RESPIRATORY PHYSIOLOGY

Question 1

Laryngospasm treatment

Answer 1

1. 100% Fi O2
2. Remove noxious stimuli
3. Deepen anesthetic
4. CPAP 15 - 20 cmH2O
5. Open airway (head extension, chin lift)
6. Larson’s maneuver
7. Succinylcholine (or roc if pt can’t have sux, can be given IM)

Question 2

Describe how the respiratory muscles function during the breathing cycle

Answer 2

Contraction of the inspiratory muscles reduces thoracic pressure and increases thoracic volume.

Example of Boyles Law (Pressure and Volume are inversely proportional)

Question 3

Describe how respiratory muscles function during inspiration

Answer 3

1. Diaphragm and external intercostals contract during tidal breathing
2. Diaphragm increases the superior-inferior dimension of the chest
3. External intercostals increase the anterior-posterior diameter
4. accessory muscles include the sternocleidomastoid and scalene muscles

Question 4

Describe how respiratory muscles function during expiration

Answer 4

Exhalation is usually passive, driven by chest wall recoil

Abdominal musculature (rectus abdominis, transverse abdominis, internal obliques, and external obliques) assist in ACTIVE exhalation

Question 5

What is minute ventilation

Answer 5

Ve is the amount of air (Vt) in a single breath multiplied by the number of breaths per minute

Ve = Vt x RR

Question 6

What is alveolar ventilation

Answer 6

VA only measures the fraction of Va available for gas exchange.

VA = (Vt - anatomic dead space) x RR

Question 7

What is the difference between minute ventilation and alveolar ventilation

Answer 7

Alveolar ventilation measures the fraction of Ve available for gas exchange. It removes anatomic dead space gas from the minute ventilation equation.

Question 8

How is alveolar ventilation related CO2 & PaCO2

Answer 8

VA is DIRECTLY proportional to CO2 production

VA is INDIRECTLY proportional to PaCO2

VA = (CO2 production)/PaCO2

Question 9

What are 4 types of deadspace

Answer 9

Anatomic
Alveolar
Physiologic
Apparatus

Question 10

Define the 4 types of deadspace

Answer 10

ANATOMIC = air in conducting airway

ALVEOLAR = alveoli that are ventilated but NOT perfused

PHYSIOLOGIC = Anatomic Vd + alveolar Vd

APPARATUS = Vd added by equipment

Question 11

Give an example for each type of deadspace (4)

Answer 11

ANATOMIC = nose/mouth to terminal bronchioles

ALVEOLAR = DEC pulmonary BF (i.e. DEC CO)

PHYSIOLOGIC = anything that increases anatomic or alveolar Vd

APPARATUS = facemask, HME, limb of circle system w/ incompetent valve

Question 12

What does the alveolar compliance curve tell you?

Answer 12

Alveolar ventilation is a function of alveolar size and its position on the alveolar compliance curve.

• Best ventilated alveoli are the MOST compliant (steep slope)
• Poorest ventilated alveoli are the LEAST compliant (flat slope)

Question 13

State the alveolar gas equation?

Answer 13

Alveolar Oxygen = FiO2 x (Pb - PH2O) - (PaCO2/RQ)

Question 14

What variables are included in the alveolar gas equation?

Answer 14

FiO2
Pb=Barometric pressure
PH2O = humidity of inhaled gas (47 mmHg)
PaCO2
RQ = Respiratory quotient (0.8)

Question 15

What is the purpose of the alveolar gas equation?

Answer 15

To estimate the partial pressure of O2 in the alveoli

Question 16

How is the alveolar gas equation useful

Answer 16

It can tell us the maximal PAO2 that can be achieved at a given FiO2

Question 17

Define Henry’s Law.

Answer 17

The solubility of a gas in a liquid is directly proportional to the partial pressure of the gas above the liquid

Question 18

How is oxygen content calculated.

Answer 18

CaO2 = (1.34 x Hgb x SaO2) + (PaO2 x 0.003)

Question 19

What is the difference between CaO2 & DO2

Answer 19

CaO2 is how much O2 is in the blood

DO2 is how much O2 is delivered to tissue per minute

Question 20

How is DO2 calculated?

Answer 20

DO2 = CaO2 x CO x 10

Question 21

What does CaO2 measure

Answer 21

Oxygen content in 1 deciliter (100 mL) of blood

Question 22

How is O2 consumption calculated?

