INTRODUCTION
At least 20% of chicken fresh-cut carcasses are transformed into mechanically deboned chicken meat (MDCM) [1]. Mechanically deboned chicken meat is high-calorie food material as 12 kJ/g and contains plenty of unsaturated fatty acids including phospholipids [2]. However, as it contains approximately 12% crude fat, MDCM has low preservability due to rancidity [2,3] Therefore, most of MDCM has been used as substitutes in processed meats, such as meat emulsion, paste meat and chicken nuggets [1].
The companion animal food industry relies heavily on by-products of meat processing industries as sources of protein [4]. Therefore, the less-utilized MDCM could be reused as a value-added protein resource in the companion animal food industry through suitable procedures. The drawback of MDCM with respect to low preservation could be fully overcome by well-established fermentation technology. It is well known that the food fermentation has several advantages as follows: it preserves the raw materials at low cost; enhances the nutritional quality by improving digestibility and protein quality; destroys toxic and undesirable components and harmful biota, protects against re-infection and adds antibacterial components; and improves the appearance, flavor and texture of foods [5,6]. In addition, allergic reactions induced by the increased use of proteins could be resolved by suitable fermentation [7]. With this background, the aim of this study was to evaluate the MDCM-based fermented snack for dogs.
Materials and methods
Materials
Chicken breast meat (CBM) and MDCM as main protein ingredients were obtained from a local chicken processing plant (Singgreen Food System, Iksan, Korea). Upon the receipt of CBM and MDCM, they were stored at –20℃ until use. The proximate analysis revealed the MDCM had 63.1% moisture, 53.2% CP, 18.9% EE and 2.7% ash on a DM basis. The CBM was composed of 73.5% moisture, 87.8% CP, 4.6% EE and 5.4% ash on a DM basis.
Starter culture
Pediococcus acidilactici (ATCC 8042) and P. pentosaceus (ATCC 8081) were obtained from the Korean Culture Centre of Microorganisms (KCCM, Seoul, Korea). Strains were enriched on MRS Agar (BD Difco, NJ, USA) at 37℃ for 24 h. Colonies were suspended with sterilized distilled water and used as a starter culture.
Snack production
The CBM and MDCM based meats were prepared for snack production. In brief, MDCM and CBM were thawed in refrigerator at 4℃, cut by 3 × 3 × 3 cm in size, and chopped with a meat grinder (M-12S, Hankook Fujee, Hwaseong, Korea) into small particles of 2.5 mm in diameter. The chopped raw meats were then mixed with sodium chloride, nitrate, nitrite, phosphate, corn-starch, and glucose. The mixtures were then divided into six equal batches of 1 kg each and wrapped with foils. Three of the batches were sterilized immediately at 121℃ for 20 min, kept in –20℃ until use and served as a non-fermented snack control. The other three batches were inoculated with the prepared starter culture to reach 107 CFU/g meat mixtures and incubated in incubator (HB-101L, Hanbaek, Bucheon, Korea) at 37℃ for 24 h. The fermented batches were sterilized as described in the non-fermented control and kept in –20℃ until use. The ingredients and chemical compositions of chicken meat-based snacks were presented in Table 1.
Table 1. Formula and chemical composition of chicken meat based mixture
MDCM, mechanically deboned chicken meat; CBM, chicken breast meat.
Snack sampling
During a 24-hr fermentation, small portions (n = 3) were sampled at 0, 3, 6, 9, 12, 18, and 24 h after the initiation of the incubation to measure the pH and the enumeration of lactic acid bacteria (LAB). In addition, the fermented and non-fermented snacks were analyzed for lactic acid, ammonia, moisture, crude protein, crude fat, crude ash, minerals, cholesterol, gross energy, amino acids, fatty acids, and in vitro pepsin digestibility.
Preservability test
To test preservability of the fermented or non-fermented snack food, approximately 200 g of the wet samples were weighed into 10 cm petri dishes and kept them with lid open on a laboratory at room temperature. Samples were taken at 0, 1, 2, 3, 5, 7, and 14 d after exposure to the environment, and analyzed for the total bacteria, pathogenic bacteria, and LAB.
