Respiration

Question 1

What is the primary function of respiration?

Answer 1

Gas exchange

Question 2

What is the pleural space?

Answer 2

A fluid filled sack wrapping around lungs connecting to ribcage

Question 3

Describe the layers of the pleura getting closer and closer to the lungs

Answer 3

Parietal pleura
Intrapleural fluid
Visceral pleura

Question 4

The pressure of the intrapleural space is (positive/negative)

Answer 4

Negative

Question 5

How do lungs operate?

Answer 5

negative pressure pump (mechanical)

Question 6

List the subdivisions of the airways

Answer 6

Trachea, bronchi, bronchioles, terminal bronchioles,

respiratory bronchioles, alveolar ducts, alveolar sacs

Question 7

What are the 4 functions of the conducting pathways?

Answer 7

1. Defense against bacterial infection/foreign particles (Mucociliary defense system)
2. Warm and moisten air
3. Sound/speech
4. Regulation of air flow (smooth muscle can contract/relax to alter resistance)

Question 8

What are the tyo circulations in the lungs?

Answer 8

Pulmonary circulation: brings mixed venous blood to the lungs allowing the blood to get oxygenated

Bronchial circulation: supplies oxygenated blood from the systemic circulation to the tracheobronchial tree (allows the airways to get oxygenated)

Question 9

What are the three types of alveolar cells?

Answer 9

1. Epithelial cells: Type I and II, Type II secretes surfactant, type I we have no idea
2. Endothelial cells: Constitute the walls of the pulmonary capillaries (very thin)
3. Alveolar macrophages (housekeeping/defense)

Question 10

Name the 3 principal and 2 accessory muscles of inspiration

Answer 10

External intercostals
Parasternal intercartilaginous muscles
Diaphragm

Sternocleidomastoid
Scalenus

Question 11

What muscles are involved in quiet expiration?

Answer 11

None (expiration results from passive recoil of lungs)

Question 12

What are the 5 muscles involved in active expiration?

Answer 12

Internal intercostals (except for the parasternal intercartilaginous muscles)
Abdominal muscles
Rectus Abdominis
External Oblique
Internal Oblique
Transversus Abdominis

Question 13

What servical segments provide the phrenic nerves that innervate the diaphragm?

Answer 13

Segments 3, 4, and 5

Question 14

What is tidal volume?

Answer 14

The volume that is expired during normal breathing

Question 15

What is inspiratory reserve volume?

Answer 15

The distance from the maximum of tidal volume to the maximum possible inspiration

Question 16

What is expiratory reserve volume?

Answer 16

The volume of air that can be expelled after expiring from tidal volume

Question 17

What is residual volume?

Answer 17

The volume from 0 to the base of expiratory reserve volume

Question 18

What is Vital capacity?

Answer 18

The amount of air from maximum inspiration to maximum expiration

Question 19

What is functional residual capacity?

Answer 19

The amount of air in the lungs when expiring from tidal volume

Question 20

What is inspiratory capacity?

Answer 20

The amound of air that could be inspired when expiring from tidal volume

Question 21

What is total lung capacity?

Answer 21

The amount of oxygen from maximum inspiration to 0

Question 22

How do you measure FRC?

Answer 22

Patient exhales and places mouth on tube connected to a container filled with radiolabelled gas
inspires labelled gas

You had the initial volume and concentration of the gas, you can calculate the final concentration of the gas, then use C1xV1 = C2xV2

FRC = (C1 x V1/C2) - V1

Question 23

What is minute ventilation and how is it calculated?

Answer 23

The amount of air inspired (or expired) in one minute (V_E)

V_E = V_T x f

Where V_T is tidal volume and f is the numer of breaths per minute

Normally: V_T = 500 mL, f = 12 breaths/min
V_E = 6000 mL/min

Question 24

What is anatomical dead space?

Answer 24

The amount of air that remains in conducting airways during respiration
Approximately 150 mL

Question 25

What is Alveolar ventilation?

Answer 25

The amount of air that actuall reaches lungs

If tidal volume is typically 500 mL
and frequency is typically 12 breaths /min
And anatomical dead space is 150 mL,
then
V_A = (500-150) x 12 = 4200 mL/min

Question 26

What is alveolar dead space? What causes it?

