Pulmonary Ventilation Clinical Trial
Official title:
Flow Controlled Ventilation With the Evone Ventilator and Tritube Versus Volume Controlled Ventilation: A Clinical Pilot Study Describing Oxygenation, Ventilation and Haemodynamic Variables
The Evone® ventilator is a new device capable of lung ventilation through a narrow-bore cannula, the Tritube.Two ventilation modes are possible: high frequency jet ventilation (HFJV) and flow-controlled ventilation (FCV). In this prospective pilot study the efficacy of FCV using the Evone® ventilator and Tritube is investigated when compared with Volume Controlled Ventilation (VCV) via a normal tracheal tube.
The Evone® (Ventinova Medical, Eindhoven, The Netherlands) is an automated mechanical
ventilator providing pulmonary ventilation by generating a continuous flow into the patient's
lungs during inspiration as well as a continuous flow during expiration (flow controlled
ventilation, FVC). FCV is a relatively new concept in which ventilation via the Tritube
(Ventinova), an ultrathin endotracheal tube, has been made possible due to active suctioning
of gas from the lungs during expiration (expiratory ventilation assistance, (EVA)).
Adjustable parameters that govern the FCV cycle are: Inspiration Flow, Inspiratory:Expiratory
ratio (I:E ratio), maximum tracheal pressure (PMAX) and end expiratory pressure (EEP).
Measured parameters are: end-tidal carbon dioxide partial pressure (PE'CO2 ) as measured by
capnography, Minute Volume, Peak Tracheal Pressure, End Expiratory Pressure, Respiratory
Frequency, I:E ratio and Tidal Volume ( VT). The ventilator screen continuously displays a
capnograph with end-tidal CO2, intra-tracheal pressure and inspiratory tidal volume
waveforms. In FCV mode, inspiration occurs with the pre-set, constant inspiratory flow until
the intratracheal pressure reaches the pre-set value. Assisted expiration then occurs until
the pre-set EEP is reached. Expiratory flow is controlled in such a way to achieve a mainly
linear reduction in tracheal pressure, whilst ensuring the set I:E ratio. There are no
inspiratory or expiratory pauses and EVA does not result in negative tracheal pressures.
Thus, minute volume is determined by the set flow rate and the I:E ratio. The set inspiratory
peak and end expiratory pressures determine the tidal volumes. Ventilatory frequency is a
result of these parameter settings.
The Tritube is a 40 centimeter long narrow diameter cuffed tracheal tube (internal diameter
2.4 millimeter, outer diameter 4,4 millimeter) that can be used with either the manual
Ventrain® or automated Evone® ventilator. It consists of three lumens: a ventilatory channel
with Murphy eye, a channel for airway pressure measurement and a channel for inflating the
high volume, low pressure polyurethane cuff. Preliminary data suggests that Evone® not only
provides adequate ventilation via the Tritube, but in comparison with conventional modes of
ventilation (volume-controlled, pressure-controlled modes) may result in improved alveolar
gas distribution, ventilation/perfusion matching, respiratory mechanics and oxygenation. In
this prospective pilot study the efficacy of FCV using the Evone® ventilator and Tritube is
investigated when compared with VCV (Aisys Carestation, GE Healthcare, WI, USA) via a normal
tracheal tube.
All participants meeting inclusion criteria and having signed Informed Consent will undergo
anesthesia and monitoring as per standard of care for the designated surgical procedure (5
lead ECG, non-invasive blood pressure cuff, saturation monitor). Neuromuscular blockade will
be monitored by use of the TOF Watch®SX (train-of- four). Depth of anesthesia will be
monitored by use of NeuroSENSE ®NS 701 Monitor( NeuroWave Systems incorporated - Cleveland
Heights,OH). Following placement of a peripheral intravenous infusion, induction of standard
intravenous anesthesia (propofol/remifentanil) and deep neuromuscular relaxation (rocuronium)
will be established. Following 3 minutes of preoxygenation (Fractional end-tidal oxygen
concentration (FE'O2> 0.9), patients will be intubated with a conventional cuffed tracheal
tube cut to 24 centimeter length via oral route and ventilated in standard VCV mode with
Fractional Inspired Oxygen concentration (FIO2) at 0.3 percent, Positive End Expiratory
Pressure (PEEP + 5cmH2O) and frequency (f) of 12 breaths per minute. Tidal volume will be
adjusted to ensure normocapnia. A radial arterial catheter will be placed and attached to a
FloTrac sensor and Vigileo monitor ( Edwards Lifesciences, Irvine CA, USA) for continuous
measuring of arterial blood pressure and cardiac output. It will facilitate blood gas
sampling. Bladder temperature is monitored by means of a urinary catheter and patient is kept
warm by means of a warming mattress and air warming blanket. After this preparation phase and
prior to start of surgery, each subject will undergo two randomly allocated study periods:
one with VCV, the other with FCV. In both cases FIO2 will be 0.3%, EEP at +5 cmH2O and I:E
1:1. Before starting the study protocol all subjects will be pre-oxygenated with 100% Oxygen
for three minutes and undergo a recruitment manoeuvre. The recruitment manoevre will be
conducted as follows: respiratory rate 12 breaths/minute, tidal volume 6mL/kg, initial PEEP
5cm H2O, with PEEP increasing in 5cm H2O increments to 15cm H2O per 5 breaths and then in
decremental steps of 5cm H2O per 5 breaths back to 5 cm H2O PEEP. Peak pressure will be
limited to 35 cm H2O.The respiratory circuit will then be disconnected for one minute. This
provides sufficient time for placement of the Tritube through the tracheal tube when the
subject is randomised to FCV in the first study period. For subjects initially randomised to
VCV, VCV will be continued after this sham manoevre. Data collection starts after 15 minutes
to allow stabilisation of respiratory and hemodynamic variables. Following data collection, a
second 3 minutes pre-oxygenation period with recruitment manoevre and 1 minute apnea will be
used before switching to the second ventilation mode.
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