Your search keyword '"Kessler V"' showing total 4 results

1. The Traveling Shutter Wave analyses non-linear compliance during mechanical ventilation.

Author

Mols G, Kessler V, Benzing A, Schneider M, Kühne L, Geiger K, and Guttmann J

Subjects

Feasibility Studies, Humans, Monitoring, Physiologic instrumentation, Reproducibility of Results, Lung Compliance, Monitoring, Physiologic methods, Nonlinear Dynamics, Respiration, Artificial adverse effects, Respiration, Artificial methods, Signal Processing, Computer-Assisted instrumentation, Tidal Volume

Abstract

Mechanical ventilation is an important, often life-saving component of modern intensive care medicine. However, it may further aggravate pulmonary pathology by endinspiratory overdistension of the alveoli or by their endexpiratory collapse. To prevent both the ventilator may be adjusted based on the slope of the pressure-volume curve, named as compliance, which is often determined by a stepwise inflation of the lungs. This maneuver gained no widespread clinical acceptance because of being cumbersome and invasive. Therefore, we developed a modification of the well known interrupter technique - the Traveling Shutter Wave. A wave of short-term (300 ms) occlusions "travels" over the tidal volume range. Differential compliance is calculated by division of volume and pressure differences between two adjacent occlusion maneuvers. The technique is well suited for the clinical setting because the ventilatory pattern does not need to be changed. This manuscript describes the realization of the Traveling Shutter Wave as well as its application in two patients.

Published

1999

2. Detection of endotracheal tube obstruction by analysis of the expiratory flow signal.

Author

Guttmann J, Eberhard L, Haberthür C, Mols G, Kessler V, Lichtwarck-Aschoff M, and Geiger K

Subjects

Aged, Diagnosis, Differential, Equipment Failure, Female, Humans, Intubation, Intratracheal instrumentation, Male, Middle Aged, Prospective Studies, Retrospective Studies, Airway Obstruction diagnosis, Airway Obstruction etiology, Airway Resistance, Intubation, Intratracheal adverse effects, Respiration, Artificial adverse effects, Respiratory Distress Syndrome therapy, Signal Processing, Computer-Assisted, Spirometry methods

Abstract

Objective: Acute obstruction of endotracheal tubes (ETT) increases airway pressure, decreases tidal volume, increases the risk of dynamic hyperinflation by prolonging the duration of passive expiration, and prevents reliable calculation of tracheal pressure. We propose a computer-assisted method for detecting ETT obstruction during controlled mechanical ventilation. The method only requires measurement of the expiratory flow., Design: Computer simulation; prospective study in two cases; retrospective study in one case and in seven patients with the adult respiratory distress syndrome (ARDS)., Setting: Laboratory of the Section of Experimental Anaesthesiology (University of Freiburg); surgical adult intensive care units in a university hospital (University of Basel) and in a university affiliated hospital (Zentralklinikum Augsburg)., Patients: 3 patients with partial ETT or bronchial obstructions and 7 ARDS patients., Measurements and Results: Expiratory flow was measured using a pneumotachograph and integrated to obtain expiratory volume. The time-constant of passive expiration (tauE) as a function of expired volume [tauE(V(E)) function] was calculated from the expiratory volume/flow curve. We investigated the tauE(V(E)) function of data obtained from: (1) computer simulation of mechanically ventilated homogeneous and inhomogeneous lungs intubated with ETTs of different sizes; (2) one patient with an artificial ETT obstruction of 7.5 and 25% of the cross-sectional area of the ETT (case 1); (3) one patient with ETT obstruction due to secretions (case 2); (4) one patient with acute bronchial constriction (case 3); (5) seven ARDS patients who showed an increase in airway resistance of more than 2 cm H2O x s/l. It was found that an ETT obstruction caused an increase in tauE in early expiration (at high flow), whereas tauE in late expiration was virtually unchanged. The reason for this is the flow dependency of the increase in ETT resistance produced by ETT obstruction. Unlike ETT obstruction, an increase in pure airway resistance produced an increase in tauE throughout expiration., Conclusions: An ETT obstruction can be reliably distinguished from an increase in pure airway resistance by a characteristic pattern change in the tauE(V(E)) function, which can be detected easily even by an automated pattern recognition system.

Published

1998

3. [Detection of partial obstructions of the endotracheal tube].

Author

Schumann S, Kessler V, Mols G, Geiger K, and Guttmann J

Subjects

Airway Resistance physiology, Computer Simulation, Equipment Failure Analysis, Humans, Lung Compliance physiology, Models, Theoretical, Intubation, Intratracheal instrumentation, Monitoring, Physiologic instrumentation, Signal Processing, Computer-Assisted instrumentation, Ventilators, Mechanical

Published

1998

4. [Noninvasive determination of tracheal pressure in ventilated children--a model study].

Author

Kessler V, Mols G, Hentschel R, Geiger K, and Guttmann J

Subjects

Airway Resistance physiology, Child, Computer Graphics, Equipment Design, Humans, Monitoring, Physiologic instrumentation, Computer Simulation, Intubation, Intratracheal instrumentation, Pulmonary Ventilation physiology, Respiration, Artificial, Signal Processing, Computer-Assisted instrumentation

Published

1997