Physiology Review Book Notes Flashcards

Question 1

Q

What are the 2 main portions of the respiratory system? And what is the general fcn of each?

Answer

A

Conducting Portion: ventilation/to warm, humidify & filter the air
Respiratory Portion: gas exchange

Question 2

Q

What structures are a part of the conducting portion?

Answer

A

nose, nasopharynx, larynx, trachea, bronchi, bronchioles, terminal bronchioles

Question 3

Q

When particles in the air are not removed in the nose…how are they removed in the conducting portion?

Answer

A

they are captured by mucus along the conducting portion b/c there are mucus-secreting cells…then they are swept upward by the rhythmic beating of the ciliated cells…

Question 4

Q

Explain the sympathetic & parasympathetic innervation of the conducting portion.

Answer

A

Smooth muscle lines the conducting airways.
These are innervated by nerve fibers.
Sympathetic: acts on beta 2 receptors & causes dilation.
Parasympathetic: acts on muscarinic receptors & causes constriction.

Question 5

Q

What are 3 substances that can be used to treat asthma? Why are they useful?

Answer

A

Epinephrine (released by the adrenal medulla sometimes)
Isoproterenol
Albuterol
**these are all beta 2 agonists
**they cause dilation of the airways...

Question 6

Q

Which structures are a part of the respiratory portion?

Answer

A

Respiratory Bronchioles
Alveolar Ducts
Alveolar Sacs

Question 7

Q

Why are respiratory bronchioles considered a part of the respiratory portion? What characteristics do they share w/ the conducting portion?

Answer

A

They share the characteristics of cilia & smooth muscle…

But they are considered a part of the respiratory b/c sometimes alveoli bud off their walls.

Question 8

Q

What are the characteristics of the alveolar ducts & the alveolar sacs?

Answer

A

Alveolar Ducts: completely lined w/ alveoli
no cilia & only a little smooth muscle…
Alveolar Sacs: termination of the alveolar ducts…totally lined w/ alveoli…NO smooth muscle or cilia, however.

Question 9

Q

What makes alveoli a good structure for gas diffusion?

Answer

A

thin walls

large surface area for diffusion

Question 10

Q

What makes up the walls of the alveoli?

Answer

A

elastic fibers

epithelial cells: Type 1 & 2 pneumocytes.

Question 11

Q

Which epithelial cell type makes surfactant?

Answer

A

Type II pneumocytes

Question 12

Q

Which epithelial cell type can reproduce & regenerate both cell types?

Answer

A

Type II pneumocytes…

Question 13

Q

What does the body do when debris finds its way all the way down by the alveoli?

Answer

A

It uses its alveolar macrophages. Macrophages eat the debris & move toward the bronchioles.
The cilia are at this level again & they beat the debris up to be swallowed or whatever…

Question 14

Q

Where does the main source of blood flow to the lungs come from? What is it called?

Answer

A

Pulmonary blood flow (pulmonary arteries) pumped out of the right ventricle…basically cardiac output. This is the source of blood flow that participates in gas exchange.

Question 15

Q

Aside from pulmonary arteries…what is the more minor source of blood flow to the lungs?

Answer

A

Bronchial arteries…don’t participate in gas exchange…supplies the tissues of the conducting portion of the respiratory system…

Question 16

Q

How is pulmonary blood flow regulated?

Answer

A

Altering the resistance of the pulmonary arterioles…

controlled by local factors: mainly O2

Question 17

Q

T/F In the supine position, the blood flow is equal at different parts of the lungs.

Question 18

Q

T/F In the standing position, the blood flow is equal at different parts of the lungs.

Answer

A

False.
due to gravitational effects…it is not equal…
Apex has low blood flow
Base has high blood flow

Question 19

Q

How are static volumes of the lung measured?

Answer

A

Spirometer

Question 20

Q

Normal breathing involves the inspiration & expiration of _______….

Answer

A

a tidal volume, about 500 mL

Question 21

Q

What makes up the tidal volume?

Answer

A

about 500mL the amount of air in the alveoli & the airways…

Question 22

Q

What is considered the inspiratory reserve volume? What is its approximate volume?

Answer

A

the extra amount above the tidal volume that you can inspire during maximal inspiration…about 3000 mL

Question 23

Q

What is considered the expiratory reserve volume?

