosis: Chronic hepatitis → stellate cell activation → excess ECM → nodular architecture.
2.6.3 Therapeutic Modulation
NSAIDs: Inhibit COX → reduce prostaglandin‑mediated pain and swelling but may impair mucosal healing.
Anti‑TNF Agents: Block chronic inflammation in rheumatoid arthritis and inflammatory bowel disease.
2.7 Key Points for Exams
Outline Steps: Neutrophil recruitment cascade with adhesion molecules and chemokines.
Compare: Serous vs. fibrinous exudates—composition and examples.
Draw: Granuloma structure labeling epithelioid cells and giant cells.
Phases Sketch: Timeline of wound healing showing key cellular events.
Mediator Roles: Match five mediators (e.g., bradykinin, LTB₄, histamine) to their functions.
Unit 3: Cardiovascular Disorders (Atherosclerosis, Hypertension & Heart Failure)
An in-depth exploration of major cardiovascular pathologies—detailing their definitions, etiologies, pathogenesis, clinical features, complications, and therapeutic implications.
3.1 Atherosclerosis
3.1.1 Definition & Clinical Significance
Atherosclerosis: Chronic inflammatory disease of medium- and large-sized arteries characterized by intimal lipid accumulation, fibrous cap formation, and plaque development.
Consequences: Myocardial infarction, stroke, peripheral arterial disease, aneurysm.
3.1.2 Risk Factors
Non-modifiable: Age, male sex (until menopause), family history/genetics (e.g., familial hypercholesterolemia).
Modifiable:
Lipid Abnormalities: ↑ LDL-cholesterol, ↓ HDL-cholesterol.
Hypertension: Endothelial injury from high shear stress.
Smoking: Oxidative endothelial damage.
Diabetes Mellitus: Glycation of proteins, dyslipidemia.
Obesity & Sedentary Lifestyle: Pro-inflammatory adipokines.
3.1.3 Pathogenesis (Response-to-Injury Hypothesis)
Endothelial Dysfunction
Triggered by hypertension, hyperlipidemia, smoking → ↑ permeability, leukocyte adhesion molecule expression (VCAM-1, ICAM-1).
Lipoprotein Entry & Modification
LDL infiltrates intima, becomes oxidized (oxLDL) by ROS → chemotactic for monocytes.
Monocyte Recruitment & Differentiation
Monocytes adhere, transmigrate → macrophages expressing scavenger receptors ingest oxLDL → foam cells.
Fatty Streak Formation
Aggregates of foam cells visible even in adolescence; reversible at this stage.
Smooth Muscle Cell (SMC) Migration & Proliferation
SMCs from media migrate to intima under PDGF and TGF-β influence, secrete extracellular matrix (collagen, proteoglycans) to form fibrous cap.
Plaque Progression & Complications
Necrotic lipid core, calcification, neovascularization.
Plaque Rupture or Erosion → thrombosis → acute vessel occlusion.
Aneurysm Formation: Destruction of media in the aorta.
3.1.4 Clinical Manifestations
Coronary Artery Disease: Angina pectoris, myocardial infarction.
Cerebrovascular Disease: Transient ischemic attacks, stroke.
Peripheral Arterial Disease: Claudication, non-healing ulcers.
Aortic Aneurysm/Dissection: Pulsatile abdominal mass, sudden chest pain.
3.2 Hypertension
3.2.1 Definition & Classification
Hypertension: Sustained elevation of arterial blood pressure ≥ 140/90 mm Hg (ESC/ESH now defines ≥ 140/90; ACC/AHA ≥ 130/80).
Types:
Primary (Essential): ~95% of cases; multifactorial (genetic, environmental).
Secondary: Renal disease, endocrine causes (pheochromocytoma, Cushing’s), coarctation of the aorta, medications.
3.2.2 Pathophysiology
Cardiac Output (CO) × Systemic Vascular Resistance (SVR) determines BP.
Essential Hypertension Mechanisms:
Renin–Angiotensin–Aldosterone System (RAAS) Overactivity → vasoconstriction, sodium retention.
Sympathetic Nervous System (SNS) Hyperactivity → increased heart rate and vasoconstriction.
Endothelial Dysfunction: ↓ nitric oxide, ↑ endothelin.
