Respiratory-Physiology

Question 1

Question 2

What is inspiratory reserve volume?

Answer 2

air that can still be inspired after normal tidal inspiration

Question 3

What is tidal volume?

Answer 3

Air that moves into the lung with each quiet inspiration, normally 500 mL

Question 4

What is exspiratory reserve volume?

Answer 4

air that can still be breathed out after normal expiration

Question 5

What is residual volume?

Answer 5

The total amount of air remaining in the lung after maximal expiration (cannot be measured on spirometry)

Question 6

What is inspiratory capacity?

Answer 6

IRV +TV

Question 7

What is functional residual capacity?

Answer 7

RV + ERV (cannot be measured on spirometry because it includes residual volume)

Question 8

What is vital capacity?

Answer 8

TV + IRV + ERV, or the maximum volume of gas that can be expired after a maximal inspiration

Question 9

What is total lung capacity?

Answer 9

IRV + TV + ERV+ RV (cannot be measured on spirometry)

Question 10

What is physiologic dead spead?

Answer 10

Vd= the anatomic dead space of conducting airways plus alveolar dead space, or the volume of inspired air that does not participate in gas exchange

Question 11

What is the eqn for physiologic dead space?

Answer 11

Vd= Vt *((PaCo2- PECo2)/PaCo2), where

Vt= tidal volume

PaCo2= arterial Co2

PeCo2= expired air Co2

Taco Paco Peco Paco

Question 12

What part of the lung is the largest contributor of alveolar dead space?

Answer 12

the apex

Question 13

What is the eqn for minute ventilation?

Answer 13

total volume of gas entering the lungs per minute

Ve= Vt*RR

Question 14

What is the eqn for alveolar ventilation?

Answer 14

Volume of the gas per unit time that reaches the alveoli

Va= (Vt-Vd)*RR

Question 15

What is a normal physiological dead space volume?

Answer 15

150 mL/breath

Question 16

Compliance increases in what kinds of lung disease?

Answer 16

obstructive, such as emphysema, and in normal aging

Question 17

Compliance decreases in what kinds of lung disease?

Answer 17

Restrictive disease, such as Pulmonary fibrosis, pneumonia, and pulmonary edema

Question 18

What is hysteresis?

Answer 18

the fact the the lung inflation curve is different than that of the deflation curve due to the need to overcome surfac tension to expand

Question 19

What is the structure of hemoglobin?

Answer 19

4 polypeptide subunits, 2 alpha, and 2 beta

Question 20

What are the conformations of hemoglobin?

Answer 20

T (taut) and R (relaxed)

Taut near tissue and

Relaxed near respiratory areas

Question 21

What are some characteristics of taut hemoglobin?

Answer 21

This form has LOW affinity for O2, thus promoting release/unloading of oxygen (whereas hemoglobin in a relaxed form would be more likely to hold onto oxygen)

Question 22

What things promote a taut orientation of hemoglobin?

Answer 22

increased Cl-, CO2, H+ (acidotic), 2-3-BPG, and increased temp all favor a RIGHT SHIFT of the dissociation curve for increased o2 unloading

Question 23

What is the composition of fetal hemoglobin?

Answer 23

2a and 2y subunits that have HIGHER affinity for O2 than adult Hb, driving duffion of oxygen across the palcenta to the fetus

NOTE: a higher affinity for O2 moves the fetal oxygen-hemoglobin dissociation curve to the LEFT

Question 24

What is methemoglobin?

Answer 24

A modified form of hemoglobin in which the central iron is in a ferric (Fe3+) state that does NOT bind O2 as readily, but has increased affinity for cyanide

NOTE: Iron in normal hemoglobin is an Fe2+ state

Question 25

How might someone with methemoglobemia present?

Answer 25

cyanosis and chocolate-colored blood

Question 26

How can methemoglobinemia be treated?

Answer 26

methylene blue and vitamin C

Question 27

What are some things that cause methemoglobinemia?

Answer 27

nitrates and benzocaine

Question 28

How can methemoglobinemia be used medically to our advantage?

Answer 28

It can be medically induced using nitrrites followed by thiosulfate to treat cyanide poisoning

Question 29

How would carboxyhemoglobin be treated?

Answer 29

100% O2

Question 30

Describe these curves

Answer 30

Hemoglobin has a sigmodial curve due to positive cooperativity of O2 binding by successive hemoglobin subunits, while myoglobin does not exhibit this property

Question 31

What happens when the oxygen-hemoglobin dissociation curve shifts to the right?

Answer 31

There is decreased affinity of Hb for O2, which facilitates easier unloading of O2 into tissue

Question 32

What things cause a right shift of the oxygen-hemoglobin dissociation curve?

Answer 32

Right shift: ACE BATs right

Acid

Co2

Exercise

2,3-BPG

Altitude

Temperature

Question 33

Which shift, right or left, of the oxygen-hemoglobin dissociation curve would cause increased EPO synthesis?

Answer 33

left because O2 is not being unloaded as easily leading to hypoxia

Question 34

What is the eqn for the oxygen content of blood?

Answer 34

(1.34*Hb*SaO2) + (0.003*PaO2)

Hb= hemoglobin levels

SaO2= arterial O2 saturation

Question 35

T or F. With decreased hemoglobin, there is decreased O2 content of blood but no change in O2 saturation and PaO2

Answer 35

T.

Question 36

What is the eqn for O2 delivery to tissue?

Answer 36

CO x O2 content of blood

Question 37

How does CO poisoning affect Hb concentration? SaO2? PaO2? Total O2 content?

