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Literature DB >> 22254481

Breath gas analysis for estimating physiological processes using anesthetic monitoring as a prototypic example.

Julian King¹, Karl Unterkofler, Susanne Teschl, Anton Amann, Gerald Teschl.

Abstract

Analysis of exhaled trace gases is a novel methodology for gaining continuous and non-invasive information on the clinical state of an individual. This paper serves to explore some potential applications of breath gas analysis in anesthesia, describing a monitoring scheme for target site concentrations and cardiac output via physiological modeling and real-time breath profiles of the anesthetic agent. The rationale given here is mainly simulation-based, however, the underlying concepts are directly applicable to a routine clinical setting.

Mesh：

Year: 2011 PMID： 22254481 DOI： 10.1109/IEMBS.2011.6090232

Source DB: PubMed Journal: Conf Proc IEEE Eng Med Biol Soc ISSN： 1557-170X

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Cited

5 in total

1. Product ion distributions for the reactions of NO⁺ with some physiologically significant aldehydes obtained using a SRI-TOF-MS instrument.

Authors: Paweł Mochalski; Karl Unterkofler; Patrik Španěl; David Smith; Anton Amann
Journal: Int J Mass Spectrom Date: 2014-04-15 Impact factor: 1.986

2. Breath isoprene: muscle dystrophy patients support the concept of a pool of isoprene in the periphery of the human body.

Authors: J King; P Mochalski; K Unterkofler; G Teschl; M Klieber; M Stein; A Amann; M Baumann
Journal: Biochem Biophys Res Commun Date: 2012-06-05 Impact factor: 3.575

Breath gas analysis for estimating physiological processes using anesthetic monitoring as a prototypic example.

1. Product ion distributions for the reactions of NO⁺ with some physiologically significant aldehydes obtained using a SRI-TOF-MS instrument.

2. Breath isoprene: muscle dystrophy patients support the concept of a pool of isoprene in the periphery of the human body.

3. Assessment of the exhalation kinetics of volatile cancer biomarkers based on their physicochemical properties.

4. Multi-capillary-column proton-transfer-reaction time-of-flight mass spectrometry.

Review 5. Assessment, origin, and implementation of breath volatile cancer markers.

Breath gas analysis for estimating physiological processes using anesthetic monitoring as a prototypic example.

1. Product ion distributions for the reactions of NO+ with some physiologically significant aldehydes obtained using a SRI-TOF-MS instrument.

2. Breath isoprene: muscle dystrophy patients support the concept of a pool of isoprene in the periphery of the human body.

3. Assessment of the exhalation kinetics of volatile cancer biomarkers based on their physicochemical properties.

4. Multi-capillary-column proton-transfer-reaction time-of-flight mass spectrometry.

Review 5. Assessment, origin, and implementation of breath volatile cancer markers.

1. Product ion distributions for the reactions of NO⁺ with some physiologically significant aldehydes obtained using a SRI-TOF-MS instrument.