Respiratory - First Aid Flashcards

Question 1

Q

Large airways consist of…

Answer

A

nose, pharynx, larynx, trachea and bronchi.

Question 2

Q

Small airways consist of…

Answer

A

bronchioles and terminal bronchioles (large numbers in parallel give the least resistance).

Question 3

Q

The conducting zone acts to…

Answer

A

warm, humidify and filter air but it does not participate in gas exchange. It is anatomic dead space.

Question 4

Q

Cartilage and goblet cells extend to…

Answer

A

the end of the bronchi.

Question 5

Q

Pseudostratified ciliated columnar cells (which beat mucus up and out of the lungs) extend to…

Answer

A

the beginning of the terminal bronchiles and then transitions to the cuboidal cells.

Question 6

Q

Airway smooth muscles extend to…

Answer

A

the end of terminal bronchioles and is sparse beyond this point.

Question 7

Q

The respiratory zone consists of…

Answer

A

respiratory bronchiles, alveolar ducts and alveoli. These participate in gas exchange.

Question 8

Q

The respiratory zone is mostly made of…

Answer

A

cuboidal cells in respiratory bronchioles and then is simple squamous cells up to the alveoli. No cilia.

Question 9

Q

Type I pneumocytes make up…

Answer

A

97% of the alveolar surfaces. They line the alveoli. Squamous. Thin for optimal gas diffusion.

Question 10

Q

Type II pneumocytes secrete…

Answer

A

pulmonary surfactant which leads to decreased alveolar surface tension and prevention of alveolar collapse (atelectasis). They are cuboidal and clustered.

Question 11

Q

Type II pneumocytes also serve as…

Answer

A

precursors to type I cells and other type II cells. They proliferate during lung damage.

Question 12

Q

Clara (club) cells are…

Answer

A

nonciliated; columnar/cuboidal with secretory granules.

Question 13

Q

Clara cells secrete…

Answer

A

a component of surfactant and degrade toxins.

Question 14

Q

Collapsing pressure =

Answer

A

2(surface tension)/radius

Question 15

Q

Alveoli have increased tendency to collapse on…

Answer

A

expiration as radius decreases.

Question 16

Q

Pulmonary surfactant is a complex mixture of…

Answer

A

lecithins, the most important of which is dipalmitoylphosphatidylcholine.

Question 17

Q

Surfactant synthesis begins around…

Answer

A

week 26 of gestation but mature levels are not achieved until around week 35.

Question 18

Q

Lecithin to sphingomyelin ratio that indicates fetal lung maturity is…

Question 19

Q

Right lung has…

Answer

A

3 lobes. Left Lobe has Less and Lingula.

Question 20

Q

The more common site for inhaled foreign bodies is…

Answer

A

the right lung bc the right main stem bronchus is wider and more vertical than the left.

Question 21

Q

Aspiration while upright ends up in the…

Answer

A

lower portion of the right inferior lobe.

Question 22

Q

Aspiration while supine ends up in the…

Answer

A

superior portion of the right inferior lobe.

Question 23

Q

The relation of the pulmonary artery to the bronchus at each lung hilus is described by…

Answer

A

RALS - Right Anterior; Left Superior.

Question 24

Q

Structures perforating the diaphragm:

Answer

A

-At T8: IVC -At T10: esophagus, vagus -At T12: aorta, thoracic duct, azygous vein

Question 25

Q

The diaphragm is innervated by…

Answer

A

C3, 4 and 5 (phrenic nerve).

Question 26

Q

Pain from diaphragm irritation can be referred to..

Answer

A

the shoulder (C5) or the trapezius ridge (C3, 4).

