Variability of End-Expiratory Lung Volume in Premature Infants

Émériaud, Guillaume; Baconnier, Pierre; Eberhard, André; Debillon, Thierry; Calabrese, Pasquale; Benchetrit, Gila

doi:10.1159/000281262

Cited by 11 publications

(15 citation statements)

References 72 publications

(99 reference statements)

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“…A decreased variability is associated with respiratory disease in adults (29) and in infants (22), and a lower variability is a predictor of weaning failure (30). In this study, the patients exhibited a large variability of their ventilatory drive whatever the mode, as reflected by large coefficient of variation of peak Edi.…”

Section: Respiratory Variabilitymentioning

confidence: 54%

“…However, the dispersion of delays in PCV and PSV reflects that the cycling off is dependent on conditions that are varying cycle by cycle. These varying parameters include patient inspiratory effort, neural inspiratory and expiratory time, the level of assist, the time constant of the Articles NAVA in infants respiratory system, and the level of end-expiratory lung volume (22,23). Up to one-fifth of the breaths during conventional ventilation showed cycling off before the peak of the Edi.…”

Section: Nava In Infantsmentioning

confidence: 99%

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Neurally adjusted ventilatory assist improves patient–ventilator interaction in infants as compared with conventional ventilation

et al. 2012

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Background: Neurally adjusted ventilatory assist (NaVa) is a mode of ventilation controlled by the electrical activity of the diaphragm (edi). The aim was to evaluate patient-ventilator interaction in infants during NaVa as compared with conventional ventilation. Methods: Infants were successively ventilated with NaVa, pressure control ventilation (PcV), and pressure support ventilation (PsV). edi and ventilator pressure (Pvent) waveforms were compared and their variability was assessed by coefficients of variation. results: Ten patients (mean age 4.3 ± 2.4 mo and weight 5.9 ± 2.2 kg) were studied. In PcV and PsV, 4 ± 4.6% and 6.5 ± 7.7% of the neural efforts failed to trigger the ventilator. This did not occur during NaVa. Trigger delays were shorter with NaVa as compared with PcV and PsV (93 ± 20 ms vs. 193 ± 87 ms and 135 ± 29 ms). During PcV and PsV, the ventilator cycled off before the end of neural inspiration in 12 ± 13% and 21 ± 19% of the breaths (0 ± 0% during NaVa). During PcV and PsV, 24 ± 11% and 25 ± 9% of the neural breath cycle was asynchronous with the ventilator as compared with 11 ± 3% with NaVa. a large variability was observed for edi in all modes, which was transmitted into Pvent during NaVa (coefficient of variation: 24 ± 8%) and not in PcV (coefficient of variation 2 ± 1%) or PsV (2 ± 2%). conclusion: NaVa improves patient-ventilator interaction and delivers adequate ventilation with variable pressure in infants.c onventional modes of mechanical ventilation are clearly limited in their ability to provide synchrony between the patient and the assist delivered, as demonstrated repeatedly in adults (1,2) and more recently in children (3). Patientventilator asynchrony has been associated with poor clinical outcome (1,2,4). Despite the attempt to improve synchrony with "patient-triggered" modes such as pressure control ventilation (PCV) or pressure support ventilation (PSV), 25% of adult patients show more than 10% asynchrony with the ventilator (1,2,5). In pediatric patients, synchrony is particularly difficult to achieve because of the small tidal volumes, high respiratory rates, and weak airway flows and pressures. Ironically, during synchronized intermittent mandatory ventilation, more than half of the patient's breathing cycle is spent in asynchrony (3) with the ventilator.Besides the poor timing between the patient and the ventilator, patient-ventilator asynchrony also includes the inability of the ventilator to respond to patient demand and the natural breath-to-breath variability. Respiratory variability is a sign of a well functioning respiratory system (6). By definition, PCV and PSV deliver fixed levels of assist, thereby offering no possibility to respond to the patient's respiratory demand and variability.Neurally adjusted ventilatory assist (NAVA) is a mode of mechanical ventilation that delivers assist in time and in proportion to the electrical activity of the diaphragm (Edi) on a breath-by-breath basis (7). Numerous studies have shown that NAVA efficiently unloads the respirat...

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Section: Respiratory Variabilitymentioning

confidence: 54%

Section: Nava In Infantsmentioning

confidence: 99%

Neurally adjusted ventilatory assist improves patient–ventilator interaction in infants as compared with conventional ventilation

et al. 2012

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“…Most studies on this problem have been carried out using variability analysis in the HF band corresponding to the respiratory rate. A theory was formed in the 1990s that the variability of the respiratory pattern found in both experimental animals and humans reflects the dynamic interaction between the chemoreflex and mechanoreflex feedback mechanisms regulating the ventilatory function of the external respiration [10,14,15]. It was shown in a number of studies on the vari ability of the pulmonary ventilation function of the lung, estimated using statistical criterions of chaos, that the chemoreceptor regulation is the main factor determining the variability [16,17].…”

Section: Discussionmentioning

confidence: 99%

The variability of pulmonary gas exchange and respiratory pattern

Grishin

Kovalenko

2012

Hum Physiol

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“…Whole-body plethysmography (Stocks et al 2001 ) and gas dilution (Sivan et al 1990 ;Vilstrup et al 1992 ), both of which give absolute values for EELV, are not appropriate for repeated measurements in a clinical setting. Other methods, including respiratory inductance plethysmography (Adams 1996 ;Emeriaud et al 2010 ), fi bre-optic plethysmography (Davis et al 1999 ) and electrical impedance tomography (Frerichs et al 2001 ), allow measurement not of absolute volume but of change in EELV relative to a baseline condition, and only with prior calibration can a gas volume change in mL be derived. Despite these limitations, a great deal of information has been obtained from experimental studies in which EELV has been measured, either at the bedside or in the laboratory, as alterations in PEEP have been made.…”

Section: Manipulating End-expiratory Lung Volumementioning

confidence: 99%