500

Question 1

3 basic steps of respiration`

Answer 1

1) pulmonary ventilation
2) external respiration
3) internal respiration

Question 2

The respiratory system acts with the cardiovascular system to supply oxygen (O2) and remove carbon dioxide (CO2) from the blood.

Answer 2

the respiratory system consists of the nose, pharynx, larynx, trachea, bronchi, and lungs

Question 3

The partial pressure of a gas is the pressure exerted by that gas in a mixture of gases.

Answer 3

It is symbolized by Px, where the subscript is the chemical formula of the gas

Question 4

According to Dalton’s law, each gas in a mixture of gases exerts its own pressure as if all the other gases were not present.

Answer 4

3. Henry’s law states that the quantity of a gas that will dissolve in a liquid is proportional to the partial pressure of the gas and its solubility (given constant temperature)

Question 5

In internal and external respiration, O2 and CO2 diffuse from areas of higher partial pressures to areas of lower partial pressures.

Answer 5

External respiration or pulmonary gas exchange is the exchange of gases between pulmonary alveoli and pulmonary blood capillaries. It depends on partial pressure differences, a large surface area for gas exchange, a small diffusion distance across the respiratory membrane, and the rate of airflow into and out of the lungs

Question 6

In each 100 mL of oxygenated blood, 1.5% of the O2 is dissolved in blood plasma and 98.5% is bound to hemoglobin as oxyhemoglobin (Hb–O2).

Answer 6

The binding of O2 to hemoglobin is affected by PO2, acidity (pH), PCO2, temperature, and 2,3-bisphosphoglycerate (BPG).

Question 7

Bohr effect

Answer 7

In an acidic environment, hemoglobin’s affinity for O2 is lower, and O2 dissociates more readily from it

Question 8

Haldane effect

Answer 8

In the presence of O2, less CO2 binds to hemoglobin

Question 9

How Co2 is transported?

Answer 9

7%Plasma
23%Hemoglobin
70%Bicarbonate

Question 10

4 different TB tests

Answer 10

Mantoux (skin test)
Chest X-ray
lymph node biopsy
Blood test

Question 11

Blood gas ranges

Answer 11

Ph. 7.35-7.45
HCO3 21-26mEq/ml
SpO2 80-100%
ETCo2 34-45mmHg

Question 12

H2CO3

Answer 12

carbonic acid

Question 13

HCO3-

Answer 13

bicarb

Question 14

H+

Answer 14

hydrogen

Question 15

CO2

Answer 15

carbon dioxide

Question 16

H2O

Answer 16

water

Question 17

CO2 and H2O=H2CO3=HCO3- and H+

Answer 17

carbon dioxide plus water make carbonic acid (weak acid)
carbonic acid hates it self and splits. it drops 1 hydrogen and becomes bicarb and hydrogen

nothing is added or removed from equation just re-arranged

Question 18

Causes of Pulmonary Edema

Answer 18

L-Sided heart failure
Capillary membrane damage
Lymphatic system issue

Question 19

signs and symptoms of Pulmonary embolism

Answer 19

• cough
• dyspnea
• hemoptysis
• pain
• tachypnea
• tachycardia
• distended neck veins
• Chest splinting
• pleuritic pain
• pleural friction rub
• crackles
• localized wheezing

Question 20

How to size tubes for pediatrics

Answer 20

Cuffed age/4+3.5

noncuffed age/4+4

Question 21

upper and lower air way divided at

Answer 21

glottic opening

Question 22

upper air way

Answer 22

1-Nasal cavity
2-Olfactory membranes
3-Sinuses
4-Frontal 
5-Maxillary 
6-Ethmoid 
7-Sphenoid
8-Nasopharynx
9-Oropharynx 
10-Laryngopharynx

Question 23

Nasal cavity

Answer 23

• divided into left and right by nasal septum
• Rich blood supply
• warms and humidifies air
• hair traps foreign bodies

