Harmonic excitation of linear respiratory mechanics for physiological dual controlled ventilation

Montecchia, F.

doi:10.4236/jbise.2012.511085

Cited by 1 publication

(1 citation statement)

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“…The mathematical model employed here is based on linear respiratory mechanics applied for determining the different components of resistance and compliance related to lung and chest expansion/recoil dynamics [6][7][8][9][10][11][12]. The model takes into account quasi-static variations of such respiratory parameters inside each single spontaneous breaths.…”

Section: F Matematical Modelmentioning

confidence: 99%

Pharyngeal and esophageal pressure measurements to evaluate respiratory mechanics in infants on high flow nasal cannula: A feasibility study

Montecchia

Luciani

Cicchetti

et al. 2015

2015 IEEE International Symposium on Medical Measurements and Applications (MeMeA) Proceedings

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High-flow humidified nasal cannula (HFNC) is often\ud used to relieve respiratory distress in children with acute\ud pulmonary disease, although its effects on respiratory mechanics\ud have not been objectively studied. The purpose of this study was\ud to test the feasibility of measuring pharyngeal (PP) and\ud esophageal (Pes) pressures of young children on HFNC oxygen\ud therapy through a specifically designed new monitoring,\ud acquisition, and elaboration system (MAES). Through MAES we\ud recorded and elaborated Pes and PP tracings obtained through\ud esophageal and pharyngeal catheters in a group of young children\ud hospitalized in a Pediatric Intensive Care Unit because of\ud respiratory distress. All traces were recorded during spontaneous\ud breathing and on HFNC 1 and 2 L/kg/min. To determine the\ud onset and the end of inspiration, the Pes and PP signals were\ud synchronized with the inspiratory flow obtained by a flow\ud transducer placed in the HFNC circuit. Direct measurement of\ud inspiratory flow by a face mask pneumotachograph also allowed\ud for inspiratory tidal volume (TV) measurement which was used\ud together with Pes curve to build Campbell’s diagram as well as\ud the static lung and chest wall recoil curves required for pressure\ud time product (PTP) evaluation. Using MAES we were able to\ud obtain: time interval between the beginning of inspiratory effort\ud and inspiration (Tdelay), TV, intrinsic positive end expiratory\ud pressure (PEEPi), total inspiratory Pes variation (ΔPes),\ud transpulmonary pressure at end of inspiration (Ptpei), dynamic\ud lung compliance (CLdyn), total lung resistance (RLtot) along with\ud all the relevant components of the inspiratory work of breathing\ud (WOB) and PTP. We believe that this new system will allow\ud clinicians for a bedside monitoring of respiratory distress in\ud infants treated with HFNC and to modify flow rates accordingly.\ud Index Terms—biological system modeling, biomedica

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