10b: Resp

Question 1

Respiration is possible after which week of embryonic development?

Answer 1

Week 25 - end of canalicular stage

incompatible with life before that

Question 2

Errors at (X) stage of lung development can lead to tracheoesophageal fistula

Answer 2

X = Embryonic (weeks 4-7)

Question 3

By the end of the embryonic stage of lung development, the (X) (bronchi/bronchioles/alveoli) have formed

Answer 3

X = tertiary (segmental)

bronchi

Question 4

By the end of the pseudoglandular stage of lung development, the (X) (bronchi/bronchioles/alveoli) have formed

Answer 4

X = terminal
bronchioles

(Weeks 5-17)

Question 5

The respiratory bronchioles and alveolar ducts are formed by (X) stage of respiratory development.

Answer 5

X = Canalicular (Weeks 16-25)

Question 6

Alveolar ducts form terminal sacs in which stage of lung development?

Answer 6

Saccular (Week 26-birth)

Question 7

Pneumocytes develop in which stage of lung development?

Answer 7

Saccular (Week 26-birth) - mature levels not achieved until around week 35

Question 8

The terminal sacs become adult alveoli in (X) stage of lung development. What is the key feature that distinguishes the two structures?

Answer 8

X = Alveolar (Week 36-8 years old)

Secondary septation (adult alveoli) versus primary septation (terminal sacs)

Question 9

CXR of newborn shows discrete, round, sharply defined density in medial 1/3 of lungs. What is the likely congenital malformation?

Answer 9

Bronchogenic cyst (fluid-filled; air-filled if infected)

Question 10

Pulmonary surfactant is a complex mix of (X). (Y) is the most important of these

Answer 10

X = lecithins
Y = dipalmitoylphosphatidylcholine (DPPC)

Question 11

List the potential complications of neonatal oxygen supplementation for respiratory distress

Answer 11

“RIB”

1. Retinopathy of prematurity (hyperoxia, high VEGF/neovascularization, retinal detachment/blindness)
2. Intraventricular hemorrhage
3. Bronchopulmonary dysplasia

Question 12

Screening test for fetal lung maturity:

Answer 12

Measure phospholipid content of amniotic fluid

Lecithin/Sphingomyelin ratio (L/S ratio) in amniotic fluid; greater than 2 is healthy, less than 1.5 predictive of NRDS

Question 13

Anatomic dead space refers to air in which structure(s)?

Answer 13

Conducting zone of respiratory tree (no gas exchange) = nose up to terminal bronchioles

Question 14

(X) structure(s) are lost when bronchi become bronchioles

Answer 14

X = cartilage and goblet cells

Question 15

Transition from (X) epithelium to (Y) epithelium occurs at the (Z) bronchioles

Answer 15

X = pseudostratified columnar (ciliated)
Y = cuboidal (ciliated; lose cilia in respiratory bronchioles)
Z = terminal

Question 16

T/F: Mucociliary clearance remains the primary clearance mechanism throughout the entire conducting zone of lung

Answer 16

True (alveolar macrophages clear debris in resp zone)

Question 17

Least resistance in airway/respiratory tree is seen at level of (X) (bronchi/bronchioles/alveoli). And highest resistance?

Answer 17

X = terminal
Bronchioles (large numbers in parallel)

Med-sized bronchioles (due to turbulent flow)

Question 18

RALS (“right anterior, left superior”) refers to (X) relationship to (Y) in lungs

Answer 18

X = pulmonary artery
Y = bronchus

In hilum

Question 19

The carina is sandwiched between which two key structures in thorax?

Answer 19

(Carina is bifurcation of trachea into R and L bronchi)

Anterior: ascending aorta
Posterior/lateral: descending aorta

Question 20

T/F: Aspirating peanut while upright or supine will both cause it to enter R lower lobe

Answer 20

False - if supine, R upper lobe probably

Question 21

List the three main structures perforating the diaphragm and at which levels they do so

Answer 21

1. IVC (T8)
2. Esophagus (T10)
3. Aortic hiatus (T12)

“I(VC) 8 10 eggs (esophagus) at (aorta) 12”

Question 22

The IVC as well as (X) perforate diaphragm at T(8/10/12).

Answer 22

X = right phrenic n

T8

Question 23

The Esophagus as well as (X) perforate diaphragm at T(8/10/12).

