1 / 19

Which parameters are practical in evaluating the efficacy of mechanical ventilation?

Which parameters are practical in evaluating the efficacy of mechanical ventilation?. Turkish Thoracic Society 11 th Annual Congress Antalya, Turkey April 2008. Gökhan M. Mutlu, M.D. Pulmonary and Critical Care Medicine Northwestern University Feinberg School of Medicine.

adila
Download Presentation

Which parameters are practical in evaluating the efficacy of mechanical ventilation?

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Which parameters are practical in evaluating the efficacy of mechanical ventilation? Turkish Thoracic Society 11th Annual Congress Antalya, Turkey April 2008 Gökhan M. Mutlu, M.D. Pulmonary and Critical Care Medicine Northwestern University Feinberg School of Medicine Financial Disclosure: Nothing to disclose

  2. Goals of mechanical ventilation Treatment of respiratory failure Life support Supporting respiratory muscles Correction of hypoxemia and hypercapnia Prevention of complications associated with mechanical ventilation Barotrauma (i.e., pneumothorax, pneumomediastinum) VILIMOSF

  3. Goals of mechanical ventilation 1. Monitor vital signs, ABG and airway pressures 2. Small VT 6 ml/kg in ALI/ARDS 6-8 ml/kg in obstructive airway disease 3. Keep Pplat < 30 cm H2O 4. Administer enough PEEP to improve oxygenation 5. Keep FiO2 < 0.6

  4. Common parameters in monitoring MV Clinical Vital signs SpO2 Gas exchange Invasive Arterial blood gas (SaO2, PaO2, pH, PaCO2) Non-invasive SpO2 VO2 ETCO2

  5. Common parameters in monitoring MV Lung and chest wall mechanics Paw (Ppeak and Pplat) Compliance and elastance Airway resistance Auto-PEEP P-V relationship

  6. Resistance (Raw) Plateau Pressure Compliance (Csrs) Measurement of lung mechanics Peak Pressure 30 Airway Pressure (cm H2O) 20 10 PEEP Time

  7. Airway pressures Ppeak =Presistive+ Pelastance + Pinertia Ppeak = (Flow x Resistance) + (VT x Elastance) Ppeak = (Flow x Resistance) + (VT x 1/Compliance)

  8. PIPvsPplat PIP High Raw Normal PIP PPlat PPlat Paw (cm H2O) PIP PPlat Low Compliance Time (sec)

  9. Compliance and airway resistance Compliance (static)RS= ΔV/ΔP CRS= VT/Pplat-PEEP Normal values- 60-80 ml/cm H2O Severely decreased compliance <25 ml/cm H2O Resistance Constant flow 60 L/min (1L/sec) PIP - Pplat cmH2O L/sec Normal < 15 cmH2O/L/sec

  10. Airway pressures Parenchymal diseases (Pneumonia, ALI, ARDS, pulmonary edema) ↑ Ppeak ↑ Pplat ↓ Compliance Airway diseaseas (COPD, asthma) ↑ Ppeak N Pplat ↑ Airway resistance Auto-PEEP

  11. Normal Patient Normal vs. Obstruction Inspiration Time (sec) Flow (L/min) } Expiration

  12. Auto-PEEP Determination Auto PEEP Expiration Inspiration Paw (cm H2O) Total PEEP Set PEEP Time (sec) Expiratory hold

  13. Case 1 34 yo woman with no PMH CC: productive cough, fever and pleuritic chest pain Exam: RR-34/min, SpO2 81% on RA, crackles at both bases Labs: WBC 21,000/mm3, 98% PMNs BUN 31, Crea 1.2

  14. Case 2 41 yo man with history of asthma CC: SOB, wheezing, not responding to q2 hour SABA Exam: RR-37/min, SpO2 92% on RA, decreased BS BL, prolonged exp, and wheezing Labs: WBC 14,000/mm3, 84% PMNs, 11% eos ABG 7.24/60/62

  15. ETCO2

  16. VT and PEEP

  17. Effects of a 50%shunt on oxygenation 150 CxO2 = 1.39*HG*% sat + PO2*0.003 21% oxygen 100 15 20 CvO2=15 PvO2 = 45 SvO2 = 75% CcO2=20 PcO2 = 100 ScO2 = 98% 17.5 CaO2=17.5 PaO2 = 57 SaO2 = 87%

  18. Effects of 100% oxygen in 50% shunt 713 CxO2 = 1.39*Hgb*% sat + PO2*0.003 100% oxygen 650 15 22 CvO2=15 PvO2 = 45 SvO2 = 75% CcO2=22 PcO2 = 650 SaO2 = 100% 18.5 CaO2=18.5 PaO2 = 65 SaO2 = 92%

  19. Oxygenation

More Related