Detection of Umami Substances and Umami Intensity Based on Near-Infrared Spectroscopy

Jian Hu; Yaoze Feng; Yijian Wang; Jie Huang; Guifeng Jia; Ming Zhu

doi:10.3788/AOS202242.0130002

[1] Moskowitz H R. Umami: a basic taste[M]. //Kamamura Y, Kare M R. Appetite. New York: Marcel Dekker, Inc., 75-76(1987).

[2] Yuzo N, Masaya F. Peripheral neural basis for behavioural discrimination between glutamate and the four basic taste substances in mice[J]. Comparative Biochemistry and Physiology Part A: Physiology, 92, 371-376(1989).

[3] Yamamoto T, Matsuo R, Kiyomitsu Y et al. Taste effects of ‘umami’ substances in hamsters as studied by electrophysiological and conditioned taste aversion techniques[J]. Brain Research, 451, 147-162(1988).

[4] Gong J, Tao N P, Gu S Q. Overview of umami substance in food and its detection methods[J]. China Condiment, 39, 129-135(2014).

[5] Li X P, Xie X X, Zhu W H et al. Research progress of umami substances and umami peptides in food[J]. Science and Technology of Food Industry, 39, 319-327(2018).

[6] Ma J R, Pan T, Wang Z Y et al. Analysis of taste components of traditional charcoal roast mutton[J]. Food Science and Technology, 44, 110-116(2019).

[7] Yamaguchi S. The synergistic taste effect of monosodium glutamate and disodium 5’-inosinate[J]. Journal of Food Science, 32, 473-478(1967).

[8] Liu D Y, Liu H, Zhang Q Y et al. Cumulative effect of main non-salt taste compounds on braised chicken brine during repeated braising[J]. Science and Technology of Food Industry, 39, 64-69, 75(2018).

[9] Lin H B, Yu X Y, Fang J X et al. Flavor compounds in Pixian broad-bean paste: non-volatile organic acids and amino acids[J]. Molecules, 23, 1299(2018).

[10] Yu F Z, Bo C M, Liu D Y. Research progress of umami substances in food[J]. Journal of Food Safety & Quality, 11, 5554-5561(2020).

[11] Zhu Y W, Zhang N L, Jiang S et al. The research progress on food umami perception[J]. Journal of Chinese Institute of Food Science and Technology, 21, 1-16(2021).

[12] Li S H, Wang J, Song C F et al. Effects of different drying methods on physicochemical and sensory characteristics of instant scallop[J]. Transactions of the Chinese Society of Agricultural Engineering, 27, 373-377(2011).

[13] Xu Y, Chen Y P, Deng S L et al. Application of sensory evaluation, GC-ToF-MS, and E-nose to discriminate the flavor differences among five distinct parts of the Chinese blanched chicken[J]. Food Research International, 137, 109669(2020).

[14] Pang G C, Chen Q S, Hu Z H et al. Advances in research on taste receptors and application prospects of taste sensors[J]. Food Science, 38, 288-298(2017).

[15] Wei X W, Qin C L, Gu C L et al. A novel bionic in vitro bioelectronic tongue based on cardiomyocytes and microelectrode array for bitter and umami detection[J]. Biosensors and Bioelectronics, 145, 111673(2019).

[16] Wang G X, Sun J F, Yao Y et al. Detection of inosine monophosphate (IMP) in meat using double-enzyme sensor[J]. Food Analytical Methods, 13, 420-432(2020).

[17] Hao Y, Wu W H, Shang Q Y et al. Analysis model of oleic and linoleic acids in camellia oil via near-infrared spectroscopy[J]. Acta Optica Sinica, 39, 0930004(2019).

[18] Liu Y D, Zhang Y, Xu H et al. Detection of sugar content of pomegranates from different producing areas based on near-infrared spectroscopy[J]. Laser & Optoelectronics Progress, 57, 013002(2020).

[19] Nørgaard L, Saudland A, Wagner J et al. Interval partial least-squares regression (iPLS): a comparative chemometric study with an example from near-infrared spectroscopy[J]. Applied Spectroscopy, 54, 413-419(2000).

[20] Li H D, Liang Y Z, Xu Q S et al. Key wavelengths screening using competitive adaptive reweighted sampling method for multivariate calibration[J]. Analytica Chimica Acta, 648, 77-84(2009).

[21] Centner V. Massart D L, de Noord O E, et al. Elimination of uninformative variables for multivariate calibration[J]. Analytical Chemistry, 68, 3851-3858(1996).

[22] Galvão R K H, Araújo M C U, Fragoso W D et al. A variable elimination method to improve the parsimony of MLR models using the successive projections algorithm[J]. Chemometrics and Intelligent Laboratory Systems, 92, 83-91(2008).

[23] Li H D, Xu Q S. Liang Y Z. libPLS: an integrated library for partial least squares regression and discriminant analysis[J]. Chemometrics and Intelligent Laboratory Systems, 176, 34-43(2018).

[24] Poerio D V, Brown S D. Stacked interval sparse partial least squares regression analysis[J]. Chemometrics and Intelligent Laboratory Systems, 166, 49-60(2017).

[25] Li P, Zhou J, Jiang L W et al. A variable selection approach of near infrared spectra based on window competitive adaptive reweighted sampling strategy[J]. Spectroscopy and Spectral Analysis, 39, 1428-1432(2019).

[26] Tian H, Zhang L N, Li M et al. Weighted SPXY method for calibration set selection for composition analysis based on near-infrared spectroscopy[J]. Infrared Physics & Technology, 95, 88-92(2018).

[27] Xu H, Liu Z C, Cai W S, Shao X G. A wavelength selection method based onrandomization test for near-infrared spectral analysis[J]. Chemometrics and Intelligent Laboratory Systems, 97, 189-193(2009).

[28] Xiao X, Ma J F, Ge F H et al. Application of near-infrared spectroscopy for the rapid analysis of Lonicerae Japonicae Flos solution extracted by water[J]. Journal of Innovative Optical Health Sciences, 7, 1350063(2014).

[29] Katuwal S, Knadel M, Norgaard T et al. Predicting the dry bulk density of soils across Denmark: comparison of single-parameter, multi-parameter, and VIS-NIR based models[J]. Geoderma, 361, 114080(2020).

[30] Xiang L L, Li M H, Li J M et al. Determination of wine original regions using information fusion of NIR and MIR spectroscopy[J]. Spectroscopy and Spectral Analysis, 34, 2662-2666(2014).

[31] Büning-Pfaue H. Analysis of water in food by near infrared spectroscopy[J]. Food Chemistry, 82, 107-115(2003).