Fermentation Characteristics and Lactic Acid Bacteria Succession of Total Mixed Ration Silages Formulated with Peach Pomace

Article information

Asian-Australas J Anim Sci. 2015;28(4):502-510
*Corresponding Author: Chuncheng Xu. Tel: +86-10-62736480, Fax: +86-10-62737997, E-mail: xucc@cau.edu.cn
College of Engineering, China Agricultural University, Beijing 100083, China
Received 2014 July 10; Revised 2014 September 16; Accepted 2014 October 09.

Abstract

The objective of this study was to assess the use of peach pomace in total mixed ration (TMR) silages and clarify the differences in aerobic stability between TMR and TMR silages caused by lactic acid bacteria (LAB). The TMR were prepared using peach pomace, alfalfa hay or Leymus chinensis hay, maize meal, soybean meal, cotton meal, limestone, a vitamin-mineral supplement, and salt in a ratio of 6.0:34.0:44.4:7.0:5.0:2.5:1.0:0.1 on a dry matter (DM) basis. Fermentation quality, microbial composition, and the predominant LAB were examined during ensiling and aerobic deterioration. The results indicated that the TMR silages with peach pomace were well fermented, with low pH and high lactic acid concentrations. The aerobic stability of TMR silages were significantly higher than that of TMR. Compared with TMR silages with alfalfa hay, TMR silage with Leymus chinensis hay was much more prone to deterioration. Although the dominant LAB were not identical in TMR, the same dominant species, Lactobacillus buchneri and Pediococcus acidilactici, were found in both types of TMR silages after 56 d of ensiling, and they may play an important role in the aerobic stability of TMR silages.

INTRODUCTION

Peach juice is an internationally popular beverage because of its high nutritional value and health benefits, and with its consumption rising, approximately 700,000 tons of peach pomace is released annually by juice factories in China. Owing to its high moisture content (94.1%) and a high water-soluble carbohydrates (WSC) content (25.9% dry matter [DM]), peach pomace is difficult to preserve at ambient temperature. It is easy for microorganisms to propagate if the pomace is not treated promptly, which can lead to great waste and potential environmental problems. Currently, most peach pomace is dumped in landfills, and a small amount is used for extraction of dietary fiber, pectin (Faravash and Ashtiani, 2008), and polyphenols (Adil et al., 2007). Peach pomace contains 7.36% crude protein (CP), 4.71% ether extract (EE) and 20.0% neutral detergent fiber (NDF) on a DM basis, and therefore could possibly be a source of nutrients for ruminants.

Many agricultural and industrial by-products have been used as feeds, including vegetable residues (Yang et al., 2010), rice straw (Gao et al., 2008), tomato and apple pomace (Abdollahzadeh et al., 2010), and green tea grounds (Wang et al., 2011), and they have shown good feed characteristics. Since high moisture can increase the risk of effluent production, mixing these by-products with other dry feeds to form a total mixed ration (TMR) would minimize the risk, stabilize microbial function, and improve energy and protein utilization in the rumen (Xu et al., 2007a, b). Furthermore, the efficient utilization of by-products also helps to develop new feed resources, thereby relieve the competition with humans for grain consumption.

Aerobic deterioration of silage has a severe impact on farm profitability. Spoiled silages not only reduce the palatability but also negatively affect livestock production performance. TMR silages have improved aerobic stability in comparison with silages (Nishino et al., 2004; Xu et al., 2010); however, the specific reason for this is still unknown. Nishino and Hattori (2007) isolated Lactobacillus buchneri as the predominant species of lactic acid bacteria (LAB) from aerobically stable silage, and they confirmed that inoculation of this bacterium can suppress aerobic deterioration of maize, Italian ryegrass, and festulolium silages. Results also suggested that L. buchneri might be associated with the stability of TMR silages, although the mechanism by which L. buchneri promotes aerobic stability in TMR silages has not been elucidated.

The purpose of this study was to evaluate the feasibility of TMR silages formulated with peach pomace and clarify the aerobic stability in TMR silages by comparing fermentation characteristics, aerobic stability, and dynamic changes in dominant LAB communities between TMR and TMR silages with peach pomace during ensiling and aerobic deterioration.

