Your search keyword '"exhaled breath analysis"' showing total 157 results

151. Technological Advancements in Breath Analysis

Author

de Silva, Geethanga

Subjects

Electrical Engineering, Exhaled breath analysis

Abstract

Exhaled breath analysis of volatile organic compounds for disease diagnosis is considered the new frontier in clinical diagnosis. Exhaled breath biomarkers of many diseases including various cancers have been identified. Exhaled breath analysis is most suitable as a preliminary screening method due to the simplicity of the process and the abundance of constituents of diagnostic value present in exhaled breath. However, the progress of exhaled breath analysis is hindered due to several limitations. Lack of a standard sampling method is a major shortcoming and has been identified as a main cause of inconsistencies found in initial clinical studies. Cost and complexity of analytical instruments used for analysis of volatile organic compounds further limit the viability of breath analysis as a rapid and low cost clinical screening method. To address these shortcomings, the overall objective of this project is to develop technologies/devices necessary to transform exploratory clinical studies into clinical diagnostic tests are consistent and repeatable while providing an analysis platform that is cost effective and easily useable by a clinical care providers at the point of patient care (i.e. in the doctors office or in the patient care facility).The Smart breath sampling device is an exhaled breath sample collection apparatus for repeatable sample collection. The device controls factors known to negatively influence the volatile organic compounds levels during sample collection. Sampling protocols are developed for repeatable and reproducible sample collection using this device.At the heart of this novel point of care breath analysis device is a polymer core intrinsic optical waveguide sensor. When coupled with a novel, separation method known as the Heat Stripping Absorption, the polymer core intrinsic optical sensor can provide analytical performance comparable to gas chromatography mass spectrometry. The sensor technology has high selectivity for identification various species and high sensitivity for quantification of volatile organic compounds in a complex sample such exhaled breath. Perhaps most important, the sensor and associated readout electronics are easily integratable into a handheld device technology that is easily used by care providers and medical technicians who do not have clinical laboratory skills.

Published

2016

152. Exceptional High-Performance of Pt-Based Bimetallic Catalysts for Exclusive Detection of Exhaled Biomarkers.

Author

Kim SJ, Choi SJ, Jang JS, Cho HJ, Koo WT, Tuller HL, and Kim ID

Subjects

Biomarkers, Catalysis, Nanofibers, Nanoparticles, Oxides, Platinum chemistry

Abstract

Achieving an improved understanding of catalyst properties, with ability to predict new catalytic materials, is key to overcoming the inherent limitations of metal oxide based gas sensors associated with rather low sensitivity and selectivity, particularly under highly humid conditions. This study introduces newly designed bimetallic nanoparticles (NPs) employing bimetallic Pt-based NPs (PtM, where M = Pd, Rh, and Ni) via a protein encapsulating route supported on mesoporous WO 3 nanofibers. These structures demonstrate unprecedented sensing performance for detecting target biomarkers (even at p.p.b. levels) in highly humid exhaled breath. Sensor arrays are further employed to enable pattern recognition capable of discriminating between simulated biomarkers and controlled breath. The results provide a new class of multicomponent catalytic materials, demonstrating potential for achieving reliable breath analysis sensing., (© 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

153. Exhaled breath analysis in obstructive sleep apnea.

Author

Schwarz EI, Engler A, and Kohler M

Subjects

Adult, Aged, Exhalation, Humans, Middle Aged, Respiratory System metabolism, Sleep Apnea, Obstructive metabolism, Sleep Apnea, Obstructive physiopathology, Breath Tests, Metabolomics methods, Respiratory System physiopathology, Sleep Apnea, Obstructive diagnosis

Abstract

Introduction: Breath analysis is a novel application that can be used for non-invasive metabolic phenotyping and identification of disease specific breath patterns. Obstructive sleep apnea (OSA) is highly prevalent and has diverse metabolic and cardiovascular consequences, many of them incompletely understood. Areas covered: This review systematically summarizes the current evidence from breath metabolomics using immunoassays of breath condensate, off-line mass spectrometry as well as real-time analysis by electronic sensors and by untargeted mass spectrometry, and discusses the challenges and perspectives of breath analysis in OSA. Expert commentary: Analysis of exhaled breath is an innovative approach that is likely to provide profound insights into the metabolomics of OSA and its consequences and might facilitate diagnosis and therapy monitoring.

Published

2017

154. Development of an Exhaled Breath Monitoring System with Semiconductive Gas Sensors, a Gas Condenser Unit, and Gas Chromatograph Columns.

Author

Itoh T, Miwa T, Tsuruta A, Akamatsu T, Izu N, Shin W, Park J, Hida T, Eda T, and Setoguchi Y

Subjects

Adult, Female, Humans, Male, Middle Aged, Volatile Organic Compounds analysis, Biosensing Techniques methods, Breath Tests methods, Gas Chromatography-Mass Spectrometry methods, Lung Neoplasms metabolism

Abstract

Various volatile organic compounds (VOCs) in breath exhaled by patients with lung cancer, healthy controls, and patients with lung cancer who underwent surgery for resection of cancer were analyzed by gas condenser-equipped gas chromatography-mass spectrometry (GC/MS) for development of an exhaled breath monitoring prototype system involving metal oxide gas sensors, a gas condenser, and gas chromatography columns. The gas condenser-GC/MS analysis identified concentrations of 56 VOCs in the breath exhaled by the test population of 136 volunteers (107 patients with lung cancer and 29 controls), and selected four target VOCs, nonanal, acetoin, acetic acid, and propanoic acid, for use with the condenser, GC, and sensor-type prototype system. The prototype system analyzed exhaled breath samples from 101 volunteers (74 patients with lung cancer and 27 controls). The prototype system exhibited a level of performance similar to that of the gas condenser-GC/MS system for breath analysis., Competing Interests: The authors declare no conflict of interest.

