Pulmonary

Question 1

Elderly smoker with FEV1/FVC 0.35 presents with: Fever Dyspnea Worsening cough CXR: Lobar consolidation, in addition to chronic changes Sputum Gram stain: Gram-negative cocci What is the diagnosis?

Answer 1

Moraxella community-acquired pneumonia (CAP). Explanation Clues: COPD and the bacterial morphology. There are only a couple of clinically significant gram-negative cocci: Neisseria species and Moraxella. Dx: Clinical + microbiologic (Gram stain and/or culture); perfectly acceptable to treat pneumonia empirically. Targeted Tx: Amoxicillin/clavulanic acid, macrolide (azithromycin or clarithromycin), tetracycline, or cephalosporin.

Question 2

There are only a couple of clinically significant gram-negative cocci: ___ species and ___.

Answer 2

There are only a couple of clinically significant gram-negative cocci: Neisseria species and Moraxella.

Question 3

Rx: Moraxella community-acquired pneumonia (CAP).

Answer 3

Amoxicillin/clavulanic acid, macrolide (azithromycin or clarithromycin), tetracycline, or cephalosporin.

Question 4

Nonsmoking patient presents with 4 months of: Weight loss Fever Progressive cough, productive of profuse watery sputum with a salty taste

Answer 4

Bronchoalveolar adenocarcinoma alias: adenocarcinoma in situ. Explanation - associated with profuse sputum production, termed “bronchorrhea” (which by definition is > 100 cc of sputum/day). - Occasionally, the bronchorrhea is associated with salt-wasting and can cause electrolyte imbalances. Dx: Lung imaging + PET scan + tissue biopsy. Tx: Variable, based on extent of disease.

Question 5

Dx-criteria: Bronchoalveolar adenocarcinoma

Answer 5

Lung imaging + PET scan + tissue biopsy.

Question 6

Bronchioloalveolar carcinoma (BAC)

Answer 6

• a subset of adenocarcinoma - peripheral - well-differentiated histology - lepidic growth pattern - potential for both aerogenous and lymphatic spread.

Question 7

Female in her 40s presents with:

Exertional syncope

Exam: JVD, large v waves, a loud P2, holosystolic murmur at LLSB, and normal lungs

PFTs: Normal except for ↓ DLCO

VQ scan: Low probability

What is the diagnosis?

Answer 7

Idiopathic pulmonary arterial hypertension (IPAH).

Explanation: Murmur of TR

Dx: Echo followed by right heart catheterization, extensive evaluation. Confirmed by PASP is ≥25 mmHg at rest
Tx: O2 + diuretics + CCBs ± endothelin receptor antagonists (bosentan) ± PDE-5 inhibitors (sildenafil) +warfarin ± prostacyclins (iloprost) ± lung transplant.

Question 8

Pulmonary hypertension: which group benefits from anti-coagulation?

Answer 8

Group 4 PH (eg, chronic thromboembolic pulmonary hypertension [CTEPH])

Anticoagulation in patients with group 1 PAH is controversial.

Group 1 pulmonary arterial hypertension (PAH) have idiopathic pulmonary arterial hypertension (IPAH, formerly called primary pulmonary hypertension), hereditary PAH, or PAH due to diseases that localize to small pulmonary arterioles, such as connective tissue diseases, HIV infection, portal hypertension, congenital heart disease, schistosomiasis, and drug use.

Question 9

Asthma exacerbations every 2 months while on an inhaled and LABA + medium-dose ICS

± Eosinophilia

Sputum: Branching hyphae

CXR: central bronchiectasis with “fingers in glove” pattern

What is the diagnosis?

Answer 9

Allergic bronchopulmonary aspergillosis (ABPA).

Dx: Clinical (history of asthma) + positive prick test + evidence of fungus (fungal elements in the sputum or antibodies against Aspergillus in the serum).
Tx: Systemic glucocorticoids + itraconazole.

Explanation: presence of fungal elements in the sputum of a patient with uncontrolled asthma = ABPA.

Alternative: prick test is positive and that the patient has an increased IgE level.

