Spontaneous Breathing Trial Clinical Trial
Official title:
Entropy Analysis and Complex Patient-ventilator Interactions During Invasive Mechanical Ventilation at Intensive Care Unit Setting
Complex patterns of patient-ventilator interactions could be miscalculated by visual observation of mechanical ventilator screens or current algorithms based on physiologic waveforms to detect patient-ventilator asynchronies. Therefore, we aim to characterize, validate and study the clinical distribution and implications of an automated and personalized non-invasive tool based on Entropy to detect Complex Patient-Ventilator Interactions (CP-VI) during mechanical ventilation, defined as breathing pattern change and/or clusters of asynchronies, over the signals of airway pressure (Paw) and airway flow (Flow).
Methods
1. Defining complex patient ventilator interactions The Investigators defined "Complex
Patient-Ventilator Interactions" (CP-VI) as the presence alone or in combination of a
change in the respiratory rate of more than 50%, and/or the occurrence of any kind of
asynchronies
2. Data acquisition and data analysis Paw and Flow signals will continuously recorded
throughout patient's stay in the Intensive Care Unit (UCI) using BetterCare® system
(Better Care®, Barcelona, Spain). BetterCare uses drivers specifically designed to
interact with the output signal of mechanical ventilators and bedside monitors rather
than directly with patients. Recorded signals are synchronized and stored for further
analysis. MATLAB (The MathWorks, Inc., vR2018b, Natick, MA, USA) will be used to perform
the signal processing, data analysis and visual assessment.
3. Study Population The Investigators will obtain data from an prospectively constructed
database from a connectivity platform (Better Care®) to interoperate signals from
different ventilators and monitors and subsequently compute algorithms to diagnose
patient-ventilator asynchronies (ClinicalTrial.gov, NCT03451461). All of those patients
corresponding to a self-extubation event previously recorded will be recruited for the
characterization and validation process, in order to guarantee at patient-ventilator
interactions and episodes when they fight the ventilator. Also, patients in whom an
spontaneous breathing trial previous to an attempt to librate him/her from the
ventilator will be recruited in order to obtain signals of Paw and Flow. Clinical and
demographic data will obtained from the medical chart. The institutional review board
approved the protocol and waived informed consent because the study was
non-interventional, posed no added risk to patients, and did not interfere with usual
care.
4. Visual validation of CP-VI Three researchers will visually review the Flow and Paw
recordings of events. The segments duration will selected based on previous studies
where asynchronous clusters are evaluated. The dataset will be previously selected by an
expert in mechanical ventilation ensuring balance by ventilation modes (grouped by
Pressure Support Ventilation (PSV) and Assist-Control Ventilation modes) and equal
distribution of CP-VI presence or absence. The controlled modes included volume
assist-control ventilation (VACV) and pressure assist-control ventilation (PACV). Flow
and Paw tracings will be randomly ordered in MATLAB prior to visual analysis to ensure
blinding of the scorers. Scorers will be provided with written description of CP-VI
characteristics before visual analysis, as a reference. On base of CP-VI definition
previously described, each researcher will score for the presence or absence of CP-VI
events, without time limitation. The visual assessment will considered as the gold
standard.
5. Entropy Entropy is a non-linear measure that allows assessing the randomness of a series
of data. Entropy calculation requires three parameters: the embedding dimension, m (a
positive integer); the tolerance value or similarity criterion, r (a positive real
number); and the total length, N, of the analysed series.
6. Automatic CP-VI detection An automated algorithm for CP-VI detection based on Entropy
tool will be implemented.
7. Statistical analysis Fleiss's kappa coefficient will be used as reliability of agreement
among raters for visual assessment. The automated algorithm for CP-VI detection will be
applied over the entropy series derived from the same Flow and Paw. The performance of
the automated algorithm will be evaluated on base of sensitivity (Se), specificity (Sp),
positive and negative predictive values (PPV and NPV, respectively), accuracy (ACC) and
Matthews correlation coefficient (MCC).
8. Selection of m, r and N In entropy studies, an important step is to determine the
optimal settings to robust extract the randomness of a series of data. Therefore, an
optimization procedure of m, r and N will performed to properly estimate CP-VI.
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