Salt Sensitivity & Volume Expansion: Genetic predisposition to sodium retention.
3.2.3 Target Organ Damage (“Hypertensive End-Organ Damage”)
Heart: Left ventricular hypertrophy (LVH), ischemic heart disease, heart failure.
Brain: Stroke, hypertensive encephalopathy.
Kidneys: Hypertensive nephrosclerosis → chronic kidney disease.
Eyes: Hypertensive retinopathy (arteriolar narrowing, “cotton-wool” spots).
Vessels: Accelerated atherosclerosis, aneurysm risk.
3.2.4 Clinical Presentation & Diagnosis
Often Asymptomatic (“Silent Killer”) identified on routine BP measurement.
Symptoms: Headache, dizziness, visual disturbances in severe cases.
Work-up:
Multiple readings, ambulatory BP monitoring.
Laboratory: Serum creatinine, electrolytes, fasting glucose, lipid profile.
ECG/Echocardiography: LVH, diastolic dysfunction.
Urinalysis: Proteinuria.
3.2.5 Management Principles
Lifestyle: Weight loss, dietary sodium restriction (< 2.3 g/day), DASH diet, exercise, alcohol moderation.
Pharmacotherapy (individualized):
Thiazide Diuretics (e.g., hydrochlorothiazide)
ACE Inhibitors (e.g., enalapril) or ARBs (e.g., losartan)
Calcium Channel Blockers (e.g., amlodipine)
Beta-Blockers (e.g., metoprolol)
Mineralocorticoid Receptor Antagonists (e.g., spironolactone) in resistant cases.
3.3 Heart Failure
3.3.1 Definition & Classification
Heart Failure (HF): Syndrome in which the heart cannot pump blood at a rate commensurate with metabolic demands or can do so only with elevated filling pressures.
Types:
HFrEF (reduced EF ≤ 40%; “systolic HF”)
HFpEF (preserved EF ≥ 50%; “diastolic HF”)
Acute vs. Chronic; Left, Right, or Biventricular.
3.3.2 Etiologies
Ischemic Heart Disease (most common)
Hypertension
Valvular Disease (e.g., aortic stenosis)
Cardiomyopathies (dilated, hypertrophic)
Myocarditis, toxins (alcohol, chemotherapy), arrhythmias.
3.3.3 Pathophysiology & Compensatory Mechanisms
Reduced Cardiac Output → tissue hypoperfusion.
Neurohormonal Activation: SNS ↑, RAAS ↑, vasopressin ↑ → initial compensation but maladaptive long-term.
Ventricular Remodeling: Myocyte hypertrophy, fibrosis, chamber dilation or stiffening.
Congestion:
Left HF → pulmonary edema, dyspnea, orthopnea.
Right HF → systemic venous congestion, hepatomegaly, peripheral edema, ascites.
3.3.4 Clinical Features & Diagnosis
Symptoms: Exertional dyspnea, orthopnea, paroxysmal nocturnal dyspnea, fatigue.
Signs: Elevated JVP, crackles, S3 gallop, peripheral edema, hepatomegaly.
Investigations:
Echocardiography: EF assessment, chamber size, wall motion, diastolic function.
BNP/NT-proBNP: Biomarkers elevated with increased cardiac wall stress.
Chest X-ray: Cardiomegaly, pulmonary congestion.
3.3.5 Management Strategies
General Measures: Sodium restriction, fluid management, weight monitoring, exercise.
Pharmacotherapy:
ACE Inhibitors/ARBs
Beta-Blockers (bisoprolol, carvedilol)
Mineralocorticoid Receptor Antagonists
Diuretics (loop diuretics for congestion)
ARNI (sacubitril/valsartan) in HFrEF
Device Therapy: ICD for sudden death prevention; CRT for dyssynchrony.
Advanced: Heart transplantation, LV assist devices.
3.4 Key Points for Exams
Atherosclerosis Pathway: Illustrate foam-cell formation and fibrous cap development, naming key mediators (PDGF, TGF-β).
Hypertension Classification: Differentiate primary vs. secondary causes, and list three systemic complications.
HF Mechanisms: Contrast HFrEF vs. HFpEF pathophysiology and hemodynamics.
Clinical Correlation: Describe orthopnea mechanism in left-sided HF.