Question 10

Nonsmoking female presents with:

Intermittent cough with hemoptysis

Long bone pain

Clubbing

Pain with palpation of the anterior tibias

What is the diagnosis?

Answer 10

Adenocarcinoma of the lung with hypertrophic pulmonary osteoarthropathy (HPOA).

Dx: Clinical.
Tx: NSAIDs + treatment of underlying disorder.

Question 11

digital clubbing + periostosis of tubular bones and synovial effusions, which are most prominent in the large joints: Trigger.

Answer 11

Hypertrophic osteoarthropathy (HOA)

is a syndrome characterized by abnormal proliferation of the skin and osseous tissue at the distal parts of the extremities.

Look for lung neoplasm, primary or secondary.

Question 12

oundry worker with h/o cough and “hilar eggshell calcifications” on CXR presents with 3 months of:

Weight loss

Night sweats

Productive cough

Occasional hemoptysis

Sputum: +Acid-fast organisms

Diagnosis is ______________________ associated with ______________________.

Answer 12

tuberculosis associated with silicosis.

Explanation
Dx: Clinical and of exclusion + abnormal chest radiograph ± HRCT of the chest.
Mx: Avoidance + yearly TB screening (induration of ≥ 10 mm using the PPD test or positive IGRA) + lung transplant in young patients with severe disease.

Question 13

Patient with months of bilateral hand and knee pain presents with:

Dyspnea

Exudative pleural effusion

Active synovitis of bilateral MCPs, PIPs, and elbows

Soft tissue nodular lesions over the olecranon bursa

Pleural fluid glucose: < 30 mg/dL

TB skin test: Nonreactive

What is the cause of the pleural effusion?

Answer 13

Pleural effusion is caused by rheumatoid arthritis (RA).

Ex: Very low pleural fluid glucose, exudative
Dx: Clinical and of exclusion.
Tx: Treat underlying RA.

Question 14

Male presents with:

Dyspnea

Productive cough

Occasional hemoptysis

Nasal ulcer

↓ Hgb and Hct with normal MCV and MCHC

U/A: Protein, RBCs, RBC casts

CXR: Cavitary lesions and nodules

+Anti-PR3 and c-ANCA

What is the diagnosis?

Answer 14

GPA

Dx: Clinical + biopsy of tissue showing vasculitis.

Question 15

GPA: Rx

Answer 15

Limited disease: Steroid and methotrexate + rituximab?

Severe disease: Steroid and (daily) cyclophosphamide, controversial. Some authors/editors favor a cyclophosphamide-based regimen as initial therapy, while others choose a rituximab-based regimen for the majority of patients.

Disease appears to accelerate when serum creatinine begins to rise; detection of renal involvement signals medical emergency that must be treated swiftly

ANCA serologies useful in making diagnosis, but serial testing of ANCA titers not useful

Reflecting dramatic improvements in treatment, there is now 90% survival at 5 years

Question 16

GPA: Rx in severe disease controversy

approach to initial therapy depends upon the severity of the disease and the organ systems involved:

• Non-organ-threatening and non-life-threatening disease – This group of patients has no evidence for “active” glomerulonephritis (ie, normal serum creatinine and no red cell casts or proteinuria) and no organ-threatening or life-threatening manifestations (eg, absence of pulmonary hemorrhage, cerebral vasculitis, progressive neuropathy, orbital pseudotumor, gastrointestinal bleeding, pericarditis, or myocarditis). Such patients may have rhinosinusitis, arthritis, and/or pulmonary nodules. Non-organ-threatening and non-life-threatening disease can still result in substantial disease burden and long-term damage.
• Organ-threatening or life-threatening disease – Other patients with GPA or MPA are classified into this group for the purpose of initial therapy. Such patients may have ma

Answer 16

Some authors/editors favor a cyclophosphamide-based regimen as initial therapy, while others choose a rituximab-based regimen for the majority of patients.

Question 17

Nonsmoking hunter from Alabama develops:

An indolent productive cough

CXR: Mass-like lesion

Sputum KOH: Broad-based budding yeasts

What is the diagnosis?