Answer 23

X = vagus n (CN 10)

T10

Question 24

The Aorta as well as (X) perforate diaphragm at T(8/10/12).

Answer 24

X = azygos vein, thoracic duct
T12

“At T-1-2 is the red, white, and blue”

Question 25

The trachea bifurcates at which SC level?

Answer 25

T4 (biFOURcates)

Question 26

The common carotid bifurcates at which SC level?

Answer 26

C4 (biFOURcates)

Question 27

Functional residual capacity calculation:

Answer 27

RV+ERV (volume of gas in lungs after normal expiration)

Question 28

Vital capacity calculation:

Answer 28

IRV + TV + ERV (max volume of gas that can be expired after max inspiration; also equals TLC - RV)

Question 29

Aging changes: (increased/decreased) chest wall compliance, (increased/decreased) lung compliance, and (increased/decreased) (RV/TLC).

Answer 29

Decreased (calcification/stiffening of ribs)
Increased (loss of elastic recoil)
Increased RV; no change in TLC

Question 30

Physiologic dead space equation

Answer 30

VD = VT*((PaCO2-PeCO2)/PaCO2)

“Taco, Paco, Peco, Paco”
VT= Tidal V
PeCo2 = expired air PCO2

Question 31

Physiologic dead space refers to air in:

Answer 31

Conducting zone (aka anatomical dead space) + alveolar dead space (primarily in apices of lungs)

Question 32

T/F: Physiologic dead space is much greater than anatomical dead space in normal lungs

Answer 32

False - the two are approximately equal in healthy lungs (barely any physio dead space), but physiological dead space may be greater if V/Q defect

Question 33

At (X) lung volume, airway/alveolar pressures are zero and intrapleural pressure is (pos/zero/neg).

Answer 33

X = FRC (note: inward pull of lung balanced by outward pull of chest wall at this volume)

Neg (about -5 cm H2O)

Question 34

T/F: Alveolar transmural pressure is always positive, regardless of volume of air in lungs.

Answer 34

True - perpetual collapsing force on lungs

Question 35

Deoxy Hgb has (high/low) oxygen affinity

Answer 35

Low (taut form;promotes release/unloading of O2)

Oxy Hgb is relaxed form and has high affinity for O2

Question 36

Mutations that alter (X) in Hgb will cause lower 2,3-BPG affinity

Answer 36

X = 2,3-BPG binding pocket positive charge

2,3-BPG is negatively charged, so mutation in binding pocket that decreases positive charge will decrease affinity (ex: familial erythrocytosis)

Question 37

The phrenic nerve carries pain fibers from which parts of (visceral/parietal) pleura?

Answer 37

Parietal (diaphragmatic and mediastinal; the rest is via intercostal nerves)

Visceral pleura does not have pain fibers

Question 38

Oxidized form of Hgb is (X). It binds O2 (more/less) readily and patient presents with which unique features?

Answer 38

X = MetHgb (Fe3+ state)
O2 less readily (but high affinity for CO)

Cyanosis (dusky skin) and chocolate-colored blood

Question 39

Carboxyhemoglobin, aka bound to (X), (increases/decreases) Hgb affinity for O2.

Answer 39

X = CO
Increases; curve shifts left (puts Hgb in relaxed, high affinity state)

BUT also binds Hgb competitively with 200x greater affinity (so both lower O2 binding capacity and lower O2 unloading in tissues)

Question 40

(X) Hgb modification Sx: headaches, dizziness, cherry red skin

Answer 40

X = carboxyHgb (CO poisoning)

Question 41

Altitude will (R/L)-shift Hgb curve

Answer 41

R

Question 42

T/F: Normal, healthy lungs are perfusion-limited

Answer 42

True (diffusion-limited examples: emphysema, fibrosis)

Question 43

Which parts of the diffusion equation are (increased/decreased) in emphysema? And in pulm fibrosis?

Answer 43

Equation: V = AD(P1-P2)/T

Emphysema: Decreased area (for diffusion)
Fibrosis: Increased thickness (T)

Question 44

Oxygenation (dips/rises) between alveolar capillary blood and systemic arterial blood. Why?

Answer 44

Dips slightly

Mix of pulmonary vein oxygenated blood with deoxy blood from bronchial and Thebesian veins

Question 45

Pulmonary vascular resistance is lowest at which lung volume?