Therapeutic Rationale: Explain how ACE inhibitors improve remodeling in HFrEF.
Unit 4: Respiratory Disorders (COPD, Asthma & Pneumonia)
A thorough examination of prevalent respiratory pathologies—detailing definitions, etiologies, pathophysiologic mechanisms, clinical manifestations, complications, and therapeutic strategies.
4.1 Chronic Obstructive Pulmonary Disease (COPD)
4.1.1 Definition & Clinical Significance
COPD: Progressive airflow limitation that is not fully reversible, associated with abnormal inflammatory response to noxious particles or gases.
Components: Chronic bronchitis (airway inflammation) and emphysema (alveolar wall destruction).
Global Impact: 3rd leading cause of death worldwide.
4.1.2 Risk Factors
Smoking: Primary cause (> 80% of cases).
Environmental Exposures: Biomass fuel, occupational dusts/chemicals.
Genetic: α₁‑Antitrypsin deficiency (panacinar emphysema in non‑smokers).
4.1.3 Pathogenesis
Chronic Inflammation
Infiltration by neutrophils, macrophages, CD8⁺ T‑cells → release of proteases and ROS.
Protease–Antiprotease Imbalance
Excess elastase activity → alveolar septal destruction (emphysema).
Oxidative Stress
Cigarette smoke and activated inflammatory cells generate ROS → tissue injury.
Airflow Limitation
Small airway remodeling: fibrosis, mucous gland hyperplasia → increased resistance.
4.1.4 Clinical Features
Symptoms:
Chronic productive cough (≥ 3 months in ≥ 2 consecutive years).
Dyspnea on exertion progressing to at rest.
Examination:
Barrel chest, prolonged expiration, wheezes/crackles.
Hyperresonance on percussion (emphysema).
Spirometry:
Post‑bronchodilator FEV₁/FVC < 0.70 confirms airflow obstruction.
GOLD staging based on FEV₁ % predicted.
4.1.5 Complications & Acute Exacerbations
Exacerbations: Often triggered by infections (viral/bacterial) or pollutants—worsening dyspnea, sputum change, hypoxia.
Cor Pulmonale: Right‑heart failure secondary to pulmonary hypertension.
Respiratory Failure: Type II (hypercapnic) in late-stage disease.
4.1.6 Management
| Intervention | Mechanism | Examples |
|---|---|---|
| Smoking Cessation | Halts progression | Behavioral therapy, NRT, varenicline |
| Bronchodilators | ↓ Airway smooth muscle tone | Short/long‑acting β₂‑agonists; anticholinergics (ipratropium, tiotropium) |
| Inhaled Corticosteroids | ↓ Airway inflammation | Fluticasone, budesonide (in severe COPD) |
| Phosphodiesterase‑4 Inhibitors | ↓ Inflammation | Roflumilast (severe chronic bronchitis) |
| Oxygen Therapy | Corrects hypoxemia; improves survival | Long‑term O₂ if PaO₂ < 55 mm Hg |
| Rehabilitation & Vaccines | Improves exercise capacity; prevents infections | Influenza, pneumococcal vaccines |
4.2 Asthma
4.2.1 Definition & Epidemiology
Asthma: Chronic inflammatory disorder of airways with variable airflow obstruction and bronchial hyperresponsiveness.
Prevalence: Affects ~300 million globally; often begins in childhood but can occur at any age.
4.2.2 Pathophysiology
Airway Inflammation
Eosinophils, mast cells, Th₂ lymphocytes → release of cytokines (IL‑4, IL‑5, IL‑13).
Airway Hyperresponsiveness
Exaggerated bronchoconstrictive response to stimuli (allergens, exercise, cold air).
Remodeling
Chronic changes: subepithelial fibrosis, smooth muscle hypertrophy, goblet cell hyperplasia.
4.2.3 Clinical Features
Symptoms: Episodic wheezing, chest tightness, cough (often nocturnal), dyspnea.
Triggers: Allergens (dust mites, pollen), exercise, cold air, NSAIDs, infections.
Spirometry:
↑ Variability in FEV₁ (> 12% and 200 mL improvement after bronchodilator).
Peak Expiratory Flow (PEF): Diurnal variability > 20%.