Question 27

Q

Inspiratory Reserve Volume (IRV)

Answer

A

air that can still be breathed in after normal inspiration

Question 28

Q

Tidal Volume (TV)

Answer

A

air that moves into the lung with each quiet inspiration (about 500 mL)

Question 29

Q

Expiratory Reserve Volume (ERV)

Answer

A

air that can still be breathed out after normal expiration

Question 30

Q

Residual Volume (RV)

Answer

A

air in lung after maximal expiration; cannot be measured on spirometry

Question 31

Q

Inspiratory capacity (IC)

Question 32

Q

Functional Residual Capacity (FRC)

Answer

A

RV + ERV (volume in lungs after normal expiration)

Question 33

Q

Vital Capacity (VC)

Answer

A

TV + IRV + ERV; maximum volume of gas that can be expired after a maximal inspiration

Question 34

Q

Total Lung Capacity (TLC)

Answer

A

IRV + TV + ERV + RV; volume of gas present in lungs after a maximal inspiration

Question 35

Q

V(D) =

Answer

A

physiologic dead space = anatomic dead space of conducting airways plus functional dead space in the alveli (volume of inspired air that does not participate in gas exchange)

Question 36

Q

Equation for V(D) =

Answer

A

VT x (PaCO - PECO)/PaCO

Question 37

Q

The largest contributor of functional dead space is…

Answer

A

the apex of a healthy lung.

Question 38

Q

Minute ventilation (V(E))

Answer

A

total volume of gas entering the lungs per minute V(E) = V(T) x RR

Question 39

Q

Alveolar ventilation (V(A))

Answer

A

volume of gas per unit time that reaches the alveoli V(A) = (VT-VD) x RR

Question 40

Q

The lungs have a tendency to…

Answer

A

collapse inward and the chest wall has a tendency to spring outward.

Question 41

Q

At FRC, the inward pull of the lung is…

Answer

A

balanced by outward pull of the chest wall and the system pressure is atmospheric.

Question 42

Q

Elastic properties of the chest wall and lungs determine their…

Answer

A

combined volume.

Question 43

Q

At FRC, airway and alveolar pressures are…

Answer

A

0 and intrapleural pressure is negative (which prevents pneumothorax). PVR is at minimum.

Question 44

Q

Compliance is…

Answer

A

the chang in lung volume for a given change in pressure.

Question 45

Q

Compliance is decreased in…

Answer

A

pulmonary fibrosis, pneumonia and pulmonary edema.

Question 46

Q

Compliance is increased in…

Answer

A

emphysema and normal aging.

Question 47

Q

Hemoglobin (Hb) is composed of…

Answer

A

4 polypeptide subunits (2 alpha and 2 beta) .

Question 48

Q

Hb exists in 2 forms:

Answer

A

T (taut) form has a low affinity for O2 2. R (relaxed) form has a high affinity for O2

Question 49

Q

Hb exhibits..

Answer

A

positive cooperativity and negative allostery.

Question 50

Q

Factors that favor the taut form of Hb

Answer

A

-increased Cl -increased H+ -CO2 -2,3-BPG -Temperature

Question 51

Q

Factors that favor the taut form of Hb cause…

Answer

A

the dissociation curve to shift to the right leading to increased oxygen unloading

Question 52

Q

Fetal Hb (2 alpha and 2 gamma) has lower affinity for…

Answer

A

2,3-BPG and thus higher affinity for O2.

Question 53

Q

Methemoglobin is…

Answer

A

the oxidized form of Hb (ferric, Fe3+) that does not bind O2 as readily but has increased affinity for cyanide.

Question 54

Q

Methemoglobinemia may present with…

Answer

A

cyanosis and chocolate-colored blood.

Question 55

Q

To treat cyanide poisoning, use…

Answer

A

nitrites to oxidize Hb to methemoglobin which binds the cyanide. Then use thiosulfate to bind this cyanide forming thiocyanate which is renally excreted.

Question 56

Q

Methemoglobinemia can be treated with…

Answer

A

methylene blue.

Question 57

Q

Carboxyhemoglobin is a…

Answer

A

form of Hb bound to CO in place of O2. This causes decreased oxygen binding capacity with a left shift in the oxygen hemoglobin dissociation curve and decreased O2 unloading in tissues.

