Age-related changes in compliance US Medical PG Practice Questions and MCQs
Practice US Medical PG questions for Age-related changes in compliance. These multiple choice questions (MCQs) cover important concepts and help you prepare for your exams.
Age-related changes in compliance US Medical PG Question 1: During a clinical study examining the diffusion of gas between the alveolar compartment and the pulmonary capillary blood, men between the ages of 20 and 50 years are evaluated while they hold a sitting position. After inhaling a water-soluble gas that rapidly combines with hemoglobin, the concentration of the gas in the participant's exhaled air is measured and the diffusion capacity is calculated. Assuming that the concentration of the inhaled gas remains the same, which of the following is most likely to increase the flow of the gas across the alveolar membrane?
- A. Deep exhalation
- B. Entering a cold chamber
- C. Treadmill exercise (Correct Answer)
- D. Standing straight
- E. Assuming a hunched position
Age-related changes in compliance Explanation: ***Correct: Treadmill exercise***
- **Treadmill exercise** increases cardiac output and pulmonary blood flow, which in turn recruits and distends more **pulmonary capillaries**. This increases the **surface area** available for gas exchange and reduces the diffusion distance, thereby enhancing the flow of gas across the alveolar membrane.
- Exercise also typically leads to deeper and more frequent breaths, increasing the **ventilation-perfusion matching** and overall efficiency of gas exchange.
- According to Fick's law of diffusion (Vgas = A/T × D × ΔP), increasing the surface area (A) directly increases gas flow.
*Incorrect: Deep exhalation*
- **Deep exhalation** would empty the lungs more completely, potentially leading to alveolar collapse in some regions and thus **decreasing the alveolar surface area** available for gas exchange.
- This would also reduce the **driving pressure** for gas diffusion by lowering the alveolar concentration of the inhaled gas.
*Incorrect: Entering a cold chamber*
- Exposure to a **cold chamber** can cause **bronchoconstriction** in some individuals, particularly those with reactive airways, which would increase airway resistance and potentially reduce alveolar ventilation.
- While metabolic rate may slightly increase in the cold, the primary effect on the lungs is unlikely to promote increased gas diffusion in a healthy individual.
*Incorrect: Standing straight*
- **Standing straight** is a normal physiological posture and does not significantly alter the **pulmonary capillary recruitment** or the alveolar surface area in a way that would dramatically increase gas flow compared to a seated position.
- There might be minor gravitational effects on blood flow distribution, but these are generally less impactful than dynamic changes like exercise.
*Incorrect: Assuming a hunched position*
- **Assuming a hunched position** can restrict chest wall expansion and diaphragm movement, leading to **reduced tidal volume** and overall alveolar ventilation.
- This posture, by reducing lung volumes and potentially compressing the lungs, would likely **decrease the effective surface area** for gas exchange and therefore reduce gas flow.
Age-related changes in compliance US Medical PG Question 2: A 60-year-old woman presents to the clinic with a 3-month history of shortness of breath that worsens on exertion. She also complains of chronic cough that has lasted for 10 years. Her symptoms are worsened even with light activities like climbing up a flight of stairs. She denies any weight loss, lightheadedness, or fever. Her medical history is significant for hypertension, for which she takes amlodipine daily. She has a 70-pack-year history of cigarette smoking and drinks 3–4 alcoholic beverages per week. Her blood pressure today is 128/84 mm Hg. A chest X-ray shows flattening of the diaphragm bilaterally. Physical examination is notable for coarse wheezing bilaterally. Which of the following is likely to be seen with pulmonary function testing?
- A. Decreased FEV1: FVC and decreased total lung capacity
- B. Normal FEV1: FVC and decreased total lung capacity
- C. Increased FEV1: FVC and decreased total lung capacity
- D. Decreased FEV1: FVC and increased total lung capacity (Correct Answer)
- E. Increased FEV1: FVC and normal total lung capacity
Age-related changes in compliance Explanation: ***Decreased FEV1:FVC ratio and increased total lung capacity***
- This patient's symptoms (shortness of breath on exertion, chronic cough, 70-pack-year smoking history, coarse wheezing, and diaphragmatic flattening on X-ray) are highly suggestive of **Chronic Obstructive Pulmonary Disease (COPD)**, specifically **emphysema**, an obstructive lung disease.
- In COPD, there is airflow limitation, causing a **decreased FEV1:FVC ratio** (typically <0.70). Over time, air trapping occurs due to damaged alveoli and loss of elastic recoil, leading to an **increased total lung capacity (TLC)** and residual volume.