Answer 26

A pathological condition where inspired air reaches the respiratory zone but does not parttake in gas exchange

Caused by Decreased/no blood supply

Question 27

How do you calculate physiological dead space?

Answer 27

V_D = Alveolar + anatomical Dead space

Question 28

What happens to V_A and PaCO2 under normal ventilation?`

Answer 28

V_A matches CO2 and keeps PaCO2 at a constant level

Question 29

What is the PO2 and PCO2 of air?

Answer 29

PO2 = 160 mmHg
PCO2 = 0.3 mmHg

Question 30

What is the PO2 and PCO2 of an alveoli?

Answer 30

PO2 = 105 mmHg
PCO2 = 40 mmHg

Question 31

What is the PO2 and PCO2 of the pulmonary vein and systemic arteries?

Answer 31

PO2 = 100 mmHg
PCO2 = 40 mmHg

Question 32

What is the PO2 and PCO2 of an aerobic cell?

Answer 32

PO2 < 40 mmHg

PCO2 > 46 mmHg

Question 33

What is the PO2 and PCO2 of systemic and pulmonary veins?

Answer 33

PO2 = 40 mmHg
PCO2 = 46 mmHg

Question 34

What happens to PO2 and PCO2 during hyperventilation?

Answer 34

PO2: increases
PCO2: decreases

Question 35

What happens to PO2 and PCO2 during hypoventilation?

Answer 35

PO2: decreases
PCO2: increases

Question 36

According to Fick’s Law, what does diffusion depend on?

Answer 36

Proportional to surface area
Proportional to partial pressure gradient
Inversely proportional to thickness

Question 37

To diffuse through a liquid a gas must be ____ in that liquid

Answer 37

Soluble

Question 38

CO2 is more or less soluble than O2 in water? What is a consequence of this?

Why does that not really matter? ( i mean it does but)

Answer 38

Much more (20 times)

Because of this it diffuses much faster than O2

HOWEVER the difference in PCO2 is 10 times smaller than that for PO2, so they diffuse in almost exactly the same amount of time

Question 39

In what ways (3) does the pulmonary circulation differ from systemic circulation?

Answer 39

• The RIGHT ventricle develops a pressure of 25 mmHg (compared to 120 mmHg in the LEFT)
• Blood pressure in the pulmonary circulation is LOWER than in systemic circulation
• The blood vessels are THINNER and contain less smooth muscle in pulmonary circulation compared to systemic circulation

Question 40

How do you calculate flow?

Answer 40

Flow = Pressure / Resistance

Question 41

What is the total pressure drop from pulmonary artery to left atrium?

Answer 41

10 mmHg

Question 42

What determines the low vascular resistance in pulmonary circulation?

Answer 42

The thin walls of the vascular system
*The low vascular resistance and high compliance of the pulmonary circulation allows the LUNG to accept the whole cardiac output at ALL TIMES

Question 43

What are two ways the pulmonary circulation can accommodate 2- to 3-fold increases in cardiac output with little change in resistance?

Answer 43

Recruitment (opening more vessels)

Distension (dilating already open vessels)

Question 44

Which drugs cause contraction of smooth muscle, and what is a consequence of this?

Answer 44

Serotonin, histamine, norepinephrine

Increased pulmonary resistance

Question 45

Which drugs cause relaxation of smooth muscle and what is a consequence of this?

Answer 45

Acetylcholine and Isoproteranol

Decreased pulmonary resistance

Question 46

What is reflex vasoconstriction?

Answer 46

regions in the lungs that are poorly oxygenated will contract automatically

Question 47

True/False? Pulmonary blood flow is affected by gravity

Answer 47

True (test performed by injecting radioactive xenon in a peripheral vein)

Question 48

What are West’s 3 zones and which receive blood flow?

Answer 48

Top, middle, bottom of lungs
Top receives little blood flow (PA > Pa > Pv)
Middle receives some blood flow (Pa > PA > Pv)
Bottom receives most blood flow (Pa > Pv > PA)

Question 49

What happens to vascular resistance above FRC?