Palatability trial
Seven 2-year-old male adult Maltese with average body weight of 3.4 kg (SD = 0.35) were used for palatability trial. The dogs were randomly allocated to individual stainless cages of 75 × 50 × 60 cm. A commercial feed (Natural Balance, Suwon, Korea) was used as the basal feed which contained 10% moisture, 25.6% CP, and 14.4% EE on a DM basis. All dogs were initially fed to satiety with the basal diet and subsequently provided each dog with 50 g (approximately 1.5% of the individual body weight) of the fermented and non-fermented snacks. Palatability parameters monitored included smelling and eating behaviors, first choice, and eating time during 10 min after snack presentation. During 10 min, smelling and eating behaviors on respective snacks were counted, and first choice was calculated as the percentage of dogs eaten the first snack sample. After 10 min of the test, the leftovers were measured to calculate food intake. Snacks were located in the same distance from each dog. The palatability test was repeated three times and averaged.
Feeding trial
Dogs that had been used for the palatability trial were initially provided with the commercial feed (Natural Balance, Suwon, Korea) every morning at the same time and the allowance was calculated based on the maintenance energy requirement [8]. Fermented and non-fermented snack foods were prepared as described earlier. The basal feed was gradually replaced with either fermented or non-fermented snack over the course of 7 days. After 7-d adaptation period, four Maltese dogs were provided with the non-fermented snack while three Maltese with fermented one during subsequent 12 days. Snacks (as-is basis) equivalent to 10% of the individual body weight were supplied ad libitum. The fecal and urine samples were collected during the last 5 days of the experimental period and pooled per dog. Urine samples were recorded per dog. All dogs were individually weighed at the initiation and the termination of the trial. All dogs had ad libitum access to drinking water using companion animal waterers. This experiment repeated twice with one-month interval. All experiment protocols were approved by the Animal Care Committee of KULF Corp. (KULF-19-1).
pH measurement
A 5-g portion of the snack and fecal samples was homogenized with twice (w/w) the amount of distilled water, and measured by a pH meter (HI 120, Hanna instruments, RI, USA).
Chemical analysis
The proximate composition of MDCM, CBM, non-fermented and fermented snacks, and fecal samples were analyzed by the methods of AOAC [9]. Gross energy was measured using Bomb calorimeter (C200H, IKA, Staufen, Germany). Cholesterol was quantified as described by An et al. [10] using IATRO SCAN (MK5, Iatron Laboratories, Tokyo, Japan) after extraction of the total lipid according to the methods of Folch et al. [11]. Lactic acid and ammonia were pre-treated by lactic acid kit (Megazyme, Wicklow, Ireland) and ammonia kit (Megazyme, Wicklow, Ireland), respectively, and then the concentrations were read at 340 nm by spectrophotometer (Synergy2, BioTek, VT, USA). To determine the fatty acid composition of the snack samples, total lipids were extracted according to the Folch et al. [11]. Then, the fat was saponified with 0.5 N methanolic sodium hydroxide and methylated with boronitrifloride-methanol complex according to the method of Metcalfe et al. [12]. The methylesters were separated and quantified by gas chromatography (HP5890, Agilent, CA, USA). Amino acid contents in the snack samples were quantified by amino acid analyzer (S433, Sykam, Eresing, Germany), following hydrolysis in 6 N HCl for 24 h at 100℃ as described elsewhere [9]. All the analysis was triplicated.
In vitro digestibility assay
Pepsin digestible nitrogen in the snack samples was determined according to the procedure of the AOAC [9] using 0.2% pepsin solution. The samples were defatted before analysis. The analysis was triplicated.
Enumeration of bacteria
Total bacteria, LAB, and pathogenic bacteria were measured using LB agar media (BD Difco, NJ, USA), MRS agar media (BD Difco, NJ, USA), and Orientation agar media (CHROMagar, Paris, France). Ready-to-use orientation agar medium is a non-selective medium for the isolation, direct identification, differentiation and enumeration of pathogens including Escherichia coli due to pathogen-specific colony color. Plates were incubated for 24 h at 37℃, and colonies were counted and expressed as log10 transformed colony forming unit (CFU).
Statistical analysis
All data, if not stated otherwise, were analyzed by general linear model (GLM) of a SAS (SAS Institute, Cary, NC, 2002). Pearson’s correlation between the pH and LAB in the fermented snack during fermentation process was also assessed. A p < 0.05 was considered statistically significant.
