Respiration 1

Question 0

What is the most critical function the respiratory system provides?

Answer 0

Providing oxygen

Need oxygen for the electron transport chain–>final electron acceptor

Question 1

What are the 7 main functions of the respiratory system

Answer 1

1. Provide Oxygen
2. Eliminate Carbon Dioxide
3. Regulate Blood pH
4. Facilitate speech
5. Microbial Defense
6. Activate and Inactivate Chemical Messengers
7. Defend Against Blood Clots

Question 2

How does respiratory system regulate blood pH

Answer 2

The ventilation rate affects how much CO2 is released which in turn affects how much CO2 is in the plasma

Question 3

Why do we need respiratory system for speech

Answer 3

When we say words air flows out of the mouth

We don’t suck in air when we speak

Question 4

How does the respiratory system combat pathogens (3 major ways)

Answer 4

Coughing and sneezing: expel mucous that is loaded with pathogens

Epithelial secretions: respiratory tubes lined with epithelium secrete antibacterial substances

Lymphoid tissue: B and T lymphocytes cluster beneath the mucosal layer

Question 5

What is an example of activation of chemical messengers by the respiratory system

Answer 5

Angiotensin I–> Angiotensin II

Angiotensin II stimulates aldosterone secretion

Question 6

How does respiratory system prevent clot formation

Answer 6

The endothelial cells lining the capillaries secrete substances that promote protein lysis

Cause fibrolysis: break down fibers in clots and inhibit platelet aggregation

Question 7

What are the three main components of the respiratory system

Answer 7

1. Lungs
2. Airways
3. Mechanical aids

Question 8

What is the main purpose for the airways

Answer 8

Series of tubes to exchange air between the lungs and the environment

Need a way for CO2 to leave the lungs and get out to the environment

Question 9

What major process occurs at the lung and what is happening during this process

Answer 9

Site for gas exchange

O2 into the blood
CO2 out of the blood

Question 10

What are the three different zones the airways are divided

Answer 10

1. Upper Airways
2. Conducting Zone
3. Respiratory Zone

Question 11

What are mechanical aids and what are they used for

Answer 11

Skeletal muscles

Help relax and contract the diaphragm to change the volume in the thoracic cavity

Question 12

what structures make up the upper airway and where are they in relation to the thoracic cavity

Answer 12

mouth/nose, pharynx, larynx, upper trachea

these structures are outside the thoracic cavity

Question 13

what structures make up the conducting zone and where are they in relation to the thoracic cavity

Answer 13

trachea and its branches
-primary
-secondary
-tertiary
bronchioles and terminal bronchioles

inside the thoracic cavity

Question 14

what is characteristic of the tubules in the conducting zone to allow proper air flow

Answer 14

the tubules are not collapsible and stay open at all times

Question 15

what zone of the airways do gas exchange occur

Answer 15

respiratory zone

conducting zone has no gas exchange

Question 16

what is the trend regarding cartilage and smooth muscle in the conducting zone

Answer 16

Bronchi, as they get smaller, will lose cartilaginous rings and increase in smooth muscle

Question 17

where are mucous glands present in the conducting zone?

Answer 17

in the bronchi but not in the bronchioles

as move down the tubules there are less and less mucous glands

Question 18

what is a key thing that happens in the respiratory zone

Answer 18

gas exchange

Question 19

what is characteristic about the respiratory zone that allows for gas exchange

Answer 19

thin walled respiratory bronchioles

Question 20

what makes the tubules in the respiratory zone different from the tubules in the conducting zone

Answer 20

these tubules are collapsible

need to have air flowing through to keep them open

Question 21

the structures of the respiratory zone

Answer 21

respiratory bronchioles
alveolar ducts
alveolar sacs

Question 22

when initially inhaling air it is cold and dry, what does the respiratory system do to it?

