Respiratory System Review - Oxygen Supply and Demand

Question 1

Surfactant

Answer 1

reduces the amount of pressure needed to inflate the alveoli. Decreases surface tension

Question 2

Anatomical deadspace

Answer 2

Nose to the bronchioles. only the conducting pathway and is it termed anatomic deadspace. Not involved in gas exchange

Question 3

Where the trachea bifurcates

Answer 3

the carina or angle of louis
anything above it is the upper respiratory tract and anything below is the lower respiratory tract

Question 4

which lung is more likely to have aspirate in it and why?

Answer 4

the right lung because the bronchi is shorter, fatter and less angled. also more likely for deep suction catheter or NG tubes to go into that side.

Question 5

Blood supply

Answer 5

Pulmonary circulation (pulmonary arteries bring deoxygenated blood)
Bronchial circulation (supplies blood to the larger airways of the respiratory tract)

Question 6

Normal tidal volume

Answer 6

500 mls

Question 7

Three structures involved in ventilatory function

Answer 7

Thoracic cage
Pleura
Respiratory muscles

Question 8

Thoracic cage

Answer 8

24 ribs (12 on each side)
Sternum

Question 9

Pleura (2 layers)

Answer 9

Chest cavity is lined with parietal pleura and lungs are lined with visceral pleura these are joined and form a sac for the lungs.
Intrapleural space is the space between the layers. increases cohesion, faciliates chest expansion and lubrication.

Question 10

how much fluid should be in the intrapleural space?

Answer 10

20-25 mls

Question 11

Respiratory Muscles

Answer 11

Diaphragm
Intercostal muscles
Abdominal muscles

Question 12

How is fluid drained from the intrapleural space

Answer 12

lymphatic circulation drains fluid from the intrapleural space. shouldnt have additional fluid. If we develop fluid its because there is deficiency in normal drainage.

Question 13

what is it called when too much fluid accumulates in the pleural space

Answer 13

pleural effusion

Question 14

what causes a pleural effusion

Answer 14

malignant cells blocking lymphatic drainage
imbalance between fluid pressures (intravascular and oncotic pressure) this occurs in HF and is an example of third-spacing. can’t be brought back into the vascular space

Question 15

Which nerve innervates the diaphragm

Answer 15

the phrenic nerve. paralysis at or above C3 will mean the patient is reliant on mechanical ventilation.

Question 16

Empyema

Answer 16

the presence of purulent fluid with bacterial infection

Question 17

Pneumothorax

Answer 17

Air in the pleural space

Question 18

Hemothorax

Answer 18

Blood in the pleural space

Question 19

Empyema
Pneumothorax
Hemothorax

Answer 19

each of these conditions can lead to partial or complete collapse of the lung

Question 20

ventilation involves

Answer 20

inspiration and expiration

Question 21

inspiration is

Answer 21

active

Question 22

expiration is

Answer 22

passive

Question 23

Compliance

Answer 23

a measure of the elasticity of the lungs and the thorax
when compliance is decreased, inflation of the lungs is more difficult.

Question 24

what conditions decreased lung complaince (3):

Answer 24

those that increase fluid in the lungs (pulmonary edema)
diseases that affect lung tissue and make it less elastic (pulmonary fibrosis)
conditions that restrict lung movement (pleural effusion)

Question 25

how do O2 and CO2 move across the alveolar capillary membrane ?

Answer 25

diffusion

Question 26

The ability of the lungs to properly oxygen arterial blood is determined by

Answer 26

Partial pressure of oxygen in arterial blood or PaO2 (the amount of O2 dissolved in the plasma)
Arterial oxygen saturation or SaO2 (amount of O2 bound to hemoglobin of how much is available)

Question 27

Oxygen-Hemoglobin Dissociation Curve

Answer 27

Oxygen delivered to the tissues depends on the amount of oxygen transported to the tissues and the ease with which hemoglobin gives up hemoglobin onces it gets to the tissues. Affinity
Upper flat portion – large changes in PaO2 cause small changes in hemoglobin saturation. Large change in PaO2 before we see it in the pulse ox. For this reason, if the PaO2 drops from 100 to 60 the percentage of the SaO2 will only drop 7%. Also explains why a patient is considered adequately oxygenated when the PaO2 is > 60 mmHg. Increasing the PaO2 does little for the SaO2.
On the left side – as hemoglobin is desaturating, larger amounts of oxygen are released for tissue use. This is an important method to ensure adequate oxygen supply even if O2 delivery is compromised.