4.2.4 Severity Classification
| Severity | Symptoms | FEV₁ or PEF | Treatment Step |
|---|---|---|---|
| Intermittent | ≤ 2 days/week | Normal between attacks | Step 1: PRN SABA |
| Mild Persistent | > 2 days/week but not daily | FEV₁ ≥ 80% predicted | Step 2: Low‑dose ICS |
| Moderate Persistent | Daily | FEV₁ 60–80% predicted | Step 3: Low‑dose ICS + LABA or medium ICS |
| Severe Persistent | Throughout day | FEV₁ < 60% predicted | Step 4/5: Medium/high‑dose ICS + LABA ± add‑on (LAMA, biologics) |
4.2.5 Management
Relievers:
Short‑acting β₂‑agonists (SABA: albuterol) for acute symptoms
Controllers:
Inhaled corticosteroids (ICS) mainstay
Long‑acting β₂‑agonists (LABA) in combination with ICS
Leukotriene receptor antagonists (montelukast)
Biologics for severe asthma: anti‑IgE (omalizumab), anti‑IL‑5 (mepolizumab), anti‑IL‑4Rα (dupilumab)
Non‑pharmacologic: Trigger avoidance, allergen immunotherapy.
4.3 Pneumonia
4.3.1 Definition & Classification
Pneumonia: Infection of pulmonary parenchyma leading to alveolar inflammation and consolidation.
Types:
Community‑Acquired (CAP) vs. Hospital‑Acquired (HAP) and Ventilator‑Associated (VAP)
Typical (bacterial: Streptococcus pneumoniae) vs. Atypical (Mycoplasma, Chlamydophila, Legionella).
4.3.2 Pathogenesis
Pathogen Inhalation/Aspiration into alveoli.
Host Defense Overcome: Impaired mucociliary clearance, macrophage dysfunction.
Inflammatory Response: Neutrophil infiltration, exudate filling alveoli → impaired gas exchange.
4.3.3 Clinical Features
Symptoms: Fever, productive cough with purulent sputum, pleuritic chest pain, dyspnea.
Signs: Tachypnea, crackles, bronchial breath sounds, egophony, dullness to percussion.
4.3.4 Diagnosis & Investigations
Chest X‑ray: Lobar consolidation (typical) vs. interstitial infiltrates (atypical).
Sputum Gram Stain & Culture
Blood Cultures (in severe CAP)
PCR & Urinary Antigens: Legionella and S. pneumoniae antigen tests.
Severity Assessment: CURB‑65 score (Confusion, Urea, Respiratory rate, Blood pressure, age ≥ 65) to guide inpatient vs. outpatient management.
4.3.5 Management
| Setting | Empiric Therapy (CAP) | Duration |
|---|---|---|
| Outpatient | Amoxicillin or doxycycline or macrolide | 5–7 days |
| Inpatient (Non‑ICU) | β‑lactam + macrolide or respiratory fluoroquinolone | 7–10 days |
| ICU | β‑lactam + macrolide (or fluoroquinolone) ± MRSA coverage (vancomycin) | 7–14 days |
| HAP/VAP | Broad‑spectrum coverage guided by local antibiogram (anti‑pseudomonal β‑lactam + aminoglycoside/fluoroquinolone ± MRSA agent) | 7 days |
4.4 Key Points for Exams
COPD Pathogenesis: Explain protease–antiprotease imbalance and its role in emphysema.
Asthma Definition: Differentiate variable vs. irreversible airflow obstruction.
Spirometric Criteria: State the diagnostic thresholds for COPD and asthma reversibility.
Pneumonia Classification: Use CURB‑65 to determine management setting and empiric antibiotics.
Therapeutic Rationale: Justify the use of ICS + LABA in moderate persistent asthma.
Unit 5: Gastrointestinal Disorders (Peptic Ulcer Disease, Hepatitis & Inflammatory Bowel Disease)
An in‑depth exploration of key GI pathologies—covering definitions, etiologies, pathogenesis, clinical presentations, complications, diagnostic approaches, and therapeutic strategies.
5.1 Peptic Ulcer Disease (PUD)
5.1.1 Definition & Epidemiology
Peptic Ulcer: Break in the mucosal lining of the stomach or duodenum extending through the muscularis mucosae.
Prevalence: Affects ~10% of the population; duodenal ulcers more common than gastric.
