Lesson 13-14a Part 2 - Respiratory System

Question 1

breathing depends on…

Answer 1

repetitive stimulation of skeletal muscles from the brain

Question 2

breathing is controlled at two levels of the brain

Answer 2

• one is cerebral and conscious
• other is unconscious and automatic

Question 3

automatic, unconscious breathing is controlled by…

Answer 3

respiratory

Question 4

two pairs of respiratory centers are located where?

Answer 4

medulla oblongata?

Question 5

which respiratory center is the primary generator of the respiratory rhythm?

Answer 5

ventral respiratory group (VRG)

Question 6

where is the ventral respiratory group (VRG) located?

Answer 6

medulla oblongata

Question 7

the ventral respiratory group (VRG) is a collection of reverberating circuits of…

Answer 7

• inspiratory (I) neurons
• expiratory (E) neurons

Question 8

what rhythm does the VRG produce?

Answer 8

12 breaths per minute

Question 9

the dorsal respiratory group (DRG) is also called…

Answer 9

the inspiratory center

Question 10

what does the inspiratory center stimulate?

Answer 10

inspiratory muscles

Question 11

which respiratory group functions in both quiet and forced breathing?

Answer 11

dorsal respiratory group (DRG)

Question 12

the dorsal respiratory group (DRG) modifies what? how?

Answer 12

(1) the rate and depth of breathing by (2) affecting the VRG

Question 13

the dorsal respiratory group receives influence from…(4)

Answer 13

external sources like the pons, medulla, receptors in the lungs, and higher brain centers

Question 14

central chemoreceptors

Answer 14

brainstem neurons that respond to changes in pH of cerebrospinal fluid (CSF)

Question 15

the pH of cerebrospinal fluid reflects what?

Answer 15

the CO2 level in the blood

Question 16

the lower the pH in the CSF the……in blood?

Answer 16

more CO2 in blood

Question 17

central chemoreceptors regulate respiration to maintain…(2)

Answer 17

stable pH/stable CO2 levels in blood

Question 18

where are peripheral chemoreceptors?

Answer 18

carotid and aortic bodies

Question 19

what do peripheral chemoreceptors respond to? (3)

Answer 19

O2 and CO2 content and the pH of blood

Question 20

stretch receptors are located where in the lungs? (2)

Answer 20

• smooth muscle of bronchi and bronchioles
• visceral pleura

Question 21

what do stretch receptors in the lungs respond to?

Answer 21

inflation of the lungs

Question 22

inflation (Hering-Breuer) reflex

Answer 22

protective reflex that inhibits inspiratory neurons and stops inspiration to stop excessive inflation/stretching of lung tissue

Question 23

what is the Hering-Breuer reflex triggered by?

Answer 23

excessive inflation

Question 24

irritant receptors

Answer 24

nerve endings amid the epithelial cells of the airway

Question 25

irritant receptors respond to (6)

Answer 25

• smoke
• dust
• pollen
• chemical fumes
• cold air
• excess mucus

Question 26

irritant receptors trigger protective reflexes such as…(4)

Answer 26

• bronchoconstriction
• shallower breathing
• breath-holding
• coughin

Question 27

apnea

Answer 27

breath-holding

Question 28

where does voluntary control over breathing originate?

Answer 28

in the motor cortex of the frontal lobe of the cerebrum

Question 29

what does the motor cortex of the frontal lobe of the cerebrum send?

Answer 29

impulses down corticospinal tracts to respiratory neurons in the spinal cord, bypassing the brainstem

Question 30

the breaking point

Answer 30

when CO2 levels rise to a point where automatic controls override one’s voluntary will

Question 31

respiratory airflow is governed by…

Answer 31

the same principles of slow, pressure, and resistance as blood flow

Question 32

the flow of a fluid is _____ proportional to the pressure difference between two points

Answer 32

directly

Question 33

the flow of fluid is _____ proportional to the resistance

Answer 33

inversely

Question 34

atmospheric (barometric) pressure

Answer 34

the weight of the air above us

Question 35

where is atmospheric pressure lower?

Answer 35

higher elevations

Question 36

intrapulmonary pressure

Answer 36

air pressure within the lungs

Question 37

intrapulmonary pressure changes with lung volume according to what law?

