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![Initial Ventilator Setup and
Adjustments
• Calculate Ideal Body Weight (IBW):
– For Males, IBW (kg) = 50 + 0.91 (height [cm] – 152.4)
– For Females, IBW(kg) = IBW (kg) = 45.5 + 0.91 (height
[cm] – 152.4)
• Select Volume Assist-Control as the ventilator
mode
• Set Initial Tidal Volume to 8 mL/kg IBW
• Reduce tidal volume by 1 ml/kg IBW at intervals
=2 hours until the tidal volume = 6ml/kg IBW.](https://image.slidesharecdn.com/basicmodesofventilation1-250424075045-089c1c54/75/Basic-Modes-of-Ventilation-in-ventilator-26-2048.jpg)
Basic Modes of Ventilation in ventilator
- 1. INDIAN SOCIETY OFANAESTHESIOLOGISTS (ISA) MECHANICAL VENTILATION MODULE (BASIC) Orientation Course for Clinical Specialists & Refresher Course for Anaesthesiologists JAI MATA DI !!
- 2. Basic Modes of MechanicalVentilation
- 3. Basics • All ventilatorsdo only one thing: Push in air in inspiration • Compressor +Two valves • Inspiration – I. valve =Open – E. valve = Closed • Insp Pause = both valves closed • Expiration – I. valve = Closed – E. valve = Open • Exp Pause (PEEP) = both valves closed
- 4. Volume vs. PressureControl Variable Volume Control Pressure Control TV Set, constant variable PIP Variable Set, constant Inspiratory time Set Set Inspiratory flow Set Variable Inspiratory flow waveform Set, constant Decelerating type, variable
- 5. Volume vs. PressureControl Volume Preset • Set parameter is the tidal volume; airway pressure is variable • Constant tidal volume in the face of changing lung characteristics • Patient-ventilator asynchrony due to fixed flow rate • No leak compensation Pressure Preset • Set parameter is airway pressure; tidal volume delivered is variable • Tidal volume varies with changes in lung characteristics • Flow will vary according to patient's demands • Compensates for leaks
- 6. What to monitor:VCV & PCV • During Volume Controlled Ventilation – Peak airway pressure – Plateau Airway Pressure – Low Pressure alarms • During Pressure Controlled Ventilation – Expired Tidal volume – Expired minute volume
- 7. Trigger • Time – Ventilatorinitiates the breath according to a set frequency, independent of patient effort • Pressure – Patient’s breathing produces a decrease in baseline circuit pressure which starts inspiration • Flow – Ventilator senses inspiratory flow by the patient and initiates inspiration
- 8. Triggering Time (sec) Patient Machine Pressure (cmH20) Essentialsof Ventilator Graphics. 2000 RespiMedu, Inc. Deshpande and Restrepo
- 9. Inspiration - Limit •Either flow rate or pressure • Inspiration continues at the limit for the duration of inspiration • It remains at that level till changeover to expiration occurs
- 10. Cycling • Changeover frominspiration to expiration • Inspiration ends when some variable has reached a preset value • Time / Volume – Most ventilators measure flow rather than volume; with a set flow rate, adjust inspiratory time. Hence time cycled • Flow – When expiratory flow reaches a preset value. PSV • Pressure – When pressure reaches a preset value. E.g. Bird Mark 8
- 11. Expiration - Baseline •From start of expiratory flow to beginning of inspiratory flow • Most commonly baseline pressure is controlled – PEEP or CPAP
- 12. Types of Breaths •Mandatory – Ventilator determines either start of inspiration or end of inspiration or both – Assisted breath if patient triggered • Spontaneous – Start and end of inspiration are determined by patient – Supported breath if inspiratory pressure is greater than baseline
- 13. Modes of Ventilation •Control variables – Are the breaths Pressure Controlled or Volume controlled? • Type of Breath – Mandatory or Spontaneous, or a Combination • Conditional Variables – Any variables which may determine a change in ventilator function
- 14. Set TV/ Pressure,Resp. Rate, PEE, FiO2, Ti / Flow rate / I:E ratio. CMV • All breaths are mandatory • Preset frequency, inspiratory time • Pressure or volume control • Time triggered • Volume, flow or pressure limited • Time cycled
- 15. Assist Control Like CMV •Each additional assisted breath at prefixed tidal volume or pressure • Trigger: ventilator or patient • Limit: Flow / volume or Pressure • Cycling: volume or time Set TV/ Pressure, f, PEEP, FiO2, Ti/ I:E ratio
- 16. SIMV • IMV – Machinetriggered breaths with spontaneous breaths allowed in between • SIMV – Synchronised mandatory breaths with spontaneous breaths allowed in between – Ventilator creates a time window around the scheduled delivery of mandatory breath – If a patient effort is detected, it synchronises the machine breath with the patient’s inspiration – If no patient effort is detected, it delivers a breath at the scheduled time
- 17. Pressure Support • Completelyspontaneous mode in which patient triggers each breath • On inspiration patient exposed to a preset pressure • Inspiration is terminated when the flow rate reaches a minimum level or % of peak flow – Trigger: Patient – Limit: Pressure – Cycling: flow
- 18. Pressure Support Ventilation (PSV) • Spontaneous mode • Pt initiates breath and vent delivers pre-set inspiratory pressure to help overcome airway resistance • Pt controls the rate, tidal volume and minute ventilation • TV is variable • Can be used in conjunction with SIMV or CPAP • ALWAYS set low TV / MV alarm and apnea backup Set Pressure support, peep, Fio2, Apnea settings
- 19. Three Golden Rules •Never silence alarm unless Problem identified and sorted out Chest is clearly moving Patient is put on AMBU bag • When in doubt AMBU the patient Doubt about airway pressures Fall in SO2 Patient not coordinating with ventilator Unexplained alarm • AMBU bag behind each bed
- 20.