5.1.2 Etiology & Risk Factors
Helicobacter pylori infection (~70–90% of duodenal, 50–70% of gastric ulcers)
NSAIDs: Inhibit prostaglandin synthesis → reduced mucosal protection
Acid Hypersecretion: Zollinger–Ellison syndrome (gastrinoma)
Lifestyle: Smoking, stress, alcohol
5.1.3 Pathogenesis
Mucosal Defense Disruption
↓ Mucus–bicarbonate barrier, ↓ epithelial cell restitution, ↓ mucosal blood flow.
Acid–Pepsin Injury
Gastric acid and pepsin degrade exposed tissue.
H. pylori Mechanisms
Urease production → ammonia neutralizes acid locally, cytotoxins (CagA, VacA) induce inflammation.
NSAID Mechanisms
COX‑1 inhibition → ↓ prostaglandin E₂ → impaired mucosal blood flow and repair.
5.1.4 Clinical Features
Symptoms: Epigastric burning pain—
Duodenal: Pain 2–5 h after meals; relieved by food (“pain–food–pain” pattern).
Gastric: Pain aggravated by meals; weight loss.
Alarm Signs: Melena, hematemesis, anemia, weight loss, dysphagia.
5.1.5 Complications
Bleeding: Erosion into submucosal vessels.
Perforation: Sudden severe abdominal pain; peritonitis.
Gastric Outlet Obstruction: Edema or scarring of pylorus.
5.1.6 Diagnosis
Endoscopy: Visualization & biopsy for H. pylori and malignancy exclusion.
Noninvasive H. pylori Tests: Urea breath test, stool antigen, serology.
5.1.7 Management
Eradication Therapy (for H. pylori)
PPI + clarithromycin + amoxicillin (or metronidazole) for 10–14 days
Acid Suppression
Proton‑pump inhibitors (omeprazole) or H₂‑blockers (ranitidine)
NSAID Management
Discontinue or switch to COX‑2 selective; co‑prescribe PPI or misoprostol.
5.2 Hepatitis
5.2.1 Definition & Classification
Hepatitis: Inflammation of the liver parenchyma.
Types:
Viral: A, B, C, D, E (blood‑borne vs. fecal–oral routes)
Nonviral: Alcoholic, autoimmune, drug‑induced, metabolic (e.g., NAFLD/NASH)
5.2.2 Viral Hepatitis Pathogenesis
HAV/HEV: Acute, self‑limiting; no chronic stage.
HBV/HCV/D: Can progress to chronic hepatitis, cirrhosis, hepatocellular carcinoma.
HBV: Partially double‑stranded DNA; integrates into host genome.
HCV: RNA flavivirus with high genetic variability; immune evasion leads to chronicity.
5.2.3 Clinical Features
Acute: Malaise, anorexia, nausea, RUQ discomfort, jaundice, dark urine, pale stools.
Chronic: Often asymptomatic until advanced fibrosis; fatigue, hepatomegaly, elevated transaminases.
5.2.4 Diagnostics
Serology:
HAV IgM, HBV surface antigen (HBsAg), HCV antibody + HCV RNA PCR.
Liver Function Tests: ↑ AST/ALT (viral > 1,000 U/L in acute), ↑ bilirubin, ↓ albumin in chronic.
Imaging & Biopsy: Ultrasound elastography for fibrosis; histology for staging.
5.2.5 Management
Acute Viral: Supportive; no specific antivirals for HAV/HEV.
Chronic HBV: Nucleos(t)ide analogs (entecavir, tenofovir) or interferon‑α.
Chronic HCV: Direct‑acting antivirals (sofosbuvir + velpatasvir) achieving > 95% SVR.
Nonviral:
Alcohol cessation, corticosteroids/immunosuppressants for autoimmune hepatitis, weight loss and insulin sensitizers for NASH.
5.3 Inflammatory Bowel Disease (IBD)
5.3.1 Definition & Types
IBD: Chronic, relapsing inflammatory disorders of the GI tract.
Major Forms:
Ulcerative Colitis (UC): Continuous mucosal inflammation confined to colon and rectum.
Crohn’s Disease (CD): Transmural, segmental (“skip lesions”) inflammation anywhere from mouth to anus.