Answer 37

Boyle’s law
- P = 1/V

Question 38

Boyle’s Law

Answer 38

at a constant temperature, the pressure of a given quantity of gas is inversely proportional to its volume
- P = 1/V

Question 39

if the lungs contain a quantity of gas, and the lung volume increases, what happens to internal pressure?

Answer 39

it falls

Question 40

what happens if the intrapulmonary pressure falls below atmospheric pressure?

Answer 40

air moves into the lungs

Question 41

what happens if intrapulmonary pressure rises above atmospheric pressure?

Answer 41

air moved out of the lungs

Question 42

during inspiration, the lungs expand and…

Answer 42

follows the expansion of the thoracic cage due to the intrapleural pressure

Question 43

intrapleural pressure

Answer 43

the slightly negative pressure that exists between the two pleural layers (parietal and viseral)

Question 44

what causes the lungs and chest wall to be pulled in opposite directions? (2)

Answer 44

(1) recoil of lung tissue and (2) tissues of the thoracic cage

Question 45

the potential space between the parietal and visceral pleurae contains?

Answer 45

a small amount of watery serous fluid called pleural fluid

Question 46

how do the layers of the pleura stay together?

Answer 46

cohesion of water

Question 47

what happens to the pleura when the ribs swing upward/outward during inspiration?

Answer 47

the pleura follows!

Question 48

in quiet breathing , the thoracic cage moves a few _____ in each direction, which is enough to increase its volume by 500ml

Answer 48

mm (millimeter)

Question 49

the _____ pleura clings to and follows the _____ pleura

Answer 49

visceral, parietal

Question 50

what happens when the visceral pleura stretches?

Answer 50

the alveoli near the surface of the lungs stretches, and because they are coupled to deeper alveoli they got pulled too

Question 51

as alveoli increase volume, the ______ (______) pressure drops below atmospheric pressure

Answer 51

intrapulmonary (alveolar)

Question 52

another force that expands lungs is…

Answer 52

the warming of inhaled air

Question 53

Charles’s Law

Answer 53

the volume of a gas is directly proportional to its absolute temperature

Question 54

is expiration a passive or active process in quiet expiration?

Answer 54

passive

Question 55

how is expiration achieved in quiet expiration?

Answer 55

mainly by elastic recoil of the thoracic cage

Question 56

elastic recoil of the thoracic cage _____ the lungs

Answer 56

compresses

Question 57

in normal lungs, the intrapleural pressure is always _____ in both inhalation and exhalation

Answer 57

negative

Question 58

pneumothorax

Answer 58

presence of air in the pleural cavity

Question 59

describe how a pneumothorax occurs (2)

Answer 59

• thoracic wall is punctured
• inspiration sucks air through the wound into the pleural cavity

Question 60

the potential space a pneumothorax creates causes what?

Answer 60

an air-filled cavity causing the loss of negative intrapleural pressure allowing the lungs to recoil and collapse

Question 61

atelectasis

Answer 61

collapse of part of all of a lung

Question 62

potential causes of atelectasis (4)

Answer 62

• lung tumor
• aneurysm
• swollen lymph node
• aspirated object into airways

Question 63

how does an aspirated object lead to atelectasis?

Answer 63

an airway obstruction causes blood to absorb gases from the alveoli causing a decrease in alveolar volume and subsequent alveolar collapse

Question 64

two factors influence airway resistance

Answer 64

• bronchiole diameter
• pulmonary compliance

Question 65

bronchodilation

Answer 65

increase in diameter of bronchus or bronchiole

Question 66

bronchoconstriction

Answer 66

decrease in diameter of bronchus or bronchiole

Question 67

pulmonary compliance

Answer 67

ease with which the lungs can expand; change in lung volume relative to a given pressure change

Question 68

compliance is reduced by…

Answer 68

degenerative lung diseases in which the lungs are stiffened by scar tissue

Question 69

lung diseases that cause scar tissue (2)

Answer 69

• tuberculosis
• black lung disease

Question 70

compliance of the lungs is limited by…

Answer 70

the surface tension of the water film inside the alveoli

Question 71

what does surfactant do?

Answer 71

disrupts hydrogen bonds between water molecules and thus reduces the surface tension, making them easier to fill with air

Question 72

surfactant is secreted by..