Answer 45

FRC

Question 46

As lung volume increases, Pulm vasc resistance (increases/decreases) due to (alveolar/extra-alveolar) vessels

Answer 46

Increases;

Alveolar (lower diameter at higher volumes)

Question 47

As lung volume decreases, Pulm vasc resistance (increases/decreases) due to (alveolar/extra-alveolar) vessels

Answer 47

Increases

Extra-alveolar

Question 48

Alveolar gas equation:

Answer 48

PAO2 = PIO2 - (PaCO2/R)

PIO2 is PO2 of inspired air
R is respiratory quotient (CO2 produced/O2 consumed; normally 0.8)

Question 49

Normal A-a (PAO2-PaO2) gradient

Answer 49

10-12 mmHg

Question 50

Main two causes of hypoxemia with normal A-a gradient

Answer 50

Altitude and hypoventilation (ex: opioids, obesity hypovent syndrome)

Question 51

V/Q at base of lung is (0.6/3) and at apex is (0.6/3).

Answer 51

0.6 (wasted perfusion)

3 (wasted ventilation)

Question 52

T/F: Ventilation is greater at apex of lung and perfusion is greater and base of lung

Answer 52

False - both greater at base

Question 53

How does exercise alter the V/Q ratio?

Answer 53

Vasodilation of apical capillaries (causes V/Q to approach 1 instead of 3ish)

Question 54

Pulmonary embolus V/Q ratio:

Answer 54

Infinity (Q = 0); blood flow obstruction, physiologic dead space (an example of V/Q mismatch)

Question 55

Haldane effect seen in (periphery/lungs)

Answer 55

Lungs; O2 displaces H+ from Hgb, promoting CO2 formation/release from RBCs

Question 56

Bohr effect seen in (periphery/lungs)

Answer 56

Periphery; high H+ from metabolism causes R curve shift and promotes O2 unloading

Question 57

Major form of CO2 in blood is carried as:

Answer 57

HCO3-

Question 58

Renal excretion of (H/HCO3) occurs after (X) hours at high altitude. What would the pH, PCO2, PO2 be at that time?

Answer 58

HCO3
X = 24-48
pH = mildly alkalotic
PCO2 = still low 
PO2 = super low (ex: 55 mmHg)

Question 59

T/F: Exercise increases PaO2 and decreases PaCO2

Answer 59

False - values don’t change; but venous CO2 increases and venous O2 decreases

Question 60

(X) sinus is most typically affected in rhinosinusitis. It drains into (Y)

Answer 60

X = maxillary
Y = middle meatus

Question 61

Life-threatening nosebleeds can result from hemorrhage of (X) artery

Answer 61

X = sphenopalatine (branch of maxillary; in posterior segment of nostril)

Question 62

T/F: Both tobacco and alcohol are risk factors for H+N squamous cell carcinoma

Answer 62

True

Question 63

Pre- and post-mortem thrombi can be distinguished by which finding?

Answer 63

Lines of Zahn: inter-digitating areas of pink (platelets, fibrin) and red (RBCs) only in pre-mortem thrombi

Question 64

Clots in pulmonary vasculature staining black with osmium tetroxide

Answer 64

Fat emboli

Question 65

Imaging test of choice of PE:

Answer 65

CT pulm angiography

Question 66

(Proximal/distal) PEs are more likely to cause lung infarct

Answer 66

Distal (under 3 mm, in small aa) since they occlude areas distal to pulmonary and bronchial system anastamoses

Question 67

Curschmann spirals:

Answer 67

Asthma

Shed epithelium forming whorled mucous plugs

Question 68

Charcot-Leyden crystals

Answer 68

Asthma

Formed from eosinophil breakdown in sputum; eosinophilic, hexagonal, needle-like crystals

Question 69

Primary immune cells/response in asthma

Answer 69

Th2 (excess IgE; IL-4, 5, 13 and eosinophils)

Question 70

Primary cells increased/involved in pathogenesis of COPD

Answer 70

Neutrophils (and their elastase);

also macros, CD8 T cells

Question 71

Which (obstructive/restrictive) lung disease associated with Kartagener?

Answer 71

Bronchiectasis (poor ciliary motility); obstructive

Question 72

Asthma: key pathology is (X) (hypertrophy/atrophy)

Answer 72

X = smooth muscle
Hypertrophy and hyperplasia

(Mucous glands as well in chronic asthma)

Question 73

Sudden onset cough, wheezing, tachypnea in 6 yo child. Lungs appear vertically elongated on CXR and you hear pulsus paradoxus on exam.