Answer 17

blastomycosis.

Dx: Definitive diagnosis requires growth of the organism from a clinical specimen. Unlike Candida and Aspergillus spp, colonization or contamination with B. dermatitidis does not occur, which means that visualizing the organism on histology or obtaining a positive culture confirms the diagnosis of blastomycosis. Presumptive diagnosis of blastomycosis may be made by visualization of the characteristic yeast form in clinical specimens, such as sputum, tissue, or purulent material.

Visualization may justify beginning empirical antifungal therapy. Serology is not useful

Tx: Itraconazole or amphotericin B (for severe infections and any involving the CNS).

Question 18

Asthmatic on montelukast and omalizumab who is weaning from high-dose prednisone develops:

Allergic rhinitis

Tender upper extremity nodules or other forms of skin rash

Chronic cough and dyspnea

CBC: ↑ Eosinophils

U/A: Protein and RBC casts

What is the diagnosis?

Answer 18

EGPA

4 or more of these criteria had a sensitivity of 85 percent and a specificity of 99.7 percent:

●Asthma

● > 10 percent eosinophils

● Mononeuropathy (including multiplex) or polyneuropathy

●Migratory/transient pulmonary opacities

●Paranasal sinus abnormality

●Biopsy: blood vessel + eosinophils in extravascular areas

Rx:

Question 19

Anca and EGPA: why is not useful?

Answer 19

Low sensitivity and specificity

There are no laboratory tests that are specific for EGPA, although eosinophilia is characteristic. For patients who have suspected EGPA, we typically obtain a complete cell count with differential, a total eosinophil count, and an IgE level. We also usually obtain an ANCA test, although the sensitivity and specificity are low.

Question 20

CGD vs CVID

Answer 20

CGD: first 2 years of life + abscess

Question 21

The functional residual capacity is comprised of two lung volumes:

Answer 21

ERV + RV

The expiratory reserve volume represents the additional volume of air that can be exhaled from the lungs when acted upon by the respiratory muscles of exhalation. The residual volume is the volume of air that remains in the lung following a complete exhalation and is determined by the closing pressure of the small airways.

Question 22

At what lung volume does the outward recoil of the chest wall equal the inward elastic recoil of the lung?

Expiratory reserve volume

Functional residual capacity

Residual volume

Tidal volume

Total lung capacity

Answer 22

Functional residual capacity

The functional residual capacity of the lung refers to the volume of air that remains in the lung following a normal tidal respiration.

This volume of air represents the point at which the outward recoil of the chest wall is in equilibrium with the inward elastic recoil of the lungs. The lungs would remain at this volume if not for the actions of the respiratory muscles.

The functional residual capacity is comprised of two lung volumes: the expiratory reserve volume and the residual volume.

The expiratory reserve volume represents the additional volume of air that can be exhaled from the lungs when acted upon by the respiratory muscles of exhalation. The residual volume is the volume of air that remains in the lung following a complete exhalation and is determined by the closing pressure of the small airways.

Question 23

A 65-year-old man has progressive dyspnea on exertion over past 3 months. History of necrotizing pancreatitis that resulted in multiorgan failure and ARDS., requiring mechanical ventilation for 6 weeks prior to his recovery.

Examination: a low-pitched inspiratory and expiratory wheeze is heard that is loudest over the mid-chest area. FEV1 is 2.5 L (78% predicted), forced vital capacity is 4.00 L (94% predicted), FEV1/FVC ratio is 62.5%. Most likely cause?

Aspirated foreign body

Chronic obstructive pulmonary disease

Idiopathic pulmonary fibrosis

Subglottic stenosis

Unilateral vocal cord paralysis

Question 24

Flow volume: box-like appearance

Answer 24

Fixed central airflow obstruction

results in flattening of the flow-volume loop in both inspiration and expiration, yielding the characteristic boxlike effect.