MATERIALS AND METHODS

Preparation of total mixed ration silages

The TMR were prepared using peach pomace, hay, maize meal, soybean meal, cotton meal, limestone, a vitamin-mineral supplement, and salt in a ratio of 6.0:34.0:44.4:7.0:5.0:2.5:1.0:0.1 on a DM basis (Table 1). Two common roughages, alfalfa hay and Leymus chinensis hay, were used for the TMR with alfalfa hay (ATMR) and TMR with Leymus chinensis hay (LTMR) formulations in this study. The peach pomace was obtained from a local juice factory in Beijing and used within 12 h of production. The hays were cropped to a length of 1 to 2 cm prior to ensiling.

Ingredient, chemical and microbial composition of peach pomace and TMR

TMR were ensiled in plastic film bags (Hiryu KN type, 800×1,500 mm, Asahikasei, Tokyo, Japan). Approximately 2 kg of TMR were packed into each plastic film bag and the bags were degassed, sealed with a vacuum packing machine (BH950, Matsushita, Osaka, Japan), and stored at 18°C to 23°C. The experiment was carried out according to a completely randomized design, and triplicate bags were opened after 1, 3, 7, 14, 28, and 56 d of ensiling.

Evaluation of aerobic stability

The TMR were subjected to an aerobic stability experiment right after preparation. Approximately 2 kg of TMR were placed in a 10 L polyethylene barrel without compaction. The temperatures of ambience and the materials were automatically monitored at 1 h intervals using a thermocouple wire connected to a data logger (DT85 Series2, dataTaker, Melbourne, Australia). Aerobic deterioration was considered to have occurred if the difference between the ambient temperature and the temperature of the material reached 2°C. The aerobic stability test for the TMR was conducted for 7 d, and subsamples were collected after 0, 6, 12, 24, 48, 72, 120, and 168 h of air exposure. To determine the aerobic stability of the TMR silages, bags were opened after 28 and 56 d of ensilage and the entire contents were manually mixed. Half of the contents were placed loosely in a 10 L barrel and monitored as described above for unfermented TMR. Temperatures were recorded for 14 d and subsamples were collected at 0, 6, 12, 24, 48, 72, 120, 168, 216, 264, and 336 h. The aerobic stability experiments were carried out in a room maintained at 27°C to 31°C. Triplicate samples were taken during ensiling and the aerobic stability test for evaluation of chemical composition, fermentation quality, and microbial composition.

Chemical analysis

Samples were dried in a fan-forced oven at 60°C for 48 h and ground with a Wiley mill to pass a 1 mm screen. DM, CP, and EE were analyzed according to methods 934.01, 976.05, and 920.39, respectively, of the AOAC (1990). NDF and acid detergent fiber were analyzed as described by Van Soest et al. (1991). WSC content was determined using the method of Wang et al. (2011).

Fermentation qualities were determined by measuring fermentation products in cold-water extracts of the TMR. Wet samples (10 g) were homogenized with 90 mL of sterilized distilled water. The pH was measured with a glass-electrode pH meter (S20, Mettler Toledo, Greifensee, Switzerland). After centrifugation (18,000×g, 15 min, 4°C), the supernatant was analyzed for ammonia nitrogen (NH3-N) by the method of Wang et al. (2011). The TMR extracts were centrifuged at 12,000×g for 5 min. The supernatants were passed through a 0.45 μm filter under pressure and then injected into a liquid chromatography system to determine organic acid concentrations. The analytical conditions were as follows: column, Hitachi GL C-610H; oven temperature 70°C; mobile phase, 0.2% H3PO4, 1.0 mL/min; detector, L-7420 SUV-Vis.

Microbiological analysis

The numbers of LAB and yeast were counted using the plate count method (Xu et al., 2008). Colonies were counted from the plates at appropriate dilutions and the numbers were expressed as colony-forming unit (cfu) per gram on fresh matter (FM) basis. The predominant LAB was considered as the one that appears on plates at the highest dilution. According to the colonial morphology, each kind of LAB colony was purified by repeated streaking on de Man-Rogosa and Sharp agar until only colonies of the same morphology formed on each plate. DNA of purified LAB was extracted by the hexadecyl trimethyl ammonium bromide method (Kim et al., 1990). In order to identify the species of LAB, polymerase chain reaction (PCR) was carried out to amplify the 16S rRNA gene with the forward primer 27f (5′-AGAGTTTGATCCTGGCTCAG-3′) and the reverse primer 1492r (5′-GGTTACCTTGTTACGACTT-3′). The PCR mixture contained 2.5 μL of 10×PCR buffer (with Mg2+), 2 μL of dNTPs (2 mM), 0.4 μL of Taq polymerase (5 U/μL), 2 μL of DNA template, and 0.2 μL of each primer (10 mM), and double-distilled water was added to obtain a final volume of 25 μL. The PCR program comprised an initial denaturation at 95°C for 4 min; 35 cycles of denaturation at 94°C for 1 min, annealing at 50°C for 1 min 20 s, and extension at 72°C for 1 min 30 s; and a final extension at 72°C for 8 min. The reaction was conducted in a PCR thermal cycler (TP-600, Takara Bio Inc., Shiga, Japan). Sequencing was carried out by Shanghai Sunny Biotechnology Co., Ltd.

