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http://dx.doi.org/10.5851/kosfa.2018.e66

The Relationship between Muscle Fiber Composition and Pork Taste-traits Assessed by Electronic Tongue System  

Hwang, Young-Hwa (Institute of Agriculture & Life Science, Gyeongsang National University)
Ismail, Ishamri (Division of Applied Life Science (BK21+), Gyeongsang National University)
Joo, Seon-Tea (Institute of Agriculture & Life Science, Gyeongsang National University)
Publication Information
Food Science of Animal Resources / v.38, no.6, 2018 , pp. 1305-1314 More about this Journal
Abstract
To investigate relationships of electronic taste-traits with muscle fiber type composition (FTC) and contents of nucleotides, porcine longissimus lumborum (LL), psoas major (PM), and infra spinam (IS) muscles were obtained from eight castrated LYD pigs. FTC and taste-traits in these three porcine muscles were measured by histochemical analysis and electronic tongue system, respectively. IS had significantly higher proportion of type I fibers while LL had significantly higher proportion of type IIB than other muscles (p<0.05). IS had the highest inosine monophosphate (IMP) content while LL had the lowest IMP content (p<0.05). In contrast, LL had significantly higher hypoxanthine content compared to PM and IS (both p<0.05). For taste-traits, IS had significantly higher umami and richness values but lower sourness value than LL and PM (p<0.05). Sourness and astringency values of LL were significantly higher than those of IS (p<0.05). The proportion of type IIB fiber was positively correlated with sourness and astringency but negatively correlated with saltiness. These results suggest that sourness and astringency tastes are increased with increasing proportions of type IIB fibers in porcine muscles due to increase of hypoxanthine content. These results also imply that umami and richness tastes are increased with increasing contents of type I and IIA fibers because of increased IMP content in porcine muscles.
Keywords
pork taste; electronic taste-traits; electronic tongue system; nucleotide compounds; fiber type composition;
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1 Nishimura T, Rhue MR, Okitani A, Kato H. 1988. Components contributing to the improvement of meat taste during storage. Agric Biol Chem Tokyo 52:2323-2330.
2 Nishimura T. 1998. Mechanism involved in the improvement of meat taste during postmortem aging. Food Sci Technol Int 4:241-249.
3 Okumura T, Inuzuka Y, Nishimura T, Arai S. 1996. Changes in sensory, physical and chemical properties of vacuum packed pork loins during the prolonged conditioning at $4^{\circ}C$. J Anim Sci Technol 67:360-367.
4 Okumura T, Yamada R, Nishimura T. 2004. Sourness-suppressing peptides in cooked pork loins. Biosci Biotechnol Biochem 68:1657-1662.   DOI
5 Ozogul F, Ozden O, Ozogul Y, Erkan N. 2010. The effects of gamma-irradiation on the nucleotide degradation compounds in sea bass (Dicentrarchus labrax) stored in ice. Food Chem 122:789-794.   DOI
6 Realini CE, Venien A, Gou P, Gatellier P, Perez-juan M, Danon J, Astruc T. 2013. Characterization of Longissimus thoracis, Semitendinosus and Masseter muscles and relationships with technological quality in pigs. 1. Microscopic analysis of muscles. Meat Sci 94:408-416.   DOI
7 Ruusunen M, Puolanne E. 2004. Histochemical properties of fibre types in muscles of wild and domestic pigs and the effect of growth rate on muscle fibre properties. Meat Sci 67:533-539.   DOI
8 Ryu YC, Choi YM, Lee SH, Shin HG, Choe JH, Kim JM, Hong KC, Kim BC. 2008. Comparing the histochemical characteristics and meat quality traits of different pig breeds. Meat Sci 80:363-369.   DOI
9 Ryu YC, Kim BC. 2005. The relationship between muscle fiber characteristics, postmortem metabolic rate, and meat quality of pig longissimus dorsi muscle. Meat Sci 71:351-357.   DOI
10 Sasaki K, Motoyama M, Mitsumoto M. 2007. Changes in the amounts of water-soluble umami-related substances in porcine longissimus and biceps femoris muscles during moist heat cooking. Meat Sci 77:167-172.   DOI
11 Sasaki K, Tani F, Sato K, Ikezaki H, Taniguchi A, Emori T, Iwaki F, Chikuni K, Mitsumoto M. 2005. Analysis of pork extracts by taste sensing system and the relationship between umami substances and sensor output. Sens Mater 17:397-404.