Examples of fixed airflow obstruction include tracheal stenosis and an obstructing central airway tumor

Question 25

Fixed airway obstruction: causes

Answer 25

1. tracheal stenosis
2. obstructing central airway tumor

Fixed central airflow obstruction results in flattening of the flow-volume loop in both inspiration and expiration, yielding the characteristic boxlike effect.

Examples of fixed airflow obstruction include tracheal stenosis and an obstructing central airway tumor

Question 26

Patterns of airflow obstructoin

Answer 26

1. Fixed
2. Variable
   
   1. intra-thoracic: eg: tracheomalacia
   2. extra-thoracic: eg: VCD paralysis or tumor

Examples of fixed airflow obstruction include tracheal stenosis and an obstructing central airway tumor.

Variable obstruction: In these situations, flattening of the flow-volume curve occurs on only one limb of the flow-volume loop, and the pattern of flattening can be explained by the dynamic changes in pressure that affect the trachea.

A variable intrathoracic obstruction causes flattening of the flow-volume curve only on expiration. During inspiration the pleural pressure is more negative than the tracheal pressure, and the trachea remains unimpeded to flow. However, when pleural pressure rises on expiration relative to tracheal pressure, there is collapse of the trachea and flattening of the flow-volume curve. An example of a variable intrathoracic obstruction is tracheomalacia.

In contrast, the variable extrathoracic defect leads to flattening of the flow-volume loop on inspiration but not expiration. The relevant pressure acting on airflow in the trachea in an extrathoracic obstruction is atmospheric pressure. During inspiration, the tracheal pressure drops below atmospheric pressure, leading to compromised airflow and the characteristic flattening of the flow-volume loop. However, tracheal pressure rises above atmospheric pressure during expiration, leading to a normal expiratory curve.

Question 27

Flow volume loops

Answer 27

A = lower airway obstruction (COPD/asthma)
B = fixed upper airway obstruction (tracheal stenosis)
C = variable intrathoracic upper airway obstruction (tumour in lower trachea)
D = variable extrathoracic upper airway obstruction (vocal cord tumour or paralysis, enlarged thyroid)

Question 28

A 32-year-old woman presents to the emergency department in her 36th week of pregnancy complaining of acute dyspnea. Blood pressure 128/78, heart rate 126 beats/min, respiratory rate 28 breaths/min, and oxygen saturation is 96% on room air. Afebrile. Her lung and cardiac examinations are normal. There is trace bilateral pitting pedal edema.

CXR: normal, ECG: sinus tachycardia. ABG: pH is 7.52, PaCO2 is 26 mmHg, and PaO2 is 85 mmHg.

Management

Answer 28

CTPA

The normal arterial blood gas in pregnancy shows a chronic respiratory alkalosis with a pH ranging as high as 7.47 and PaCO2 between 30 and 32 mmHg. Calculation of the alveolar-arterial gradient (A-a gradient) can be helpful in this situation. It is easy to be fooled by the presence of a normal oxygen saturation and partial pressure of oxygen on arterial blood gas, but the A-a gradient may still be elevated in the presence of respiratory alkalosis.

To calculate the A-a gradient, one first must calculate the alveolar oxygen tension with the alveolar gas equation shown below:

PaO2 = PiO2 − (PaCO2/R) where,

PiO2 = inspired partial pressure of oxygen = FiO2 × (Pbar − PH2O), and

R = respiratory quotient = carbon dioxide production/oxygen consumption = ∼0.8

In this patient, calculation of the PaO2 = [0.21 × (760 − 47)] − (26/0.8) = 117.23 mmHg. At the same time the measured arterial partial pressure of oxygen was 85. Thus, the A-a gradient is elevated at 32 mmHg and should prompt the physician to perform further workup for pulmonary embolism.

The choice of test for diagnosis of pulmonary embolism in pregnant patients is most commonly CT pulmonary angiography, although ventilation-perfusion scanning may also be used.

Question 29

ABG on room air: pH is 7.52, PaCO2 is 26 mmHg, and PaO2 is 85 mmHg.

What is the AA gradient?

