The primary function of mechanical ventilation
To provide respiratory support while treating the underlying process that caused respiratory failure
how to approximate alveolar pressure
measure the plateau pressure with an end inspiratory pause in a passively breathing or paralyzed patient
target plateau pressure
less than 30 cm H2O
initial settings in pressure control
start with a pressure control of 10 cm H2O above PEEP and adjust pressure up and down to target tidal volume of 6-8 mL/kg ideal body weight
remarks for patients who are not intubated for severe hypoxemia or obstructive lung disease
consider transitioning to pressure support after a volume-targeted mode because the former may be more comfortable for the patient
Remarks on setting the respiratory rate
- Most adult patients with normal respiratory physiology have adequate ventilation at a respiratory rate of 10 to 20 breaths/min
- However, anticipate demands, e.g., in severe metabolic acidosis (eg DKA), set a higher respiratory rate to maintain adequate minute ventilation
- For patients with obstructive lung disease, set RR at 10-14 for longer expiratory time (counterintuitive, yes)
remarks on obese patients
obese patients and those with tense abdomen require higher PEEP
start at 8-10 cm H2O
remarks on hyperoxia
hyperoxia increases patient mortality in a dose-dependent relationship. Many recommend titrating the FiO2 to target an O2 saturation of no greater than 96% as soon as the patient recovers from the apneic induction period
Post-ROSC recommendations include ≥94%.
So target SpO2 should be 94-96%
targets in sedation
target a Richmond Agitation-Sedation Scale (RASS) score of
-2 awakens and makes eye contact to voice (<10 seconds)
-1awakens and makes aye contact to void (>10 seconds)
0 awake, alert, and calm
Remarks on PEEP
improvements in oxygen saturations through increased PEEP are not immediate, so use incremental changes in pEEP of 2 cm H2O every 10-20 minutes rather than rapidly increasing or decreasing because there is potential for unanticipated hemodynamic, intrathoracic, or intrapulmonary changes
remarks on sedation in mechanical ventilation
although often not an ED issue, ending sedation or using sedation holidays allow for more prompt return to spontaneous ventilation
Remarks on obstructive lung diseases and mechanical ventilation
- The primary pathology is NOT improved by intubation.
- The problems encountered are increased airway resistance, pulmonary hyperinflation, and increased dead space causing hypercapnia
What is dynamic hyperinflation?
- Arterial hypercapnia in obstrucive lung disesaes (asthma/copd) tempts the treating physician to increase the RR to exhale more CO2. However, this is counterproductive because it shortens exhalation time, leading to an additional breath prior to the lungs completely emptying.
- This latter event is called DYNAMIC HYPERINFLATION
- Incomplete emptying can be detected by monitoring the expiratory flow limb in a passively breathing patient
What is auto-PEEP
A.k.a intrinsic PEEP
The difference between the total PEEP (from end-expiratory hold) and the set PEEP
[TOTAL PEEP] - [SET PEEP]
Ventilator management principles for obstructive lung diseases
- Slow respiratory rate
- Tolerate hypercapnia
- Check for gas trapping
RR in obstructive lung diseases (OLD)
1. SLOW RESPIRATORY RATE
- start with a rate of 10-14 bpm
- a slow resiratory rate is the best way to increase emptying time compared with a decrease in inspiratory time
Hypercapnia in OLD
2. TOLERATE HYPERCAPNIA
- tolerate a pH of ≥7.20
- if a respiratory acidosis is causing systemic effects, increase the TV >8 mL/kg while keeping a low RR to maximize alveolar ventilation
How to check for gas trapping in OLD
- Ensure the expiratory flow limb of the flow curve reaches zero before the next breath (in a passively breathing patient)
- Calculate auto-PEEP by performing an end-expiratory hold (Total PEEP - set PEEP; should be less than 5)
- If Auto-PEEP >5, decrease RR until expiratory flow limb approaches zero before inspiration or RR =10.
- If hypotension occurs, disconnect the patient from the ventilator for 15-20 seconds and decrease the RR after reconnection
Other maneuver for obstructive lung disease to prevent lung trapping
increase IFR (inspiratory flow rate)
*typically, it’s 60 LPM
recommendation in COPD is 80-100 LPM
^however, these may cause increased pressures
Weingart: 60-80 LPM
ARDS definition
Berling definition:
Onset within 1 week of a known clnical insult or new or worsening repiratory symptoms
Bilateral opacities on chest imaging not fully explained by lobar/lung collapse or nodule
Respiratory failure not fully explained by cardiac failure or volume overload
PF ratio ≤300 mmHg with PEEP ≥5.0 cm H20
Conditions that place patients at risk for ARDS
Pneumonia
Sepsis
Trauma
Pancreatitis
Any shock state
Mainstays of treatment for suspected ARDS
- Low TV ventilation
- Adequate PEEP
- Treatment of the underlying condition
in patients with bilateral lug disease and at risk for ARDS, and the plateau pressure is above 30 cm H2O, what to do with tidal volume?
the tidal volume should be incrementally decreased by 1 mL/kg to as low as 4 mL/kg
these protective lower tidal volumes may lead to hypercapnea and acidemia although a pH of >7.20 is usually well tolerated
Oxygenation in ARDS
- Avoid hyperoxia; do NOT routinely seek a saturation of 98-100% in most patients.
- in ARDS, many seek an O2 sat of 88% to 95% or PaO2 55 to 80 mm Hg
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Post-Cardiac Arrest Syndrome23
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Ethical Issues of Resuscitation3
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Tracheal Intubation25
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Mechanical Ventilation27
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Surgical Airways I13
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Surgical Airways II31
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Surgical Airways III15
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Resus Procs Most Commons14
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Pericardiocentesis6
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Resus Prox Pearls, part 121
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Resus Prox Pearls, part 225
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CTT20
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Cardiac Resuscitation, part 118
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Cardiac Resuscitation, part 227
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Cardiac Resuscitation, part 323
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(32) Hemodynamic monitoring30
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Vascular access0