Results and discussion
Fermentation characteristics and in vitro nutrient digestibility of the fermented snack
Changes in pH and LAB population of the snack samples during fermentation process were presented in Fig. 1. The pH of the fermented snack decreased from 6.28 to 5.08 during the first 12 h of fermentation, and further declined to 4.76 at the end of fermentation. The initial LAB numbered 6.2 × 107 CFU/g and dramatically increased to 2.8 × 109 CFU/g by the time of 12 h fermentation. Based on this result, it is expected that the decrease in pH was secondary to the increased production of lactic acid contents by LAB during fermentation. The inverse relation (r = –0.96) (Fig. 1) between pH and lactic acid seen in this study has been well documented [13,14].
Fig. 1. Changes in pH and lactic acid bacteria (LAB) number of chicken meat snacks during 24 h fermentation. Data were represented as mean ± standard error of 3 replications (n = 3).
Chemical compositions of fermented and non-fermented snack samples were shown in Table 2. Amino acid and fatty acid compositions were presented in Tables 3 and 4, respectively. Overall, fermented and non-fermented snack samples were not different in the analyzed nutrient compositions. However, fermented vs. non-fermented snack contained higher lactic acid and ammonia concentration, but had lower pH. It was shown that lactic acid concentrations increased from 2.5 mg/g to 6 mg/g when pork was fermented with LAB at 20℃ for 48 h [15]. Bruna [16] reported that ammonia contents increased approximately 200% when the surface of sausage batch was sprayed with Penicillium camemberti and fermented at 22℃ to 18℃ for 72 h. Xu [17] also reported that protein is decomposed to peptides and amino acids. Thus, the latter two studies explained the increased ammonia concentration in the fermented snack seen in this study.
Table 2. Characteristics and chemical composition of fermented and non-fermented snack foods
Table 3. Amino acid composition of fermented and non-fermented snacks (g/100 g of fresh sample)
Table 4. Fatty acid composition of fermented and non-fermented snack food (%)
SFA, saturated fatty acid; MUFA, monounsaturated fatty acid; PUFA, polyunsaturated fatty acid; ω, Omega.
In vitro pepsin digestibility in the fermented vs. non-fermented snacks was increased (Fig. 2), of which observation could provide the evidence that the fermentation can improve nutritive value. However, proximate analysis showed that fermentation did not affect the chemical compositions, amino acids and fatty acids.
Fig. 2. In vitro pepsin digestibility of fermented and non-fermented snack food. Error bars indicate the standard error of three repeated measurements. abp < 0.05.
Preservability of the fermented and non-fermented snacks
Fig. 3 shows the preservability of the fermented and non-fermented snacks. The total bacteria of the non-fermented snacks started to appear on the first and the second day after exposure, respectively, and they increased linearly up to the 7th day, reaching at 5.23 log10 CFU/g. Lactic acid bacteria grew slowly, and kept lower in number compared with the total and pathogenic bacteria. On the other hand, total bacteria of the fermented snack reached to 3.18 log10 CFU/g on the 14th day of exposure which was substantially lower than that of the non-fermented snack. Lactic acid bacteria appeared after the 7th day of exposure. Colonies in Orientation agar plate were formed with non-fermented snack sample, but color-identifiable pathogen-specific colonies were not detected. No single colony on Orientation agar plate was found with the fermented snack during the exposure. Based on this result, it is likely that organic acids, or bacteriocins, if any, present in the fermented snack could inhibit or delay the growth of bacteria. It is well documented that LAB could rapidly acidify the raw materials during fermentation, through the production of organic acids, mainly lactic acid and acetic acid, and also produce a variety of antimicrobial substances, which can consequently prevent the growth of the most hazardous food microorganisms [18].
Fig. 3. Changes in bacterial number in fermented and non-fermented snack food exposed to environment at room temperature for 14 days. Total bacteria, lactic acid bacteria, and pathogenic bacteria were measured using LB agar media (BD Difco, NJ, USA), MRS agar media (BD Difco, NJ, USA), and Orientation agar media (CHROMagar, Paris, France). Colonies in Orientation agar plate were formed with nonfermented snack sample, but color-identifiable pathogen-specific colonies were not detected. NF-T, total bacteria in non-fermented snack sample; NF-P, pathogenic bacteria in non-fermented snack sample; NF-L, lactic acid bacteria in non-fermented sample; F-T, total bacteria in fermented snack sample; F-P, pathogenic bacteria in fermented snack sample; F-L, lactic acid bacteria in fermented sample.