Answer 22

VO2 = CO x (CaO2 - CvO2) x 10

Question 23

What 2 ways is O2 carried in the blood

Answer 23

1. Reversibly binds with Hgb (97%)

2. Dissolves in plasma (3%)

Question 24

Equation for O2 bound to Hgb

Answer 24

(1.34 x Hgb x SaO2)

Question 25

Equation for O2 dissolved in plasma

Answer 25

PaO2 x 0.003

Question 26

What is the Fick principle

Answer 26

Oxygen consumption is the difference in oxygenated arterial blood and returning pulmonary venous blood. Thus flow (CO) can be calculated

Question 27

What is the Bohr effect

Answer 27

An increased partial pressure of CO2 and decreased pH causes hgb to release O2.

CO2 and hydrogen ions cause a conformational change in the hgb molecule which causes hgb to release O2

Question 28

What does the oxyhemoglobin dissociation curve describe?

Answer 28

The tendency of hgb to bind O2

Question 29

What is 2,3-DPG

Answer 29

It is produced during RBC glycolysis and stabilizes the deoxygenated form of hgb facilitating O2 release at tissues
(2,3 diphophoglyceric acid)

Question 30

How is 2,3-DPG & the Oxyhemoglobin dissociation curve affected by banked blood

Answer 30

The concentration of 2,3-DPG falls and shifts the dissociation curve left, reducing the amount of O2 available at the tissues

Question 31

How does Hgb F respond to 2,3-DPG and the associated effect on the oxyhemoglobin dissociation curve

Answer 31

Hgb F doesn’t respond to 2,3-DPG which is why there is a left shift (P50 = 19)

Question 32

How does hypoxia affect 2,3-DPG

Answer 32

It increases 2,3-DPG production and facilitates O2 offloading (right shift)

Question 33

What is the Hamburger shift?

Answer 33

Chloride(-) shift into the deoxygenated erythrocyte to maintain neutrality w/ H+. It replaces HCO3-

Question 34

What is the Bohr effect?

Answer 34

Hgb-O2 binding affinity is inversely related to acidity and CO2 concentration

High acidity = low affinity = release(right)

Low acidity = high affinity = lock(left)

Question 35

What is the Haldane effect?

Answer 35

Effect of O2 on CO2 transport

Deoxygenated blood can carry increasing amounts of CO2, whereas oxygenated blood has reduced CO2 capacity

Produces left shift (venous blood becomes more acidic)

Question 36

How is carbonic acid produced in the RBC?

Answer 36

Carbonic anhydrase is an enzyme that facilitates formation of carbonic acid (H2CO3).
Carbonic anhydrase is only found in the erythrocyte

Question 37

What is the result of carbonic acid

Answer 37

rapid dissociation into H+ & HCO3-

Question 38

3 ways that CO2 is transported in the blood. From greatest to least

Answer 38

Bicarbonate (70%)
Carbamino compounds ( (23%)
Dissolved CO2 (7%)

Question 39

What is CO2 solubility compared to O2

Answer 39

CO2 solubility = 0.067 mL/dL/mmHg
It is 20x more soluble than O2

O2 solubility = 0.0031 mL/dL/mmHg

Question 40

How does the CO2 dissociation curve shift in the presence of oxygenated hgb and why?

Answer 40

RIGHT SHIFT

• blood has decreased affinity for CO2
• facilitates CO2 unloading in lungs

Question 41

How does the CO2 dissociation curve shift in the presence of DEOXYgenated hgb and why?

Answer 41

LEFT SHIFT

• Blood has increased affinity for CO2
• Facilitates CO2 loading in systemic capillaries

Question 42

Where in the body is the CO2 dissociation curve right-shifted?

Answer 42

Lungs to facilitate CO2 offloading from Hgb

Question 43

Where in the body is the CO2 dissociation curve left-shifted?

Answer 43

Systemic capillaries to facilitate CO loading on Hgb

Question 44

3 categories of hypercapnia

Answer 44

Increased CO2 production
Decreased CO2 elimination
Rebreathing

Question 45

Examples of reasons for hypercapnia d/t increased CO2 production

Answer 45

sepsis
overfeeding
MH
Intense shivering
Prolonged seizure
Thyroid storm
Burns

Question 46

Examples of reasons for hypercapnia d/t decreased CO2 elimination

Answer 46

Airway obstruction
Increased DS
Increased Vd/Vt
ARDS
COPD
Respiratory center depression
Drug OD
Inadequate NMB reversal

Question 47

Examples of reasons for hypercapnia d/t rebreathing

Answer 47

Exhausted soda lime
incompetent unidirectional valve in circle system
inadequate FGF

Question 48

Hypercapnia effects on P50

Answer 48

RIGHT shift

Release more O2

Question 49

Hypercapnia effect on cardiac and smooth muscle depression

Answer 49

CO2 is myocardial depressant and directly dilates peripheral vasculature

It activates SNS, increasing catecholamine release from adrenal medulla

Question 50

Result of hypercapnia on cardiac rate and rhythm changes

Answer 50

Tachycardia, increasing myocardial O2 consumption and decreasing O2 delivery
Dysrhythmias
Prolonged QT interval