What is its approximate volume?

Answer

A

the extra amount below the tidal volume that you can expire during maximal expiration….about 1200 mL

Question 24

Q

What is the residual volume? What is its approximate value?

Answer

A

The amount of air that is left over in the lungs even after maximal expiration…about 1200 mL

Question 25

Q

What is inspiratory capacity?

Answer

A

Tidal Volume + Inspiratory Reserve Volume

Question 26

Q

What is functional residual capacity?

Answer

A

Expiratory Reserve Volume + Residual Volume

**amount left in lungs after expiring normal tidal volume…

Question 27

Q

What is total lung capacity?

Answer

A

Everything added together, including residual volume.

Question 28

Q

What is vital capacity?

Answer

A

inspiratory reserve volume + tidal volume + expiratory reserve volume
**expiration ability after maximal inspiration

Question 29

Q

What are the 2 capacities that can’t be measured using spirometry? Why? Which is more important to find another way to measure?

Answer

A

Functional Residual Capacity & Total Lung Capacity

*both include residual volume
*FRC is more important

Question 30

Q

What are the 2 weird methods by which you can measure FRC?

Answer

A

Helium Dilution

Body Plethysmograph

Question 31

Q

What is dead space? What are the 2 types?

Answer

A

Volume of the airways & lungs the does not participate in gas exchange…
Anatomic Dead Space
Physiologic Dead Space

Question 32

Q

What is anatomic dead space?

Answer

A

The amount of air that naturally gets caught in areas of the lungs that do NOT participate in gas exchange…
Ex: conducting airways.
Volume is usu 150 mL

Question 33

Q

If you want to get a sample of alveolar air…which part of the air do you want to capture?

Answer

A

the end-expiratory air…b/c the air caught in the conducting airways/anatomic dead space is the air that comes out first….

Question 34

Q

What is physiological dead space?

Answer

A

total volume of the lungs that does not participate in gas exchange…
anatomic dead space + functional dead space…

Question 35

Q

What is functional dead space?

Answer

A

the amount of space in the lungs, esp the alveoli that does not participate in gas exchange…
**ventilated alveoli that don’t participate in gas exchange…

Question 36

Q

What is the main reason for functional dead space?

Answer

A

mismatch of ventilation & perfusion…when ventilated alveoli aren’t perfused by pulmonary capillary blood…

Question 37

Q

What is the idea behind measuring physiological dead space? What is the equation?

Answer

A

compare the amount of CO2 in the expired air & the capillary CO2=alveolar CO2.
Higher the dead space, lower the expired air CO2 compared to alveolar CO2.
Vdead=Vtidal volume X PaCO2-PECO2/PaCO2

Question 38

Q

What is minute ventilation?

Answer

A

the total rate of air movement into & out of the lungs in a minute…
Minute Ventilation = Vt X RR

Question 39

Q

What is alveolar ventilation?

Answer

A

ventilation rate that takes into account dead space…
Alveolar Ventilation:
Va = (Vt-Vd) X RR

Question 40

Q

What is the alveolar ventilation equation that includes the term PACO2? What relationship does this show?

Answer

A

VA=VCO2 X K/PACO2

**it shows that the alveolar ventilation is inversely proportional to the arterial & alveolar CO2 concentration…

Question 41

Q

What is K equal to in the alveolar ventilation equation?

Answer

A

K=863 mmHg normally…

Question 42

Q

What 2 variables determine alveolar PCO2?

Answer

A

CO2 production in the tissues
alveolar ventilation (how much CO2 you get rid of thru expiration)

Question 43

Q

If CO2 production is constant, then what determines PACO2?

Answer

A

Alveolar Ventilation

Question 44

Q

In the alveolar ventilation equation what value can we put in for PACO2?

Answer

A

PaCO2…the arterial PCO2 b/c there is an equilibrium b/w capillaries & alveoli & PaCO2 can actually be measured…

Question 45

Q

An increase in alveolar ventilation would do what to PACO2?

Answer

A

It would decrease it.

Question 46

Q

How can you increase the production of CO2? In this case if you wanted to maintain a constant PaCO2 & PACO2 what would have to happen?