Answer 72

great cells of the alveoli

Question 73

infant respiratory distress syndrome (IRDS)

Answer 73

premature babies lacking surfactant are treated with artificial surfactant until they can make their own

Question 74

what air is available for gas exchange?

Answer 74

the air that enters the alveoli

Question 75

about how much air fills the conducting zone of the airway?

Answer 75

150ml

Question 76

anatomical dead space

Answer 76

the conducting zone of the respiratory system in which no gas exchange occurs

Question 77

the anatomical dead space can be altered somewhat by what?

Answer 77

sympathetic dilation which increases dead space but allows greater flow

Question 78

spirometry

Answer 78

measuring pulmonary ventilation

Question 79

spirometry aids in what?

Answer 79

diagnosis and assessment of restrictive and obstructive lung disorders

Question 80

restrictive disorders include (3)

Answer 80

• black lung disease
• tuberculosis
• any disease that produces pulmonary fibrosis

Question 81

restrictive disorders

Answer 81

reduction in pulmonary compliance, limiting how much lungs can inflate

Question 82

obstructive disorders of the lungs

Answer 82

interfere with airflow by narrowing or blocking the airway making it harder to inhale or exhale a given amount of air

Question 83

obstructive disorders include (2)

Answer 83

• asthma
• chronic bronchitis

Question 84

_____ bombines both elements of both restrictive and obstructive disorders

Answer 84

emphysema

Question 85

eupnea

Answer 85

relaxed, quiet breathing

Question 86

apnea

Answer 86

temporary cessation of breathing

Question 87

dyspnea

Answer 87

labored, gasping breath/shortness of breath

Question 88

hyperpnea

Answer 88

increased rate and depth of breathing in response to exercise, pain, or other conditions

Question 89

hyperventilation

Answer 89

increased pulmonary ventilation in excess of metabolic demand

Question 90

hypoventilation

Answer 90

reduced pulmonary ventilation leading to an increase in blood CO2

Question 91

kussmaul respiration

Answer 91

deep, rapid breathing often induced by acidosis, diabetes-related ketoacidosis

Question 92

air contains

Answer 92

• 78.6% nitrogen
• 20.9% oxygen
• 0.04% carbon dioxide
• 0-4% water vapor

Question 93

air contains minor amounts of…(5)

Answer 93

• argon
• neon
• helium
• methane
• ozone

Question 94

Dalton’s Law

Answer 94

total atmospheric pressure in the sum of the contributions of the individual gases

Question 95

partial pressure

Answer 95

the separate contribution of each gas in a mixture

Question 96

composition of inspired and alveolar air differs because of three influences

Answer 96

• air is humidified by contact with mucus membranes
• alveolar air mixes with residual air
• alveolar air exchanges O2 and CO2 with blood

Question 97

air is humidified by contact with mucous membranes

Answer 97

alveolar PH2O is more than 10x higher than inhaled air

Question 98

alveolar air mixed with residual air

Answer 98

oxygen gets diluted and air is enriched with CO2

Question 99

alveolar air exchanges O2 and CO2 with blood (2)

Answer 99

• PO2 of alveolar air is about 65% that of inspired air
• PCO2 is more than 130x higher

Question 100

alveolar gas exchange

Answer 100

the movement of O2 and CO2 across the respiratory membrane

Question 101

for oxygen to get into the blood, it must…

Answer 101

dissolve in the alveolar epithelium (water) and pass through the respiratory membrane separating the air from the bloodstream

Question 102

for carbon dioxide to leave the blood, it must…

Answer 102

pass the other way and then diffuse out of the water film into the alveolar air

Question 103

gases diffuse down their own gradients until…

Answer 103

the partial pressure of each gas in the air is equal to its partial pressure in water

Question 104

what is the first step in alveolar gas exchange?

Answer 104

air in the alveolus is in contact with a film of water covering the alveolar epithelium

Question 105

Henry’s Law

Answer 105

at the air-water interface, for a given temperature, the amount of gas that dissolves in the water is determined by its solubility in water and its partial pressure in air

Question 106

the _____ the PO2 in the alveolar air, the ____ O2 the blood picks up

Answer 106

greater, more

Question 107

because the blood arriving at the alveolus has…

Answer 107

a higher PCO2 than air, so it releases the CO2 in the air

Question 108

at the alveolus, the blood is said to

Answer 108

unload CO2 and load O2

Question 109

the unloading of CO2 and loading involves…

Answer 109

erythrocytes

Question 110

efficiency of the alveolar gas exchange depends on…

Answer 110

how long an RBC stays in the alveolar capillaries

Question 111

how long does a RBC need to stay in the alveolar capillaries to reach equilibrium?

