This is a single-center proof-of-concept clinical trial designed to establish the feasibility of transvenous phrenic-nerve stimulation (PNS) to maintain diaphragm activation over the first 24 hours and for up to seven days of mechanical ventilation in patients who are likely to require more than 48 hours of invasive mechanical ventilation.
The diaphragm is the main muscle of breathing and for most of us therefore is continuously being used (and hence exercised) when in health. When people are unwell with severe breathing difficulties to the degree that their lungs are needing a lot of support from a breathing machine (ventilator) in the intensive care unit (ICU), or are recovering from major lung/chest surgery on a ventilator in ICU, the diaphragm can quickly start to weaken from its inactivity. This means that even when starting to recover from the underlying medical problem, or from the surgery itself, the diaphragm may be unable perform well enough to take over the work of breathing once again. This can lead to not only longer times on the ventilator (time to gradually rebuild diaphragm strength by rehabilitation and physiotherapy) but also therefore longer times in ICU and in hospital with the risk of complications that can be associated with this. Stimulating the diaphragm by use of a pacemaker (electrical stimulation) is an established treatment for a number of patients with certain types of long-term breathing problems. These pacemakers are permanent and are inserted by invasive surgical methods. More recently however, there have also been a number of studies looking to see if it is possible to safely, temporarily and less invasively stimulate the diaphragm of patients who only have temporary diaphragm inactivity. This has been done either during surgery or during their intensive care stay. A number of methods of temporarily stimulating the diaphragm have been looked at, but the simplest has been to integrate the function of stimulating the nerves (that ultimately control the diaphragm) with a catheter that is frequently placed into a vein in the neck to enable delivery of medications during surgery and in ICU.
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
PREVENTION
Masking
AeroPace Catheter will be placed percutaneously into the left internal jugular vein or left subclavian vein and stimulating electrodes mapped for therapy.
University Health Network
Toronto, Ontario, Canada
Feasibility of placing AeroPace Catheter
Feasibility will be defined as the device being successfully deployed in at least 11 of the 20 patients. Successful deployment of the device defined as: * AeroPace Catheter insertion and placement successfully confirmed * Initial Catheter electrode mapping/calibration successfully completed * Adequate diaphragm activation achieved, defined as hourly Edi level sufficient to generate a Pocc of ≤ -5 cm H2O, for at least 50% of LAPS-PNS stimulated breaths over the first 24 hours after commencing stimulation.
Time frame: 30 days
Safety of AeroPace Catheter
The technique will be considered safe if there are no unexpected serious adverse events (USADEs) and the incidence of device- or procedure-related SAEs is below that established in literature.
Time frame: 30 days
LAPS-PNS successfully achieved at the time of the mapping/calibration procedure on each of the subsequent days up to the end of the study intervention period
Time frame: 7 days
The proportion of time that adequate diaphragm activation is maintained during phrenic nerve stimulation and during the absence of phrenic nerve stimulation.
This is defined as the percentage of hours the patient has an Edi ≥ minimum Edi required to maintain Pocc ≤ -5 cm H2O.
Time frame: 7 days
The proportion of hours in which the maintenance of diaphragm activation is due to LAPS-PNS rather than endogenous patient respiratory effort.
Time frame: 7 days
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NONE
Enrollment
20