Answer

A

Exercise can increase metabolic demands in the tissues & give off more CO2.
This would require an increase in alveolar ventilation in order to maintain a constant PaCO2 & PACO2.

Question 47

Q

What is the alveolar gas equation?

Answer

A

PAO2=PIO2 - PACO2/R
R=0.8
PIO2 is for the inspired air

Question 48

Q

If you have a R=0.8…& you decrease your alveolar ventilation by half…what does this do to your PACO2 & PAO2?

Answer

A

Your PACO2 doubles.

Your PAO2 decreases by a little more than half.

Question 49

Q

If your R value changes in your alveolar gas equation…what has changed physiologically?

Answer

A

Your CO2 production relative to your O2 consumption ratio has been altered…

Question 50

Q

What is forced vital capacity?

Answer

A

It is the amount of air that can be forcibly expired after maximal inspiration. This is usu accomplished after 3 seconds of maximal expiration.

Question 51

Q

What is FEV1, FEV2, & FEV3?

Answer

A

These are the forced expiratory volumes after 1, 2, & 3 seconds respectively. Usu you reach your full FVC after 3 seconds.

Question 52

Q

What is significant about the ratio of FEV1/FVC? What is this value in a normal person?

Answer

A

This helps differentiate b/w different lung diseases.

0.8 in a normal person…

Question 53

Q

In a person with an obstructive lung disease…such as _______…both FVC & FEV1 ______ but _____ decreases more. Thus the ratio of FEV1/FVC _____.

Answer

A

obstructive lung disease
asthma
both decrease, but FEV1 decreases more.
Ratio decreases.

Question 54

Q

In a person with a restrictive lung disease…such as _____….both FVC & FEV1 _____ but ______ decreases more. Thus the ratio of FEV1/FVC _____.

Answer

A

Restrictive Lung Disease
Fibrosis
both decrease
FVC decreases more
Ratio increases.

Question 55

Q

What are the muscles of inspiration at rest? During vigorous exercise?

Answer

A

At rest: diaphragm

Exercise: external intercostal muscles & accessory muscles

Question 56

Q

What are the muscles of expiration at rest? During vigorous exercise?

Answer

A

At rest: passive

During exercise or w/ asthma: abdominal muscles, internal intercostal muscles

Question 57

Q

What is it that the diaphragm does when it contracts that causes inspiration?

Answer

A

When it contracts…it moves the diaphragm down & the ribs up & out. This increases intrathoracic volume & decreases intrathoracic pressure. Thus, air flows in.

Question 58

Q

What is compliance?

Answer

A

relates to the distensibility of the lungs & chest wall…how the volume changes as a result of a pressure change…

Question 59

Q

What is the relationship b/w elastance & compliance?

Answer

A

They are inversely proportional…think of a thick rubber band. Thicker (more elastic) the greater the recoil force & the smaller the compliance/distensibilty.

Question 60

Q

What is transmural pressure?

Answer

A

the pressure taken across a structure…

Question 61

Q

What is the intrapleural space?

Answer

A

the space that lies b/w the lungs & the chest wall…

Question 62

Q

How do you determine the compliance of a lung based off of a pressure volume loop?

Answer

A

You can determine compliance by taking the slope of the curves.
Note: there will be a different compliance/slope for the inspiration curve than for the expiration curve.

Question 63

Q

What does a negative pressure outside of the lungs do to the lung volume?

Answer

A

It expands the volume. Air rushes in.

Question 64

Q

What does a less negative pressure outside of the lungs do to the lung volume?

Answer

A

It decreases the volume. Expiration.

Answer 64

A

It is the name for the phenomenon of the different slopes/compliances for the curves on the pressure volume loop during inspiration & expiration.

Answer 65

A

The expiration curve has a higher compliance.

Explanation is basically: surfactant/surface tension.

Answer 66

A

The surfactant can’t be laid down as fast as the surface area increases (alveoli become available)…surfactant density is low, surface tension is high, compliance is low…slope is flatter

Answer 67

A

The surfactant can’t be removed as fast the surface area decreases…surfactant density is high, surface tension is low, compliance is high. Slope is steeper.