Statistical analysis

The chemical composition, fermentation quality, microbial composition and hours of aerobic stability were subjected to one-way analysis of variance using the general linear model procedure of the SAS software package (SAS, 2004) to evaluate the statistical significance of the differences between TMR and TMR silage, setting fermentation time and experimental data as the main factor and random factor, respectively. Tukey’s test was used to differentiate between means and significance was declared at p<0.05.

RESULTS

Chemical and microbial composition of materials

The peach pomace had a low DM content and a high WSC content. No LAB or yeasts were detected in the peach pomace. The two TMR had similar DM and WSC contents. Mixing with other dry feed reduced the moisture content and WSC content of peach pomace. In addition, the CP content increased to 15.1% and 12.3% DM in ATMR and LTMR, respectively, improving the utilization of peach pomace as a feed resource. The populations of LAB and yeasts were approximately 104 cfu/g FM in both TMR (Table 1).

Chemical and microbial composition and fermentation quality of total mixed ration silages

Irrespective of the type of roughage, the DM contents of TMR silages reduced by less than 2.0% compared with the corresponding unfermented TMR (Table 2). DM contents decreased significantly (p<0.05) between 3 and 7 d and between 1 and 7 d in ATMR and LTMR, respectively. After 28 and 56 d of ensiling, the WSC contents decreased to below 9.50% DM in both TMR silages. There was a rapid decline (p<0.05) in WSC content during the first 7 d in ATMR silage and then followed by a slow decline (p>0.05) until 56 d. In LTMR silage, WSC content decreased significantly (p<0.05) throughout the entire ensiling period. The CP contents increased (p<0.05) in both TMR silages compared with the corresponding TMR after 56 d of ensiling, but the increase was small.

Changes in chemical composition, fermentation quality and microbial composition during ensiling of ATMR silage and LTMR silage

Both TMR silages were well preserved after 28 and 56 d of ensiling, as indicated by low pH values and NH3-N concentrations and high lactic acid concentrations. The pH of ATMR silage and LTMR silage stabilized after 14 and 28 d of ensiling, respectively. Concentrations of NH3-N reached the maximum at 14 d in ATMR silage and LTMR silage, respectively; they decreased thereafter, but the change was not significant (p>0.05). Lactic acid concentration increased rapidly during the first 14 d in ATMR silage and peaked at 7.11% DM after 56 d of ensiling. In LTMR silage, lactic acid concentration increased during the first 28 d and then decreased, but there was no significant difference (p>0.05) between 28 and 56 d. Acetic acid concentration increased throughout the ensiling period in ATMR silage but reached a maximum at 3 d in LTMR silage.

The LAB populations increased rapidly after the start of ensiling and reached a maximum at 3 d in both TMR silages. After 56 d of storage, LAB populations were 106cfu/g FM. There were no large changes in the number of yeast between TMR and TMR silages, and populations were above 104cfu/g FM after 28 and 56 d of ensiling. These large populations were probably due to the high content of available carbohydrates in peach pomace.

Aerobic stability of total mixed ration and total mixed ration silages

Regardless of hay species, both TMR and TMR silages increased in temperature during the aerobic stability test. In both TMR, the temperature increased and aerobic deterioration occurred at the same time. Compared with TMR, the aerobic stability of TMR silage significantly increased (p<0.05) after fermentation. After 28 d of ensiling, the time of increase in temperature extended to 120 and 72 h, and aerobic deterioration was observed at 148 and 90 h for ATMR silage and LTMR silage, respectively. When ensiling was prolonged to 56 d, the temperature of ATMR silages increased at 144 h and aerobic deterioration occurred at 155 h, while the temperature of LTMR silage began to increase at 72 h and aerobic deterioration occurred at 90 h (Figure 1).

