Source: https://www.healthmonitor.pro/about_de
Timestamp: 2019-04-22 16:30:41+00:00

Document:
Health Monitor is based on emission spectroscopy in the visible wavelength range of glow discharge. The spectral range covers almost all biomarkers in the exhaled air. For example, concentration of acetone in the exhalated air strongly corresponds with blood glucose level. Other gases corresponds with different diseases - that are extremely interesting for medical applications.
Also this principle does not affect the environment or living creatures in any way. The device does not need to be medically certified, and has a wide range of use cases. The sensor is insensitive to the presence of water vapor that is why it can be used to analyze the exhaled air. It has a high spectral and sensor selectivity that allow it to cover many poisoning and toxic impurities in the air. In addition, sensativity of the principle allows to detect minuscule concentration of gases, that helps to diagnose diseases in very early stage.
An unlimited number of analyses allows the Health Monitor to be used as a vending machine (in supermarkets, airports, railway stations, etc.). The widening of the database will be followed by the software update. To detect additional gases that are not added by software today, Health Monitor device does not need upgrading due to its versatility.
It is now known that the normal exhalation of a person is a complex mixture of about 600 volatile compounds. Therefore, there is already plenty of data confirming the relationship of a number of gaseous compounds with some pathological processes in the human body and the possibility of using them as biomarkers for the diagnosis of diseases. Existing devices have a number of drawbacks: they are highly specialized and work with one or more of the substances being tested, similar to their properties. In addition, the technologies for their manufacture are too expensive and difficult to produce, as well as difficult and inconvenient for their operation. All of these disadvantages limit their practical use and mass implementation.
Every specter is unique and is easily recognizable. Using this method, specters of the following gases were gathered :Acetone (propanone), Ammonia, Argon, Butylamine, Carbon dioxide, Carbon tetrachloride, Nitrogen, Oxygen, Ethanol (ethyl alcohol), Helium, Hydrogen peroxide, Isobutane (methylpropane), Isopropanol (isopropyl alcohol), Mercury, Methane, Methanol (methyl alcohol), Nitric Oxide, Radon, Toluene, Xenon.
The amount of gases analyzed by the device is not limited; works are currently taking place on the registration of new specters and adding them to the database.
"Detection of a Small Admixture of Acetone in the Exhaled Air for Noninvasive Diagnosis of Type I Diabetes"
A method for measuring the concentration of a biomarker (acetone in human's breath), which is based on the use of glow-discharge emission spectroscopy in the air, is proposed for the purpose of noninvasive glucose monitoring in diabetes patients' blood. The experimental setup and measurement techniques are described, and preliminary results of clinical trials of the developed system under ambulatory conditions are presented.
The patent for this development was registered in the Russian Federation.
«METHOD OF MONITORING ACETONE LOW IMPURITIES IN THE EXPIRED AIR AND DEVICE FOR ITS IMPLEMENTATION» RU 2597943 (C1) 2015-07-15.
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Light-Induced Drift under condition of ground state optical hyperfine pumping.
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46. S.N. Atutov, K.A. Nasyrov, S.P. Pod'yachev, A.M. Shalagin, O.A. Vostricov.
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70. S. N. Atutov, R. Calabrese, V. Guidi, B. Mai, A. G. Rudavets, E. Scansani, L. Tomassetti, V. Biancalana, A. Burchianti, C. Marinelli, E. Mariotti, L. Moi, and S. Veronesi.
Fast and efficient loading of a Rb magneto-optical trap using light-induced atomic desorption.
11th International Conference on Ions Sources (ICIS05), Rev. Sci. Instrum.
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