Answer 49

Alveoli increase in size, alveolar vessels stretch longitudinally
Longitudinal stretch causes decrease in diameter, which increases resistance

Question 50

What happens to vascular resistance below FRC?

Answer 50

Alveoly shrink, extra-alveolar vessels collapse because they are not stretched by pulmonary tissues (resistance still increases)

Question 51

True/False? Gravity does not affect the distribution of ventilation

Answer 51

False
In an upright lung at rest, in normal gravity, the alveoli at the top of the lungs are more opened than the bottom ones (think of a slinky)
Can be measured with inhalation of radiolabelled gas

Question 52

What happens to Blood flow and ventilation as you move from the bottom of the ribs to the top?

Answer 52

They decrease (at different rates, sweet spot around rib #3)

Question 53

What is the average value for VA/Q?

Answer 53

1

Question 54

O2 consumption per minute (VO2dot)) is ___ the O2 taken up by the blood in the lungs in one minute

Answer 54

EQUAL

Question 55

Describe the structure of hemoglobin

Answer 55

Each molecule contains 4 subunits bound together
Each subunit is made up of heme joined to a globin
Heme contains Fe++ which can bind one molecule of O2

Question 56

True/False? Hb binds irreversibly to O2

Answer 56

False

Question 57

What is the total amount of O2 bound to Hb? at PO2 of 100 mmHg

Answer 57

19.5% vol

Question 58

Does O2 contribute to PO2 once bound to Hb?

Answer 58

No (but the PO2 of plasma determines the amount of O2 bound to Hb)

Question 59

What does the O2 dissociation curve show?

Answer 59

The amount of O2 carried by Hb at a given partial pressure of O2

Question 60

How does Oxygen “know how to” bind Hb in alveoli and dissociate near aerobic cells?

Answer 60

At low PO2, O2 dissociates from Hb

At high PO2, O2 associates to Hb

Question 61

Why is the O2 dissociation curve a curve and not linear?

Answer 61

Once the first O2 binds, it increases the affinity of the second heme (cooperative binding)

Question 62

What O2 binding molecule is found in skeletal muscle? How is it different from hemoglobin and what is a result of this difference?

Answer 62

Myoglobin, only binds one O2

O2 myoglobin curve is hyperbolic, only releases O2 at very low PO2 (safety measure)

Question 63

What is the Bohr effect? What is a result of it?

Answer 63

The shift in HbO2 dissociation curve to the right when blood CO2 or temperature increases (or when blood pH decreases)
Occurs during exercise

eg. for a given drop in PO2, an additional amount of O2 is released from Hb into the aerobic tissues (releases O2 at higher concentrations)

Question 64

Why is carbon monoxide poisioning a threat?

Answer 64

CO has an extremely high affinity for the O2 binding sites in hemoglobin
Reduces amount of O2 bound to Hb
Shifts O2Hb curve to the left
Doesn’t stimulate increased ventilation because PaO2 remains normal

Question 65

What is the main product of oxidative processes taking place in the body?

Answer 65

CO2

Question 66

What are the three forms of CO2 found in blood?

Answer 66

Straight up CO2 (disolved in blood) 10%
Combined with Hb to form HbCO2 11% (no competition between O2)
As Bicarbonate 79%

Question 67

How is bicarbonate formed?

Answer 67

CO2 + H2O -> H2CO3

H2CO3 -> HCO3- + H+

Question 68

How is CO2 transported in tissue capillaries? In pulmonary capillaries?

Answer 68

CO2 enters RBC from plasma
Forms Bicarbonate + H+
Cl- enters cell to maintain charge balance
(bicarbonate circulates in plasma)

Reverse for Pulmonary capis

Question 69

Why doesn’t CO2 compete with O2 in Hemoglobin?

Answer 69

CO2 binds gloin, whereas O2 binds heme

Question 70

What is the Haldane effect?

Answer 70

In tissue capillaries, O2-free Hb may combine with H+
H+ + HbO2 -> HHb + O2
This occurs because reduced Hb is less acidic than HbO2 (Hb acts as a buffer)

Bottom line: For a given PCO2, more CO2 is carried in deoxygenated blood than oxygenated blood

Question 71

What is the main symptom of respiratory failure? What are the three ways this can happen?