12 Yang NC, Ho WM, Chen YH, Hu ML. 2002. A convenient one-step extraction of cellular ATP using boiling water for the luciferin-luciferase assay of ATP. Anal Biochem 306:323-327.   DOI
13 Shi C, Cui J, Liu X, Zhang Y, Qin N, Luo Y. 2017. Application of artificial neural network to predict the change of inosine monophosphate for lightly salted silver carp (Hypophthalmichthys molitrix) during thermal treatment and storage. J Food Process Preserv 41:e13246.   DOI
14 Toko K. 1996. Taste sensor with global selectivity. Mater Sci Eng C 4:69-82.   DOI
15 Toko K. 1998. Electronic tongue. Biosens Bioelectron 13:701-709.   DOI
16 Fuke S, Konosu S. 1991. Taste-active components in some foods: A review of Japanese research. Physiol Behav 49:863-868.   DOI
17 Brooke MH, Kaiser KK. 1970. Muscle fiber types: How many and what kind? Arch Neurol 23:369-379.   DOI
18 Chikuni K, Oe M, Sasaki K, Shibata M, Nakajima I, Ojima K, Muroya S. 2010. Effects of muscle type on beef taste-traits assessed by an electric sensing system. Anim Sci J 81:600-605.   DOI
19 Choi YM, Kim BC. 2009. Muscle fiber characteristics, myofibrillar protein isoforms, and meat quality. Livest Sci 122:105-118.   DOI
20 Hwang YH, Kim GD, Jeong JY, Hur SJ, Joo ST. 2010. The relationship between muscle fiber characteristics and meat quality traits of highly marbled Hanwoo (Korean native cattle) steers. Meat Sci 86:456-461.   DOI
21 Kim GD, Jeong JY, Jung EY, Yang HS, Lim HT, Joo ST. 2013. The influence of fiber size distribution of type IIB on carcass traits and meat quality in pigs. Meat Sci 94:267-273.   DOI
22 Jeong JY, Jeong TC, Yang HS, Kim GD. 2017. Multivariate analysis of muscle fiber characteristics, intramuscular fat content and fatty acid composition in porcine longissimus thoracis muscle. Livest Sci 202:13-20.   DOI
23 Joo ST, Kim GD, Hwang YH, Ryu YC. 2013. Control of fresh meat quality through manipulation of muscle fiber characteristics. Meat Sci 95:828-836.   DOI
24 Jung EY, Hwang YH, Joo ST. 2015. Chemical components and meat quality traits related to palatability of ten primal cuts from Hanwoo carcasses. Korean J Food Sci An 35:859-866.   DOI
25 Jung EY, Hwang YH, Joo ST. 2016. The relationship between chemical compositions, meat quality, and palatability of the 10 primal cuts from Hanwoo steers. Korean J Food Sci An 36:145-151.   DOI
26 Kawai M, Okiyama A, Ueda Y. 2002. Taste enhancements between various amino acids and IMP. Chem Senses 27:739-745.   DOI
27 Kim GD, Yang HS, Jeong JY. 2018. Intramuscular variations of proteome and muscle fiber type distribution in semimembranosus and semitendinosus muscles associated with pork quality. Food Chem 244:143-152.   DOI
28 Klont RE, Brocks L, Eikelenboom G. 1998. Muscle fibre type and meat quality. Meat Sci 49:S219-S229.   DOI
29 Lee SH, Choe JH, Choi YM, Jung KC, Rhee MS, Hong KC, Lee SK, Ryu YC, Kim BC. 2012. The influence of pork quality traits and muscle fiber characteristics on the eating quality of pork from various breeds. Meat Sci 90:284-291.   DOI
30 Morita S, Cassens RG, Briskey EJ, Kauffman RG, Kastenschmidt LL. 1970. Localization of myoglobin in pig muscle. J Food Sci 35:111-112.   DOI