Question 58

Q

The affinity of CO for Hb is…

Answer

A

200x greater than O2.

Question 59

Q

The oxygen-Hb dissociation curve has a…

Answer

A

sigmoidal shape due to the positive cooperativity (tetrameric Hb can bind 4 O2 molecules and has higher affinity for each subsequent O2 molecule bound).

Question 60

Q

Myoglobin does not show positive cooperativity bc…

Answer

A

it is monomeric. Curve lacks sigmoid shape.

Question 61

Q

When the oxygen-hemoglobin curve shifts to the right, there is…

Answer

A

decreased affinity of Hb for O2. (facilitates unloading of O2 to tissue)

Question 62

Q

An increase in all factors of the O2-Hb curve cause…

Answer

A

a shift of the curve to the right.

Question 63

Q

The curve for fetal Hb is…

Answer

A

shifted to the left.

Question 64

Q

Factors that cause right shift (BAT ACE):

Answer

A

B - BPG A - Altitude T - Temperature A - Acid (H+) C - CO2 E - Exercise

Answer 63

A

deoxygenated Hb > 5 g/dL.

Answer 64

A

low-resistance, high-compliance system.

Answer 65

A

a hypoxic vasoconstriction (opposite of most tissues) that shifts blood away from poorly ventilated regions of the lung to well-ventilated regions.

Answer 66

A

-O2 (normal health) -CO2 -N2O

Answer 67

A

equilibrate early along the length of the capillary and diffusion can be increased only if blood flow increases.

Answer 68

A

does not equilibrate by the time blood reaches the end of the capillary.

Answer 69

A

-O2 (emphysema, fibrosis) -CO

Answer 70

A

hypoxemia; causes include shunting, V/Q mismatch, fibrosis

Answer 71

A

-high altitude -hypoventilation

Answer 72

A

-V/Q mismatch -diffusion limitation -right to left shunt

Answer 73

A

decreased CO 2. hypoxemia 3. anemia 4. CO poisoning

Answer 74

A

3 (wasted ventilation)

Answer 75

A

.6 (wasted perfusion)

Answer 76

A

the base of the lung than the apex.

Answer 77

A

exercise because there is vasodilation of apical capillaries resulting in a V/Q ratio that approaches 1.

Answer 78

A

flourish in the apex (TB).

Answer 79

A

airway obstruction (shunt). 100% O2 will not improve PO2.

Answer 80

A

blood flow obstruction. 100% O2 will improve PO2.

Answer 81

A

HCO3- (90%) 2. Carbaminohemoglobin (HbCO2) (5%) 3. dissolved CO2 (5%)

Answer 82

A

In the lungs, oxygenation of Hb promotes dissociation of H+ from Hb. This shifts equilibrium toward CO2 formation. Therefore, CO2 is released from RBCs.

Answer 83

A

In peripheral tissues, increased H+ from tissue metabolism shifts the curve to the right unloading O2.

Answer 84

A

decreased PaO2 which increases ventilation which decreases PaCO2.

Answer 85

A

-decreased PaCO2 -increased ventilation -increased erythropoietin -increased 2,3-BPG -increased mitochondria -increased renal excretion of HCO3- (to compensate for respiratory alkalosis)

Answer 86

A

increased hematocrit and Hb

Answer 87

A

-increased CO2 production -increased O2 consumption -increased ventilation rate to meet O2 demand -increased pulmonary bf due to increased CO -decreased pH (secondary to lactic acidosis)

Answer 88

A

PaO2 and PaCO2 but ther is increase in venous CO2 and decrease in venous O2.

Answer 89

A

obstruction of sinus drainage into the nasal cavity leading to inflammation and pain over the affected area (typically maxillary sinuses).

Answer 90

A

viral URI. This may cause a superimposed bacterial infxn (S. pneumoniae, H. influenzae and M. catarrhalis).