Answer 71

Failure of the respiratory system to do its job
Due to failure in:
- gas exchanging capabilities of the lungs
- Neurol control of ventilation
- Neuromuscular breathing apparatus

Question 72

What are the 5 general causes of hypoxia?

Answer 72

Inhalation of low PO2 (eg low altitude)
Hypoventilation
Ventilation/Perfusion imbalance in the lungs
Shunts of blood across lungs (venous blood bypasses gas exchanging region of lungs)
O2 diffusion impairment (eg thickening of capillary membrane, or edema)

Question 73

Which parts of the brain control voluntary breathing? which control involuntary breathing?

Answer 73

Voluntary: Cerebral hemispheres
Involuntary: brainstem (pons/medulla)

Question 74

What is the breaking point of respiration?

Answer 74

When arterial PCO2 reaches 50 mmHg and PO2 reaches about 70 mmHg, the voluntary control of respiration is overridden

Question 75

What are the two sensors for respiratory control?

Answer 75

Pulmonary receptors (info about lung volume)
Chemoreceptors (info about O2 and CO2 content)

Question 76

What is the controller of respiratory control?

Answer 76

The brainstem (pons and medulla) Gathers info from sensors and integrates them

Question 77

What are the effectors of respiratory control?

Answer 77

Respiratory muscles

Question 78

What are the two respiratory groups of the medulla? What happens if this medullary center is lysed?

Answer 78

Ventral: generates basic rhythm (pacemakers)
Dorsal: receives sensory inputs

Ventral and Dorsal groups talk to each other to determine the afferent rhythm of respiration

Cutting these centres leads to irregular breathing

Question 79

What do cells in the rostral (upper) pons do in relation to breathing? What happens if these pneumotaxic centers are lysed?

Answer 79

They “turn off” breathing, leading to smaller tidal volume and increased breathing frequency

Cutting these centres leads to deep, slow breathing (same effect as cutting vagus nerves which bring afferent information)

Question 80

What happens if you remove the influence of the upper pons and the vagus nerves?

Answer 80

Apneuses (tonic inspiratory activity interrupted by short expirations)

Seen in severe brain injuries

Question 81

What do cells in the apneustic centre (lower pons) do in relation to breathing? what happens if these apneustic centres are lysed?

Answer 81

Send exitatory impulses to respiratory groups of medulla, promotic inspiration

Question 82

What are sensed by chemoreceptors?

Answer 82

PO2, PCO2, and pH in arterial blood
Changes in these cause a change in ventilation
(activity proportional to respiration)

Question 83

What are the two types of chemoreceptors?

Answer 83

Central and peripheral

Question 84

Where are central chemoreceptors located? What do they detect? Where do they detect it?

Answer 84

Located in Ventral surface of medulla

Detect pH of cerebrospinal fluid (CSF) surrounding them *PCO2 and pH are influenced by those of arterial blood

Question 85

What is the term given to elevated CO2 in blood?

Answer 85

Hypercapnia

Question 86

Where are peripheral chemoreceptors located? What do they detect? Where do they detect it?

Answer 86

Mainly sensitive to changes in PO2, but stimulated by increased PCO2 and decreased pH
They are located in carotid bodies and in aortic bodies

Question 87

Increasing PCO2 ____ ventilation at any given PO2

Answer 87

Increases (due to chemoreceptor function)

Question 88

What are the three types of receptors in the lung that respond to mechanical stimuli? How do these impulses travel? what is the result of vagotomy?

Answer 88

Pulmonary stretch receptors
Irritant receptors
Juxta-capillary or J-receptors (C-fibres)

All afferent fibers travel in vagus nerves, vagotomy results in slow, deep breathing

Question 89

Where are pulmonary stretch receptors located?
When do they discharge?
What reflex stimulates them?

Answer 89

Located in smooth muscles of trachea down to terminal bronchioles
Discharge in response to distension of the lung
Main reflex effect is the Hering-Breuer Inflation Reflex (Decrease in respiratory frequency due to prolonged expiratory time)

Question 90

Where are irritant receptors located?
When are they stimulated?
What does their stimulation lead to?