Answer 22

heat and water vapor are exchanged with the blood in the airway walls to moisten and warm the air

Question 23

what does branching structure do to the air flow rate

Answer 23

decreases resistance to flow

Question 24

what are the two types of cells that are in the conducting zone that protect against microbes and how

Answer 24

goblet cells:
-secrete mucous that traps pathogens and airborne particles

ciliated epithelial cells:
-cillia on epithelial cells pulse upward to move mucous up and out of the larynx into the esophagus to be swallowed or expelled

“frog in throat”

Question 25

how does the mucous produced by the goblet cells become watery so it can be easily moved up into the esophagus to eliminate microbes

Answer 25

there are Cl- channels in the tracheal cells that normally transport Cl- from the inside of the cell to the lumen of the trachea

Na+ goes with it

Extracellular fluid goes with it making the mucous more watery

Question 26

what is cystic fibrosis

Answer 26

a disease that impairs normal function of the conduction zone

Question 27

how does cystic fibrosis affect the normal function of the conducting zone

WHAT ARE 2 CONSEQUENCES OF CYSTIC FIBROSIS

Answer 27

mutation in genetic code for Cl- channel reduces the amount of Cl- and Na+ that moves into the lumen of the trachea

water does not follow and the mucous becomes thick, dry, and sticky

cilia cannot beat hard enough to move the mucous upwards

1. infectious agents are trapped in the mucous but cannot be expelled–INFECTIONS
2. airways obstruction

Question 28

what are 3 functions of the conducting zone

Answer 28

1. branching to decrease resistance to airflow
2. microbial defense
3. warm and moisten air

Question 29

what are 3 functions of the respiratory zone

Answer 29

1. regulate airflow
2. site for gas exchange
3. microbial defense

Question 30

what is responsible for regulating airflow in the respiratory zone

Answer 30

the smooth muscles in bronchioles

Question 31

how is airflow regulated in the respiratory zone

Answer 31

controlled by psymp and symp nervous system

sympathetic stimulation causes smooth muscle to relax and dilate bronchioles to increase air flow

Question 32

how are alveoli modified to promote gas exchange (4)

Answer 32

1. INCREASED SURFACE AREA
2. HIGHLY VASCULARIZED:
   - lots of capillaries
3. LOW RATE of BLOODFLOW
   - provides time for gas exchange
   - need time for O2 to be picked up by the blood
   - low resistance to flow, low pressure
4. THIN SURFACES
   - good diffusion of O2 from air into the blood

Question 33

how does respiratory zone provide microbial defense

Answer 33

by pulmonary macrophages

Question 34

what are the mechanical aids of the respiratory system

Answer 34

skeletal muscles and bones of the thoracic cavity

Question 35

what are the main purposes of respiratory mechanical aids

Answer 35

do work of respiratory system

allows air to flow in and out of the lungs

bones provides protection to lungs

Question 36

what are three types of cells found in alveoli

Answer 36

1. type I cells
2. type II cells
3. macrophages

Question 37

what is the main function of type I cells in alveoli

what is their structure like

Answer 37

gas exchange

squamous epithelial cells (pavement cells)

Question 38

what is the main function of type II cells in the alveoli

Answer 38

secrete surfactant

Question 39

what is surfactant and what does the secretion of this do for the lung

Answer 39

surfactant is a detergent like substance (mix of proteins and salts)

• keeps lungs from sticking to itself
• decreases surface tension

Question 40

what are pulmonary macrophages and what is their function

Answer 40

immune cells that remove infected tissue in the lungs

Question 41

what characteristics of the alveoli help with gas exchange

Answer 41

thin surface and small diameter

pulmonary capillaries

Question 42

what does small diameter of alveolus do for gas exchange

Answer 42

allows for more gas to be in contact with the surface of the alveolus

Question 43

what is the diameter of the alveolar sac

Answer 43

0.5 micrometers

Question 44

what is the distance between the pulmonary capillary and the alveolus

Answer 44

0.2 micrometers

Question 45

solubility diffusion rates O2 vs CO2

Answer 45

diffuse at different rates due to different solubilities

CO2=77mmol/L
O2=2.2mmol/L

CO2 more easily diffuses

Question 46

diffusion of respiratory gases

• what decides the direction of diffusion
• describe polarity

Answer 46

respiratory gases are small non polar molecule

they diffuse along concentration gradient

they readily diffuse through membranes; do not diffuse as easily through bodily fluids

Question 47

trace the path of diffusion of O2 from respiratory tubule to blood (name all the surfaces the gas must cross)

Answer 47

1. cross plasma membrane on apical side of epithelial cell
2. cross intracellular fluid
3. cross basal membrane on other side of epithelial cell
4. cross basal lamina which is where connective tissue is located where type I alveoli cells are attached
5. cross extracellular fluid
   GET INTO BLOOD VESSEL
6. cross basal side of endothelial cell
7. cross intracellular fluid of endothelial cell
8. cross apical membrane of endothelial cell

O2 now in blood vessel!