Answer 91

A

Virchow Triad: 1. Stasis 2. Hypercoagulability (most commonly Factor V Leiden) 3. Endothelial damage

Answer 92

A

doriflexion of foot leads to leg pain; seen in DVT

Answer 93

A

V/Q mismatch which leads to hypoxemia and then respiratory alkalosis.

Answer 94

A

-sudden onset dyspnea -chest pain -tachypnea -sudden death

Answer 95

A

fat 2. air 3. thrombus 4. bacteria 5. amnitotic fluid 6. tumor

Answer 96

A

long bone fractures and liposuction.

Answer 97

A

Hypoxemia 2. Neuro abnormalities 3. Petechial rash

Answer 98

A

DIC, especially post-partum.

Answer 99

A

nitrogen bubbles that precipitate in ascending divers; treat with hyperbaric oxygen.

Answer 100

A

CT pulmonary angiography.

Answer 101

A

interdigitating areas of pink (platelets, fibrin) and red (RBCs) found only in thrombi formed before death.

Answer 102

A

air trapping in the lungs. Airways close prematurely at high lung volumes leading to: increaesed RV, decreased FVC.

Answer 103

A

-markedly decreased FEV1 -decreased FVC -decreased FEV1/FVC (hallmark) -V/Q mismatch

Answer 104

A

cor pulmonale.

Answer 105

A

Bronchitis (blue bloater) 2. Emphysema (pink puffer) 3. Asthma 4. Bronchiectasis

Answer 106

A

hyperplasia of the mucus secreting glands in the bronchi (Reid index > 50%)

Answer 107

A

wheezing 2. crackles 3. cyanosis 4. late-onset dyspnea 5. CO2 retention

Answer 108

A

a productive cough for more than 3 months per year for more than 2 years.

Answer 109

A

enlargement of airway spaces, decreased recoil, increased compliance, decreased DLCO.

Answer 110

A

loss of elastic fibers due to increased elastase activity.

Answer 111

A

Centriacinar - associated with smoking 2. Panacinar - associated with alpha1-antitrypsin acitivity

Answer 112

A

-barrel chest -exhalation through pursed lips (to increase airway pressure and prevent airway collapse during respiration)

Answer 113

A

bronchial hyperresponsiveness that causes reversible bronchoconstriction.

Answer 114

A

smooth muscle hypertrophy Curschmann spirals (shed epithelium form mucus plugs) Charcot-Leyden crystals (from breakdown of eosinophils)

Answer 115

A

the methacholine challenge.

Answer 116

A

-cough -wheezing -tachypnea -dyspnbea -hypoxemia -decreased I/E ratio -pulsus paradoxus -mucus plugging

Answer 117

A

chronic necrotizing infection of bronchi leading to permanently dilated airways, purulent sputum , recurrent infxns and hemoptysis.

Answer 118

A

bronchial obstruction 2. poor ciliary motility (smoking) 3. Karatgener 4. cystic fibrosis 5. allergic bronchopulmonary aspergillosis

Answer 119

A

decreased lung volumes decreased FVC decreased TLC

Answer 120

A

-FEV1/FVC ratio is > 80%

Answer 121

A

Poor breathing mechanics 2. interstitial lung diseases

Answer 122

A

extrapulmonary 2. peripheral hypoventilation 3. normal A-a gradient

Answer 123

A

-polio -myasthenia gravis

Answer 124

A

-scoliosis -morbid obesity

Answer 125

A

-decreased pulmonary diffusing capacity -increased A-a gradient

Answer 126

A

-bilateral hilar lymphadenopathy -noncaseating granuloma -increased ACE and Ca2+

Answer 127

A

farmers and those exposed to birds. It is a mixed type III?IV HSR due to rxn to environmental Ag.

Answer 128

A

cor pulmonale and Caplan syndrome.

Answer 129

A

RA, and pneumoconioses with intrapulmonary nodules.

Answer 130

A

shipbuilding, roofing and plumbing.

Answer 131

A

-“ivory white” calcified pleural plaques -asbestos (ferruginous) bodies: golden-brown fusiform rods resembling dumbbells

Answer 132

A

asbestos exposure but they are not pre-cancerous. They are associated with an increased incidence of bronchogenic carcinoma and mesothelioma.

