Chronic Respiratory Failure Clinical Trial
Official title:
Safe Use of Speaking Valve in Children During Sleep Using Trans-tracheal Pressure Measurement
Many children who are born medically fragile due to prematurity, multiple congenital abnormalities or an acquired insult (i.e. cardiac, neurologic, etc.) may require tracheostomy tube placement due to need of chronic respiratory support. Patients on tracheostomy tubes are often unable to vocalize, causing a delay in speech development and poor speech. To help restore normal phonation and promote language development in young pediatric patients with tracheostomies, speaking valves are used. Previously it was shown that the Passy-Muir speaking valve was safe to use during sleep in children by showing there were no adverse cardiopulmonary events seen. One objective measurement that was not evaluated was trans-tracheal pressure manometry. The purpose of this study is to continue to validate the safety of the Passy-Muir speaking valve while asleep, with the use of trans-tracheal manometry by comparing expiratory pressure manometry while the patient is awake and asleep.
Previously it was shown that the Passy-Muir speaking valve was safe to use during sleep in
children. There were no adverse cardiopulmonary events seen while wearing the speaking valve
during sleep. However, trans-tracheal pressure was not measured while these children were
asleep wearing the Passy-Muir speaking valve.The investigators hypothesize that patients who
tolerate speaking valve while awake will have similar trans-tracheal pressure measurement
when asleep as when they are awake.
The specific aims of this proposal are:
1) to show that the Passy-Muir speaking valve worn during sleep has similar trans-tracheal
pressure manometry as when worn while awake.
The primary outcome measure is to show that trans-tracheal manometry measurement is similar
while on the Passy-Muir speaking valve when patients are awake and asleep
Secondary outcomes are a) recording of symptoms (i.e. choking, gagging, increased
respiratory rate, abnormal breathing pattern, coughing, chest tightness and aversion) while
wearing the speaking valve either awake or asleep b) recording vital signs which will be
compared to normal and baseline for age (i.e. heart rate, respiratory rate, end-tidal carbon
dioxide and oxygen saturation) while awake and asleep.
Background and significance:
Previously it was shown that Passy-Muir speaking valve is safe to use during sleep in
children. However it continues to be contraindicated for use while asleep. A small
prospective study done on 10 tracheostomized adult patients with a mean age of 70 years
showed that the use of the speaking valve for one night in seriously ill patients was not
associated with apneas or significant desaturations. A cohort study of 32 tracheostomized
patients showed that 14 patients were able to tolerate speaking valve for 24 hours; even
during sleep.
Pediatric patients with tracheostomy tube are often unable to vocalize. Tracheostomy tubes
allow the exhaled flow of air to bypass the vocal cords out through the opening of the tube
making speech difficult. This causes a delay in speech development and poor speech. Speaking
valves, like the Passy-Muir valve, restore normal phonation and promote language development
in young pediatric patients with tracheostomies. Speech development is not the only benefit
seen with speaking valves. Speaking valves can lead to improvement in swallowing safety
reducing aspiration, improved ventilator weaning leading to more rapid tracheal
decannulation, reduce secretion management, improve hygiene, and enhance smell and taste.
Evaluation of speaking valve tolerance can be done by monitoring vital signs (i.e.
respiratory rate, heart rate, and oxygen saturation). In addition, measurement of
trans-tracheal pressure is an invaluable tool in evaluating subjects for speaking valve
placement. Measurement of trans-tracheal pressure is predictive of good tolerance of the
valve.
The measurement allows one to quickly and easily assess patency of the upper airway and the
ability to force air through the vocal cords. If the pressures are elevated, greater than 10
cm of water on inhalation phase and 30cm of water on the exhalation phase, it would indicate
an obstruction in the upper part of the trachea (i.e. subglottic stenosis). The pressures
can also evaluate respiratory function prior to considering patients for placement of the
valve.