*Decreased FEV1:FVC ratio and decreased total lung capacity*
- A **decreased FEV1:FVC ratio** indicates an **obstructive lung disease**.
- However, a **decreased total lung capacity (TLC)** is characteristic of a **restrictive lung disease**, which does not align with the patient's presentation typical of COPD/emphysema.
*Normal FEV1:FVC ratio and decreased total lung capacity*
- A **normal FEV1:FVC ratio** is inconsistent with the patient's strong history of smoking and symptoms suggestive of airflow obstruction.
- A **decreased total lung capacity (TLC)** indicates a restrictive lung disease, which is not the primary diagnosis here.
*Increased FEV1:FVC ratio and decreased total lung capacity*
- An **increased FEV1:FVC ratio** is not physiologically possible in significant lung disease and is therefore incorrect.
- A **decreased total lung capacity (TLC)** would point towards a restrictive pattern not seen in generalized emphysema.
*Increased FEV1:FVC ratio and normal total lung capacity*
- An **increased FEV1:FVC ratio** is not a characteristic finding in any lung disease and is therefore incorrect.
- A **normal total lung capacity** would not be expected in advanced emphysema where air trapping is prominent.
Age-related changes in compliance US Medical PG Question 3: A 35-year-old woman volunteers for a study on respiratory physiology. Pressure probes A and B are placed as follows:
Probe A: between the parietal and visceral pleura
Probe B: within the cavity of an alveolus
The probes provide a pressure reading relative to atmospheric pressure. To obtain a baseline reading, she is asked to sit comfortably and breathe normally. Which of the following sets of values will most likely be seen at the end of inspiration?
- A. Probe A: -6 mm Hg; Probe B: 0 mm Hg (Correct Answer)
- B. Probe A: 0 mm Hg; Probe B: -1 mm Hg
- C. Probe A: -4 mm Hg; Probe B: 0 mm Hg
- D. Probe A: -4 mm Hg; Probe B: -1 mm Hg
- E. Probe A: -6 mm Hg; Probe B: -1 mm Hg
Age-related changes in compliance Explanation: ***Probe A: -6 mm Hg; Probe B: 0 mm Hg***
- At the **end of inspiration**, the **intrapleural pressure (Probe A)** is at its most negative, typically around -6 to -8 cm H2O (equivalent to -4 to -6 mmHg), reflecting the maximum expansion of the thoracic cavity.
- At the **end of inspiration**, just before exhalation begins, there is **no airflow**, so the **intrapulmonary pressure (Probe B)** equalizes with atmospheric pressure, resulting in a 0 mm Hg reading.
*Probe A: 0 mm Hg; Probe B: -1 mm Hg*
- An **intrapleural pressure of 0 mm Hg** would indicate a **pneumothorax** since it should always be negative to prevent lung collapse.
- An **intrapulmonary pressure of -1 mm Hg** would indicate that **inspiration is still ongoing**, as air would be flowing into the lungs.
*Probe A: -4 mm Hg; Probe B: 0 mm Hg*
- While an **intrapulmonary pressure of 0 mm Hg** is correct at the end of inspiration, an **intrapleural pressure of -4 mm Hg** is typical for the **end of expiration (Functional Residual Capacity)** during quiet breathing, not the end of inspiration.
- The **intrapleural pressure becomes more negative** during inspiration due to increased thoracic volume, so -4 mm Hg would be insufficient.
*Probe A: -4 mm Hg; Probe B: -1 mm Hg*
- An **intrapleural pressure of -4 mm Hg** is the normal pressure at the **end of expiration**, not the end of inspiration, where it becomes more negative.
- An **intrapulmonary pressure of -1 mm Hg** indicates that **inspiration is still in progress**, not at its end, as air would still be flowing into the lungs.
*Probe A: -6 mm Hg; Probe B: -1 mm Hg*
- While an **intrapleural pressure of -6 mm Hg** is consistent with the end of inspiration, an **intrapulmonary pressure of -1 mm Hg** means that **airflow is still occurring into the lungs**.
- At the **very end of inspiration**, just before the start of exhalation, airflow momentarily ceases, and intrapulmonary pressure becomes zero relative to the atmosphere.
Age-related changes in compliance US Medical PG Question 4: A 57-year-old man comes to the physician because of a 2-year history of fatigue, worsening shortness of breath, and a productive cough for 2 years. He has smoked 1 pack of cigarettes daily for the past 40 years. Examination shows pursed-lip breathing and an increased anteroposterior chest diameter. There is diffuse wheezing bilaterally and breath sounds are distant. Which of the following parameters is most likely to be decreased in this patient?
