Resp Function Tests

Question 1

Spirometry Aim

Answer 1

Diagnostic tool to assess lung disease, quantify lung impairment, monitor the effects of occupational/environmental exposure + determine effects of medications

Question 2

Spirometry Description

Answer 2

Measure expired + inspired air
Volume, time and flow
Measure FEV1 and VC

Question 3

Hering-Breuer Reflex

Answer 3

Reflex triggered to prevent over-inflation of the lung

Question 4

Obstructive defect

Answer 4

FEV1 more reduced than VC
FEV1/VC <75%
Asthma
COPD

Question 5

Restrictive defect

Answer 5

FEV1 reduced no more than VC
FEV1/VC ratio >75% and may be 100%
VC reduced

Question 6

Peak flow measurement

Answer 6

Only valid if done at TLC and with max effort

Question 7

Peak flow reduction

Answer 7

Large airway obstruction
Upper airway obstruction
Asthma

Question 8

Peak flow less affected in

Answer 8

COPD

Small airway disease

Question 9

Interpreting Spirometry data

Answer 9

In adults, age, height, sex + race main determinants

Question 10

Reduced inspiratory limb flow with normal expiratory flow

flow vol loop

Answer 10

Extra-thoracic obstruction

Question 11

Equal reduction in both flows

flow vol loop

Answer 11

Intrathoracic obstruction

e.g. retrosternal goitre

Question 12

Obstructive Flow vol loop

Answer 12

Shifts to left
Scoop in top bit, and smaller top bit
Same bottom bit

Question 13

Restrictive flow vol loop

Answer 13

Shifts to right

Exact same shape as normal but smaller

Question 14

FEV1/FVC ratio

Answer 14

Ratio of Forced Expiratory volume in 1 sec + forced vital capacity

Question 15

FEV1/FVC ratio incorrect in

Answer 15

Asian communities

Question 16

Total lung capacity measurement

Answer 16

Inspiration of gas mixture which includes helium, with rebreathing and VC manoeuvre for mixing
Dilution of helium + decrease in concentration x VC gives TLC

Question 17

Alveolar volume + gas transfer calculation

Answer 17

Single large breath of air + CO + helium

Hold breath for 10 seconds

Question 18

TLCO equation

Answer 18

KCO x Ca

Question 19

Decreased TLCO

Answer 19

Decrease perfusion
Decrease ventilation
V/Q mismatch
Anaemia

Question 20

Increased TLCO

Answer 20

Increased CO
Polycythaemia
Alveolar haemorrhage

Question 21

The Fick principle

Answer 21

the volume of gas per unit time which diffuses across a tissue sheet is proportional to:

• proportional to area of sheet
• inversely proportional to thickness
• proportional to difference in pressure on 2 sides
• dependent upon permeability coefficient for that gas

Question 22

Fick equation

Answer 22

Volume/time = area/thickness x pressure (P2-P1) x diffusion constant

Question 23

Diffusion constant

Answer 23

Dependent on solubility + molecular weight of gas

More soluble, easier to pass

Question 24

Graham’s law

Answer 24

Rate of diffusion of a gas is inversely proportional to the square root of molecular weight
Bigger things diffuse more slowly

Question 25

Gas transfer reduced with

Answer 25

Reduced SA
Increased thickness of membrane
Reduced O2 conc.
Inadequate time

Question 26

DLCO/TLCO

Answer 26

Measures how efficient lungs are at exchanging gases

Ability of lungs to transfer gas from inhaled air to RBCs

Question 27

Haemoglobin binding

Answer 27

CO>O2 (200-250x)

Question 28

DLCO

Answer 28

Lung SA available for gas exchange (Va) x rate of capillary blood CO uptake (Kco)

Question 29

DLCO/TLCO

Answer 29

Quantity of CO transferred per min from alveolar gas to red blood cells (mL/min/mmHg)

Question 30

DLCO/TLCO normal

Answer 30

> 75%

Question 31

Increased DLCO

Answer 31

Exercise
Supine
Pulmonary haemorrhage
Polycythemia
Obesity
Left to right shunt- atrial septal defect
Muller manoeuvre- inspiration against closed mouth + nose after expiration

Question 32

Decrease DLCO

Answer 32

Post exercise
Standing
Valsava manoeuvre 
Lung resection
Pulmonary emphysema
Interstitial lung disease

Question 33

ILD

Answer 33

Decreased DLCO due to decreased Kco (fibrosis of interstitium)
Useful for early ILD detection