Answer 73

Asthma

Question 74

Bronchiectasis pathophysiology

Answer 74

Chronic necrotizing infection of bronchi leading to permanently dilated airway

Question 75

Asbestos affects (upper/lower) lung lobes. What about Silica? Coal?

Answer 75

Asbestos: lower (“Asbestos from the roof, but affects base”)

Silica and coal: upper (“Silica and coal from base/earth, but affect roof”)

Question 76

Aerospace industry worker with restrictive lung disease

Answer 76

Berylliosis (non-caseating granulomas, usually upper lungs)

Question 77

Which restrictive lung disease increases susceptibility to TB?

Answer 77

Silicosis (impairs macrophages and disrupts phagolysosomes)

Question 78

Ferruginous bodies can be visualized using (X) stain

Answer 78

X = Prussian (since coated with iron)

Question 79

PCWP in ARDS

Answer 79

Normal (non-cardiogenic pulmonary edema)

Question 80

Distinguishing features between obstructive sleep apnea and Obesity hypoventilation syndrome

Answer 80

OHS/Pickwickian syndrome associated with hypoventilation and high PaCO2 during waking hours as well as during sleep;
OSA not necessarily only in obese patients and involves airways obstruction, snoring, etc.

Question 81

Heritable Pulm HT caused by mutation in (X), the product of which normally has what function?

Answer 81

X = BMPR2 gene (AD inheritance)

Inhibits smooth muscle proliferation

Question 82

Pulm HT Rx:

Answer 82

Bosentan (endothelin-R antagonist)

Question 83

Lungs: Decreased breath sounds, decreased fremitus with hyperresonance on percussion. Differential?

Answer 83

Either simple or tension pneumothorax

Check tracheal deviation (will be away from side of lesion in tension pneumothorax; no deviation in simple)

Question 84

Lungs: decreased breath sounds, dullness to percussion, decreased fremitus. Differential?

Answer 84

Either pleural effusion or atelectasis (bronchial obstruction)

Check tracheal deviation (will be toward side of lesion in atelectasis; no deviation or away from lesion in pleural effusion)

Question 85

(PaO2/PaCO2) is the significant drive for respiration in chronic COPD patients

Answer 85

PaO2 (unlike healthy individuals) due to decreased sensitivity of central chemoreceptors for PaCO2

So carotid bodies sensing increase in PaO2 are responsible for decreasing respiratory rate in these patients

Question 86

Aging: TLC (increases/decreases), RV (increases/decreases), forced VC (increases/decreases).

Answer 86

No change;
Increases
Decreases

Question 87

Obesity effect on lungs:

Answer 87

Obesity-related restrictive lung disease (decline in all lung volumes except minimal effect on RV)

Question 88

Air enters pleural space and can’t exit. Trachea deviated (toward/away from) affected lung

Answer 88

Away from

Tension pneumothorax

Question 89

H. flu and S. aureus cause which type of pneumonia?

Answer 89

Bronchopneumonia (patchy distribution involving 1+ lobes)

Question 90

Non-infectious pneumonia characterized by inflammation of bronchioles and surrounding structures. Negative sputum/blood cultures and non-responsive to antibiotics

Answer 90

COP (Cryptogenic organizing pneumonia); unknown etiology

Question 91

Most common causes of SVC syndrome

Answer 91

1. Lung cancer (superior sulcus aka Pancoast tumor)

2. NHL

Question 92

“Innominate” vein

Answer 92

Brachiocephalic v

Question 93

Lung cancer staining positive for Chromogranin A and synaptophysin

Answer 93

Small cell (neuroendocrine tumor)

Question 94

EML4-ALK Fusion protein codes for (X) and usually seen in (Y) cancer

Answer 94

X = constitutively active Tyr Kinase (like Bcr-Abl)
Y = adenocarcinoma of lung

Question 95

Pseudoephedrine belongs to which class of drugs?

Answer 95

Alpha 1 agonists (like phenylephrine) - used as nasal decongestant

…Also illicitly used to make meth

Question 96

Methylxanthines can be used to treat (X) via which MOA?

Answer 96

X = asthma

Inhibit PDE and thus increase cAMP (by decreasing its hydrolysis)