Answer 37

Hb concentration- normal

SaO2- decreased

PaO2- normal

Total O2 content- decreased

Question 38

How does anemia affect Hb concentration? SaO2? PaO2? Total O2 content?

Answer 38

Hb concentration- decreased

SaO2- normal

PaO2- normal

Total O2 content- decreased

Question 39

How does polycythemia affect Hb concentration? SaO2? PaO2? Total O2 content?

Answer 39

Hb concentration- increased

SaO2- normal

PaO2-normal

Total O2 content- increased

Question 40

How does hypoxia affect the pulmonary circulation?

Answer 40

Normally it is a low-resistance, high-compliance system but in the absence of adequate oxygen, hypoxic vasoconstriction occurs that helps shift blood away from poorly ventilated regions

Question 41

What are some situations of gas exchange that are perfusion limited?

Answer 41

O2 in normal states, CO2, N2O

In these states, diffusion can only be increased if blood flow increases

Question 42

What are some situations of gas exchange that are diffusion limited?

Answer 42

emphysema and fibrosis, CO

In these states, gas does not equilibrate by the time blood reaches the end of a capillary

Question 43

What is the eqn for diffusion of a gas?

Answer 43

Diffusion= A*Dk*(P1-P2)/T, where

A= area

Dk(P1-P2)= difference in partial pressure

T= thickness of wall

Question 44

What variable of the gas exchange eqn is changed in emphysema?

Answer 44

A is decreases

Question 45

What variable of the gas exchange eqn is changed in pulmonary fibrosis?

Answer 45

T is increased

Question 46

What is the eqn for pukmonary vascular resistance?

Answer 46

PVR= (Ppulm a.- Pleft atrium)/CO

Question 47

What is the eqn for alveolar gas exchange?

Answer 47

pAO2= PIo2- PaCO2/R, where

pA02= alveolar O2

PaCO2= arterial Co2

R= respiratory quotient, or Co2 produced at tissue/O2 consumed

Question 48

Normal alveolar gas eqn.

Answer 48

PAO2= 150- PaCo2/0.8

Question 49

What is the A-a gradient?

Answer 49

PAo2- PaO2

Normal= ~10 mm Hg

Question 50

What things can make an A-a gradient increase?

Answer 50

hypoxia caused by shunting, V/Q mismatch, and fibrosis

Question 51

What is hypoxia?

Answer 51

decreases O2 delivery to tissue

Question 52

What are some causes of hypoxia?

Answer 52

decreased CO, anemia, CO poisoning, and hypoxemia

Question 53

What is hypoxemia?

Answer 53

decreased PaO2

Question 54

What are some causes of hypoxemia with a NORMAL A-a gradient?

Answer 54

high altitude and hypoventilation (i.e. overdose)

Question 55

What are some causes of hypoxemia with an INCREASED A-a gradient?

Answer 55

V/Q mismatch, Diffusion limitation (fibrosis), Right-to-left shunt

Question 56

What are the V/Q ratios in different parts of the lung?

Answer 56

Apex= 3 (wasted ventilation)

Base= 0.6 (wasted blood flow/perfusion)

Question 57

T or F. Both ventilation and perfusion are greater at the base of the lung compared to the apex

Answer 57

T.

Question 58

What happens to the V/Q ratio with exercise?

Answer 58

vasodilation of apical capillaries occurs, and the V/Q ratio approaches 1

Question 59

What kinds of organisms would thrive in the apex of the lung?

Answer 59

Aerobes like TB

Question 60

A V/Q of/near zero suggests what?

Answer 60

airway obstruction (shunt). I.e. foreign body aspiration

In a shunt, 100% O2 WILL NOT improve PaO2

Question 61

A V/Q of/near infinity suggests what?

Answer 61

blood flow obstruction (i.e. pulmonary embolism)

In this case 100 O2 WILL improve PaO2

Question 62

What are the pressure ratios in the apex of the lung?

Answer 62

PA > Pa > Pv

Question 63

What are the pressure ratios in the middle of the lung?

Answer 63

Pa > PA > Pv

Question 64

What are the pressure ratios in the base of the lung?

Answer 64

Pa > Pv > PA

Question 65

How is Co2 transported from tissue?

Answer 65

3 forms:

as HCO3- (90%)

carbaminohemoglobin (5%)

Dissolved CO2 (5%)

Question 66

Describe venous transport of Co2 via carbaminohemoglobin

Answer 66

In this case Co2 is bound to Hb at the N-terminus of globin (not heme).

Question 67

How is Co2 converted to HCO3?

Answer 67

. CO2 released from tissue enters RBCs where carbonic anhydrase converts it to H2CO3, which then dissociates to H+ and HCO3-. HCO3- leaves the cell in exchange for Cl-

Question 68

Study more about Haldane, Bohr, and other effects of Co2, O2 exchnage in hemoglobin

Question 69

How does the body respond to high altitude?

Answer 69

decreased PiO2 leads to decreased PaO2 leading to increased ventilation, pushing off more PaCO2 leading to a short state of respiratory alkalosis. The kidneys then respond by pushing off HCo3-

Study more from pulm

Question 70

How else does the body react to altitude?

Answer 70

EPO increases and 2,3-BPG also increases to improve O2 unloading at tissues due to the hypoxia

The lungs respond to hypoxia by vasoconstricting which can lead to pulmonary hypertension

Question 71

How do the lungs respond to exercise?

Answer 71

CO2 production increases, as does O2 consumption, leading to ventilation increasing and V/Q ratios throughout the lung becoming more uniform

Question 72

How do PaO2 and PaCo2 change in exercise?

Answer 72

They dont, but there is an increase in venous Co2 content and a decrease in venous O2 content