[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5851/kosfa.2018.e30

Quality Characteristics of Functional Fermented Sausages Added with Encapsulated Probiotic Bifidobacterium longum KACC 91563

Song, Min-Yu (Animal Products Development and Processing Division, National Institute of Animal Science)
Van-Ba, Hoa (Animal Products Development and Processing Division, National Institute of Animal Science)
Park, Won-Seo (Animal Products Development and Processing Division, National Institute of Animal Science)
Yoo, Ja-Yeon (Animal Products Development and Processing Division, National Institute of Animal Science)
Kang, Han-Byul (Animal Products Development and Processing Division, National Institute of Animal Science)
Kim, Jin-Hyoung (Animal Products Development and Processing Division, National Institute of Animal Science)
Kang, Sun-Moon (Animal Products Development and Processing Division, National Institute of Animal Science)
Kim, Bu-Min (Animal Products Development and Processing Division, National Institute of Animal Science)
Oh, Mi-Hwa (Animal Products Development and Processing Division, National Institute of Animal Science)
Ham, Jun-Sang (Animal Products Development and Processing Division, National Institute of Animal Science)

Publication Information

Food Science of Animal Resources / v.38, no.5, 2018 , pp. 981-994 More about this Journal

Abstract

The present study aimed at evaluating the utilization possibility of encapsulated probiotic Bifidobacterium longum for production of functional fermented sausages. The B. longum isolated from the feces samples of healthy Korean infants encapsulated with glycerol as a cryprotectant was used for fermented sausages production as a functional bacterial ingredient, and its effect was also compared with those inoculated with commercial starter culture (CSC). Results showed that most inoculated encapsulated B. longum (initial count, 5.88 Log CFU/g) could survive after 4 days fermentation (5.40 Log CFU/g), and approximately a half (2.83 Log CFU/g) of them survived in the products after 22 days of ripening. The products inoculated with encapsulated B. longum presented the lowest lipid oxidation level, while had higher total unsaturated fatty acid content and more desirable n-6/n-3 fatty acids than those inoculated with CSC or non-inoculated control. Moreover, the odor and taste scores in the samples made with B. longum were comparable to those in the treatment with CSC. The inoculation with the B. longum had no effects on the biogenic amine contents as well as did not cause defects in color or texture of the final products. Thus, the encapsulation could preserve the probiotic B. longum in the meat mixture, and the encapsulated B. longum could be used as a functional ingredient for production of healthier fermented meat products.

