M. Fleischer scite author profile

BACKGROUND: Detection of disease by means of volatile organic compounds from breath samples using sensors is an attractive approach to fast, noninvasive and inexpensive diagnostics. However, these techniques are still limited to applications within the laboratory settings. Here, we report on the development and use of a fast, portable, and IoT-connected point-of-care device (so-called, SniffPhone) to detect and classify gastric cancer to potentially provide new qualitative solutions for cancer screening. METHODS: A validation study of patients with gastric cancer, patients with high-risk precancerous gastric lesions, and controls was conducted with 2 SniffPhone devices. Linear discriminant analysis (LDA) was used as a classifying model of the sensing signals obatined from the examined groups. For the testing step, an additional device was added. The study group included 274 patients: 94 with gastric cancer, 67 who were in the high-risk group, and 113 controls. RESULTS: The results of the test set showed a clear discrimination between patients with gastric cancer and controls using the 2-device LDA model (area under the curve, 93.8%; sensitivity, 100%; specificity, 87.5%; overall accuracy, 91.1%), and acceptable results were also achieved for patients with high-risk lesions (the corresponding values for dysplasia were 84.9%, 45.2%, 87.5%, and 65.9%, respectively). The test-phase analysis showed lower accuracies, though still clinically useful. CONCLUSION: Our results demonstrate that a portable breath sensor device could be useful in point-of-care settings. It shows a promise for detection of gastric cancer as well as for other types of disease.

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Adsorbed water as key to room temperature gas-sensitive reactions in work function type sensors: the carbonate–carbon dioxide system

Ostrick

Mühlsteff

Fleischer

et al. 1999

Sensors and Actuators B: Chemical

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Thin-film gas sensors based on high-temperature-operated metal oxides

Fleischer

Meixner²

1999

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Research into the characteristics of semiconducting metal-oxide films that are stable at high temperatures intensified with the aim of providing reproducible and reliable gas detection in various ambients. First, there is a discussion of the specifics relating to these materials, for example, the effect of grain-boundary barriers on the sensing mechanism, the influence of humidity, and the temperature dependence of the sensing mechanism. Then, the technology for the preparation of the gas sensors will be described. Examples that have already been implemented like λ detection, oxygen and NOx measurements in exhaust gases, detection of explosive and toxic gases in air, as well as hydrogen leakage detection are discussed.

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Optimization of physical filtering for selective high temperature H2 sensors

Weh

Fleischer

Meixner

2000

Sensors and Actuators B: Chemical

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M. Fleischer

Work function based gas sensing with Cu-BTC metal-organic framework for selective aldehyde detection

Sensing gastric cancer via point‐of‐care sensor breath analyzer

Adsorbed water as key to room temperature gas-sensitive reactions in work function type sensors: the carbonate–carbon dioxide system

Thin-film gas sensors based on high-temperature-operated metal oxides

Optimization of physical filtering for selective high temperature H2 sensors

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