Answer 133

A

the lower lobes.

Answer 134

A

macrophages laden with carbon leading to inflammation and fibrosis. aka black lung disease.

Answer 135

A

the upper lobes.

Answer 136

A

an asymptomatic condition found in many urban dwellers exposed to sooty air.

Answer 137

A

foundaries, sandblasting, and mines.

Answer 138

A

macrophages respond to silica and release fibrogenic factors leading to fibrosis.

Answer 139

A

TB and bronchogenic carcinoma.

Answer 140

A

upper lobes.

Answer 141

A

“eggshell” calcification of hilar lymph nodes

Answer 142

A

surfactant deficiency that leads to increased surface tension and alveolar collapse.

Answer 143

A

neonatal RDS.

Answer 144

A

retinopathy of prematurity and bronchopulmonary dysplasia.

Answer 145

A

prematurity 2. maternal diabetes (due to increased fetal insulin) 3. C-section (due to decreased release of fetal gluococorticoids)

Answer 146

A

maternal steroids before birth 2. artificial surfactant for the infant

Answer 147

A

trauma, sepsis, shock, gastric aspiration, uremia, acute pancreatitis or amniotic fluid embolism.

Answer 148

A

diffuse alveolar damage leads to increased alveolar capillary permeability leadsto protein-rich leakage into alveoli and noncardiogenic pulmonary edema (normal PCWP)

Answer 149

A

formation of intra-alveolar hyaline membrane

Answer 150

A

release of neutrophilic substances toxic to the alveolar wall, activation of coagulation cascade and oxygen-derived free radicals.

Answer 151

A

10-14 mmHg

Answer 152

A

>25 mmHg at rest

Answer 153

A

arteriosclerosis, medial hypertrophy, and intimal fibrosis of the pulmonary arteries.

Answer 154

A

an inactivating mutation in the BMPR2 gene (which normally functions to inhibit vascular smooth muscle proliferation; poor prognosis.

Answer 155

A

COPD (destruction of lung parenchyma) mitral stenosis (increased resistance leading to increased pressure) recurrent thromboemboli (decreased cross-sectional area of pulmonary vascular bed) autoimmune disease (sclerosis) left to right shunt (endothelial injury) sleep apnea living at high altitude

Answer 156

A

severe respiratory distress leads to cyanosis and RVH leads to death from decompensated cor pulmonale

Answer 157

A

repeated cessation of breathing for more than ten seconds during sleep.

Answer 158

A

HTN, arrhythmias and sudden death

Answer 159

A

no respiratory effort

Answer 160

A

respiratory effort against airway obstruction; associated with obesity and loud snoring

Answer 161

A

-weight loss -CPAP -surgery

Answer 162

A

the hypoxia leads to increased EPO release.

Answer 163

A

obesity leads to hypoventilation leads to decreased PaO2 and increased PaCO2 during waking hours

Answer 164

A

decreased breath sounds dull to percussion decreased fremitus

Answer 165

A

decreased breath sounds dull to percussion decreased fremitus trachea deviation toward side of lesion

Answer 166

A

decreased breath sounds hyperresonant to percussion decreased fremitus tracheal deviation toward side of lesion

Answer 167

A

decreased breath sounds hyperresonant to percussion decreased fremitus tracheal deviation away from side of lesion

Answer 168

A

bronchial breath sounds late inspiratory crackles dull to percussion increased fremitus

Answer 169

A

radiolucent (dark).

Answer 170

A

pulmonary embolism

Answer 171

A

cough hemoptysis bronchial obstruction wheezing pneumonic “coin” lesion on CXR noncalcified nodule on CT

Answer 172

A

Superior vena cava syndrome Pancoast tumor Horner syndrome Endocrine (paraneoplastic) Recurrent laryngeal symptoms Effusions

Answer 173

A

bronchial carcinoid.