Question 48

what are the “two layers” of the pleural sac

Answer 48

parietal: adheres to underside of thoracic wall and top of diaphragm
visceral: pleura covers outer surface of lung

Question 49

what separates the two lungs

Answer 49

mediastinum

Question 50

what is the space called between the “two layers”

Answer 50

pleural sac

Question 51

how is airflow related to pressure difference and resistance to flow

Answer 51

airflow= change in pressure/resistance

directly related to change in pressure
indirectly related to resistance

Question 52

what are the purposes of intrapleural fluid (3)

Answer 52

1. lubricate surfaces: so when lungs expand, don’t rub on ribs
2. subject to pressure changes when thoracic cavity expands or contracts
3. controls volume of lung

Question 53

ventilation relies on…

Answer 53

pressure differences between air in the lungs and air outside the lungs

Question 54

how do we calculate change in pressure

Answer 54

pressure in alveoli minus pressure in atmosphere

Question 55

describe air pressure inside lung and in atmosphere at inspiration

Answer 55

air pressure in lung is less than air pressure of atmosphere

Question 56

describe air pressure inside lung and in atmosphere during expiration

Answer 56

air pressure in lung is more than air pressure of atmosphere

Question 57

what causes pressure in the alveoli to change

Answer 57

change in volume of alveoli will change the air pressure if the molecules are constant

change in molecules but constant volume will change air pressure

Question 58

are the lungs capable of changing volume

Answer 58

yes the lungs can stretch and recoil

Question 59

what is the alveolar pressure

Answer 59

the pressure in the lung

Question 60

what is the intrapleural pressure

Answer 60

pressure in the fluid in the intrapleural space

Question 61

what is transpulmonary pressure

Answer 61

the difference between alveolar pressure and intrapleural pressure

important in inflation/deflation of the lung

Question 62

what happens with muscles at the beginning of inspiration

Answer 62

diaphragm contracts which increases the volume of the thoracic cavity

external intercostals contract to lift rib cage further increasing the thoracic cavity

Question 63

what happens with muscles at the beginning of expiration

Answer 63

the diaphragm relaxes which decreases the volume in the thoracic cavity (diaphragm domes up)

external intercostals relax lowering the rib cage and also decreasing the thoracic cavity (decrease volume)

Question 64

what is the relationship between air pressure of alveoli and atmosphere between breaths

Answer 64

air pressure of alveolar and atmosphere equal each other (no air is moving)

Question 65

what pressure is always negative and why

Answer 65

interpleural pressure

because chest wall tends to pull outward and lungs tend to recoil inward (opposite direction)

don’t want high pressure cause don’t want lungs to collapse

Question 66

what happens to air pressure as diaphragm contracts and thorax expands

Answer 66

inspiration

interpleural pressure becomes more negative

makes transpulmonary pressure increase so lung will expand and pressure will decrease lower than atmospheric pressure therefore air will flow into the lungs until Palv=Patm again

Question 67

what happens to air pressure as diaphragm relaxes and thorax compresses

Answer 67

expiration

interpleural pressure becomes less negative (increases)

transpulmonary pressure will then decrease so lung volume will decrease and pressure will increase higher than atmospheric air pressure therefore air will flow out of lung until Palv=Patm again

Question 68

if additional muscles are involved other than diaphragm

Answer 68

forced expiration and forced inspiration

Question 69

follow the pathway from beginning of inspiration to when air flows into the lungs

Answer 69

1. diaphragm contacts
2. thorax expands
3. interpleural pressure decreases (more negative)
4. transpulmonary pressure increases (Palv minus or more negative making more positive)
5. lungs expand
6. pressure in alveoli becomes less than atmospheric pressure
7. air flows into lung

Question 70

follow the pathway from beginning of expiration to when air flows out of the lungs

Answer 70

1. diaphragm relaxes
2. thorax compresses (chest wall recoils)
3. interpleural pressure increases (becomes less negative)
4. transpulmonary pressure decreases (Palv minus a less negative number)
5. lungs recoil (compressed)
6. pressure in alveolus increases above atmostpheric pressure
7. air flows out of lungs

Question 71

what causes pneumothorax

Answer 71

punctured lung

no longer different pressures

Question 72

what happens to the lung and chest wall if pneumothorax

Answer 72

lung collapses; chest wall expands

can happen to just one lung while the other stays inflated