Question 28

End Organ Perfusion Assessment: Brain

Answer 28

Level of consciousness is the most sensitive neurological assessment parameter for evaluating cerebral perfusion and oxygen supply

Question 29

End Organ Perfusion Assessment: Heart

Answer 29

Signs of myocardial ischemia will alert us to imbalances in myocardial oxygen supply and demand. Anginal chest pain, SOB, and ECG changes provide clues to myocardial perfusion

Question 30

End Organ Perfusion Assessment: Lungs

Answer 30

Inadequate pulmonary perfusion will result in poor gas exchange. decreased PaO2 and SaO2

Question 31

End Organ Perfusion Assessment: Gut

Answer 31

Decreased gut function will result from poor gut perfusion. Decreased gut perfusion can result in decreased gut motility, abdominal pain, nausea, and vomiting.

Question 32

End Organ Perfusion Assessment: Liver

Answer 32

The liver is responsible for many functions that are important to the body (metabolic, filtration, and storage). Changes in lab parameters related to these functions would alert us to decreased liver perfusion.

Question 33

End Organ Perfusion Assessment: Kidneys

Answer 33

BUN and creatinine provide information regarding renal perfusion, as does the amount of urine being produced by the kidneys.

Question 34

End Organ Perfusion Assessment: General tissue perfusion

Answer 34

Skin warmth, color, pulse strength, and capillary refill all provide indications of general tissue perfusion

Question 35

Oxygen Supply: Arterial Oxygen Content

Answer 35

amount of oxygen that is present in the arterial blood when it leaves the lungs (PaO2)

Question 36

Oxygen Supply: Hemoglobin

Answer 36

capacity of the blood to transport oxygen to the cells (hgb)

Question 37

Oxygen Supply: Heart Function

Answer 37

Effectiveness of the pump that circulates the blood throughout the body

Question 38

Oxygen Demand (3)

Answer 38

1. Temperature
2. Activity Level
3. Stress (emotional and physiological)

Question 39

Factors Affecting Oxygen Supply: Ventilation (4)

Answer 39

1. PaCO2
2. RR
3. Tidal volume, vital capacity, functional residual capacity
4. Work of breathing (resp muscle function, lung compliance, airway resistance)

Question 40

Tidal Volume

Answer 40

The amount of air that moves in or out of the lungs with each inspiration and expiration

Question 41

Vital Capacity

Answer 41

greatest volume of air that can be expelled from the lungs after taking the deepest possible breath

Question 42

Functional Residual Capacity

Answer 42

The volume remaining in the lungs after a normal passive expiration - 3L

Question 43

Work of Breathing 3 Factors that impact a patient’s capacity to increase their work of breathing

Answer 43

Respiratory Muscle Function
Lung compliance
Airway resistance

Question 44

Respiratory Muscle Function

Answer 44

Neuromuscular function, spinal cord injuries, pts who cant expectorate

Question 45

Lung compliance

Answer 45

the lungs ability to stretch and expand. Pulmonary fibrosis or COPD

Question 46

Alveolar Gas Exchange

Answer 46

PaO2
V/Q mismatch
- alveoli ventilated?
- alveoli perfused?
Cardiac Output (CO)
Diffusion

Question 47

V/Q mismatch

Answer 47

typically our lungs have a 1:1 ratio. We should be equally as well ventilated as we are perfused. The lung is receiving oxygen but doesn’t have blood flow or is receiving blood flow but doesn’t have oxygen.
where the mismatch is happening impacts the treatment we give

Question 48

Diffusion

Answer 48

CO2 diffuses 20x more rapidly than O2
CO2 levels are significantly affected by ventilation
Driving pressure of CO2
CO2 monitor is a more accurate representation of oxygen than pulse ox. another vital sign of ventilation

Question 49

Oxygen transport and Delivery Impacted By (2)

Answer 49

Hbg Level
Oxygen Hemoglobin Affinity
a) PH
b) CO2
c) Temperature
- lower the CO2, higher pH and low temperature - the higher the oxygen hemogloin affinity SHIFT TO THE LEFT
Higher Co2, lower pH, higher temperature (sepsis) - tissues get more oxygen. Lower afinity. This is a shift to the right.

Question 50

Shift to the RIGHT

Answer 50

higher CO2
Higher temp
lower pH
tissues get more oxygen. lower affinity between oxygen and hemoglobin

Question 51

Shift to the LEFT

Answer 51

Lower CO2
Lower temp
Higher pH
The higher the oxygen hemoglobin affinity.

Question 52

Cardiac Output

Answer 52

Heart Rate x Stroke Volume

Question 53

Stroke Volume (3)

Answer 53

Contractility - how effectively te heart pumps and can eject its full volume of blood
Preload - the filling time of the heart
Afterload: systemic vascular resistance. The pressure it has to pump against

Question 54

Blood Pressure and HR
What is MAP?

Answer 54

Essentially reflects the diameter and elasticity of the blood vessels
MAP: influenced by CO. care about it because if its low it means we aren’t perfusing tissues properly. The definition of MAP is the average arterial pressure throughout one cardiac cycle, systole and diastole.