Published

2016

155. Noninvasive detection of gastric cancer.

Author

Wan QS and Zhang KH

Subjects

Biomarkers, Tumor analysis, Breath Tests, DNA blood, DNA, Mitochondrial analysis, Gastric Juice chemistry, Gastroscopy, Humans, Neoplastic Cells, Circulating, Spectrum Analysis, Raman, Stomach Neoplasms diagnostic imaging, Stomach Neoplasms diagnosis

Abstract

Gastric cancer (GC) is the fifth most common cancer and the third common cause of cancer death worldwide. Endoscopy is the most effective method for GC screening, but its application is limited by the invasion. Therefore, continuous efforts have been made to develop noninvasive methods for GC detection and promising results have been reported. Here, we review the advances in GC detection by protein and nucleic acid tumor markers, circulating tumor cells, and tumor-associated autoantibodies in peripheral blood. Some potential new noninvasive methods for GC detection are also reviewed, including exhaled breath analysis, blood spectroscopy analysis and molecular imaging.

Published

2016

156. Predicting co-morbidities in chemically sensitive individuals from exhaled breath analysis.

Author

Zeliger HI, Pan Y, and Rea WJ

Abstract

The exhaled breath of more than four hundred patients who presented at the Environmental Health Center - Dallas with chemical sensitivity conditions were analyzed for the relative abundance of their breath chemical composition by gas chromatography and mass spectrometry for volatile and semi-volatile organic compounds. All presenting patients had no fewer than four and as many as eight co-morbid conditions. Surprisingly, almost all the exhaled breath analyses showed the presence of a preponderance of lipophilic aliphatic and aromatic hydrocarbons. The hydrophilic compounds present were almost entirely of natural origin, i.e. expected metabolites of foods. The lipophile, primarily C3 to C16 hydrocarbons and believed to have come from inhalation of polluted air, were, in all cases, present at concentrations far below those known to be toxic to humans, but caused sensitivity and signs of chemical overload. The co-morbid health effects observed are believed to be caused by the sequential absorption of lipophilic and hydrophilic chemicals; an initial absorption and retention of lipophile followed by a subsequent absorption of hydrophilic species facilitated by the retained lipophile to produce chemical mixtures that are toxic at very low levels. It is hypothesized that co-morbid conditions in chemically sensitive individuals can be predicted from analysis of their exhaled breath.

Published

2012

157. Online monitoring of carbon dioxide and oxygen in exhaled mouse breath via substrate-integrated hollow waveguide Fourier-transform infrared-luminescence spectroscopy

Author

Seichter, Felicia, T��t��nc��, Erhan, Hagemann, Leila Tamina, Vogt, Josef, Wachter, Ulrich, Gr��ger, Michael, Kress, Sandra, Radermacher, Peter, and Mizaikoff, Boris

Subjects

DDC 540 / Chemistry & allied sciences, Luminescence, Kohlendioxid, Respiration, Wellenleiter, Luminescence sensing, On-line monitoring, Fourier transform infrared spectroscopy, Sauerstoff, MIR, FT-IR-Spektroskopie, Maus, 3. Good health, Oxygen, Mice, FTIR, Substrate- integrated hollow waveguide, Carbon dioxide, Lumineszenzspektroskopie, Exhaled breath analysis, iHWG, Waveguides, Mid-infrared, Exspiration

Abstract

Exhaled breath offers monitoring bio markers, as well as diagnosing diseases and therapeutic interventions. In addition, vital functions may be non-invasively monitored on- line. Animal models are frequently used in research for determining novel therapeutic approaches and/or for investigating biological pathways. The exhaled carbon dioxide concentration, exhaled and inhaled oxygen concentration, and the subsequent respiratory quotient (RQ) offer insight into metabolic activity. One may adapt breath sampling systems and equipment designed for human applications to large animal studies, however, such adaptations are usually impossible for small animals due to their minuscule breath volume. Here, we present a system for on-line monitoring of exhaled breath in a ���mouse intensive care unit��� (MICU) based on a modified Fourier-Transform infrared (FTIR) spectrometer equipped with a substrate integrated hollow waveguide (iHWG) gas cell, and a luminescence-based oxygen flow-through sensor integrated into the respiratory equipment of the MICU. Thereby, per-minute resolution of O2 consumption and CO2 production was obtained, and the 95% confidence range of the determined respiratory quotient was ��0.04 or approximately ��5% of the nominal value. Changes in the RQ value caused by intervention in either the metabolic or the respiratory system may therefore reliably be detected., acceptedVersion