UNIT 5 - RESPIRATORY SYSTEM

Question 1

Respiratory system

Answer 1

Group of organs and tissues used for gas exchange (breathing)

Question 2

Main respiratory structures (8)

Answer 2

• Nasal cavity (nose
• Mouth
• Pharynx (throat)
• Larynx (voice box)
• Trachea (windpipe)
• Bronchi (large airways)
• Bronchioles (small airways)
• Lungs

Question 3

Nasal cavity

Answer 3

Provides airway for respiration and moistens/warms the entering air. Filtering of air by hairs the mucous (lysozyme) and contains olfactory receptors

Question 4

Pharynx

Answer 4

Common passageway for air from nasal and buccal cavity to trachea

Question 5

Larynx

Answer 5

Common path for food and air to separate controlled by swallow reflex and epiglottis. Also the voice box

Question 6

Epiglottis

Answer 6

Flap of cartilage that protects the glottis, opening to the trachea

Question 7

Trachea

Answer 7

Long U shape tube connecting larynx to lungs supported by cartilage rings to put air into and out of the lungs

Question 8

Thyroid cartilage

Answer 8

2 large plates of cartilage on anterior wall of larynx (adams apple)

Question 9

Bronchi

Answer 9

Two primary bronchi branch into secondary and tertiary bronchi and takes air into lungs from trachea

Question 10

Right primary bronchus

Answer 10

Serves the right lung

Question 11

Left primary bronchus

Answer 11

Serves the left lung

Question 12

Bronchioles

Answer 12

Further divisions of the tertiary bronchi, the air passage inside the lungs

Question 13

Branching of bronchial tree in order (9)

Answer 13

• Trachea
• Primary bronchi
• Secondary bronchi
• Bronchioles
• Terminal bronchioles
• Respiratory bronchioles
• Alveolar duct
• Alveolar sac
• Alveoli

Question 14

Alveoli

Answer 14

Air sacs at the end of bronchioles made of a single layer of squamous epithelial cells surrounded by capillaries where gas exchange occurs and accounts for most of the lungs volume with the largest surface area

Question 15

How many alveoli do we have

Answer 15

300 million

Question 16

Alveolar epithelial cells (3)

Answer 16

• Forms nearly continuous lining
• Flat shape
• Main site of gas exchange

Question 17

Other characteristics of alveolar cells (3)

Answer 17

• Free surfaces contain microvilli secreting surfactant
• Reduce tendency to collapse
• Macrophages

Question 18

Breathing

Answer 18

Process of getting oxygen into lungs and carbon dioxide out of the lungs

Question 19

Thoracic cavity

Answer 19

Sealed cavity that houses the lungs and the heart

Question 20

Rib cage

Answer 20

Surrounds the lungs for protection

Question 21

Diaphragm

Answer 21

Muscle that helps to inhale and exhale and separates the lungs from the abdomen

Question 22

Lungs

Answer 22

Major organ in chest to transport oxygen and remove carbon dioxide surrounded by two membranes (pleural membranes)

Question 23

2 types of pleural membranes:

Answer 23

• Parietal pleura (outer): attached to walls of thoracic cavity and lines inner surface
• Visceral pleura (inner): Covers the lungs

Question 24

Pleural cavity

Answer 24

Fluid filled space between pleural membranes for lubrication between lung & wall of chest cavity, and to hold the two membranes together ensuring lungs don’t collapse

Question 25

Inspiration (inhalation)

Answer 25

Process of taking air into lungs, breathing in

Question 26

Expiration (Exhalation)

Answer 26

Process of removing air from lungs, breathing out

Question 27

Inhalation process (4)

Answer 27

• Air sucked in lung
• Diaphragm contracts and move down
• External intercostal muscles contract and ribs move upward & outward
• Volume of chest cavity increases, decreasing pressure to -1mm Hg in lungs until 0 (atmospheric pressure)

Question 28

Exhalation process (4)

Answer 28

• Air is forced out lungs
• Diaphragm relaxes and moves up
• External intercostals relax and ribs move downward & inward
• Volume of chest cavity decreases, increasing pressure to +1mm Hg in lungs until intrapulmonary pressure is 0

