Pressure-volume curves US Medical PG Practice Questions and MCQs
Practice US Medical PG questions for Pressure-volume curves. These multiple choice questions (MCQs) cover important concepts and help you prepare for your exams.
Pressure-volume curves US Medical PG Question 1: An 85-year-old man with hypertension and type 2 diabetes mellitus is brought to the emergency department because of a 2-day history of shortness of breath. He has smoked one pack of cigarettes daily for 30 years. His temperature is 36.9°C (98.4°F), pulse is 100/min, respirations are 30/min, and blood pressure is 138/75 mm Hg. Pulmonary function testing shows decreased tidal volume and normal lung compliance. Which of the following is the most likely underlying etiology of this patient's tachypnea?
- A. Diabetic ketoacidosis
- B. Rib fracture
- C. Pulmonary edema (Correct Answer)
- D. Emphysema exacerbation
- E. Tension pneumothorax
Pressure-volume curves Explanation: ***Pulmonary edema***
- This patient's **hypertension** and **diabetes** are major risk factors for heart failure, and the acute onset of **shortness of breath** with **tachypnea** suggests cardiogenic pulmonary edema.
- **Decreased tidal volume** occurs because fluid accumulation in the interstitium and alveoli reduces functional lung capacity, prompting rapid, shallow breathing to maintain minute ventilation.
- While pulmonary edema typically causes **decreased lung compliance** due to fluid-stiffened lungs, early or mild cases may show relatively preserved compliance, or the normal compliance here may reflect measurement timing or technique. The clinical picture and decreased tidal volume strongly support pulmonary edema.
- The combination of cardiac risk factors, acute dyspnea, tachypnea, and altered breathing pattern make this the most likely diagnosis.
*Diabetic ketoacidosis*
- DKA causes **Kussmaul respirations** (deep, labored breathing) to compensate for metabolic acidosis, not the shallow breathing pattern (decreased tidal volume) seen here.
- DKA typically presents with polyuria, polydipsia, abdominal pain, nausea, and fruity breath odor, which are not mentioned.
- While this patient has diabetes, the respiratory pattern and absence of typical DKA symptoms make this less likely.
*Rib fracture*
- Rib fractures cause **pleuritic chest pain** that worsens with breathing, leading to voluntary splinting and reduced tidal volume.
- However, there is **no history of trauma** or chest pain reported.
- Pain from rib fractures would be localized, and the acute 2-day onset of dyspnea without trauma makes this unlikely.
*Emphysema exacerbation*
- Emphysema is characterized by **increased lung compliance** (hyperinflation) due to alveolar wall destruction, which contradicts the normal compliance finding.
- While the patient has a significant smoking history, the **normal lung compliance** argues against emphysema.
- COPD exacerbations typically present with wheezing, productive cough, and hyperinflation, not decreased tidal volume with normal compliance.
*Tension pneumothorax*
- Tension pneumothorax presents with **severe respiratory distress**, unilateral absent breath sounds, **hypotension**, tracheal deviation, and jugular venous distension.
- This patient's **blood pressure is normal** (138/75 mm Hg) and there's no mention of absent breath sounds or hemodynamic compromise.
- The clinical presentation does not support this life-threatening emergency.
Pressure-volume curves US Medical PG Question 2: A 32-year-old woman presents with progressive shortness of breath and a dry cough. She says that her symptoms onset recently after a 12-hour flight. Past medical history is unremarkable. Current medications are oral estrogen/progesterone containing contraceptive pills. Her vital signs include: blood pressure 110/60 mm Hg, pulse 101/min, respiratory rate 22/min, oxygen saturation 88% on room air, and temperature 37.9℃ (100.2℉). Her weight is 94 kg (207.2 lb) and height is 170 cm (5 ft 7 in). On physical examination, she is acrocyanotic. There are significant swelling and warmth over the right calf. There are widespread bilateral rales present. Cardiac auscultation reveals accentuation of the pulmonic component of the second heart sound (P2) and an S3 gallop. Which of the following ventilation/perfusion (V/Q) ratios most likely corresponds to this patient’s condition?