Question 24

Olfactory membranes

Answer 24

• Connect to middle ear cavity the auditory (eustachian) tubes
• smell receptors

Question 25

Sinuses – four groups

Answer 25

Frontal – above eyebrows

Question 26

Maxillary – cheekbones

Answer 26

Ethmoid – behind bridge of nose

Question 27

Sphenoid – back of skull

Answer 27

Nasopharynx – back of nasal cavity, superior part of pharynx

Question 28

Oropharynx – begins at uvula, extends to epiglottis

Answer 28

Laryngopharynx – epiglottis to esophagus

also can be called hypopharynx

Question 29

Lower air way

Answer 29

• Larynx
• Trachea
• Bronchial tree
• Lungs
• Pleural space

Question 30

Larynx

-air passageway between pharynx and lungs

Answer 30

• Protective sphincter to prevent foreign bodies
• Produces speech
• nine cartilages connected by muscles and ligaments 6 paired, 3 unpaired
• Cricoid cartilage
• Hyoid bone
• Two pairs of ligaments extend from anterior arytenoid to posterior thyroid
• Superior pair form false vocal cords
• Inferior pair compose of true vocal cords, produce voice sounds by air vibrating through

Question 31

Trachea

- air passage from larynx to lungs

Answer 31

• dense connective tissue and smooth muscle
• reinforced with 15-20 C-shaped cartilage rings 1.5cm x 9-15 cm
• Lined with ciliated epithelium that contains goblet cells
• Sweep mucus, bacteria and other small particles toward larynx

Question 32

Bronchial tree

-branches and narrows smaller until reaching the alveoli

Answer 32

-Bifurcates at the carina into left and right main stem
-Primary bronchi – lined with ciliated epithelium and supported by c-shaped cartilage rings
-Secondary bronchi –extend to the lobes of the lungs
-Tertiary Bronchi – extend to individual segments of each lobe, become bronchioles
-Bronchioles – continue to divide until reaching the alveolar ducts
Alveoli – hollow air sacs where majority gas exchange happens

Question 33

Lungs
-attached to heart by pulmonary artery and veins
Separated by mediastinum and its contents (heart, blood vessels, trachea, esophagus, lymphatic tissues, vessels)
Hilum or root – entry point of bronchi, vessels, nerves or each lung

Answer 33

• base rests on diaphragm, apex extends just superior of clavicle
• Right lung divided into 3 lobes and 10 lobules
• Left lung divided into 2 lobes and 9 lobules and has a cardiac notch where the heart sits
• Each lobule is separated by connective tissue
• vessels and bronchi do not cross connective tissue, allowing lobules to be removed should they become diseased
• Pleural and visceral layers surrounding lungs are separated by thin fluid acting as a lubricant to allow membranes to slide past each other during respiration

Question 34

Pleural space

Answer 34

• fluid lined

- potential space between pleura

Question 35

Cricoid cartilage – only complete ring, forms larynx base and supports rest of all other cartilages

Answer 35

Hyoid bone – u shaped bone, only bone in body that does not articulate with another bone, helps suspend airway, serves as ancho point for muscles of jaw

Question 36

Alveoli
– hollow air sacs where majority of respiratory gas exchange happens (functional units). Wall consists of single layer of epithelial cells, elastic fibers which permit alveoli to stretch and contract during breathing.

Answer 36

• Coated with a pulmonary surfactant, a thin fluid film which keeps alveoli from collapsing
• Each alveolus is surrounded by a fine network of blood capillaries
• Type I alveolar cells- epithelial cells
• Type II alveolar cells secrete alveolar fluid
• Alveolar macrophages – dust cells

Question 37

• Respiration – exchange of gas between atmosphere, blood, and cells
• Ventilation – Air moved into and out of the lungs

Answer 37

• Inhalation – diaphragm and external intercostal muscles contract, increasing the size of the thorax, decreasing intrapleural (intrathoracic) pressure causing lungs to expand.
• Alveolar pressure therefor falls below atmospheric pressure, allowing air to move along pressure gradient and into lungs.

-Exhalation occurs when alveolar pressure becomes higher than atmospheric pressure, diaphragm and intercostals relax, increasing intrapleural pressure decreasing lung size which increases alveolar pressure expelling air

Question 38

External Respiration – transfer of oxygen and CO2 between inspired air and pulmonary capillaries.