Question 29

Relaxed exhalation

Answer 29

Muscle relaxation

Question 30

Forced exhalation

Answer 30

Muscle relaxation and contraction of internal intercostal and abdominal muscles to increase thoracic pressure, aiding in the rapid expulsion of air from the lungs

Question 31

What mechanism controls breathing

Answer 31

Autonomic nervous system (involuntary), however we can control the rate and depth of breathing

Question 32

Breathing control center

Answer 32

AKA pons and medulla oblongata (also the cardiac centers)

Question 33

Relationship between breathing control center and cardiac center

Answer 33

The more the heart beats, the more breathing occurs. This is because as the heart beats faster, it uses more energy and sends more oxygen to body

Question 34

Medulla general function

Answer 34

Sends signals to muscles that control respiration

Question 35

Medulla (inspiratory center)

Answer 35

Accounts for normal inspiration by sending impulses to inspiratory muscles every few seconds and also activates during exercise

Question 36

Medulla (expiratory center)

Answer 36

Expiration is typically passive due to relaxation of unstimulated inspiratory muscles, but during exercise it stimulates expiratory muscles to cause forceful exhalation

Question 37

Pons general function

Answer 37

Control rate or speed of respiration

Question 38

Pons (pneumotaxic area)

Answer 38

Limits duration of inspiration and increases inspiration rate by sending inhibitory impulses to inspiratory area to prevent lungs from overfilling (eg. Exercise)

Question 39

Pons (apneustic area)

Answer 39

Increases duration of inspiration and decreases inspiration rate by sending inhibitory impulses to the inspiratory area to lengthen the inspiratory period (eg. Occurs when oxygen levels are lower than normal

Question 40

Hering-Breuer (inflation) reflex

Answer 40

Keeps the lungs from overinflating with inspired air

Question 41

Process of inflation reflex (3)

Answer 41

• Forced inspiration stimulates stretch receptors in lining of lung and sends signals to brain
• Signals inhibit inspiratory area and apneustic area
• Inspiration stops and passive expiration occurs

Question 42

Breathing control centers

Answer 42

Receives incoming information from pons/medulla and information gets interpreted, integrated and if required, response is initiated

Question 43

Efferent PNS (control of breathing)

Answer 43

Sends a response initiated by breathing control centers to respiratory muscles (intercostal/diaphragm)

Question 44

Respiratory muscles (control of breathing)

Answer 44

Respond to message from efferent PNS to increase or decrease rate/depth of breathing

Question 45

Sensory receptors:

Answer 45

Located in major arteries to measure O2 and CO2 concentrations

Question 46

Afferent PNS

Answer 46

Sends information of O2 and CO2 concentrations to the breathing control center

Question 47

Chemoreceptors

Answer 47

Special nerve/receptor that sense changes in chemical composition of blood

Question 48

2 important chemoreceptors

Answer 48

• Central chemoreceptors
• Peripheral chemoreceptors

Question 49

Central chemoreceptors

Answer 49

Located in the medulla and respond to changes in H+ and CO2 concentrations in CSF

Question 50

Peripheral chemoreceptors

Answer 50

Located in aortic bodies (aortic arch) and carotid bodies (end of common carotid) and responds to changes in H+, CO2 and O2 concentrations in blood

Question 51

Mechanism for normal blood concentrations levels

Answer 51

Via negative feedback loop

Question 52

Negative feedback control for blood concentration (5)

Answer 52

• Stimulus: Some stimulus disrupts homeostasis (Increase in arterial blood PCO2 or decrease in pH/PO2)
• Receptor: Receives stimulus by central chemoreceptors in medulla or peripheral chemoreceptors in aortic and carotid bodies send signal to inspiratory area in medulla oblongata
• Effector: Muscles of inhalation and exhalation contract more forcefully and frequently (hyperventilation)
• Cause decrease in arterial blood PCO2, increase in pH and PO2
• Repeat

Question 53

Tidal volume

Answer 53

The volume breathed in or out at rest (300-500ml)