- A. Thickness of small airways
- B. Work of breathing
- C. Lung elastic recoil (Correct Answer)
- D. Lower airway resistance
- E. Pulmonary vascular pressure
Age-related changes in compliance Explanation: ***Lung elastic recoil***
- The patient's presentation (long smoking history, dyspnea, pursed-lip breathing, increased AP diameter, distant breath sounds, and wheezing) is classic for **emphysema**, a form of **COPD**.
- Emphysema involves the destruction of **alveolar walls** and **elastic fibers**, leading to a significant decrease in the lung's ability to passively recoil during expiration.
*Thickness of small airways*
- In COPD, particularly chronic bronchitis, there is often **inflammation and thickening of the small airways** due to goblet cell hyperplasia and mucus gland hypertrophy, increasing their thickness, not decreasing it.
- This thickening contributes to increased airway resistance.
*Work of breathing*
- The **destruction of elastic recoil** in emphysema means the patient must actively use accessory muscles to exhale, significantly **increasing the work of breathing**, which is evident from pursed-lip breathing.
- Patients with COPD expend much more energy to breathe than healthy individuals.
*Lower airway resistance*
- Emphysema, while characterized by alveolar destruction, also has an obstructive component due to **airway collapse during expiration** (loss of radial traction) and potential inflammation/mucus, which leads to **increased lower airway resistance**, not decreased resistance.
- This increased resistance contributes to air trapping and wheezing.
*Pulmonary vascular pressure*
- Chronic hypoxia resulting from severe COPD can lead to **pulmonary vasoconstriction** and remodeling of the pulmonary arteries, causing **pulmonary hypertension** and an increase in pulmonary vascular pressure.
- This is a common complication in advanced COPD, not a decreased parameter.
Age-related changes in compliance US Medical PG Question 5: In which of the following pathological states would the oxygen content of the trachea resemble the oxygen content in the affected alveoli?
- A. Emphysema
- B. Exercise
- C. Pulmonary embolism (Correct Answer)
- D. Pulmonary fibrosis
- E. Foreign body obstruction distal to the trachea
Age-related changes in compliance Explanation: ***Pulmonary embolism***
- A pulmonary embolism blocks **blood flow** to a portion of the lung, creating **dead space ventilation** (high V/Q ratio).
- In the affected alveoli, **no blood perfusion** means no oxygen extraction occurs, so the alveolar oxygen content remains **high and similar to tracheal/inspired air**.
- This is the classic physiological state where ventilation continues but perfusion is absent, preventing gas exchange.
*Foreign body obstruction distal to the trachea*
- A complete obstruction **prevents fresh air** from reaching the affected alveoli.
- The trapped gas undergoes **resorption atelectasis**: oxygen is absorbed into capillary blood, CO2 diffuses in, and alveolar gas equilibrates with **venous blood** composition.
- Alveolar oxygen content becomes **very low**, not similar to tracheal air.
*Emphysema*
- Emphysema involves destruction of **alveolar walls** and enlargement of airspaces with impaired gas exchange.
- While V/Q mismatch occurs, oxygen is still extracted by perfusing blood.
- Alveolar oxygen content is **lower than tracheal air** due to ongoing (though inefficient) gas exchange.
*Exercise*
- During exercise, **oxygen consumption increases** dramatically with enhanced cardiac output and oxygen extraction.
- Alveolar oxygen content is **significantly lower** than tracheal air due to increased oxygen uptake by blood.
*Pulmonary fibrosis*
- Pulmonary fibrosis causes **thickening of the alveolar-capillary membrane**, impairing oxygen diffusion.
- Despite diffusion limitation, blood still perfuses the alveoli and extracts oxygen.
- Alveolar oxygen content is **lower than tracheal air**, though the A-a gradient is increased.
Age-related changes in compliance US Medical PG Question 6: A 30-year-old woman presents to the emergency department with breathlessness for the last hour. She is unable to provide any history due to her dyspnea. Her vitals include: respiratory rate 20/min, pulse 100/min, and blood pressure 144/84 mm Hg. On physical examination, she is visibly obese, and her breathing is labored. There are decreased breath sounds and hyperresonance to percussion across all lung fields bilaterally. An arterial blood gas is drawn, and the patient is placed on inhaled oxygen. Laboratory findings reveal:
pH 7.34
pO2 63 mm Hg
pCO2 50 mm Hg
HCO3 22 mEq/L
Her alveolar partial pressure of oxygen is 70 mm Hg. Which of the following is the most likely etiology of this patient’s symptoms?