Answer 174

A

adenocarcinoma.

Answer 175

A

k-ras EGFR ALK

Answer 176

A

hypertrophic osteoarthropathy (clubbing).

Answer 177

A

hazy infiltrates to pneumonia.

Answer 178

A

grows along alveolar septa leading to an apparent “thickening” of the alveolar walls

Answer 179

A

-hilar mass arising from bronchus -cavitation -cigarettes -hypercalcemia

Answer 180

A

produces PTHrP

Answer 181

A

-keratin pearls -intercellular bridges

Answer 182

A

-undifferentiated -amplification of myc (L-myc) -inoperable (treat with chemo)

Answer 183

A

ACTH, ADH or Antibodies against presynaptic Ca2+ channels (Lambert-Eaton)

Answer 184

A

-neoplasm of neuroendocrine Kulchitsky cells (small dark blue cells)

Answer 185

A

-highly anaplastic, undifferentiated -poor prognosis -less responsive to chemo -removed surgically

Answer 186

A

pleomorphic giant cells

Answer 187

A

-excellent prognosis -symptoms usually due to mass effect -occasionally carcionid syndrome

Answer 188

A

-nests of neuroendocrine cells -chromogranin A positive

Answer 189

A

malignancy of the pleura associated with asbestosis.

Answer 190

A

hemorrhagic pleural effusions and pleural thickening.

Answer 191

A

psammoma bodies.

Answer 192

A

carcinoma that occurs in the apex of the lung and may affect the cervical sympathetic plexus causing Horner syndrome (ipsilateral ptosis, miosis and anhidrosis), SVC syndrome, sensorimotor deficits and hoarseness.

Answer 193

A

an obstruction of the SVC that impairs blood drainage from the head (facial plethora), neck (JVD) and upper extremities (edema). Medical emergency.

Answer 194

A

malignancy and thrombosis from indwelling catheters.

Answer 195

A

intracranial pressure leading to HAs, dizziness and increased risk of aneurysm/ruptureof intracranial arteries.

Answer 196

A

-S. pneumoniae (most frequent) -Legionella -Klebsiella

Answer 197

A

-intra-alveolar exudate leading to consolidation -may involve entire lung

Answer 198

A

-S. pneumoniae -S. aureus -H. influenzae -Klebsiella

Answer 199

A

-acute inflammatory infiltrates from bronchiles into adjacent alveoli -patchy distribution

Answer 200

A

-viruses (influenza, RSV, adenoviruses) -mycoplasma -legionella -chlamydia

Answer 201

A

-diffuse, patchy inflammation localized to interstitial areas at alveolar walls -generally follows indolent course

Answer 202

A

a localized collection of pus within parenchyma

Answer 203

A

bronchial obstruction (cancer) or aspiration of oropharyngeal contents (esp in alcoholics or epileptics)

Answer 204

A

air-fluid levels

Answer 205

A

-S. aureus -anaerobes (bacteroides, fusobacterium, peptostreptococcus)

Answer 206

A

clindamycin because it covers S. aureus and anaerobes.

Answer 207

A

excess accumulation of fluid between the 2 pleural layers leading to restricted lung expansion during inspiration

Answer 208

A

-decreased protein content -due to CHF, nephrotic syndrome or hepatic cirrhosis

Answer 209

A

-increased protein content, cloudy -due to malignancy, collagen vascular disease, trauma

Answer 210

A

chylothorax. They are due to throacic duct injury from trauma or malignancy. -milky appearing fluid -increased trigs

Answer 211

A

accumulation of air in the pleural space

Answer 212

A

unilateral chest pain and dyspnea decreased tactile fremitus hyperresonance dimished breath sounds

Answer 213

A

tall, thin young males bc of rupture of apical blebs

Answer 214

A

trauma or lung infection. Air is capable of entering pleural space but not exiting so trachea deviates away from affected lung.

Brainscape's Knowledge GenomeTM

Respiratory - First Aid Flashcards

Brainscape's Knowledge Genome^TM