Answer 29

1. aa_gradient == (alveolar_pO2 - arterial_pO2)
2. alveolar_pO2= inspired_pO2 - (1.25*arterial_pco2) //
3. inspired_pO2 = FiO2 × (atmospheric_pressure − partial_pressure_o2)

If we are at sea level, inspired_pO2 = FiO2 * (760 - 47) = FiO2 * (710)

PaO2 = PiO2 − (PaCO2/R) where,

PiO2 = inspired partial pressure of oxygen = FiO2 × (Pbar − PH2O), and

R = respiratory quotient = carbon dioxide production/oxygen consumption = ∼0.8

In this case:

PaO2 = [0.21 × (760 − 47)] − (26/0.8) = 117.23 mmHg.

Measured arterial partial pressure of oxygen was 85. Thus, the A-a gradient is elevated at 32 mmHg and should prompt the physician to perform further workup for pulmonary embolism. T

Question 30

Alveolar gas equation

Answer 30

alveolar_oxygen_partial_pressure = FiO2*(atmospheric_pressure - partial_pressure_water) - arterial_co2_partial_pressure*(1/respiratory_exchange_ratio)

Typically:

alveolar_oxygen_partial_pressure = FiO2*710 - pCO2*1.25

AA_gradient = FiO2*710 - pCO2*1.25 - arterial_pO2

The 1.25 comes from the inverse of the respiratory_exchange_ratio.

The partial pressure of oxygen (pO2) in the pulmonary alveoli is required to calculate both the alveolar-arterial gradient of oxygen and the amount of right-to-left cardiac shunt, which are both clinically useful quantities. However it is not practical to take a sample of gas from the alveoli in order to directly measure the partial pressure of oxygen. The alveolar gas equation allows the calculation of the alveolar partial pressure of oxygen from data that is practically measurable.

1. pAO2: 107
2. FIO2: 0.21
3. PATM: 760
4. pH2O: 47
5. paCO2: 40
6. RER: 0.8

Assumptions:

Inspired gas contains no carbon dioxide (CO2) or water

Nitrogen (and any other gases except oxygen) in the inspired gas are in equilibrium with their dissolved states in the blood

Inspired and alveolar gases obey the ideal gas law

Carbon dioxide (CO2) in the alveolar gas is in equilibrium with the arterial blood i.e. that the alveolar and arterial partial pressures are equal

The alveolar gas is saturated with water

Question 31

High AA gradient: Cx

Answer 31

1. V/Q mismatch
2. Alveolar membrane diseases
3. Interstitial diseases

Question 32

Hypoxemia + normal AA gradient

Answer 32

Hypoventilation with displacement of alveolar O2 by CO2 or other substance.

Question 33

Normal AA Gradient

Answer 33

Aa_gradient = 2.5 + 0.21 x age

Question 34

PaO2 vs PAO2

Answer 34

“A” denotes alveolar and “a” denotes arterial oxygenation

Question 35

Hypoxia: mechanisms

Answer 35

1. Hypoventilation
2. V/Q mismatch
3. Right-to-left shunt
4. Diffusion limitation
5. Reduced inspired oxygen tension

Question 36

Hypoventilation induced hypoxemia: mechanism

Answer 36

1. once the partial pressure of one gas rises, the other must decrease.
2. Both arterial and alveolar carbon dioxide pressures increase during hypoventilation,
3. which causes the alveolar oxygen tension (PAO2) to decrease.
4. As a result, diffusion of oxygen from the alveolus to the pulmonary capillary declines with a net effect of hypoxemia and hypercapnia.
5. Because the respiratory quotient (Defined as CO2 eliminated/O2consumed) is assumed to be 0.8, hypoventilation affects PaCO2 more than O2.

Question 37

Hypoxemia due to pure hypoventilation: characteristics

Answer 37

1. Easily corrects with a small increase in FiO2
2. paCO2 is elevated.

An exception exists when the hypoventilation is prolonged because atelectasis can occur, which will increase the A-a gradient

Question 38

V/Q mismatch

Answer 38

imbalance of blood flow and ventilation. It causes the composition of alveolar gas to vary among lung regions.

