Download presentation
1
Neonatal Ventilation: “The Bivent”
Paul Kingma, MD PhD
2
Ventilation Basics: Goals
Oxygenation FiO2 Mean airway pressure Ventilation Respiratory rate Tidal volume
3
Conventional Pressure Ventilation
Itime PIP Pressure PS PEEP Time
4
Conventional Pressure Ventilation
How do you improve oxygenation? Itime PIP Pressure PS PEEP Time
5
Conventional Pressure Ventilation
How do you improve oxygenation? Itime PIP Pressure PS PEEP Time
6
Conventional Pressure Ventilation
How do you improve ventilation? Itime PIP Pressure PS PEEP Time
7
What do you do? If a 2700g intubated baby has oxygen sats 70% and pCO2 80 and… 30%FiO2 and ventilator settings of 16/5 and rate of 20? 100%FiO2 and ventilator settings of 28/7 and rate of 60?
8
Risk of Lung Injury
9
Conventional Pressure Ventilation
How do you improve oxygenation? Itime PIP Pressure PS PEEP Time
10
Conventional Pressure Ventilation
How do you improve oxygenation? LONG I time Itime PIP Pressure PS PEEP Etime Time
11
Reynolds and Strang: 1970’s
Inverse I:E ratio Improve oxygenation in neonates
12
Inverse I:E in infants = Air Leak
Factors associated with pulmonary air leak in premature infants receiving mechanical ventilation. Jpeds 1983 R.A. Primhak Compare infants with pneumothorax vs ventilated controls “No significant difference was found between the groups in any clinical factor, nor in any maximum ventilator setting other than a longer maximum inspiratory time in the study group.”
13
Conventional Pressure Ventilation
How do you improve oxygenation? LONG I time Problem: Inverse I:E…Breath Stacking…Pneumothorax PIP Pressure PS PEEP Time
14
Is there a better way to increase Itime?
15
Another Option: Airway Pressure Release Ventilation (APRV)
Think of it as sustained high CPAP with timed “releases” to encourage ventilation High and low CPAP settings: P high and P low Baseline is at P high with pressure released periodically to allow ventilation Release time is short to prevent collapse Spontaneous exhalation allowed during ALL phases of respiratory cycle. Therefore no breath stacking and no pneumothorax
17
Potential Advantages: Adults
Uses lower PIP to maintain oxygenation and ventilation without compromising the patient’s hemodynamics (Syndow AJRCCM 1994, Kaplan, CC, 2001) Longer I-time means higher mean airway pressure with lower peak pressures Shown to improved V/Q matching (Putensen, AJRCCM, 159, 1999) Decreases dead space ventilation Longer I-time allows diffusion of gases Spontaneous respiration may reduce need for sedation and avoid large changes in CO2 (Ratheberger, 1997; Putensen 2001) improved ventilation in dependent lung regions Better cardiac filling when compared to HFOV Reduces time at extremes of pressure volume curve decreased atelectasis decreased barotrauma
18
What about Pediatrics? Very little data
19
What about Pediatrics? Schultz, et al Crit Care Med 2001
Cross over study from SIMV to APRV or reverse in 15 patients with mild to moderate lung disease Findings Comparable oxygenation and ventilation with significantly lower peak pressures (33 vs 19 cm H2O) No change in hemodynamic variables
20
What about Pediatrics? Krishnan, et al Ped Pulmonol, 2007
Case series of 7 pts (age 1 – 16 years) Findings Oxygenation (decrease in OI) improved with APRV over time No problems with ventilation No change in sedation requirements but No patients required neuromuscular blockade No change in hemodynamic stability Easier pt care than with HFOV
21
What about Pediatrics? Dermirkol, et al Indian J Pediatr 2010
Case series of 3 patients ( mo old) changed from PC to APRV Findings FiO2 decreased from 0.97 to 0.68 Mean Airway pressure increased from 17.9 to 27 cm H2O Tidal volume increased from 8.3 ml/kg to 13.2 ml/kg
22
What about Pediatrics? Kamath et al. Ped Pulmonol 2010
Retrospective study of 11 pts on APRV for 12 hours due to failed conventional vent. Findings after 10 hrs on APRV FiO2 decreased from 0.83 to 0.67 Mean airway pressure increased from 16.1 to 21.1 cm H2O No change in HR, CVP, BP, UOP, IVF
23
What about Neonates? No Data
Neonatal Sheep. Martin et al, 1991 Crit Care Med Compared with PPV, APRV provided similar ventilation and oxygenation with lower peak pressures and without compromising cardiovascular performance.
24
When we know NOTHING it is easy to be an expert!
APRV in Neonates When we know NOTHING it is easy to be an expert! This is where I come in
25
APRV Terminology AKA: Bivent (Servo), APRV (Drager and Hamilton), Bilevel (Puritan-Bennett) P High - the upper CPAP level. P Low - the lower CPAP setting. T High - is the inspiratory time phase for the P High. T Low - is the release time allowing gas exchange and CO2 elimination
27
Bi-Vent Ventilation P High T low T High
29
How do you pick the settings?