Palatability of the fermented and non-fermented snacks
In palatability trial, dogs provided with the fermented vs. non-fermented snacks ate less, spent less time, and were reluctant to eat (p > 0.05) which was manifested by lowered frequency in smelling and eating (Table 5). The first choice of the non-fermented snack was significantly higher (p < 0.05) than that of the fermented snack. Based on these results, it seems that the palatability of the fermented snack is low due to the strong odor of fermentation as indicated elsewhere [19]. Alternatively, low pH of the fermented snack per se may have reduced its palatability which was the case with pigs [20]. In any events, our study indicates that additional measures such as supplementation of natural flavors are needed to increase palatability of the fermented snack.
Table 5. Palatability of fermented and non-fermented snack food in dogs
1)Data are represented mean ± SE.
* p < 0.05.
Effect of feeding of the fermented and non-fermented snacks on fecal characteristics
Dogs were fed with fermented or non-fermented snack foods for 12 days after 7-day transition period from the basal to the experimental food. During the trial, all dogs fed fermented or non-fermented snack food gained weight by 450 g and 340 g (Table 6). Dogs fed fermented vs. non-fermented snack ate more, but drank less, albeit that the difference was not statistically different. It is likely that low voluntary water intake in dogs fed fermented snack was secondary to the increase in involuntary water intake by consuming more moisture-rich snack. In this study, dogs preferred non-fermented vs. fermented snacks in the palatability trial while those offered fermented snack ate more compared with non-fermented snack-fed dogs in the 12-d-feeding trial. In addition, there was large variable in feed intake between individuals especially fed the non-fermented snack in the feeding trials. At this stage, a clear explanation is not readily available, but it seemed that individual dog differently responded to fermented snacks depending on the degree of satiety and/or feeding duration which needs to be answered.
Table 6. Fecal properties and urine production of dogs provided with fermented and non-fermented snack food
1)Data are represented mean ± SE.
**p < 0.01.
Urine production was comparable between the treatment groups (Table 6). Ammonia concentration in feces was significantly lower in dogs fed fermented snack compared with those fed non-fermented snack. In contrast, fecal lactic acid content was significantly elevated in fermented snack-fed dogs compared with those fed non-fermented snack. However, elevated lactic acid in feces of the fermented vs. non-fermented snack did not affect fecal pH. Decreased ammonia content and increased lactic acid in feces induced by dietary fermented snack may be in part secondary to balanced gut microbiota, i.e., LAB which could then inhibit pathogenic bacteria [21].
Conclusion
In this study, we manufactured Pediococcus spp.-fermented MDCM-based snack food for dogs. The nutritional compositions of the snack were not significantly altered by fermentation. However, in vitro pepsin digestibility was significantly increased by fermentation. Microbiological assay revealed that bacteria growth in fermented snack exposed to environment was delayed. In a palatability trial, dogs preferred non-fermented over fermented snack. In a feeding trial, fecal ammonia content was reduced, but fecal lactic acid content was increased in dogs fed fermented vs. non-fermented snack food. Collectively, the fermented MDCM-based snack for companion dogs can be used as a digestible snack with favorably long-term preservability. To our knowledge, this is the first report to show the possibility for utilizing the poultry by-product MDCM by fermentation process as a value-added snack for dogs, of which is considered of importance to companion animal industry.
Competing interests
No potential conflict of interest relevant to this article was reported.
Funding sources
This work was supported by Korea Institute of Planning and Evaluation for Technology in Food, Agriculture, and Forestry (IPET) through Agriculture and Life Industry Technology Development Program, funded by Ministry of Agriculture, Food and Rural Affairs (MAFRA) (118047-03-2- CG000).
Acknowledgements
Not applicable.
Availability of data and material
Upon reasonable request, the datasets of this study can be available from the corresponding author.
Ethics approval and consent to participate
All experiment procedures involving animals were conducted in accordance with the Animal Experimental Guidelines of the KULF Corp. (KULF-19-1).
References
- Negrao CC, Mizubuti IY, Morita MC, Colli C, Ida EI, Shimokomaki M. Biological evaluation of mechanically deboned chicken meat protein quality. Food Chem. 2005;90:579-83. https://doi.org/10.1016/j.foodchem.2004.05.017
- Dawson PL, Sheldon BW, Ball HR, Larick DK. Fatty acid composition of the neutral lipid and phospholipid fractions of mechanically deboned chicken meat. Poult Sci. 1990;69:1414-9. https://doi.org/10.3382/ps.0691414
- Pikul J, Kummerow FA. Thiobarbituric acid reactive substance formation as affected by distribution of polyenoic fatty acids in individual phospholipids. J Agric Food Chem. 1991;39:451-7. https://doi.org/10.1021/jf00003a005
- Morris JG. Pet food protein: current use and trends. Int News Fats Oils Relat Mater. 1990;1:206-8.
