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Interpretation of Ventilator Graphics

Interpretation of Ventilator Graphics. Dr.Ahmed Abd Elmaksoud, MD. What is ventilator waveform?. Parameters displayed in waveform:. Volume Pressure Flow Time Exhaled P co 2. Physics review. A pressure difference ( ∆ p) must be present to make a fluid to flow

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Interpretation of Ventilator Graphics

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  1. Interpretation of Ventilator Graphics Dr.Ahmed Abd Elmaksoud, MD

  2. What is ventilator waveform?

  3. Parameters displayed in waveform: Volume Pressure Flow Time Exhaled Pco2

  4. Physics review A pressure difference (∆p) must be present to make a fluid to flow The higher the pressure difference the higher the flow Flow is measured as the volume of the fluid passed a certain point in unit time,

  5. Physics review The Resistance: It is the pressure difference divided by the flow caused by it

  6. Physics review The Compliance: The compliance of a system is the volume change per unit change in pressure

  7. Physics review The Work of Breathing: It is the pressure difference across the system multiplied by the volume of the fluid moved by it

  8. Ventilator Waveforms Depend on: Mode of ventilation Ventilator properties and settings Respiratory properties of the patient

  9. Types of Ventilator Waveforms Scalar: Pressure – time Volume – time Flow – time Loops: Pressure – volume Volume – Flow Flow – pressure Trends:

  10. Pressure – time curve Volume–oriented breath (modes) Pressure–oriented breath (modes)

  11. Pressure – time curve Pressure – time curve shows airway pressure, breath timing, the breath type delivered and patient versus machine triggering

  12. Pressure – time curve (volume – oriented mode) C R

  13. Pressure – time curve (volume – oriented mode) C R

  14. Pressure – time curve (volume – oriented mode) C R

  15. Pressure – time curve (volume – oriented mode) The level of pressure at “B” is affected by the resistance and the flow

  16. Pressure – time curve (volume – oriented mode) The level of the plateau pressure is determined by the compliance and the tidal volume

  17. Pressure – time curve (volume – oriented mode) Lung recruitment and leaks in the system are possible reasons for further slight decrease in pressure (points D to E).

  18. Pressure – time curve (pressure – oriented mode) In pressure-oriented ventilation, Pressure increases rapidly from the lower pressure level until it reaches the upper pressure value and then remains constant for the inspiration time set on the ventilator.

  19. Pressure – time curve (pressure – oriented mode)

  20. Constant flow is a typical feature of a classic volume – oriented mode of ventilation. Flow – time curve

  21. Flow – time curve

  22. Decelerating flow is a typical feature of a pressure – oriented mode of ventilation. Flow – time curve

  23. Flow – time curve

  24. Flow – time curve • The course of the flow curve during inspiration is strongly influenced by the ventilation mode set on the ventilator • The course of the flow curve during expiration is influenced by the overall resistance and compliance of the lung and the system.

  25. Volume – time curve • The transferred volume is calculated as the area underneath the flow curve • The maximum volume value is the transferred tidal volume (not the entire volume in the lung)

  26. Volume – time curve

  27. Pressure – volume loop Volume controlled ventilation

  28. Pressure – volume loop Pressure controlled ventilation

  29. Pressure – volume loop Pressure support ventilation

  30. Pressure – volume loop Spontaneous ventilation

  31. Pressure – volume loop The area to the left of the vertical axis (A) is a measure of how much work the patient needs to do to trigger the ventilator. The area to the right of the axis (B) represents the work done by the ventilator to support the patient

  32. Pressure – volume loop As compliance decreases, and the ventilator settingsremain the same, the PV loop in volume-controlled ventilation takes an increasingly flat course.

  33. Pressure – volume loop The change in resistance during constant flow ventilation changes the position of the inspiratory branch of the loop while its steepness remains unchanged

  34. Pressure – volume loop A change in the height of the PV loop is a measure of the strength of the patient’s inspiratory effort (if the ventilator parameters are unchanged)

  35. Pressure – volume loop

  36. Pressure – volume loop

  37. Pressure – volume loop PV loops measured before and after resistances

  38. Pressure – volume loop The work of breathing can be much greater than what is displayed in PV loops if the pressure is measured before resistances

  39. Pressure – volume loop

  40. Pressure – volume loop The reason for setting assisted spontaneous breathing is generally to try to compensate for these airway resistance

  41. Volume – flow loop Changes in the shape of volume – flow loop are used to obtain information about airway resistance

  42. Volume – flow loop Increased airway resistance due to increased secretions

  43. Trends • Graphic trend displays enable ventilation processes to be assessed at a later stage. • An event which occurs suddenly calls for as much details as possible to be shown in the diagram; while assessing the process of weaning, for example, needs several days or even weeks to be displayed in one diagram.

  44. Trends

  45. Trends

  46. Trends

  47. What is going on here?

  48. What is going on here?

  49. What is going on here?

  50. Air leak

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