Keywords

fermented sausages; probiotics; biogenic amine; sensory quality;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	Wang J, Korber DR, Low NH, Nickerson MT. 2015. Encapsulation of Bifidobacterium adolescentis cell with legume protein and survival under stimulated gastric conditions and during storage in commercial fruit juice. Food Sci Biotechnol 24:383-391. DOI
2	Albenzio M, Santillo A, Caroprese M, Ruggieri D, Napolitano F, Sevi A. 2013. Physicochemical properties of Scamorza ewe milk cheese manufactured with different probiotic cultures. J Dairy Sci 96:2781-2791. DOI
3	Amine KM, Champagne CP, Salmieri S, Britten M, St-Gelais D, Fustier P, Lacroix M. 2014. Effect of palmitoylated alginate microencapsulation on viability of Bifidobacterium longum during freeze-drying. LWT- Food Sci Technol 56:111-117. DOI
4	Chavarri M, Maranon I, Ares R, Ibanez FC, Marzo F, Villaran MC. 2010. Microencapsulation of a probiotic and prebiotic in alginate-chitosan capsules improves survival in simulated gastro-intestinal conditions. Int J Food Microbiol 142:185-189. DOI
5	Ba HV, Seo HW, Cho SH, Kim YS, Kim JH, Park BY, Kim HW, Ham JS, Seong PN. 2017. Utilisation possibility of Enterococcus faecalis isolates from neonate's faeces for production of fermented sausages as starter cultures. Int J Food Sci Technol 52:1660-1669. DOI
6	Ba HV, Seo HW, Kim JH, Cho SH, Kim YS, Ham JS, Park BY, Kim HW, Kim TB, Seong PN. 2016. The effects of starter culture types on the technological quality, lipid oxidation and biogenic amines in fermented sausages. LWT-Food Sci Technol 74:191-198. DOI
7	Chandramouli V, Kailasapathy K, Peiris P, Jones M. 2004. An improved method of microencapsulation and its evaluation to protect Lactobacillus spp. in simulated gastric conditions. J Microbiol Methods 56:27-35. DOI
8	Ruiz-Capillas C, Jimenez-Colmenero F. 2005. Biogenic amines in meat and meat products. Crit Rev Food Sci Nutr 44:489-599. DOI
9	Latorre-Moratalla ML, Bover-Cid S, Veciana-Nogues MT, Vidal-Carou MC. 2012. Control of biogenic amines in fermented sausages: Role of starter cultures. Frontier Microbiol 3:1-9.
10	Pikul J, Leszczynski DE, Kummerow A. 1989. Evaluation of three modified TBA methods for measuring lipid oxidation in chicken meat. J Agric Food Chem 37:1309-1313. DOI
11	Sabikhi L, Kumar MHS, Mathur BN. 2014. Bifidobacterium bifidum in probiotic Edam cheese: Influence on cheese ripening. J Food Sci Technol 51:3902-3909. DOI
12	Sarkar A, Mandal S. 2016. Bifidobacteria-insight into clinical outcomes and mechanisms of its probiotic action. Microbiol Res 192:159-171. DOI
13	SAS. 2007. SAS Software for PC. SAS Institute Inc., Cary, NC, USA.
14	Song M, Park WS, Yoo J, Han GS, Kim BM, Seong PN, Oh MH, Kim KW, Ham JS. 2017. Characteristics of Kwark cheese supplemented with Bifidobacterium longum KACC 91563. Korean J Food Sci An 37:773-779. DOI
15	Fernandez-Salguero J, Gomez R, Carmona MA. 1993. Water activity in selected high-moisture foods. J Food Compos Anal 6:364-369. DOI
16	Chaves-Lopez C, Serio A, Mazzarrino G, Martuscelli M, Scarpone E, Paparella A. 2015. Control of household mycoflora in fermented sausages using phenolic fractions from olive mill wastewaters. Int J Food Microbiol 207:49-56. DOI
17	Chen Q, Kong B, Han Q, Xia X, Xu L. 2017. The role of bacterial fermentation in lipolysis and lipid oxidation in Harbin dry sausages and its flavour development. LWT- Food Sci Technol 77:389-396. DOI
18	Corral S, Salvador A, Flores M. 2016. Effect of the use of entire male fat in the production of reduced salt fermented sausages. Meat Sci 116:140-150. DOI
19	Folch J, Lees M, Stanley GHS. 1957. A simple method for the isolation and purification of total lipides from animal tissues. J Biol Chem 226:497-509.
20	Gandhi A, Shah NP. 2015. Effect of salt on cell viability and membrane integrity of Lactobacillus acidophilus and Lactobacillus casei and Bifidobacterium longum observed by flow cytometry. Food Microbiol 49:197-202. DOI
21	Grun IU, Ahn J, Clarke AD, Lorenzen CL. 2006. Reducing oxidation of meat. Food Technol 60:36-43.
22	Masco L, Huys G, De Brandt E, Temmerman R, Swings J. 2005. Culture-dependent and culture-independent qualitative analysis of probiotic products claimed to contain Bifidobacteria. Int J Food Microbiol 102:221-230. DOI