Answer 68

A

2 opposing elastic forces…lungs “want” to collapse & the chest wall “wants” to spring out.
This neg. pressure actually keeps both of these things from happening.
Pneumothorax makes the pressure in the intrapleural space equal to atmospheric pressure (0)…thus, nothing prevents the lung form collapsing & the chest from expanding…

Answer 69

A

0.

Neg. pressure is pressure less than atmospheric pressure…

Answer 70

A

At pressure 0–atmospheric

They balance each other & are at equilibrium & don’t have a tendency to collapse or expand.

Answer 71

A

Pressure less than atmospheric–negative
Tendency @ neg. pressure to expand.
**less than FRC would be like maximal expiration & then you would want to inspire…

Answer 72

A

Pressure is greater than atmospheric–positive
Tendency @ pos. pressure to collapse.
**more than FRC would be inspiration…you’d be ready to expire

Answer 73

A

Obstructive
Decreases elasticity & increases lung compliance.
It functions at a higher FRC
Patients have barrel chests

Answer 74

A

Restrictive
Increases elasticity & decreases compliance
It functions at a lower FRC

Answer 75

A

P=2T/r
r--the radius of the alveolus
P-collapsing pressure in the alveolus
T-surface tension of the alveolus
**this refers to the surface tension of the alveolus

Answer 76

A

Advantage to a small alveolus: larger surface area relative to volume–better for gas exchange
Disadvantage to a small alveolus: higher collapsing pressure

Answer 77

A

Phospholipids

amphipathic

Answer 78

A

Neonatal Respiratory Distress Syndrome

Atelectasis: the collapsing of alveoli

Answer 79

A

Shunt

Hypoxemia

Answer 80

A

before week 24

after week 35

Answer 81

A

It increases lung compliance.

It makes it less difficult to breathe.

Answer 82

A

Pressure difference. This promotes airflow.
Q=deltaP/R
Q is airflow
P is pressure difference
R is resistance to airflow

Answer 83

A

R=8nl/pir^4.

Radius is the most powerful influence here.

Answer 84

A

Medium-size bronchi b/c the smaller the greater the resistance.
However, the smallest bronchi are arranged in parallel, & therefore do not have a great resistance.

Answer 85

A

They are muscarinic agonists.
This would promote parasympathetic effect on the smooth muscle of the bronchi. This would constrict them & increase airway resistance.

Answer 86

A

This is a muscarinic antagonist.
This would block the parasympathetic effect on the smooth muscle of the bronchi. This would prevent constriction. This would decrease airway resistance.

Answer 87

A

High lung volume causes greater traction & decreases airway resistance.
This is sometimes a compensatory mechanism of asthmatics. They breathe higher lung volumes, which decreases their airway resistance from environmental irritants.

Answer 88

A

Increased viscosity of air: increased airway resistance

Decreased viscosity of air: decreased airway resistance

Answer 89

A

Rest, Inspiration, Expiration

Answer 90

A

equal to the atmospheric pressure

Answer 91

A

+5 cmH2O

Alveolar greater than intrapleural

Answer 92

A

the contraction of the diaphragm

Answer 93

A

The volume of the thorax increases
the volume of the lungs increases
the lung pressure decreases
air can flow in.

Answer 94

A

0.5L or the tidal volume.

Answer 95

A

Less than atmospheric pressure

Even more negative intrapleural pressure than during rest

Answer 96

A

equal to atmospheric pressure

Answer 97

A

FRC + Tidal volume

Answer 98

A

the extent to which intrapleural pressure changes during inspiration

Answer 99

A

It becomes more positive.

Alveolar is greater than intrapleural (mainly b/c intrapleural is so negative)

Answer 100

A

passive
alveolar pressure becomes positive
elastic recoil 
end volume is FRC
expired volume is tidal volume

Answer 101

A

expiratory muscles contractions…causes very positive pressures

Answer 102

A

This makes values super positive.

Intrapleural & Transmeural pressures are positive.

Answer 103

A

Elastic fibers are lost.
Lung compliance is increased.
The alveolar & airway pressures are lower.
Transmural pressure is positive in the alveoli.
Transmural pressure is negative in the large airways.
thus, the airways can collapse & make expiration difficult.
Thus, patients often purse their lips & expire slowly.

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Physiology Review Book Notes Flashcards

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