Question 39

V/Q mismatch in the normal lung

Answer 39

1. Both ventilation and perfusion are greater in the bases than in the apices.
2. However, the difference between apical and basilar ventilation is smaller than the difference between apical and basilar perfusion.
3. As a result, the V/Q ratio is higher in the apices than in the bases.
4. V/Q mismatch is responsible for the normal A-a gradient.

Question 40

Normal AA gradient: cause

Answer 40

Physiologic V/Q mismatch

Both ventilation and perfusion are greater in the bases than in the apices (when in an upright position). However, the difference between apical and basilar ventilation is smaller than the difference between apical and basilar perfusion. As a result, the V/Q ratio is higher in the apices than in the bases. V/Q mismatch is responsible for the normal A-a gradient.

Question 41

Hypoxemia due to V/Q mismatch: causes

Answer 41

1. obstructive lung diseases
2. pulmonary vascular diseases
3. interstitial diseases.

Question 42

Hypoventilation: causes

Answer 42

1. CNS depression: eg drug overdose
2. Obesity hypoventilation (Pickwickian) syndrome
3. Neuropathy: eg ALS, GBS high cervical spine injury, phrenic nerve paralysis, or aminoglycoside blockade
4. Muscular weakness, such as myasthenia gravis
5. Poor chest wall elasticity: eg kyphoscoliosis

Question 43

Right-to-left shunt

Answer 43

blood passes from the right to the left side of the heart without being oxygenated.

Question 44

Right-to-left shunt: types

Answer 44

1. Anatomic shunts. Eg: intracardiac shunts, pulmonary AVMs, and hepatopulmonary syndrome.
2. Physiologic shunts exist when non-ventilated alveoli are perfused. Eg: atelectasis and diseases with alveolar filling (eg, pneumonia, acute respiratory distress syndrome).

Question 45

Right to left shunt: commonest example

Answer 45

Pneumonia

1. Anatomic shunts: Examples include
   
   1. intracardiac shunts,
   2. pulmonary AVMs
   3. hepatopulmonary syndrome.
2. Physiologic shunts: exist when non-ventilated alveoli are perfused. Examples
   
   1. atelectasis
   2. diseases with alveolar filling (eg, pneumonia, ARDS).

Question 46

Mechanism of hypoxemia in pneumonia

Answer 46

Right-to-left shunt

Question 47

IPF: mild to moderate; RX

Answer 47

1. Mild to moderate: pirfenidone or nintedanib
2. Advanced: sildenafil
3. Mild or moderate IPF (PFTs) who do not have underlying liver disease start with either. Patient preference, SideFx profile guides choice.
4. Advanced IPF, a diffusing capacity (DLCO) <35 percent of predicted, right ventricular dysfunction, and no contraindications to sildenafil, a trial of sildenafil.

Question 48

Hantavirus-pulmonary-syndrome.Transmission

Answer 48

Aerosolized rat excreta

Hantavirus, seen mostly in the southwestern United States, is a rare cause of viral pneumonia that quickly evolves to acute respiratory distress in previously health individuals and is associated with a high mortality rate

Question 49

Pulmonary-embolism.chronic.Mx

Proximal arterial filling defects: Mx

Answer 49

Thrombectomy

Successful pulmonary thromboendarterectomy removes obstructive, whitish, hardened thromboembolic material and markedly improves the hemodynamic measures of mean pulmonary-artery pressure, pulmonary vascular resistance, and cardiac output (Fig. 4).29,30 Improvement in hemodynamics causes reverse right ventricular remodeling, with reductions in tricuspid regurgitation and the return of right ventricular systolic and diastolic function toward normal levels.

http://www.nejm.org/doi/pdf/10.1056/NEJMra0910203?ssource=kplus

Question 50

Specific test for rheumatoid interstitial lung disease

Answer 50

ACPA

ost patients have already had serologic testing for rheumatoid factor (RF) and anti-cyclic citrullinated peptide antibodies (ACPA), but full assessment of other autoantibodies should be performed, including antinuclear antibodies and anti-double stranded DNA antibodies, and also cryoglobulins to assess for coexistent rheumatic disease that may be contributory in the appropriate clinical setting, such as when purpura, Raynaud phenomenon, skin ulcers, or renal disease are present.