Answer 90

Located between airway epithelial cells in trachea down to respiratory bronchioles
Stimulated by noxious gases, cigarette smoke, histamine, cold air, etc
Stimulation leads to cronchoconstriction and hyperpnea (increased breathing depth)

*may be important in reflex bronchoconstriction triggered by histamine release during allergic asthmatic attack

Question 91

Where are Juxta-Capillary receptors located?
When are they stimulated?
What does their stimulation lead to?

Answer 91

Located in alveolar wall close to capillaries
NONMYELENATED FIBRES
Stimulated by increase in interstitial fluid in lungs
Stimulation leads to rapid and shallow respiration (intense stimulation causes apnea)

May play a role in dypsnea (difficulty breathing)

Question 92

How do you measure the static properties of the lungs?

Answer 92

Elastic properties - recoil pressure
Lung volumes - spirometry
Pressures - manometers
“negative pressure” means below atmospheric

Question 93

Esophageal pressure is approximately equal to what pressure? Why? How can you measure this?

Answer 93

Pleural pressure, because it is located between the two pleural spaces

Measured by inflating a balloon in the esophagus

Question 94

What is compliance and how is it calculated?

Answer 94

The ease at which a structure can be distended
C = dV/dP
Typically measured with static pressure-volume curve

Question 95

How does compliance change as pressure increases?

Answer 95

It gets harder to distend lungs as pressure increases (the slope levels off)

Question 96

What happens to compliance during Emphysema? During Fibrosis?

Answer 96

Emphysema: compliance is greatly increased (very little increase in pressure reaches TLC)

Fibrosis: Compliance is greatly decreased (huge increase in pressure to reach TLC)

Question 97

What is elastance?

Answer 97

1/compliance

Question 98

What happens to the compliance of the chest wall at a) 60% VC? b) 0% VC? c) 100% VC?

Answer 98

a) 0 mmHg (at rest)
b) -40 mmHg (wants to expand outwards)
c) ~15 mmHg (wants to recoil inwards)

Question 99

What happens to pressure at FRC?

Answer 99

Pressure is zero:

The inwards recoil of the lungs is balanced by the outward recoil of the chest wall

Question 100

How is flow calculated in an alveoli?

What happens to these pressures during inspiration? During Expiration?

Answer 100

F = (Palv - Patm)/R

Inspiration: Palv < Patm (F < 0 alvioli expands)
Expiration: Palv > Patm (F >0 alveoli shrink)

Question 101

What prevents you from inspiring indefinitely?

Answer 101

Palv becomes = to Patm, no more flow

Question 102

How are flow and alveolar pressure plotted on a graph?

Answer 102

Sinusodial, IN PHASE

Question 103

Which pressures must be different to have gas flow through airways?

Answer 103

Pao (airway opening) and Palv (alveolar)

Question 104

How do you calculate resistance of an aiway to gas flow (Raw)?

Answer 104

Raw = (Palv - Pao)/Flow

Question 105

Describe the dyanmic compression of airways when a subject inspires to TLC and expires to RV? What is universal about this curve?

Answer 105

During expiration, flow rises very rapidly to a high value then declines over the rest of expiration

The descending portion of the flow/volume curve is independent of effort because the comprassion of the airways is by intrathoracic pressure

Question 106

Describe the various changes to Paw, Ppl and Palv during inspiration to forced expiration

Answer 106

Before inspiration: Paw = 0, Ppl =-5 cm H2O
During inspiration: Ppl and Paw fall
At the end of inspiration, Paw is 0 and the airway transmural pressure is 8 cm H2O
During forced expiration, Ppl and Palv are increased

Because of the pressure drop along the airways as flow begins, there is a point at which there is a positive pressure tending to close the airways

Question 107

How is flow altered during an Obstructive disease such as Emphysema? During a restrictive disease such as Fibrosis?

Answer 107

Obstructive: lung volume shifted to left, FRV slightly smaller than TLC of normal patient, “scooped out” shape, greatly decreased peak flow

Restrictive: TLC slightly larger than normal FRV, FRVs similar, greatly decreased peak flow, “bulgy” appearance