respiratory

Question 1

diaphragm structures

Answer 1

• T8 = IVC
• T10= esophagus, vagus (CN 10)
• T12= aorta, thoracic duct and azygos vein
  
  • at T-1-2 it’s the red white and blue
• innervated by C3,4,5 (phrenic nerve) –> pain from diaphgragm irritation ca be referred to shoulder (C5) and trapz (C3,4)

Question 2

lung volumes

1. TV
2. IRV
3. ERV
4. RV
5. IC
6. FRC
7. VC
8. TLC

Answer 2

1. TV- air that mvoves into and out lung with each quiet breath (500 mL)
2. IRV- air that can still be breathed in after normal inspiration
3. ERV- air that still be breathed out after normal expiration
4. RV- air in lung after maximal expiration (can’t be measured on spirometry)
5. IC = IRV + TV
6. FRC = RV+ERV (amount of air left in lungs after normal expiraton – it is functional bc this what you normally have left)
7. VC= TV + IRV + ERV (max volume of gas that can be expired after a max inspiration)
8. TLC = IRV + TV + ERV + RV (volume of air present in lungs after maximal inspiration)

Question 3

1. determinationof physiologic dead space
2. pulmonary vascular restance
3. alveolar gas eqn

Answer 3

1. V_D=V_TVx (PaC02 - PECO2)/PaCO2
   
   • PECO2 = expired air PCO2
2. P = Q x R (change in P = flow x resistance)
3. PAO2 = 150 - PaCO2/0.8

Question 4

1. Hb basics
2. Methemoglobin
3. Carboxyhemoglobin

Answer 4

1. T form has low O2 affinity; R form has high O2 affinity
   
   • increase in Cl, H, CO2, 2,3-BPG + temp favor T form
2. Fe3+ – oxidized form of Hb that does not bind O2 readily but has increased affinity for cyanide
   
   1. caused by nitrites (ie: nitroglycerin)
   2. tx with methylene blue
   3. tx cyanide poisoning with nitrites to oxidize Hb to methemoglobin –> then use thiosulfate to bind this CN which is renally excreted
3. Hb bound to CO instead of O2 –> less O2 unloading

Question 5

Hb level, Hb sat, PaO2, total O2 content of..

1. CO poisoning
2. anemia
3. polycythemia

Answer 5

Hb Level

% O2 sat

of Hb

PaO2

Total O2 content

CO poisoning

Normal

low

Normal

low

Anemia

low

Normal

Normal

low

polycythemia

High

Normal

Normal

high

Question 6

pulmonary circulation: perfusion vs diffusion limited

Answer 6

• healthy lungs are perfusion limited
  
  • gas equilibrates early along length of capillary
• emphsema or fibrosis are diffusion limited
  
  • gas does not equilibrate by the time it reaches the end of the capillary
  • SA decreases in emphysema
  • diffusion barrier thickness increases in fibrosis

Question 7

hypoxemia (decreased PaO2)

1. high altitude
2. hypoventilation
3. V/Q mismatch
4. diffusion limitation
5. R–> L shunt
6. increased FiO2

Answer 7

• Normal A-a
  
  • high altitude
  • hypoventilation
• increased A-a
  
  • V/Q mismatch
  • diffusion limitation (pulmonary fibrosis)
  • R—> L shunt
  • increased FiO2 (you can only add so much O2 to the blood)

Question 8

1. low CO
2. hypoxemia
3. anemia
4. CO poisoning
5. impeded arterial flow
6. decreased venous drainage

Answer 8

1. hypoxia (low O2 delivery to tissue)
   
   • normal A-a: low CO, hypoxemia
   • high A-a: anemia, CO poisoning
2. ischemia
   
   • normal A-a: impeded arterial flow and low venous drainage

Question 9

V/Q mismatch

1. V/Q at apex of lung
2. V/Q at base of lung
3. airway obstruction
4. blood flow obstruction

Answer 9

1. V/Q = 3 (wasted ventilation)
   
   • becomes more uniform with exercise –> increased perfusion at apex
2. V/Q = 0.6 (wasted perfusion)
   
   • both V and Q are greater at base of lung but increase in Q is greater than increase in V
3. V/Q = 0 (shunt) – PO2 does not improve with 100% O2
4. V/Q = infinity – PO2 improves with 100% O2
   
   • lung prefentially perfuses areas that are getting O2

Question 10

• 3 forms of CO2 transport
• Haldane effect
• Bohr effect

Answer 10

1. HCO₃^- (90%)
   
   • CO2 and H20 diffuse into RBC and are converted into H+ and HCO₃^- via CA
2. HbCO₂ (carbaminohemoglobin) –
   
   • CO2 bound to Hb at N-terminus of globin (not heme)
   • CO2 bound favors T form
3. dissolved CO2 (5%)

• Haldane effect: Oxygenation of Hb promotes dissociation of H+ from Hb –> CO2 formation –> CO2 released from RBC
• Bohr effect: H+ from tissue metabolism shifts curve to the R –> unloading more O2

Question 11

1. diphenhydramine, dimenhydrinate, chlorpheniramine
2. Loratidine, fexofenadine, desloratidine, cetirizine
3. Guaifenesin
4. N-acetylcysteine

Answer 11

1. 1st gen H1 blockers: “en/ine” or “en/ate”
   
   • toxicity: sedation, antimuscarinic, anti-alpha-adrenergic
   • uses: allx, motion sickness, sleep aid
2. 2nd gen H1 blockers (“-adine”)
   
   • uses: allx
   • far less sedating than 1st gen bc less CNS penetration
3. expectorant
4. mucolytic and antidote for tylenol OD

Question 12

1. dextromethorphan
2. pseudoephedrine, phenylephrine
3. Albuterol, Salmeterol, Formoterol

Answer 12

1. antitussive; synthetic codeine analog
2. alpha-agonists
   
   • nasal decongestants
   • sudafed used to make meth
   • can cause CNS stimulation (anxiety, HTN)
3. B2 agonists
   
   1. albuterol = 1st line tx for acute asthma
   2. salmeterol and formoterol are long acting agents for prophylaxis

Question 13

1. Theophylline
2. Ipratropium
3. beclomethasone, fluticasone

Answer 13

1. methylxanthine: inhibits PDE –> increases cAMP levels
   
   • bronchodilation for asthma
   • low TI: low doses acts like caffeine, high doses causes abd pain, seizures and tachy
2. muscarinic antag –> prevent bronchoconstriction
   
   • tx asthma + COPD
   • tiotropium is long-acting muscarinic antag
3. corticosteroids
   
   • 1st line tx for chronic asthma (prophylaxis)

Question 14

1. Montelukast, zileuton
2. omalizumab
3. methacholine
4. bosentan

Answer 14

1. antileukotrienes (“lu” or “leu”)
   
   • asthma prophylaxis
2. IgE mAb
   
   • allergic asthma resistant to steroids and B2 agonists
3. muscarinic agonist
   
   • bronchial provocation challenge to dx asthma
4. tx pulmonary HTN
   
   • antagonizes endothelin-1 receptors

Question 15

HIV

Answer 15

• diploid genome (2 molecules of RNA)
• 3 structural genes
  
  • env –> forms gp41 (fusion and entry) + gp120 (attachment to host CD4+ T cell)
  • gag –> capsid protein
  • pol –> reverse transcriptase, integrase + protease
• virus binds CCR5 (early- macros) or CXCR4 (late) co-receptor + CD4 on T cells
• homozygous CCR5 mutation = immunity