Answer 38

Internal Respiration (tissue level) – transfer of oxygen and CO2 between capillary red blood cells and tissue cells

Question 39

• Hypoxia – oxygen deficiency at tissue level
• Hypoxic hypoxia – low PO2 in arterial blood
• Anemic Hypoxia – too little functioning hemoglobin

Answer 39

• Stagnant hypoxia – blood unable to carry oxygen to tissues fast enough
• Histotoxic hypoxia – tissues unable to use oxygen

Question 40

Control center of Respiration

-Respiratory center in brain stem transmits impulses to respiratory muscles

Answer 40

• Dorsal respiratory group – basic automatic rhythm
• Ventral respiratory group – active during increased respiratory effort
• Pneumotaxic center – alter pattern
• Apneustic center – alter pattern

Question 41

Lung Receptors

Answer 41

• Irritant receptors (C-fibers)
• Stretch receptors
• J-receptors (juxtapulmonary capillary receptors)
• Chemoreceptors

Question 42

Irritant receptors (C-fibers)

Answer 42

• sensitive to noxious aerosols, dust, and particulates

- initiate cough reflex, stimulate bronchoconstriction and increased ventilatory rate

Question 43

stretch receptors

Answer 43

sensitive to size and volume of lungs. Decrease ventilatory rate and volume when stimulated
J-receptors

Question 44

J-receptors (juxtapulmonary capillary receptors)

Answer 44

sensitive to increased pulmonary capillary pressure, stimulation initiates rapid, shallow breathing, hypotension and bradycardia

Question 45

Chemoreceptors

Answer 45

• monitor pH, PaCO2, PaO2 of arterial blood

- relay afferent input information to dorsal respiratory group stimulating hyperventilation

Question 46

Phrenic Nerve innervation of diaphragm

Answer 46

Spinal nerves innervate intercostal muscles

Question 47

Diffusion- process of gas exchange at cellular level

Answer 47

• Between air filled alveoli and pulmonary capillary bed

- Driven by simple diffusion, gas moves from area of high concentration to area of low concentration until equal

Question 48

Perfusion – circulation of blood through lung tissue

Answer 48

-Requires adequate blood volume, adequate hemoglobin, no occlusions in pulmonary capillaries and efficient pumping of blood

Question 49

Transport of O2 in blood

98. 5% as oxyhemoglobin
99. 5% dissolved in plasma

Answer 49

Transport of CO2 in blood

>70% transported as Bicarbonate

Question 50

Volumes

• Expiratory reserve volume – 1200mL
• Anatomical dead space – conducting airways which do not participate in respiratory exchange
• Residual volume – 1200mL
• Only about 350mL of air reaches alveoli, the other 150ml remains in airways as anatomical dead space

Answer 50

• Tidal volume – volume of one breath 500mL
• Minute volume – volume of air inspired and expired in one minute
• Alveolar ventilation rate – volume of air per minute reaching respiratory zone
• Inspiratory reserve volume – 3100mL

Question 51

Lung capacities – sum of two or more lung volumes

Answer 51

Inspiratory Reserve Volume – tidal volume + inspiratory reserve
Functional Residual – residual volume + expiratory reserve volume
Vital – inspiratory reserve + tidal + expiratory reserve
Total lung capacities

Question 52

Oxyhemoglobin Dissociation Curve

CADET – shift right – causes release of oxygen faster

Answer 52

• increased CO2 -
• increased Acid (low pH)
• increased DPG/BPG – substance formed in red blood cells during glycolysis
• increased Exercise (release lactic acid)
• Temperature

Question 53

Bohr’s – physiological dead space in lungs

Answer 53

Boyles – inverse relationship between volume and pressure

Question 54

Henry’s – quantity of gas that will dissolve in a liquid is proportional to the partial pressure of the gas and its solubility when temperature remains the same

Answer 54

Charles – temp goes up, so does volume

Question 55

Haldane effect – less oxyhemoglobin more carboxyhemoglobin

Answer 55

Daltons – each gas in a mixture of gases exerts its own pressure as if all other gasses were not present
Partial pressure is the pressure exerted by that gas in a mixture

Question 56

Partial Pressures of Gasses
Total pressure of all atmospheric gasses – 760mmHg or torr

Atmospheric partial pressures
Nitrogen 597.0 torr – 78.62%
Oxygen 159.0 torr – 20.84%
Carbon dioxide 0.3 torr – 0.04%
Water 3.7 torr – 0.5%