5.3.2 Etiology & Pathogenesis
Genetic Susceptibility: NOD2 mutation in CD, HLA‑DRB1 in UC.
Immune Dysregulation:
CD: Th1/Th17‑mediated; ↑ IL‑12, TNF.
UC: Th2‑like response; ↑ IL‑5, IL‑13.
Microbiome Alterations: Dysbiosis with loss of protective commensals.
Barrier Dysfunction: Increased intestinal permeability leading to antigen exposure.
5.3.3 Clinical Features
| Feature | UC | CD |
|---|---|---|
| Location | Colon, rectum (continuous) | Any GI, ileocaecal common |
| Depth | Mucosa/submucosa | Transmural |
| Pattern | Continuous | Skip lesions |
| Symptoms | Bloody diarrhea, urgency | Abdominal pain, weight loss, diarrhea |
| Complications | Toxic megacolon, colorectal cancer | Fistulae, strictures, malabsorption |
5.3.4 Diagnosis
Endoscopy: Colonoscopy with biopsy—crypt abscesses in UC; granulomas in CD (not always).
Imaging: MR-enterography for small‑bowel CD.
Laboratory: ↑ CRP/ESR; fecal calprotectin correlates with inflammation.
5.3.5 Management
Induction of Remission:
UC: 5‑ASA (mesalazine), corticosteroids.
CD: Corticosteroids, budesonide (ileocaecal disease).
Maintenance:
Thiopurines (azathioprine), methotrexate.
Biologics: Anti‑TNF (infliximab), anti‑integrin (vedolizumab), anti‑IL‑12/23 (ustekinumab).
Surgery:
UC: Proctocolectomy is curative.
CD: Resection of diseased segment; not curative—high recurrence.
5.4 Key Points for Exams
PUD Pathogenesis: Contrast H. pylori‑mediated vs. NSAID‑induced ulcer mechanisms.
Hepatitis Markers: Match serologic markers (IgM, HBsAg, HCV RNA) to acute vs. chronic infection.
IBD Differentiation: List four features distinguishing UC from CD in terms of pathology and presentation.
Treatment Rationale: Explain the use of bile acid sequestrants in PUD and direct‑acting antivirals in HCV.
Complication Management: Outline the approach to toxic megacolon in UC, including initial medical and surgical considerations.
Unit 6: Renal & Hepatic Disorders (Glomerulonephritis & Cirrhosis)
An in‑depth examination of key renal and hepatic pathologies—detailing definitions, etiologies, pathogenesis, clinical manifestations, diagnostic approaches, complications, and therapeutic principles.
6.1 Glomerulonephritis
6.1.1 Definition & Classification
Glomerulonephritis (GN): Inflammatory injury of the renal glomeruli resulting in hematuria, proteinuria, and variable loss of renal function.
Classification:
Acute vs. Chronic GN
Primary (renal‐limited) vs. Secondary (systemic diseases)
Histologic patterns: Proliferative (e.g., post‑streptococcal), membranous, rapidly progressive (crescentic), IgA nephropathy.
6.1.2 Etiologies & Examples
| Type | Etiology | Example |
|---|---|---|
| Post‑infectious | Immune complex deposition after infection | Post‑streptococcal GN |
| IgA Nephropathy | Mesangial IgA immune complexes | Berger’s disease |
| Membranous | Subepithelial immune deposits | Primary phospholipase A₂ receptor antibody |
| Rapidly Progressive | Pauci‑immune (ANCA), anti‑GBM, immune complex | Goodpasture’s syndrome (anti‑GBM) |
| Secondary | SLE, vasculitis, diabetic nephropathy | Lupus nephritis |
6.1.3 Pathogenesis
Immune Complex–Mediated Injury
Circulating complexes or in situ antigen–antibody binding → complement activation (C5a) → neutrophil recruitment.
Cell‑Mediated Injury
ANCA‑associated vasculitis: Neutrophil activation against endothelial targets.
Podocyte & GBM Damage
Membrane thickening (membranous GN), crescents from Bowman’s capsule epithelial proliferation (rapidly progressive GN).
6.1.4 Clinical Features
Acute GN:
Hematuria (cola‑colored urine), oliguria, hypertension, mild proteinuria (< 3.5 g/day).
Edema (periorbital) from salt retention.
