Главная Статьи THE NEW APPROACH TO A PATTERN RECOGNITION OF VOLATILE COMPOUNDS: THE INFLAMMATION MARKERS IN NASAL MUCUS SWABS FROM CALVES USING THE GAS SENSOR ARRAY

THE NEW APPROACH TO A PATTERN RECOGNITION OF VOLATILE COMPOUNDS: THE INFLAMMATION MARKERS IN NASAL MUCUS SWABS FROM CALVES USING THE GAS SENSOR ARRAY

KUCHMENKO T.1,

 

SHUBA A.1,

 

UMARKHANOV R.1,

 

LVOVA L.2

1 Department of Physical and Analytical Chemistry, Voronezh State University of Engineering Technologies (VSUET), Revolutsii Avenue 19
2 Department of Chemical Sciences and Technology, University “Tor Vergata”, Via Della Ricerca Scientifica 1

ЖУРНАЛ:

CHEMOSENSORS
eISSN: 2227-9040

АННОТАЦИЯ:

This paper discusses the application of two approaches (direct and inverse) to the identification of volatile substances by means of a gas sensor array in a headspace over nasal mucus swab samples taken from calves with differing degrees of respiratory damage. We propose a unique method to visualize sensor array data for quality analysis, based on the spectra of cross mass sensitivity parameters. The traditional method, which requires an initial sensor array trained on the vapors of the individual substances (database accumulation)—with their further identification in the analyzed bio-samples through the comparison of the analysis results to the database—has shown unsatisfactory performance. The proposed inverse approach is more informative for the pattern recognition of volatile substances in the headspace of mucus samples. The projection of the calculated parameters of the sensor array for individual substances in the principal component space, acquired while processing the sensor array output from nasal swab samples, has allowed us to divide animals into groups according to the clinical diagnosis of their lung condition (healthy respiratory system, bronchitis, or bronchopneumonia). The substances detected in the gas phase of the nasal swab samples (cyclohexanone, butanone-2,4-methyl-2-pentanone) were correlated with the clinical state of the animals, and were consistent with the reference data on disease markers in exhaled air established for destructive organism processes.