Question 54

Expiratory reserve volume

Answer 54

The maximum volume of air that can be forced out after normal exhalation (1000-1500ml)

Question 55

Inspiratory reserve volume

Answer 55

The maximum volume of air that can be inhaled after a normal inhalation

Question 56

Vital capacity

Answer 56

Maximum volume of air that can be exhaled after maximum inhalation (2800-5000ml)

Question 57

Residual volume

Answer 57

Volume of air remaining in lung after maximum exhalation

Question 58

Total lung capacity

Answer 58

Total volume of air that lungs are capable of holding

Question 59

Dead air space

Answer 59

Air that never enters the alveoli but remains in the air passageways (150ml)

Question 60

How is oxygen transported into the blood

Answer 60

Almost all of O2 (approx. 98%) is carried by an iron containing protein found inside RBC (hemoglobin) and becomes oxyhemoglobin. Each hemoglobin molecule carries 4 O2, 1 RBC contains 300 million hemoglobin = 1200 million O2 molecules per RBC

Question 61

How does oxygen get from the blood to the cell

Answer 61

O2 enters blood by diffusion and is transported as oxyhemoglobin via circulatory system to capillaries. In the capillaries, O2 is released from hemoglobin and enters cells by diffusion

Question 62

How does the CO2 get from the cell to the lungs

Answer 62

Approx. 23% of CO2 combines with hemoglobin (carbaminohemoglobin) and CO2 produced by cell enter blood stream via diffusion (7% CO2 dissolved in plasma). The CO2 reacts with H2) to form bicarbonate and leaves blood by diffusion = 1 hemoglobin can only carry 1 CO2 molecule

Question 63

How much of O2 and CO2 transported by hemoglobin

Answer 63

O2 98.5%, CO2 23%

Question 64

How much of O2 and CO2 get transported by getting dissolved in plasma

Answer 64

O2 1.5% CO2 7%

Question 65

How much of O2 and CO2 transport as bicarbonate

Answer 65

O2 N/A, CO2 70%

Question 66

Euponoea

Answer 66

Normal breathing

Question 67

Dyspnoea

Answer 67

Difficult breathing (asthma, bronchitis, emphysema)

Question 68

Tachypnoea

Answer 68

Fast breathing (anxiety, fever in children)

Question 69

Hyperpnoea

Answer 69

Deep breathing (exercise, high altitudes)

Question 70

Aponea

Answer 70

Lack of breathing (drugs, trauma)

Question 71

Hyperventilation

Answer 71

Increased rate or depth of breathing

Question 72

Causes of hyperventilation (2)

Answer 72

• Respiratory causes: Asthma, emphysema
• Non respiratory causes: Exercise, fever, hyperthyroidism, anxiety (all increased metabolism)

Question 73

Consequences of hyperventilation (2)

Answer 73

• Hypocapnia (decrease CO2 levels) = alkalosis (increase pH level) = brain dysfunction such as tingling, unconsciousness
• Hypocapnia (decrease CO2 levels = vasodilation = hypotension (lower bp)

Question 74

Hypoxia

Answer 74

Reduced oxygen supply to body tissues

Question 75

Internal causes of hypoxia (functional deficit in body systems) (7):

Answer 75

• Hemoglobin deficiencies: Anemia, carbon monoxide poisoning
• Arterial obstruction
• Hypotension
• Edema: Congestive heart failure, renal failure
• Congenital defects: Septal defect, patent ductus arteriosus
• Obstruction of airways: Asthma, bronchitis
• Diffusion deficiency in lungs: Emphysema, pneumonia, pulmonary edema

Question 76

External causes of hypoxia (low oxygen levels in environment) (3)

Answer 76

• High altitudes
• Overcrowded rooms
• Diving

Question 77

Physiological consequences of hypoxia (3):

Answer 77

• Cyanosis
• Tachycardia
• Dizziness

Question 78

Cyanosis

Answer 78

Blueish skin color due to accumulation of non oxygenated blood

Question 79

Tachycardia

Answer 79

Autonomic nervous system mediated increase in heart rate

Question 80

Dizziness

Answer 80

Caused by insufficient oxygen supply to brain