Nephrotic Syndrome (when heavy proteinuria) overlaps:
Proteinuria > 3.5 g/day, hypoalbuminemia, generalized edema, hyperlipidemia.
6.1.5 Diagnosis
Urinalysis: RBC casts, proteinuria quantification.
Serology:
Complement levels (↓ C3 in immune complex GN).
ANA, anti‑dsDNA (lupus); ANCA; anti‑GBM.
Renal Biopsy: Light microscopy, immunofluorescence (granular vs. linear deposits), electron microscopy (sub‑epithelial “humps” in post‑streptococcal).
6.1.6 Management
Supportive: Salt restriction, diuretics for edema, blood pressure control (ACE inhibitors to reduce proteinuria).
Immunosuppression:
Corticosteroids ± cyclophosphamide in rapidly progressive GN.
Mycophenolate or rituximab in membranous GN.
Plasmapheresis: In anti‑GBM disease and severe vasculitis.
6.2 Cirrhosis
6.2.1 Definition & Stages
Cirrhosis: End‑stage of chronic liver injury characterized by diffuse fibrosis, regenerative nodules, and disruption of normal architecture.
Compensated vs. Decompensated cirrhosis (ascites, variceal bleeding, encephalopathy).
6.2.2 Etiologies
| Cause | Mechanism | Examples |
|---|---|---|
| Alcoholic | Toxic acetaldehyde injury, oxidative stress | Chronic ethanol use |
| Viral | Chronic inflammation from HBV/HCV | Hepatitis B and C |
| NAFLD/NASH | Metabolic syndrome–related steatohepatitis | Obesity, diabetes |
| Autoimmune | Immune‑mediated bile duct injury | Primary biliary cholangitis, autoimmune hepatitis |
| Cholestatic | Bile duct obstruction and back pressure | Primary sclerosing cholangitis |
6.2.3 Pathogenesis
Chronic Hepatocyte Injury → apoptosis, inflammatory cytokines (TNF, TGF‑β).
Activation of Hepatic Stellate Cells → myofibroblast transformation, collagen deposition in space of Disse.
Regenerative Hyperplasia → nodular architecture encased by fibrous septae.
Vascular Remodeling → intrahepatic portal hypertension.
6.2.4 Clinical Features
Portal Hypertension:
Splenomegaly, thrombocytopenia.
Varices (esophageal, gastric) → bleeding risk.
Ascites: Albumin‐rich fluid in peritoneum.
Hepatic Insufficiency:
Jaundice, coagulopathy (↓ clotting factors), hypoalbuminemia → edema.
Hepatic encephalopathy: Confusion, asterixis from ammonia accumulation.
Complications: Hepatorenal syndrome, hepatopulmonary syndrome, hepatocellular carcinoma.
6.2.5 Diagnosis
Laboratory: ↑ AST/ALT (milder than acute hepatitis), ↑ bilirubin, ↑ INR, ↓ albumin.
Imaging: Ultrasound elastography for liver stiffness, nodularity on CT/MRI.
Endoscopy: Screen for varices.
Liver Biopsy: Confirms etiology and fibrosis stage.
6.2.6 Management
Address Underlying Cause:
Abstinence from alcohol, antiviral therapy for HBV/HCV, weight loss for NASH.
Portal Hypertension Management:
Nonselective β‑blockers (propranolol) to reduce portal pressure.
Endoscopic variceal ligation for high‑risk varices.
Ascites & Edema:
Sodium restriction, diuretics (spironolactone + furosemide), large‑volume paracentesis with albumin.
Encephalopathy:
Lactulose, rifaximin to reduce ammonia.
Liver Transplantation: Definitive in decompensated cirrhosis (MELD score guidance).
6.3 Key Points for Exams
GN Classification: Match histopathologic pattern (e.g., subepithelial humps) to disease type.
Cirrhosis Pathogenesis: Diagram stellate cell activation and fibrogenesis.
Clinical Correlates: Describe how hypoalbuminemia contributes to ascites formation.
Diagnostic Criteria: List the minimal diagnostic work‑up for a patient with suspected glomerulonephritis.
Therapeutic Rationale: Explain why ACE inhibitors reduce proteinuria in GN and β‑blockers prevent variceal bleeding in cirrhosis.