- Stanton WR. Food fermentation in the tropics. In: Wood BJB, editor. Microbiology of fermented foods. London: Elsevier; 1985. p. 193-211.
- Stanton C, Ross RP, Fitzgerald GF, Van Sinderen D. Fermented functional foods based on probiotics and their biogenic metabolites. Curr Opin Biotechnol. 2005;16:198-203. https://doi.org/10.1016/j.copbio.2005.02.008
- El-Ghaish S, Ahmadova A, Hadji-Sfaxi I, El-Mecherfi KE, Bazukyan I, Choiset Y, et al. Potential use of lactic acid bacteria for reduction of allergenicity and for longer conservation of fermented foods. Trends Food Sci Technol. 2011;22:509-16. https://doi.org/10.1016/j.tifs.2011.05.003
- Burger IH. Updated feeding recommendations for the canine diet. Waltham Focus. 1995;5:32.
- AOAC [Association of Official Analytical Chemists] International. Official methods of analysis of AOAC International. 16th ed. Arlington, VA: AOAC International; 1995.
- An BK, Nishiyama H, Tanaka K, Ohtani S, Iwata T, Tsutsumi K, et al. Dietary safflower phospholipid reduces liver lipids in laying hens. Poult Sci. 1997;76:689-95. https://doi.org/10.1093/ps/76.5.689
- Folch J, Lees M, Sloane Stanley GH. A simple method for the isolation and purification of total lipides from animal tissues. J Biol Chem. 1957;226:497-509. https://doi.org/10.1016/S0021-9258(18)64849-5
- Metcalfe LD, Schmitz AA, Pelka JR. Rapid preparation of fatty acid esters from lipids for gas chromatographic analysis. Anal Chem. 1966;38:514-5. https://doi.org/10.1021/ac60235a044
- Caplice E, Fitzgerald GF. Food fermentations: role of microorganisms in food production and preservation. Int J Food Microbiol. 1999;50:131-49. https://doi.org/10.1016/S0168-1605(99)00082-3
- Visessanguan W, Benjakul S, Riebroy S, Thepkasikul P. Changes in composition and functional properties of proteins and their contributions to Nham characteristics. Meat Sci. 2004;66:579-88. https://doi.org/10.1016/S0309-1740(03)00172-4
- Minor-Perez H, Ponce-Alquicira E, Macias-Bravo S, Guerrero-Legarreta I. Changes in fatty acids and microbial populations of pork inoculated with two biopreservative strains. Meat Sci. 2004;66:793-800. https://doi.org/10.1016/S0309-1740(03)00173-6
- Bruna JM, Hierro EM, de la Hoz L, Mottram DS, Fernandez M, Ordonez JA. Changes in selected biochemical and sensory parameters as affected by the superficial inoculation of Penicillium camemberti on dry fermented sausages. Int J Food Microbiol. 2003;85:111-25. https://doi.org/10.1016/S0168-1605(02)00505-6
- Xu HQ, Wang WW, Jiang YS, Wang ZJ. Study on fermentation properties of lactic acid bacteria isolated from traditional fermented meat products. Sci Technol Food Ind. 2008;1:88-92.
- Hu Y, Xia W, Ge C. Characterization of fermented silver carp sausages inoculated with mixed starter culture. LWT-Food Sci Technol. 2008;41:730-8. https://doi.org/10.1016/j.lwt.2007.04.004
- Yang X, Chen H, Gao H, Li Z. Bioconversion of corn straw by coupling ensiling and solid-state fermentation. Biores Technol. 2001;78:277-80. https://doi.org/10.1016/S0960-8524(01)00024-4
- Brooks PH, Beal JD, Niven S. Liquid feeding of pigs: potential for reducing environmental impact and for improving productivity and food safety. Rec Adv Anim Nutr Aust. 2001;13:49-63.
- Felix AP, Netto MVT, Murakami FY, de Brito CBM, de Oliveira SG, Maiorka A. Digestibility and fecal characteristics of dogs fed with Bacillus subtilis in diet. Cienc Rural. 2010;40:2169-73. https://doi.org/10.1590/S0103-84782010005000166
Cited by
- Evaluation of Fermented Oat and Black Soldier Fly Larva as Food Ingredients in Senior Dog Diets vol.11, pp.12, 2020, https://doi.org/10.3390/ani11123509