Answer 111

0.25 seconds

Question 112

at rest, RBC spend _____ seconds in the alveolar capillaries

Answer 112

0.75

Question 113

in strenuous exercise, RBCs stay for ___ seconds

Answer 113

0.3

Question 114

each gas in a mixture behaves _____

Answer 114

independently, one gas does not influence the diffusion of another

Question 115

variables affecting alveolar gas exchange efficiency (5)

Answer 115

• membrane thickness
• membrane surface area
• solubility of gases
• pressure gradients of the gases
• ventilation-perfusion coupling

Question 116

normally, the PO2 is…

Answer 116

= 104 mmHg in the alveolar air versus 40 mmHg in blood

Question 117

normally, the PCO2 is…

Answer 117

= 46 mmHg in blood arriving versus 40 mmHg in blood arriving versus 40 mmHg in alveolar air

Question 118

how do pressure gradients differ at high altitudes?

Answer 118

partial pressure of all atmospheric gases are lower; pressure gradient for oxygen is lower so less diffuses into blood

Question 119

hyperbaric oxygen therapy

Answer 119

treatment with oxygen at greater than 1 atm of pressure

Question 120

what is hyperbaric oxygen therapy used for? (2)

Answer 120

• gangrene
• carbon monoxide poisoning

Question 121

by the time blood reaches the left atrium, the PO2 is…

Answer 121

95 mmHg

Question 122

why is PO2 95 mmHg by the time it reaches the left atrium?

Answer 122

caused by a mixing of oxygenated blood from the pulmonary vein with deoxygenated blood from the bronchial vein

Question 123

variables affecting alveolar gas exchange efficiency: solubility of gases

Answer 123

equal amounts of O2 and CO2 are exchanged across the respiratory membrane because CO2 is much more soluble and diffuses more rapidly

Question 124

CO2 is _____ time as soluble as O2

Answer 124

20

Question 125

what disease decrease surface area for gas exchange? (3)

Answer 125

• emphysema
• lung cancer
• tuberculosis

Question 126

the respiratory membrane is only _____ thick

Answer 126

0.5um

Question 127

what would happen if the respiratory membrane was thicker?

Answer 127

gases have father to travel between blood and air and cannot equilibrate fast enough to keep up with blood flow

Question 128

what diseases cause thickening of the respiratory membrane? (2)

Answer 128

• pulmonary edema
• pneumonia

Question 129

ventilation-perfusion coupling

Answer 129

gas exchange requires both good ventilation of alveolus and good perfusion of the capillaries

Question 130

pulmonary blood vessels change diameter depending on…

Answer 130

air flow to an area of the lungs

Question 131

bronchi change diameter depending on…

Answer 131

blood flow to an area of the lungs

Question 132

if an area of the lungs is well perfused, what occurs?

Answer 132

bronchodilation

Question 133

gas transport

Answer 133

the process of carrying gases from the alveoli to the systemic tissues and vice versa

Question 134

how much O2 does blood carry?

Answer 134

20ml of O2 per deciliter

Question 135

what molecule is specialized for oxygen transport?

Answer 135

hemoglobin

Question 136

oxyhemoglobin (HbO2)

Answer 136

O2 bound to hemoglobin

Question 136

deoxyhemoglobin (HHb)

Answer 136

hemoglobin with no O2

Question 137

oxyhemoglobin dissociation curve

Answer 137

illustrates relationship between hemoglobin saturation and ambient PO2

Question 138

why does the oxyhemoglobin dissociation curve look the way it does?

Answer 138

occurs because when hemoglobin binds each oxygen, it makes it easier to bind the next one

Question 139

three forms in which carbon dioxide is transported in the body

Answer 139

• carbonic acid
• carbaminohemoglobin
• dissolved gas

Question 140

90% of CO2 is carried as…

Answer 140

carbonic acid (H2CO3)

Question 141

5% of carbon dioxide is carried as either…(2)

Answer 141

dissolved gas or carbaminohemoglobin

Question 142

70% of exchanged CO2 comes from what form of CO2?