23	Latorre-Moratalla ML, Comas-Baste O, Bover-Cid S, Vidal-Carou MC. 2017. Tyramine and histamine risk assessment related to consumption of dry fermented sausages by Spanish population. Food Chem Toxicol 99:78-85. DOI
24	Leroy F, Verluyten J, De Vuyst L. 2006. Functional meat starter cultures for improved sausage fermentation. Int J Food Microbiol 106:270-285. DOI
25	Lorenzo JM, Gonzalez-Rodriguez RM, Sanchez M, Amado IR, Franco D. 2013. Effects of natural (grape seed and chestnut extract) and synthetic antioxidants (buthylatedhydroxytoluene, BHT) on the physical, chemical, microbiological and sensory characteristics of dry cured sausage "chorizo". Food Res Int 54:611-620. DOI
26	Meile L, Le Blay G, Thierry A. 2008. Safety assessment of dairy microorganisms: Propionibacterium and Bifidobacterium. Int J Food Microbiol 126:316-320. DOI
27	Morrison WR, Smith LM. 1964. Preparation of fatty acid methyl esters and dimethylacetals from lipids with boron fluoridemethanol. J Lipid Res 5:600-608.
28	Nguyen TMP, Lee YK, Zhou W. 2009. Stimulating fermentative activities of bifidobacteria in milk by high intensity ultrasound. Int Dairy J 19:410-416. DOI
29	Oliveira M, Ferreira V, Magalhaes R, Teixeira P. 2018. Biocontrol strategies for Mediterranean-style fermented sausages. Food Res Int 103:438-449. DOI
30	Srutkova D, Spanova A, Spano M, Drab V, Schwarzer M, Kozakova H, Rittich B. 2011. Efficiency of PCR-based methods in discriminating Bifidobacterium longum ssp. longum and Bifidobacterium longum ssp. infantis strains of human origin. J Microbiol Methods 87:10-16. DOI
31	Sun Q, Chen Q, Li F, Zheng D, Kong B. 2016. Biogenic amine inhibition and quality protection of Harbin dry sausages by inoculation with Staphylococcus xylosus and Lactobacillus plantarum. Food Control 68:358-366. DOI
32	Tabanelli G, Coloretti F, Chiavari C, Grazia L, Lanciotti R, Gardini F. 2012. Effects of starter cultures and fermentation climate on the properties of two types of typical Italian dry fermented sausages produced under industrial conditions. Food Control 26:416-426. DOI
33	Kim JH, Jeun EJ, Ham JS, Jang MS, Hong CP, Lee EJ, Yang BG, Jang MH. 2013. Bifidobacterium longum subsp. longum KACC 91563 from Korean neonates alleviate the food allergy by decrease of mast cells in the gut. (P3172). J Immunol 190:61.11.
34	Ham JS, Lee T, Byun MJ, Lee KT, Kim MK, Han GS, Jeong SG, Oh MH, Kim DH, Kim H. 2011. Complete genome sequence of Bifidobacterium longum subsp. longum KACC 91563. J Bacteriol 193:5044. DOI
35	Jump DB. 2002. The biochemistry of n-3 polyunsaturated fatty acids. J Biol Chem 277:8755-8758. DOI
36	Kaban G, Kaya M. 2009. Effect of Lactobacillus plantarum and Staphylococcus xylosus on the quality characteristics of dry fermented sausage "Sucuk". J Food Sci 74:S58-S63. DOI
37	Kim JY, Choi SI, Heo TR. 2003. Screening of antioxidative activity of Bifidobacterium species isolated from Korean infant feces and their identification. Biotechnol Bioprocess Eng 8:199-204. DOI
38	Krauss RM, Deckelbaum RJ, Ernst N, Fisher E, Howard BV, Knopp RH, Kotchen T, Lichtenstein AH, McGill HC, Pearson TA, Prewitt TE, Stone NJ, Horn LV, Weinberg R. 1996. Dietary guidelines for healthy American adults. A statement for healthy professionals from the nutrition committee, American heart association. Circulation 94:1795-1800. DOI
39	Kwon EK, Kang GD, Kim WK, Han MJ, Kim DH. 2017. Lactobacillus plantarum LC27 and Bifidobacterium longum LC67 simultaneously alleviate ethanol-induced gastritis and hepatic injury in mice. J Funct Foods 38:389-398. DOI

5	(2018) Nutrients Health-Promoting Components in Fermented Foods: An Up-to-Date Systematic Review / 11 (5) , 1189
1	(2018) Fermentation : open access cy et zymurgy journal Review on Non-Dairy Probiotics and Their Use in Non-Dairy Based Products / 6 (1) , 30
5	(2020) Foods Lyophilized Probiotic Lactic Acid Bacteria Viability in Potato Chips and Its Impact on Oil Oxidation / 9 (5) , 586
10	(2018) Journal of food processing and preservation Application of microencapsulated probiotic <I>Bifidobacterium animalis</I> ssp. <I>lactis BB‐12</I> in Italian salami / 45 (10) , None
None	(2018) LWT- Food science and technology Effect of the addition of encapsulated <I>Lactiplantibacillus plantarum</I> Lp-115, <I>Bifidobacterium animalis</I> spp. <I>lactis</I> Bb-12, and <I>Lactobacillus acidophilus</I> La-5 to cooked burger / 155 (None) , 112946