- 21. Berlin Definition ofARDS • Never silence alarm unless Problem identified and sorted out Chest is clearly moving Patient is put on AMBU bag • When in doubt AMBU the patient Doubt about airway pressures Fall in SO2 Patient not coordinating with ventilator Unexplained alarm • AMBU bag behind each bed Acute Respiratory Distress Syndrome Timing Within 1 week of a known clinical insult or new or worsening respiratory symptoms Chest imaging Bilateral opacities—not fully explained by effusions, lobar / lung collapse, or nodules Origin of edema Respiratory failure not fully explained by cardiac failure or fluid overload. Need objective assessment (eg,ECHO) to exclude hydrostatic edema if no risk factor present Oxygenation Mild 200 mm Hg < PaO2/FIO2 ≤ 300 mm Hg with PEEP or CPAP ≥ 5 cm H2O Moderate 100 mm Hg PaO2/FIO2 ≤ 200 mm Hg with PEEP ≥ 5 cm H2O Severe PaO2/FIO2 ≤ 100 mm Hg with PEEP ≥ 5 cm H2O
- 22. Aerated Non-aerated Partially aerated Lung Injury inARDS Non-uniform
- 23. Lung Injury inARDS • In ARDS there is “non-homogeneous” affectation of the parenchyma. • In an ARDS patient, the lungs have several distinct areas: – areas of normal aeration (which over distend with ventilation) – poorly aerated (but potentially recruitable areas) – non-ventilated zones. • Thus in an adult patient, the volume of aerated lung is the size of lung in a 5-6 year old healthy boy, the so called “baby lung.” • The small areas of normal aeration will receive the bulk of volume and over distend, resulting in volutrauma.
- 24. ARDS Volutrauma & Atelectrauma InARDS, following mechanisms of lung injury have been described: • Atelectrauma • Oxygen toxicity • Volutrauma • Cyclical shear stress injury • Biotrauma • Barotrauma
- 25. Ventilator Induced LungInjury • Barotrauma • Over distension of ventilated alveoli – volutrauma • Cyclical opening and closing of lung units with IPPV – shear stress with alveolar injury • Release of inflammatory mediators • Oxygen toxicity
- 26. Initial Ventilator Setupand Adjustments • Calculate Ideal Body Weight (IBW): – For Males, IBW (kg) = 50 + 0.91 (height [cm] – 152.4) – For Females, IBW(kg) = IBW (kg) = 45.5 + 0.91 (height [cm] – 152.4) • Select Volume Assist-Control as the ventilator mode • Set Initial Tidal Volume to 8 mL/kg IBW • Reduce tidal volume by 1 ml/kg IBW at intervals =2 hours until the tidal volume = 6ml/kg IBW.
- 27. Subsequent adjustments • PlateauPressure Goal: Pplat 30 cm H2O – Check Pplat every 4 hours and after each change in PEEP or tidal volume. • If Pplat >30 cm H2O – decreaseTV by 1 mL/kg IBW steps (minimum tidal volume = 4 ml/kg IBW). • Arterial pH goal: pH = 7.30-7.45 • Arterial Oxygenation Goal: PaO2=55-80 mmHg or SpO2=88-95% NEJM 2000;342:1301-1308
- 28. CO2 management • Contraindicationsto permissive hypercapnia – raised intracranial pressure – severe circulatory instability – pregnancy • Initial RR of 24-30 and adjusted to pH • RR may be increased upto 35 • Deep sedation – Muscle relaxants once adequate sedation • Oral / iv NaHCO3 to maintain pH >7.25 – Increase serum HCO3 to the 30-35 range
- 29. Adjusting PEEP andFiO2 ARDS Network study • Fixed combinations of FiO2 and PEEP Arterial Oxygenation Goal: PaO2=55-80 mmHg or SpO2=88- 95% FiO2 PEEP FiO2 PEEP 0.3 5 0.7 12 0.4 5 0.7 14 0.4 8 0.8 14 0.5 8 0.9 14 0.5 10 0.9 16 0.6 10 0.9 18 0.7 10 1.0 20-24
- 30. MV in ARDS •Low tidal volumes (4-6 ml/kg IBW) • Limiting the Plateau pressures (<30 cmH2O) • Appropriate PEEP • Prone position if P/F < 150 • Consider muscle relaxants in P/F ratio < 150 and difficult to ventilate • Monitor right ventricular function • Extracorporeal support
- 31. • The VentilatoryStrategy and prevention of ventilator induced lung injury is more important than any mode of ventilation
- 32.