Many children who are born medically fragile due to prematurity, multiple congenital
abnormalities or an acquired insult (i.e. cardiac, neurologic, etc.) may require
tracheostomy tube placement due to need of chronic respiratory support. Initially, after a
patient is assessed for a speaking valve and is cleared for use, a patient may be
apprehensive toward the speaking valve.
If a patient displays discomfort, anxiety, dyspnea/respiratory distress or there is air
trapping (from the build-up of subglottic pressure from incomplete exhalation) trials are
repeated on subsequent days. However, one can assume that initial failure is due to
aversion, but it may be due to resistance in the upper airway, or vice versa.
The purpose of this study is to continue to validate the safety of the Passy-Muir speaking
valve while asleep, with the use of trans-tracheal manometry by comparing expiratory
pressure manometry while the patient is awake and asleep.
;
Observational Model: Cohort, Time Perspective: Prospective
| Status | Clinical Trial | Phase | |
|---|---|---|---|
| Completed |
NCT05084976 -
Parental Perception of COVID-19 Vaccine in Technology Dependent Patients
|
||
| Not yet recruiting |
NCT05756387 -
Improving Chronic Nocturnal Noninvasive Ventilation: a Multimodality Approach
|
||
| Enrolling by invitation |
NCT04208581 -
Yiqi Huoxue Huatan Granule for Reducing Mortality in COPD With Chronic Respiratory Failure
|
Phase 3 | |
| Recruiting |
NCT02260583 -
Effect of Extracorporeal CO2 Removal in Stable Hypercapnic COPD Patients
|
N/A | |
| Completed |
NCT01255111 -
Adaptation to Nocturnal Noninvasive Ventilation in Patients With Chronic Respiratory Failure (ROOMILA)
|
N/A | |
| Active, not recruiting |
NCT03499470 -
Structured Discharge and Follow-up Protocol for COPD Patients Receiving LTOT and NIV
|
N/A | |
| Completed |
NCT04143230 -
Identification of In-hospital Patients in Need of Palliative Care Using a New Simplified Screening Tool
|
N/A | |
| Terminated |
NCT00208078 -
Effect of Non-Invasive Ventilation in Cystic Fibrosis Patient With Chronic Respiratory Failure.
|
Phase 4 | |
| Recruiting |
NCT06286917 -
Initiation of Noninvasive Ventilation in ALS Patients With Chronic Respiratory Insufficiency
|
N/A | |
| Completed |
NCT02342899 -
Cost Effectiveness of Outpatient Set-up of Automated NIV in Obese Patients With Chronic Respiratory Failure
|
Phase 3 | |
| Terminated |
NCT03473171 -
Implementation of Nasal Non-Invasive Ventilation With a RAM Cannula in the Inpatient /Outpatient Setting
|
N/A | |
| Not yet recruiting |
NCT05258370 -
Fibroblast Growth Factor 23 in Chronic Respiratory Failure
|
||
| Completed |
NCT02804243 -
The Efficacy of Nasal High Flow Oxygen Therapy With Rehabilitation in the Patients With Chronic Respiratory Failure
|
N/A | |
| Completed |
NCT01479959 -
Impact of Patient Controlled Positive End-expiratory Pressure on Speech in Tracheostomized Ventilated Patients
|
N/A | |
| Completed |
NCT01090986 -
Home Mechanical Ventilation Effectiveness and Air Leaks
|
N/A | |
| Completed |
NCT00698958 -
Ambulatory Adaptation to Non-Invasive Mechanical Ventilation
|
Phase 4 | |
| Not yet recruiting |
NCT06119087 -
Mechanical Insufflation in the Philadelphia Amyotrophic Lateral Sclerosis Cohort (MI-PALS) Study
|
N/A | |
| Recruiting |
NCT05796297 -
Clinical Impact of Patient-ventilator Asynchrony
|
||
| Recruiting |
NCT04481295 -
Study on Optimal Oxygen Concentration During Pulmonary Rehabilitation
|
N/A | |
| Withdrawn |
NCT05379439 -
Family Connections
|
N/A |