30
Two Approaches Similar to Pressure Targeted Ventilation
Select Phigh and Plow based on expected upper and lower inflection points of pressure volume curve 1-3:1 inverse Thigh to Tlow ratio Tlow long enough to allow minimal trapping of exhaled gas
31
Two Approaches “Habashi method”
Phigh set to plateau pressure in conv vent Plow set to zero! Thigh adjusted to determine desired “release rate” Tlow adjusted to stop exhalation at 50-70% of peak-expiratory flow
32
What do we do in NICU? Initial Settings
Newly intubated P high—set at desired plateau pressure (typically 13–24 cm H2O in NICU) to achieve oxygenation and chest rise Absolute value (NOT relative to P Low) Bivent requires lower peak pressures than SIMV because of longer I-time P low—0-5 cm H2O (mostly 3 cm H2O) “Set” value but often actual PEEP is higher because of limited exhalation time T high—1–3 secs (1/0.2 = release rate of 50, 3/0.2 = release rate of 19) Used to control release rate Time in Bivent is an absolute value not a relative value T low—0.2–0.4 Used to control alveolar recruiting, “actual” PEEP, and tidal volumes More on this in a bit
33
In the NICU: Initial Settings
Transition from conventional ventilation Phigh—peak airway pressure in pressure-cycled mode minus 2-4 PEEP—0-5 cm H2O T high—1–3 secs (usually target similar rate) T PEEP—0.2–0.4 sec Transition from HFOV Phigh—target mPaw equal to HFOV plus 0–2 cm H2O T high—1–3 secs (use judgment to determine rate) T PEEP—0.2–0.4
34
Adjusting Settings: Increase Oxygenation
Increase FiO2 MAP Increase P high (1-2 cm per change) Increase T high (will impact rate also) Increase Pressure support Unlike SIMV or AC Plow in Bivent has minimal impact on oxygenation Tlow does not impact oxygenation directly (may impact recruitment)
35
Adjusting Settings: Oxygenation
T high Increasing T high will improve oxygenation by increasing time at P High and subsequently increasing mean airway pressure Increasing T high will also worsen ventilation by decreasing the number of releases per minute Therefore, when adjusting T high, make small changes ~10% to avoid dramatic shifts in both oxygenation and ventilation
36
Adjusting Settings: Increasing Ventilation
Increase P high to raise the tidal volume Decrease T high to raise the number of releases per minute (may need to increase Phigh to produce same mean airway pressure Increase PS Decrease Plow – more later Increase Tlow – more later
37
Plow Recommend set Plow at 0 cm H2O.
This provides a rapid drop in pressure, and a maximum pressure gradient for unimpeded expiratory gas flow during pressure release. However, may lead to lung collapse if left unchecked….
38
Plow Reality Check Adult literature (Habashi) recommends setting Plow at 0 cm H2O, but to avoid potential risk of severe collapse if Tlow is too long, I usually set Plow no lower than 2-3 cm in neonates. This provides a rapid drop in pressure and a maximum pressure gradient for unimpeded expiratory gas flow during pressure release. BUT if you are brave and need absolute maximum exhalation rate, then set Plow to 0 cm H20 but monitor very closely for changes in lung compliance and quickly make appropriate changes in Tlow HOW do you adjust Tlow?
39
RT Comfort Zone Tlow
40
Expiratory Flow Goal: Maximum ventilation without risk of atelectasis
De-recruitment Recruitment From Habashi, et al 2005
41
Tlow To avoid collapse Tlow
Set Tlow so that expiratory flow from patient ends at about 50 to 75% of peak expiratory flow In practice, this is difficult with neonates Can also look at “actual” PEEP on vent to determine how low of pressure patients lungs are actually seeing Target “normal” actual PEEPS of 5 cm H2O Tlow Too little results in not enough tidal volume Too much results in atelectasis Will change as compliance changes
42
Bivent Weaning With SIMV we wean by lowering PIP and increase time during expiratory phase of cycle. If you do this in BIVENT, patient will develop collapse from too long of Tlow. Therefore DO NOT WEAN RATE IN BIVENT BY INCREASING Tlow With BIVENT you lower pressure and increase time during inspiratory phase of cycle. Gradually lower Phigh to decrease mean airway pressure Gradually increase T High to lower number of releases per minute (this will increase your mean airway pressure so you may need to decrease Phigh even more) Eventually patient will wean to equivalent of CPAP PS As settings decrease remember may need to adjust PS to help with increased respiratory work load
43
Bivent Weaning: Drop and Stretch
44
Things to keep in mind Bivent is a pressure mode of ventilation and will not change in response to changes in lung compliance Tlow must be monitored frequently for changes in expiratory flow Airway plugging can significantly impact expiratory flow Technically, without spontaneous breaths, Bivent is the same as AC with a long I time BUT… Since patient initiated inhalation/exhalation can occur at P High, “breath stacking” should not occur and the risk of pneumothorax should be minimal Limited data in pediatrics and no data in neonates
45
What is our experience so far?
46
The End Questions?
Similar presentations
© 2024 SlidePlayer.com. Inc.
All rights reserved.