- A. 1.3 (Correct Answer)
- B. 1
- C. 0.8
- D. 0.5
- E. 0.3
Pressure-volume curves Explanation: ***1.3***
- This value represents an increased V/Q ratio, or **dead space ventilation**, which is characteristic of a **pulmonary embolism (PE)**. In PE, a portion of the lung is ventilated but not perfused due to the embolism blocking blood flow, leading to wasted ventilation.
- The patient's symptoms (sudden onset dyspnea after a long flight, use of oral contraceptives, calf swelling, hypoxia, and accentuated P2) are highly suggestive of a PE, which is the most likely cause of increased V/Q mismatch.
*1*
- A V/Q ratio of 1 indicates **perfect matching** of ventilation and perfusion, which is an ideal state not typically achieved throughout the entire lung, especially in disease.
- This value would not explain the patient's severe **hypoxia** and overall clinical picture of respiratory distress.
*0.8*
- This is the **average normal V/Q ratio** for the lung as a whole, representing slightly more perfusion than ventilation.
- While it's a normal physiological state, it does not account for the significant V/Q mismatch indicated by the patient's severe hypoxemia (SpO2 88%) and clinical symptoms.
*0.5*
- This value represents a **low V/Q ratio**, indicating relatively more perfusion than ventilation, often seen in conditions like **shunt physiology** (e.g., pneumonia, atelectasis, pulmonary edema).
- While the patient has rales and an S3 gallop suggesting potential pulmonary edema or heart failure secondary to increased right heart strain, the primary pathophysiology in PE is increased V/Q due to unperfused but ventilated lung regions.
*0.3*
- This is a severely **low V/Q ratio**, approaching a **shunt**, where blood passes through the lungs without being adequately oxygenated. This is typical of conditions like **severe pneumonia, ARDS, or significant atelectasis**.
- While PE can cause some degree of bronchoconstriction leading to areas of low V/Q, the predominant and most impactful V/Q mismatch in PE is the high V/Q ratio in areas of unperfused lung.
Pressure-volume curves US Medical PG Question 3: 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
Pressure-volume curves 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.
Pressure-volume curves US Medical PG Question 4: Which of the following physiologic changes decreases pulmonary vascular resistance (PVR)?
- A. Inhaling the inspiratory reserve volume (IRV)
- B. Exhaling the entire vital capacity (VC)
- C. Exhaling the expiratory reserve volume (ERV)
- D. Breath holding maneuver at functional residual capacity (FRC)
- E. Inhaling the entire vital capacity (VC) (Correct Answer)
Pressure-volume curves Explanation: ***Inhaling the entire vital capacity (VC)***
- As lung volume increases from FRC to TLC (which includes inhaling the entire VC), alveolar vessels are **stretched open**, and extra-alveolar vessels are **pulled open** by the increased radial traction, leading to a decrease in PVR.
- This **maximizes the cross-sectional area** of the pulmonary vascular bed, lowering resistance.
*Inhaling the inspiratory reserve volume (IRV)*
- While inhaling IRV increases lung volume, it's not the maximal inspiration of the entire VC where **PVR is typically at its lowest**.
- PVR continues to decrease as lung volume approaches total lung capacity (TLC).
*Exhaling the entire vital capacity (VC)*
- Exhaling the entire vital capacity leads to very low lung volumes, where PVR significantly **increases**.
- At low lung volumes, **alveolar vessels become compressed** and extra-alveolar vessels **narrow**, increasing resistance.
*Exhaling the expiratory reserve volume (ERV)*
- Exhaling the ERV results in a lung volume below FRC, which causes a **marked increase in PVR**.
- This is due to the **compression of alveolar vessels** and decreased radial traction on extra-alveolar vessels.
*Breath holding maneuver at functional residual capacity (FRC)*
- At FRC, the PVR is at an **intermediate level**, not its lowest.