Answer 56

Alveolar Partial pressures
Nitrogen 569.0 – 74.9%
Oxygen 104.0 torr – 13.7%
CO2 40 torr – 5.2%
Water 47.0 torr – 6.2%

Question 57

2/3 body water is considered intracellular fluid

Answer 57

1/3 is extracellular fluid and includes intestinal fluid, blood plasma and lymph, CSF, synovial fluid, fluid of eyes ears, pleural, pericardial and peritoneal fluids

Question 58

fluid (water) Loss through urination, evaporation, exhalation and defecation

Answer 58

Urination is primary loss of NaCl and therefor water, is a main determinate of body fluid volume

Question 59

-Angiotensin II and Aldosterone reduce urinary loss of Na+ which helps increase body water

Answer 59

-Antidiuretic hormone regulates water loss and body fluid osmolarity

Question 60

Increasing osmolarity of ISF draws water out of cells, shrinking them slightly and vice-versa

Answer 60

Besides ingesting liquids and food water can also be produced through cellular respiration and dehydration synthesis reactions

Question 61

Capillary hydrostatic pressure (blood pressure) – facilitates outward movement of water from capillary to interstitial

Answer 61

Capillary (plasma) oncotic pressure – osmotically attracts water from interstitial into capillary

Question 62

Interstitial hydrostatic pressure – facilitates inward movement of water from interstitial into capillary

Answer 62

Interstitial oncotic pressure – osmotically attracts water from the capillary into the interstitial

Question 63

Golden rule
Respiratory Acidosis

• decreased PH
• normal HCO3 (bicarb)
• increased PCO2 (partial pressure of CO2)

Answer 63

Golden rule
Respiratory Alkalosis

• increased PH
• normal HCO3 (bicarb)
• decreased PCO2 (patial pressure of CO2)

Question 64

Golden rule
Metabolic Acidosis

• decreased PH
• decreased HCO3 (bicard)
• normal PCO2 (partial pressure of CO2)

Answer 64

Golden rule
Metabolic Alkalosis

• increased PH
• increased HCO3 (bicarb)
• normal PCO2 (partial pressure of CO2)

Question 65

Patho of ARDS

Acute Respiratory Distress Syndrome

Answer 65

ARDS is

• acute lung inflamation and alveolar-capillary injury
• all disorders that result in ARDS cause severe pulmonary edema

Question 66

causes of ARDS

Answer 66

• trauma -pneumonia
• aspiration -O2 toxicity
• bypass surgery -toxic inhalation
• infections -gram negative sepsis
• over dose -multiple blood transfusions

Question 67

ARDS

-increased capillary permeability (high permeability causing pulmonary edema

Answer 67

• making lungs wet and heavy, congested, hemorrhagic and stiff
• lungs become non-compliant (requires patient to increase airway pressure to breath. PEEP)

Question 68

ARDS is respiratory failure with acute lung inflamation and alveolar capillary injury
-causing pulmonary edema

Answer 68

• pulmonary edema leads to
• hypoxemia
• intrapulmonary shunting
• reduced lung compliance
• lung tissue damage (some cases irreversible)

Question 69

ARDS is more common in men

Answer 69

mortality rate over 65%

Question 70

complications of ARDS

Answer 70

• respiratory failure
• cardiac dysrhythmias
• disseminated intravascular coagulation
• barotrauma
• CHF
• renal failure

Question 71

prehospital management of ARDS

Answer 71

-hi flow o2
-ventalation support
-fluid replacement
-drug therapy
(peep, broncho dialators, steriods, RSI, diuretics)

Question 72

normal concentraion of bi carb is 24mEq/ml

Answer 72

ratio of bicarb to carbonic acid is 20:1

Question 73

normal values of
PH
PCO2
PO2HCO3

Answer 73

PH 7.35-7.45
PCO2 35-45
PO2 80-100
HCO3 21-26 (avg 24)

Question 74

3 buffer system #1
blood buffer
respiratory
renal

Answer 74

3 buffer #2

• carbonic acid (quickest)
• phosphate renal tubes (weak acid, weak base)
• protein in Intra-cellular fluid, blood plasma. free amino or free carboxyl groups and forms hemaglobin or albuin