Question 51

Bronchiectasis.BestTest

Answer 51

HRCT

Common cause: CVID

Question 52

Status-asthmaticus.Ventilated

Evidence of auto-peep

Mx

Answer 52

Disconnect ventilator from tube

Question 53

PEEP.Auto-PEEP

Causes

Answer 53

1. high minute ventilation
2. expiratory flow limitation, and
3. expiratory resistance

There are three common situations during which auto-PEEP develops: high minute ventilation, expiratory flow limitation, and expiratory resistance. (See ‘Causes’ above.)

Question 54

Critical-Care.Ventilation

Auto-PEEP: Problems caused by

Answer 54

1. Reduces cardiac output
2. Barotrauma

Auto-PEEP increases intrathoracic pressure, which can decrease venous return, reduce cardiac output, and potentially cause hypotension. It can also cause alveolar overdistension, increasing the likelihood of pulmonary barotrauma and ventilator-associated lung injury. Finally, auto-PEEP increases the work required for a patient to trigger a ventilator breath if pressure-triggering is being used. (See ‘Potential sequelae’ above.)

Question 55

Why is moxifloxacin a good choice in CAP in a solid organ transplant recepient 6 months post-transplant?

Answer 55

6 months post-transplant: standard community organisms

Early post-transplant: need to cover for nosocomial organisms

Question 56

Endobronchial mass: why is the wheezing monophonic, expiratory?

Answer 56

Intra-thoracic airways become smaller with expiration

Question 57

Non-response to asthma therapy in spite of adherence in a young woman

DDx

Answer 57

VCD

Vocal cord dysfunction

Question 58

Septic shock

Answer 58

Need for vasopressors to keep MAP > 65

or

Lactate > 2 in the absence of hypovolemia

Question 59

Nitrogen narcosis: prevention

Answer 59

Helium-oxygen

Nitrogen narcosis is caused by the raised partial pressure of nitrogen in nervous system tissue, and usually occurs at depths greater than 100 feet. It has been called “rapture of the depths” because it induces signs and symptoms similar to alcohol or benzodiazepine intoxication, such as impairment of intellectual and neuromuscular performance and changes in behavior and personality. Hallucinations and loss of consciousness can occur at depths greater than 300 feet.

A diver’s susceptibility to nitrogen narcosis is increased by other factors that have an opioid effect on the central nervous system, such as, hypercarbia, fatigue, alcohol, and hypothermia (core temperature less than 35ºC) induced by cold water. Divers recover rapidly upon ascent to a shallower depth. The main danger of this condition stems from impairment of the diver’s judgment, which can lead to drowning accidents.

Question 60

ABPA vs aspergillus infection

Answer 60

1. ABPA: allergic response, IgE levels are up.
2. Aspergillus infection: + Galactomannan

Question 61

Filamentous, weakly Gram +ve organism

Answer 61

Nocardia

Nocardiosis is caused by an aerobic actinomycete in the genus Nocardia, an unusual gram-positive bacteria. Nocardial infection most often occurs in immunocompromised patients. (See ‘Introduction’ above.)

●The most common disease sites are the lung, central nervous system (CNS), and skin. There are no pathognomonic signs or symptoms for nocardiosis. It should be suspected in any patient who presents with brain, soft tissue, or cutaneous lesions and a concurrent or recent pulmonary process. (See ‘Introduction’ above.)

Question 62

Pulmonary alveolar proteinosis: Rx

Answer 62

whole lung lavage

Question 63

Spontaneous hemopneumothorax in a young woman: Dx

Answer 63

Catamenial hemopneumothorax

Question 64

Bilateral pleural effusions, ascites, peripheral edema: abrupt onset; female of reproductive age; recent fertility treatment

Answer 64

Ovarian hyperstimulation syndrome

Question 65

Asthma: pregnant: mild-persistent: rx

Answer 65

low dose budenoside