- This is the point where the opposing forces affecting alveolar and extra-alveolar vessels are somewhat balanced, but not optimized for minimal resistance.
Pressure-volume curves US Medical PG Question 5: A 57-year-old man presents to the clinic for a chronic cough over the past 4 months. The patient reports a productive yellow/green cough that is worse at night. He denies any significant precipitating event prior to his symptoms. He denies fever, chest pain, palpitations, weight changes, or abdominal pain, but endorses some difficulty breathing that waxes and wanes. He denies alcohol usage but endorses a 35 pack-year smoking history. A physical examination demonstrates mild wheezes, bibasilar crackles, and mild clubbing of his fingertips. A pulmonary function test is subsequently ordered, and partial results are shown below:
Tidal volume: 500 mL
Residual volume: 1700 mL
Expiratory reserve volume: 1500 mL
Inspiratory reserve volume: 3000 mL
What is the functional residual capacity of this patient?
- A. 4500 mL
- B. 2000 mL
- C. 2200 mL
- D. 3200 mL (Correct Answer)
- E. 3500 mL
Pressure-volume curves Explanation: ***3200 mL***
- The **functional residual capacity (FRC)** is the volume of air remaining in the lungs after a normal expiration.
- It is calculated as the sum of the **expiratory reserve volume (ERV)** and the **residual volume (RV)**. In this case, 1500 mL (ERV) + 1700 mL (RV) = 3200 mL.
*4500 mL*
- This value represents the sum of the **inspiratory reserve volume (3000 mL)** and the **residual volume (1700 mL)**, which does not correspond to a standard lung volume or capacity.
- It does not logically relate to the definition of functional residual capacity.
*2000 mL*
- This value represents the sum of the **tidal volume (500 mL)** and the **expiratory reserve volume (1500 mL)**, which is incorrect for FRC.
- This would represent the inspiratory capacity minus the inspiratory reserve volume, which is not a standard measurement used in pulmonary function testing.
*2200 mL*
- This value could be obtained by incorrectly adding the **tidal volume (500 mL)** and the **residual volume (1700 mL)**, which is not the correct formula for FRC.
- This calculation represents a miscombination of lung volumes that does not correspond to any standard pulmonary capacity measurement.
*3500 mL*
- This value is the sum of the **tidal volume (500 mL)**, the **expiratory reserve volume (1500 mL)**, and the **residual volume (1700 mL)**.
- This would represent the FRC plus the tidal volume, which is not a standard measurement and does not represent the functional residual capacity.
Pressure-volume curves US Medical PG Question 6: 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
Pressure-volume curves 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.
Pressure-volume curves US Medical PG Question 7: A 72-year-old obese man presents as a new patient to his primary care physician because he has been feeling tired and short of breath after recently moving to Denver. He is a former 50 pack-year smoker and has previously had deep venous thrombosis. Furthermore, he previously had a lobe of the lung removed due to lung cancer. Finally, he has a family history of a progressive restrictive lung disease. Laboratory values are obtained as follows:
Oxygen tension in inspired air = 130 mmHg
Alveolar carbon dioxide tension = 48 mmHg
Arterial oxygen tension = 58 mmHg
Respiratory exchange ratio = 0.80
Respiratory rate = 20/min
Tidal volume = 500 mL
Which of the following mechanisms is consistent with these values?
- A. Shunt physiology
- B. High altitude
- C. V/Q mismatch
- D. Pulmonary fibrosis
- E. Hypoventilation (Correct Answer)
Pressure-volume curves Explanation: ***Hypoventilation***
- The arterial oxygen tension (PaO2) of 58 mmHg is consistent with hypoxemia, and the alveolar carbon dioxide tension (PACO2) of 48 mmHg (normal 35-45 mmHg) indicates **hypercapnia**, a hallmark of hypoventilation.