Question 51

Hypercapnia effect on pulmonary vascular resistance

Answer 51

Increases PVR

CO2 constricts pulmonary vasculature, increasing PVR and workload of right heart

Question 52

Hypercapnia effect on alveolar ventilation

Answer 52

Increases alveolar ventilation d/t CO2 stimulating effects and increases in Ve

Question 53

Hypercapnia effect on K+

Answer 53

INCREASES K+
d/t activation of H+/K+ pump
Buffers CO2 acid in exchange for releasing K+ into plasma

Question 54

Hypercapnia effect on Ca++

Answer 54

INCREASES Ca++

iCa++ competes w/ H+ for binding sites on plasma proteins

Question 55

Acidosis/Alkalosis effects on Ca++/H+ binding

Answer 55

Acidosis = plasma proteins buffer H+ and release Ca++ (increase inotropy)

Alkalosis = plasma proteins release H+ and bind Ca++ (decrease inotropy)

Question 56

Hypercapnia effect on ICP

Answer 56

INCREASES

Decreased CSF pH leads to decreased cerebrovascular resistance and increased CBF/volume

Question 57

Hypercapnia effect on LOC

Answer 57

CO2 narcosis

Question 58

How do the kidneys handle acidosis

Answer 58

Kidneys excrete H+ and conserve HCO3- to return pH to normal

Question 59

How much does acute respiratory acidosis decrease pH

Answer 59

For every 10 mmHg >40 mmHg, pH decreases by 0.08

Question 60

How much does chronic respiratory acidosis decrease pH, and why is this different than acute?

Answer 60

For every 10 mmHg >40 mmHg, pH decreases by 0.03.

d/t HCO3- retention by the kidneys

Question 61

What does a right shift of the CO2 response curve demonstrate?

What are contributing examples?

Answer 61

That the respiratory center is LESS sensitive to CO2

Sevoflurane
s/p CEA
Opioids 
NMBs
Metabolic alkalosis

Question 62

What does a left shift of the CO2 response curve demonstrate?

What are contributing examples?

Answer 62

That the respiratory center is MORE sensitive to CO2

Hypoxemia
Salicylates
Surgical stimulation
Intracranial HTN
Metabolic acidosis

Question 63

What does the CO2 ventilatory response curve describe?

Answer 63

The relationship between PaCO2 and minute ventilation

Question 64

Where is the primary monitor of PaCO2 and what type is it?

Answer 64

Where = Medulla

Type = central chemoreceptors

Question 65

What is the apneic threshold?

Answer 65

It is the highest PaCO2 which a person will not breathe

When PaCO2 is greater than apneic threshold, the patient will begin to breathe

Question 66

What locations play a secondary role in monitoring in monitoring PaCO2

Answer 66

Carotid bodies
Transverse aortic arch

Peripheral chemoreceptors

Question 67

What does the slope of the CO2 ventilatory response curve indicate

Answer 67

The sensitivity of the entire respiratory apparatus to PaCO2

Question 68

At what level (mmHg) does CO2 become a respiratory depressant?

Answer 68

PaCO2 >80-100 mmHg

Question 69

How is minute ventilation affect by shifts in the CO2 ventilatory response curve?

Answer 69

Left shift = Ve is higher than expected for a given PaCO2, creating respiratory alkalosis

Right shift = Ve is lower than expected for a given PaCO2, creating respiratory acidosis

Question 70

How does the CO2 ventilatory response curve impact apneic threshold

Answer 70

Left shift = apneic threshold is decreased

Right shift = apneic threshold increased

Question 71

What is the pacemaker for normal breathing?

Answer 71

Dorsal respiratory center

Question 72

What is the role of the pneumotaxic center

Answer 72

To inhibit DRC, the pacemaker for breathing

Question 73

What is the role of the apneustic center

Answer 73

To stimulate the DRC

Question 74

What does the ventral respiratory center control

Answer 74

Responsible for expiration

Question 75

Where is the respiratory center located and what is the primary job?