Answer 142

carbonic acid

Question 143

23% of exchanged CO2 comes from what form of CO2?

Answer 143

carbaminohemoglobin

Question 144

7% of exchanged CO2 comes from what form of CO2?

Answer 144

dissolved in plasma

Question 145

blood gives up the dissolved CO2 gas and CO2 from _____ more easily than CO2 in _____

Answer 145

carbaminohemoglobin, bicarbonate

Question 146

carbon monoxide (CO)

Answer 146

colorless, odorless gas in cigarette smoke, engine exhaust, and fumes from gas furnaces

Question 147

_____ competes for the O2 binding site on hemoglobin (Hb)

Answer 147

carbon monoxide

Question 148

what is hemoglobin called when carbon monoxide binds to it?

Answer 148

carboxyhemoglobin (HbCO)

Question 149

does CO or O2 bind to hemoglobin more tightly?

Answer 149

CO

Question 150

treatment for CO binding to Hb in smokers (3)

Answer 150

• pure oxygen
• hyperbaric oxygen therapy
• blood transfusion

Question 151

systemic gas exchange

Answer 151

unloading of O2 and loading of CO2 at systemic capillaries

Question 152

carbon dioxide loading (2)

Answer 152

• CO2 diffuses into the blood
• carbonic anhydrase catalyzes the reaction to bicarbonate and hydrogen ions

Question 153

where is carbonic anhydrase found?

Answer 153

red blood cells

Question 154

chloride shift

Answer 154

bicarbonate pumped out of RBC in exchange for a chloride ion from plasma

Question 155

how is the chloride shift performed?

Answer 155

an antiport protein called the chloride-bicarbonate exchanger

Question 156

H+ binding to _____ reduces its affinity for O2

Answer 156

HbO2 (oxyhemoglobin); tends to make hemoglobin release oxygen

Question 157

HbO2 arrives at systemic capillaries _____% saturated and leave _____% saturated

Answer 157

97, 75

Question 158

utilization coefficient

Answer 158

22% of HbO2’s load is given up

Question 159

gas exchange reactions that occur in the lungs are _____ of systemic gas exchange

Answer 159

reverse

Question 160

CO2 unloading in the lungs

Answer 160

as Hb loads O2, its affinity for H+ decreases causing it to dissociate from Hb and bind with HCO3-

Question 161

reverse chloride shift

Answer 161

HCO3- diffuses back into RBC in exchange for Cl-, free CO2 that is generated diffuses into alveolus to be exhaled

Question 162

hemoglobin unloads O2 to match….

Answer 162

metabolic needs of different states of activity of the tissues

Question 163

four factors that adjust the rate of O2 unloading to match need

Answer 163

1. ambient PO2
2. temperature
3. ambient pH
4. BPG

Question 164

four factors that adjust the rate of O2 unloading to match need: ambient PO2

Answer 164

active tissues have a low PO2 causing Hb to release O2

Question 165

four factors that adjust the rate of O2 unloading to match need: temperature

Answer 165

active tissues have a higher temperature that promotes Hb to unload O2

Question 166

four factors that adjust the rate of O2 unloading to match need: ambient pH

Answer 166

active tissue pH is higher due to higher concentrations of CO2, lowering blood pH which promotes unloading of O2

Question 167

Bohr effect

Answer 167

describes hemoglobin’s lower affinity for oxygen secondary to increases in the partial pressure of carbon dioxide and/or decreased blood pH

Question 168

four factors that adjust the rate of O2 unloading to match need: BPG

Answer 168

RBCs produce a metabolic intermediate of anaerobic metabolism called BPG which binds to Hb, unloading O2 in the process

Question 169

BPG aka

Answer 169

bisphosphoglycerate

Question 170

factors that raise BPG and promote O2 unloading (5)

Answer 170

• raised body temp (fever)
• thyroxine
• growth hormone
• testosterone
• epinephrine

Question 171

describe the effect of temperature on HbO2

Answer 171

as temperature increases, more Hb unloads O2

Question 172

describe the effect of pH on HbO2

Answer 172

as pH lowers, HbO2 releases more O2