- The **alveolar-arterial (A-a) gradient** can be calculated using the alveolar gas equation: PAO2 = PiO2 - PACO2/R. Here, PAO2 = 130 mmHg - 48 mmHg/0.8 = 130 - 60 = 70 mmHg. The A-a gradient is PAO2 - PaO2 = 70 - 58 = 12 mmHg, which is within the normal range (5-15 mmHg), indicating that the hypoxemia is primarily due to **decreased alveolar ventilation**.
*Shunt physiology*
- A shunt would cause a significant reduction in PaO2 and a **widened A-a gradient** (typically >15 mmHg) due to deoxygenated blood bypassing ventilated areas.
- While shunts do not typically cause hypercapnia unless very severe, the normal A-a gradient here rules out a significant shunt as the primary mechanism for hypoxemia.
*High altitude*
- Moving to a high altitude (like Denver) causes a decrease in **inspired oxygen tension (PiO2)**, leading to hypoxemia.
- However, the provided inspired oxygen tension (130 mmHg) is above what would be expected for significant high-altitude hypoxemia at sea level equivalent, and the hypoxemia here is associated with hypercapnia, which is not a direct result of high altitude itself.
*V/Q mismatch*
- A V/Q mismatch leads to hypoxemia and a **widened A-a gradient**, as some areas of the lung are either underventilated or underperfused.
- While it can cause hypoxemia, a V/Q mismatch is typically associated with **normal or low PaCO2** due to compensatory hyperventilation, not hypercapnia, and the A-a gradient would be elevated.
*Pulmonary fibrosis*
- Pulmonary fibrosis is a restrictive lung disease that leads to impaired gas exchange, causing hypoxemia primarily due to **V/Q mismatch** and **diffusion limitation**.
- This would result in a **widened A-a gradient** and often a **low PaCO2** due to compensatory hyperventilation, rather than the elevated PaCO2 observed in this patient.
Pressure-volume curves US Medical PG Question 8: A 55-year-old man with a 60 pack-year smoking history is referred by his primary care physician for a pulmonary function test (PFT). A previously obtained chest x-ray is shown below. Which of the following will most likely appear in his PFT report?
- A. Residual volume increased, total lung capacity decreased
- B. Residual volume normal, total lung capacity decreased
- C. Residual volume normal, total lung capacity normal
- D. Residual volume decreased, total lung capacity increased
- E. Residual volume increased, total lung capacity increased (Correct Answer)
Pressure-volume curves Explanation: ***Residual volume increased, total lung capacity increased***
- The chest X-ray shows **hyperinflation** and a **flattened diaphragm**, which are classic signs of **emphysema**, a type of COPD.
- In emphysema, destruction of alveolar walls leads to air trapping, resulting in an **increased residual volume** and **total lung capacity**.
*Residual volume increased, total lung capacity decreased*
- An increased residual volume suggests **air trapping**, typical of obstructive lung diseases like emphysema.
- However, a **decreased total lung capacity** is characteristic of restrictive lung diseases, which would contradict the clinical and radiological findings for emphysema.
*Residual volume normal, total lung capacity decreased*
- A **normal residual volume** indicates no significant air trapping, which is inconsistent with emphysema.
- A **decreased total lung capacity** is seen in restrictive lung diseases, not obstructive diseases like emphysema.
*Residual volume normal, total lung capacity normal*
- **Normal lung volumes** would indicate healthy lung function, which is not expected in a patient with a heavy smoking history and radiological evidence of emphysema.
- The patient's 60 pack-year smoking history strongly points towards significant lung pathology.
*Residual volume decreased, total lung capacity increased*
- A **decreased residual volume** would suggest improved exhalation and less air trapping, which is contrary to the pathophysiology of emphysema.
- While total lung capacity can be increased in emphysema, the decrease in residual volume makes this option incorrect.
Pressure-volume curves US Medical PG Question 9: 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
Pressure-volume curves 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.
Pressure-volume curves US Medical PG Question 10: 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
Pressure-volume curves 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.
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