Browsing by Author "Petrovic, J. (11541124800)"
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Publication Real-time chest-wall-motion tracking by a single optical fibre grating: A prospective method for ventilator triggering(2018) ;Ivanović, M.D. (57038326200) ;Petrovic, J. (11541124800) ;Savić, A. (54279422000) ;Gligorić, G. (25931438200) ;Miletić, M. (57038553800) ;Vukčević, M. (6602095465) ;Bojović, B. (55903740900) ;Hadžievski, Lj (6602497159) ;Allsop, T. (9740404900)Webb, D.J. (35432474100)Objective: The ventilators involved in non-invasive mechanical ventilation commonly provide ventilator support via a facemask. The interface of the mask with a patient promotes air leaks that cause errors in the feedback information provided by a pneumatic sensor and hence patient-ventilator asynchrony with multiple negative consequences. Our objective is to test the possibility of using chest-wall motion measured by an optical fibre-grating sensor as a more accurate non-invasive ventilator triggering mechanism. Approach: The basic premise of our approach is that the measurement accuracy can be improved by using a triggering signal that precedes pneumatic triggering in the neuro-ventilatory coupling sequence. We propose a technique that uses the measurement of chest-wall curvature by a long-period fibre-grating sensor. The sensor was applied externally to the rib-cage and interrogated in the lateral (edge) filtering scheme. The study was performed on 34 healthy volunteers. Statistical data analysis of the time lag between the fibre-grating sensor and the reference pneumotachograph was preceded by the removal of the unwanted heartbeat signal by wavelet transform processing. Main results: The results show a consistent fibre-grating signal advance with respect to the standard pneumatic signal by (230 ± 100) ms in both the inspiratory and expiratory phases. We further show that heart activity removal yields a tremendous improvement in sensor accuracy by reducing it from 60 ml to 0.3 ml. Significance: The results indicate that the proposed measurement technique may lead to a more reliable triggering decision. Its imperviousness to air leaks, non-invasiveness, low-cost and ease of implementation offer good prospects for applications in both clinical and homecare ventilation. © 2018 Institute of Physics and Engineering in Medicine. - Some of the metrics are blocked by yourconsent settings
Publication Real-time chest-wall-motion tracking by a single optical fibre grating: A prospective method for ventilator triggering(2018) ;Ivanović, M.D. (57038326200) ;Petrovic, J. (11541124800) ;Savić, A. (54279422000) ;Gligorić, G. (25931438200) ;Miletić, M. (57038553800) ;Vukčević, M. (6602095465) ;Bojović, B. (55903740900) ;Hadžievski, Lj (6602497159) ;Allsop, T. (9740404900)Webb, D.J. (35432474100)Objective: The ventilators involved in non-invasive mechanical ventilation commonly provide ventilator support via a facemask. The interface of the mask with a patient promotes air leaks that cause errors in the feedback information provided by a pneumatic sensor and hence patient-ventilator asynchrony with multiple negative consequences. Our objective is to test the possibility of using chest-wall motion measured by an optical fibre-grating sensor as a more accurate non-invasive ventilator triggering mechanism. Approach: The basic premise of our approach is that the measurement accuracy can be improved by using a triggering signal that precedes pneumatic triggering in the neuro-ventilatory coupling sequence. We propose a technique that uses the measurement of chest-wall curvature by a long-period fibre-grating sensor. The sensor was applied externally to the rib-cage and interrogated in the lateral (edge) filtering scheme. The study was performed on 34 healthy volunteers. Statistical data analysis of the time lag between the fibre-grating sensor and the reference pneumotachograph was preceded by the removal of the unwanted heartbeat signal by wavelet transform processing. Main results: The results show a consistent fibre-grating signal advance with respect to the standard pneumatic signal by (230 ± 100) ms in both the inspiratory and expiratory phases. We further show that heart activity removal yields a tremendous improvement in sensor accuracy by reducing it from 60 ml to 0.3 ml. Significance: The results indicate that the proposed measurement technique may lead to a more reliable triggering decision. Its imperviousness to air leaks, non-invasiveness, low-cost and ease of implementation offer good prospects for applications in both clinical and homecare ventilation. © 2018 Institute of Physics and Engineering in Medicine. - Some of the metrics are blocked by yourconsent settings
Publication Rib-cage-movement measurements as a potential new trigger signal in non-invasive mechanical ventilation(2015) ;Ivanovic, M. (57038326200) ;Petrovic, J. (11541124800) ;Miletic, M. (57038553800) ;Danicic, A. (36643424800) ;Bojovic, B. (55903740900) ;Vukcevic, M. (6602095465) ;Lazovic, B. (36647776000) ;Gluvic, Z. (24460256500) ;Hadzievski, L.J.. (6602497159) ;Allsop, T. (9740404900)Webb, D.J. (35432474100)Non-invasive ventilation performed through an oronasal mask is a standard in clinical and homecare mechanical ventilation. Besides all its advantages, inevitable leaks through the mask cause errors in the feedback information provided by the airflow sensor and, hence, patient-ventilator asynchrony with multiple negative consequences. Here we investigate a new way to provide a trigger to the ventilator. The method is based on the measurement of rib cage movement at the onset of inspiration and during breathing by fibre-optic sensors. In a series of simultaneous measurements by a long-period fibre grating sensor and pneumotachograph we provide the statistical evidence of the 200 ms lag of the pneumo with respect the fibre-optic signal. The lag is registered consistently across three independent delay metrics. Further, we discuss exceptions from this trend and identify the needed improvements to the proposed fibre-sensing scheme. © 2015 IEEE. - Some of the metrics are blocked by yourconsent settings
Publication Rib-cage-movement measurements as a potential new trigger signal in non-invasive mechanical ventilation(2015) ;Ivanovic, M. (57038326200) ;Petrovic, J. (11541124800) ;Miletic, M. (57038553800) ;Danicic, A. (36643424800) ;Bojovic, B. (55903740900) ;Vukcevic, M. (6602095465) ;Lazovic, B. (36647776000) ;Gluvic, Z. (24460256500) ;Hadzievski, L.J.. (6602497159) ;Allsop, T. (9740404900)Webb, D.J. (35432474100)Non-invasive ventilation performed through an oronasal mask is a standard in clinical and homecare mechanical ventilation. Besides all its advantages, inevitable leaks through the mask cause errors in the feedback information provided by the airflow sensor and, hence, patient-ventilator asynchrony with multiple negative consequences. Here we investigate a new way to provide a trigger to the ventilator. The method is based on the measurement of rib cage movement at the onset of inspiration and during breathing by fibre-optic sensors. In a series of simultaneous measurements by a long-period fibre grating sensor and pneumotachograph we provide the statistical evidence of the 200 ms lag of the pneumo with respect the fibre-optic signal. The lag is registered consistently across three independent delay metrics. Further, we discuss exceptions from this trend and identify the needed improvements to the proposed fibre-sensing scheme. © 2015 IEEE.