Answer 75

In the reticular activating system in medulla and pons

Job = to determine how fast and deep you breath. REgulation of PaCO2 and PaO2

Question 76

Describe the afferent input, integration and modifier of the respiratory center

Answer 76

Afferent input = from central and peripheral chemoreceptors, lung stretch receptors

Integration = incoming signals w/ intrinsic respiratory pattern and sending a coordinated response to muscles of respiration

Question 77

What are the medullary respiratory centers

Answer 77

Dorsal respiratory group

Ventral respiratory group

Question 78

What are the pontine respiratory centers

Answer 78

Pneumotaxic center (UPPER pons)

Apneustic center (LOWER pons)

Question 79

What are the 4 determinants of respiratory rate and pattern

Answer 79

1. Neural control in respiratory center - Medulla
2. Chemical control in the central chemoreceptors - medulla
3. Chemical control in peripheral chemoreceptors - carotid bodies, aortic arch
4. Baroreceptors - lungs

Question 80

Where does the respiratory center receive afferent input from

Answer 80

Central and peripheral chemoreceptors

Lung stretch receptors

Question 81

What does new evidence report is the respiratory pacemaker

Answer 81

The central pattern generator, which includes:
DRG
pre-Botzinger complex (in VRG)
Other medullary structures

Question 82

What stimulates the central respiratory chemoreceptors and where is this located

Answer 82

pH changes in the CSF and PaCO2

location = ventral surface of medulla

Question 83

What byproduct freely diffuses across BBB

Answer 83

CO2

Question 84

Which ions do not freely diffuse across the BBB in relationship to respiration

Answer 84

H+ and HCO3-

Question 85

How does H+ and HCO3- enter CSF

Answer 85

CO2 dissociates into H+ and HCO3-

Question 86

How does H+ concentration in CSF affect respiration

Answer 86

Increases rate and depth of respirations until new steady state is achieved

Question 87

How long do effects of hyperventilation reduce ICP

Answer 87

a few hours to 2 days

Question 88

What substances can freely diffuse across CSF

Answer 88

Some gases and lipid soluble molecule

Question 89

The concentration of which ion in the CSF is most important for stimulating the central chemoreceptors of the respiratory center?

Answer 89

H+

Question 90

What type of relationship does H+ CSF concentration have with respiratory rate and depth

Answer 90

Direct relationship, as H+ rises so do rate and depth of respirations

Question 91

How doe ions, glucose and amino acids travel across the BBB

Answer 91

Active transport mechanisms

Question 92

What is the difference in response of central versus peripheral chemoreceptors

Answer 92

Central chemoreceptors respond to PaCO2

Peripheral chemoreceptors respond to PaO2

Question 93

What type of cells mediate peripheral chemoreceptor hypoxic ventilatory drive ?
How?

Answer 93

Type 1 Glomus cells

sense and transduce PaO2 into an action potential

Question 94

What nerve makes up the AP of the afferent limb of the peripheral chemoreceptor response

Answer 94

AP is propagated along the afferent limb of Hering’s nerve and glossopharyngeal nerve (CN 9)

Question 95

How does CEA affect peripheral chemoreceptor function?

Answer 95

It impairs function on the ipsilateral side

Question 96

What is the chief responsibility of the carotid bodies

Answer 96

To monitor hypoxemia

Question 97

Do the carotid bodies or transverse aortic arch chemoreceptors respond to SaO2 or CaO2?

Answer 97

No

Question 98

Why aren’t bilateral CAE performed simultaneously?

Answer 98

Because CEA severs the afferent limb of the hypoxic ventilatory response and takes time for recalibration

Question 99

Where are the carotid bodies located

Answer 99

at the bifurcation of the common carotid artery

Question 100

What are secondary responsibilities of the carotid bodies

Answer 100

Monitoring PaCO2, H+, perfusion pressure

Question 101

What layer are the carotid bodies located?

Answer 101

Adventitia

Question 102

Describe the hypoxic ventilatory response to hypoxemia (5)

Answer 102

1. Decreased PaO2 closes O2-sensitive K+ channels in Type 1 glomus cells
2. Resting membrane potentials rise d/t altered K+, Ca++ channels open and increase NT release of Ach and ATP
3. An AP is propagated via Hering’s nerve and glossopharyngeal nerve (CN 9)
4. The afferent path terminates in the inspiratory center of medulla (DRG)
5. Ve increase to restore PaO2

Question 103

Conditions that impair hypoxic ventilatory response

Answer 103

CEA

Sub-anesthetic doses of inhalation and IV anesthetics

Question 104

What is the Hering-Breuer inflation reflex

Answer 104

lung hyperinflation turns off the respiratory drive to avoid overinflation

Question 105

Hering-Breuer deflation reflex

Answer 105

Activates the respiratory drive when lung volume is too small to prevent atelectasis

Question 106

What are J receptors

Answer 106

Pulmonary C-fiber receptors

Increases the respiratory rate in the setting of PE or CHF

Question 107

How is ventilation controlled in the lungs

Answer 107

Stretch receptors in the smooth airway muscles which transduce pressure conditions inside the airway

Question 108

What nerve transduces the pressure conditions inside lung smooth muscle and to where

Answer 108

Vagus nerve (CN 10)
To the dorsal respiratory center (DRG, respiratory PM)