- A. Right to left shunt
- B. Alveolar hypoventilation (Correct Answer)
- C. Ventricular septal defect
- D. Impaired gas diffusion
- E. Ventilation/perfusion mismatch
Age-related changes in compliance Explanation: ***Alveolar hypoventilation***
- The patient exhibits features of **obesity** and **labored breathing** with decreased breath sounds and hyperresonance, along with arterial blood gas results showing **respiratory acidosis** (pH 7.34, pCO2 50 mmHg) and **hypoxia** (pO2 63 mmHg).
- The calculated A-a gradient (Alveolar O2 - arterial O2) is low (70 mmHg - 63 mmHg = 7 mmHg), indicating that the problem is primarily with **overall ventilation** rather than a defect in gas exchange across the alveolar-capillary membrane.
*Right to left shunt*
- A right-to-left shunt would cause a **large A-a gradient**, as deoxygenated blood bypasses the lungs and mixes with oxygenated blood.
- While it causes **hypoxemia**, it would not typically be associated with hypercapnia unless very severe, and the A-a gradient calculation here does not support a significant shunt.
*Ventricular septal defect*
- A ventricular septal defect is a **structural heart abnormality** that can cause a left-to-right shunt initially, leading to pulmonary hypertension and eventually a right-to-left shunt (Eisenmenger syndrome).
- While it can cause hypoxemia due to shunting, it would not primarily manifest with increased pCO2 or the specific lung physical exam findings of decreased breath sounds and hyperresonance in the absence of other cardiac signs.
*Impaired gas diffusion*
- Impaired gas diffusion would lead to a **large A-a gradient** and **hypoxemia**, but typically not significant hypercapnia unless the impairment is extremely severe.
- Conditions like **pulmonary fibrosis** or **emphysema** cause impaired diffusion, but the patient's presentation and particularly the low A-a gradient do not support this.
*Ventilation/perfusion mismatch*
- A V/Q mismatch also causes a **large A-a gradient** and **hypoxemia**, as some areas of the lung are either poorly ventilated or poorly perfused.
- While it can cause hypercapnia in severe cases, the primary issue indicated by the low A-a gradient here is one of overall inadequate ventilation, not selective areas of ventilation-perfusion imbalance.
Age-related changes in compliance US Medical PG Question 7: A 60-year-old man presents with breathlessness for the past 3 months. His symptoms have been getting progressively worse during this time. He denies any history of cough, fever, or chest pain. He works at a local shipyard and is responsible for installing the plumbing aboard the vessels. His past medical history is significant for hypertension for which he takes metoprolol every day. He denies smoking and any illicit drug use. His pulse is 74/min, respiratory rate is 14/min, blood pressure is 130/76 mm Hg, and temperature is 36.8°C (98.2°F). Physical examination is significant for fine bibasilar crackles at the end of inspiration without digital clubbing. Which of the following additional findings would most likely be present in this patient?
- A. Increased pulmonary capillary wedge pressure
- B. Increased residual lung volume
- C. Reduced FEV1/FVC ratio
- D. Decreased diffusing capacity of CO (Correct Answer)
- E. Decreased pulmonary arterial pressure
Age-related changes in compliance Explanation: ***Decreased diffusing capacity of CO***
- This patient's occupation at a **shipyard**, progressive dyspnea, and bibasilar crackles without clubbing, along with normal vital signs, are highly suggestive of **asbestosis**, a type of **interstitial lung disease (ILD)**.
- ILDs cause **fibrosis of the alveolar-capillary membrane**, leading to impaired gas exchange and a characteristic **reduction in DLCO (diffusing capacity of the lung for carbon monoxide)**. This is a hallmark of parenchymal lung disease.
*Increased pulmonary capillary wedge pressure*
- An elevated **pulmonary capillary wedge pressure (PCWP)** indicates **left-sided heart failure** or **pulmonary venous hypertension**.
- While dyspnea can be a symptom of heart failure, the patient's normal blood pressure and absence of cardiac-specific symptoms or signs point away from primary cardiac pathology.
*Increased residual lung volume*
- **Increased residual lung volume** is a characteristic finding in **obstructive lung diseases** such as **COPD** and **asthma**, where there is air trapping due to airflow limitation.
- The patient's presentation with progressive dyspnea and bibasilar crackles is more consistent with a **restrictive lung disorder** like asbestosis, which typically causes **decreased lung volumes**.
*Reduced FEV1/FVC ratio*
- A **reduced FEV1/FVC ratio** is the hallmark of **obstructive lung diseases**, indicating airflow limitation.
- In **restrictive lung diseases** like asbestosis, both FEV1 and FVC are typically reduced proportionally, often resulting in a **normal or even increased FEV1/FVC ratio**.
*Decreased pulmonary arterial pressure*
- **Pulmonary arterial pressure (PAP)** is typically **normal or increased** in patients with interstitial lung disease due to **hypoxic vasoconstriction** and vascular remodeling.
- A decreased PAP would be an unusual and atypical finding in such a patient and is not associated with this clinical picture.
Age-related changes in compliance US Medical PG Question 8: A 68-year-old man with both severe COPD (emphysema) and newly diagnosed idiopathic pulmonary fibrosis presents with worsening dyspnea. His pressure-volume curve shows a complex pattern with features of both diseases. Static compliance measured at mid-lung volumes is 120 mL/cm H2O. His pulmonologist must decide on optimal management. Synthesizing the pathophysiology of both conditions, what represents the most significant clinical challenge in managing his combined disease?
- A. Pulmonary rehabilitation cannot address the opposing mechanical derangements
- B. The increased compliance from emphysema completely negates decreased compliance from fibrosis
- C. The opposing effects on compliance create a pseudonormal total respiratory compliance masking disease severity (Correct Answer)
- D. Emphysema treatment with bronchodilators will worsen fibrosis progression
- E. Oxygen therapy beneficial for COPD will accelerate fibrotic changes
Age-related changes in compliance Explanation: ***The opposing effects on compliance create a pseudonormal total respiratory compliance masking disease severity***
- In **Combined Pulmonary Fibrosis and Emphysema (CPFE)**, the **increased lung compliance** from upper-lobe emphysema is offset by the **decreased compliance** from lower-lobe fibrosis.
- This results in a **pseudonormalization** of lung volumes (like FVC and TLC) and compliance measurements, which can lead to a significant **underestimation of disease severity** during clinical assessment.
*Pulmonary rehabilitation cannot address the opposing mechanical derangements*
- While mechanical derangements are complex, **pulmonary rehabilitation** remains a cornerstone of management to improve functional capacity and reduce dyspnea in both conditions.
- The challenge is not that rehabilitation is ineffective, but rather the **physiological monitoring** and objective assessment of progress are hampered by masked lung volumes.
*The increased compliance from emphysema completely negates decreased compliance from fibrosis*
- The two forces do not perfectly negate each other; rather, they coexist to produce a **paradoxical physiological profile** where static measurements appear mid-range while gas exchange is severely impaired.
- Patients often exhibit a **disproportionate reduction in DLCO** (diffusion capacity) despite relatively preserved lung volumes, indicating the negation is only superficial and numerical.
*Emphysema treatment with bronchodilators will worsen fibrosis progression*
- There is no clinical evidence suggesting that **bronchodilators** (beta-agonists or anticholinergics) used for COPD/emphysema accelerate the **pathological scarring** seen in idiopathic pulmonary fibrosis.
- Bronchodilators primarily target **airway smooth muscle** and do not interfere with the fibroblastic pathways driving interstitial lung disease.
*Oxygen therapy beneficial for COPD will accelerate fibrotic changes*
- **Long-term oxygen therapy (LTOT)** is used to treat chronic hypoxemia in both COPD and fibrosis and does not cause or accelerate **lung remodeling** or fibrosis.
- While high concentrations of inspired oxygen (FiO2) can cause **oxidative stress**, the flow rates used for clinical management do not contribute to the progression of pulmonary fibrosis.
Age-related changes in compliance US Medical PG Question 9: A 42-year-old woman with systemic sclerosis develops both pulmonary fibrosis and chest wall restriction from skin thickening. Her measured total respiratory system compliance is 30 mL/cm H2O. Testing with complete paralysis and positive pressure ventilation shows isolated lung compliance of 50 mL/cm H2O. She is being considered for immunosuppressive therapy versus supportive care. Evaluate which intervention would provide the greatest improvement in her respiratory mechanics.
- A. Supportive care only, as both components contribute equally and irreversibly
- B. Combined therapy targeting lung disease with chest wall mobilization (Correct Answer)
- C. Aggressive immunosuppression targeting both lung and skin disease
- D. Lung-directed therapy only, as it contributes more to total compliance reduction
- E. Chest wall-directed physical therapy, as it is the primary limiting factor
Age-related changes in compliance Explanation: ***Combined therapy targeting lung disease with chest wall mobilization*** - The total respiratory compliance (Ct) is calculated using the formula **1/Ct = 1/Clung + 1/Cchest wall**; here, 1/30 = 1/50 + 1/Ccw, which calculates the **chest wall compliance** as 75 mL/cm H2O. - Both the lungs (50 mL/cm H2O) and chest wall (75 mL/cm H2O) are significantly below the **normal value of ~200 mL/cm H2O**, meaning both require intervention for meaningful improvement. *Supportive care only, as both components contribute equally and irreversibly* - While both contribute, they are not strictly equal (50 vs 75), and **systemic sclerosis**-associated lung/skin disease may respond to modern therapeutic interventions. - Labeling these as **irreversible** ignores potential benefits from immunosuppression in the active inflammatory stages of **interstitial lung disease**. *Aggressive immunosuppression targeting both lung and skin disease* - While immunosuppression addresses the underlying **pathophysiology**, it may not provide immediate mechanical relief for fixed **chest wall restriction**. - Effective management often requires adding **physical therapy** and mobilization to address the extrinsic mechanical constraint caused by **scleroderma skin thickening**. *Lung-directed therapy only, as it contributes more to total compliance reduction* - Although lung compliance (50) is lower than chest wall compliance (75), ignoring the **chest wall component** neglects a significant portion of the patient's **work of breathing**. - Solely treating the lung disease will not bypass the **extrinsic restriction** imposed by the tight skin and musculoskeletal changes. *Chest wall-directed physical therapy, as it is the primary limiting factor* - The calculations show that **lung compliance** is actually more severely reduced (50) than chest wall compliance (75). - Focusing only on the **chest wall** would leave the primary cause of the **restrictive ventilatory defect** (pulmonary fibrosis) unaddressed.
Age-related changes in compliance US Medical PG Question 10: A 58-year-old man with end-stage pulmonary fibrosis is being evaluated for lung transplantation. His current static compliance is 25 mL/cm H2O (normal: 200 mL/cm H2O). He also has mild obesity (BMI 32) and ankylosing spondylitis affecting chest wall mobility. Post-transplant, assuming successful bilateral lung transplant with normal donor lungs, what would be the expected change in his total respiratory system compliance?
- A. Improved lung compliance but worsened chest wall compliance from surgery
- B. Worse compliance initially due to transplant rejection and denervation
- C. Return to completely normal respiratory compliance matching healthy individuals
- D. Improved but still reduced compliance due to persistent chest wall restriction (Correct Answer)
- E. No significant change because the primary problem is muscular weakness
Age-related changes in compliance Explanation: ***Improved but still reduced compliance due to persistent chest wall restriction***
- Total respiratory system compliance follows the formula **1/C_total = 1/C_lungs + 1/C_chest_wall**, meaning the total compliance is limited by the stiffest component.
- While the lung transplant corrects the **pulmonary fibrosis**, the patient's **obesity** and **ankylosing spondylitis** cause extrinsic restriction that maintains a low **chest wall compliance**.
*Improved lung compliance but worsened chest wall compliance from surgery*
- Although surgical trauma can temporarily affect chest wall dynamics, the **ankylosing spondylitis** is the primary chronic factor limiting chest wall expansion here.
- The logic is flawed because the improvement in **lung compliance** from the donor lungs far outweighs any minor surgical stiffness in the long term.
*Worse compliance initially due to transplant rejection and denervation*
- **Denervation** typically leads to loss of the cough reflex but does not significantly alter the mechanical **elasticity** or compliance of the lung tissue itself.
- Acute rejection would decrease compliance, but the question asks for the "expected" outcome of a **successful bilateral transplant**.
*Return to completely normal respiratory compliance matching healthy individuals*
- Total compliance cannot return to normal because the **chest wall** remains stiff due to the patient's underlying skeletal and adipose conditions.
- Even with perfect donor lungs, the **extrapulmonary restriction** means the total system compliance will remain below the normal **200 mL/cm H2O**.
*No significant change because the primary problem is muscular weakness*
- The patient's primary problem in the lungs was **pulmonary fibrosis**, which is a mechanical parenchymal issue, not purely muscular weakness.
- Total compliance will definitely show a **significant increase** from the baseline of 25 mL/cm H2O because the severely stiff fibrotic lungs have been replaced.
More Age-related changes in compliance US Medical PG questions available in the OnCourse app. Practice MCQs, flashcards, and get detailed explanations.