Figure 1

The time of increases in temperature and aerobic deterioration of TMR and TMR silages. The time between silo opening to increases in temperature and between increases in temperature to aerobic deterioration were marked by , respectively. TMR, total mixed ration.

Microbial composition, pH, and organic acids of total mixed ration and total mixed ration silages during aerobic deterioration

In both TMR, the LAB populations increased rapidly during the first 24 h of the aerobic stability test and then followed by a stable period until 120 h, finally, they had a declining tendency. A different pattern was observed in TMR silages: the LAB populations showed a slight downward trend during the first 120 h in ATMR silage and 72 h in LTMR silage, regardless of ensiling time, and then increased gradually until they were stable. Yeast populations increased during the first 48 and 72 h in ATMR and LTMR, respectively, and then leveled off. After 28 and 56 d of ensiling, yeast populations decreased slightly, then rose slowly and began rapidly to increase at about 72 h, and finally stabilized or declined slightly.

The changes in pH showed good agreement with the changes in organic acids, LAB populations, and time to aerobic deterioration. The pH slowly decreased and reached a minimum at 24 h in both TMR. In 28-d and 56-d ATMR silages, pH remained stable until 120 and 216 h, respectively. In LTMR silage, pH began to rise rapidly at 120 h after a stable period. With the start of aerobic deterioration, the pH increased rapidly in both TMR and TMR silages.

For both TMR, the lactic acid concentrations initially increased and then declined during air exposure, peak concentrations were observed at 24 h in ATMR and 12 h in LTMR. Similar trends were observed for acetic acid concentrations, and peak values were observed after 24 h of air exposure. For the TMR silages, lactic acid concentrations were initially stable or declined slightly and then decreased significantly. The concentration of acetic acid gradually decreased in ATMR silage, while it peaked at 24 h and then decreased in LTMR silage (Figures 2 and 3).

Figure 2

Microbial composition, pH and organic acids of ATMR and ATMR silages in the processing of aerobic deterioration. TMR were marked by ●, TMR silages after 28 d of ensiling were marked by ■, and TMR silages after 56 d of ensiling were marked by ▲. ATMR, total mixed ration with alfalfa hay; TMR, total mixed ration.

Figure 3

Microbial composition, pH and organic acids of LTMR and LTMR silage in the processing of aerobic deterioration. TMR were marked by ●, TMR silages after 28 d of ensiling were marked by ■, and TMR silages after 56 d of ensiling were marked by ▲. LTMR, total mixed ration with Leymus chinensis hay; TMR, total mixed ration.

Changes in the lactic acid bacteria community during fermentation and aerobic deterioration

During ensiling and aerobic deterioration, different stages were identified according to significant changes in the predominant LAB. Pediococcus pentosaceus, Pediococcus acidilactici, Lactobacillus brevis, Weissella paramesenteroides, Lactobacillus buchneri, and Weissella cibaria were isolated from TMR, irrespective of the type of roughage. Two additional LAB species, namely Lactobacillus plantarum and Enterococcus avium, were detected when TMR was formulated with alfalfa hay. Although the predominant LAB species were not identical in the two TMRs, after 56 d of ensiling, the two TMR silages had the same predominant species: L. buchneri and P. acidilactici (Table 3).

The composition of dominant lactic acid bacteria at different fermentation time of ATMR silages and LTMR silage

During aerobic deterioration, there were no marked changes in the predominant LAB in TMR. Although W. paramesenteroides and P. acidilactici lost their dominant position in the later stage of aerobic deterioration in ATMR and LTMR, respectively, P. acidilactici remained predominant nearly throughout the period of air exposure in both TMR silages. In 28-d and 56-d silages, L. buchneri became co-dominant in the later stage of deterioration, regardless of whether it had occurred in the early stage (Table 4).

The composition of dominant lactic acid bacteria at different time of aerobic deterioration in ATMR, LTMR, ATMR silages and LTMR silage

DISCUSSION

Many agricultural and industrial by-products with high moisture contents, such as coffee and tea grounds (Xu et al., 2007a, b; 2010), dry tofu cake, and apple pomace (Cao et al., 2009), have been ensiled with dry feeds as a TMR to avoid the risk of effluent production. The results demonstrated that these by-products can be used as ingredients of TMR without affecting palatability and nutritional value and that they are potential energy sources in ruminant diets. In this study, we prepared TMR with peach pomace and ensiled them to produce TMR silages. The TMR silages were well fermented, with low pH values and high lactic acid concentrations. Furthermore, they kept the color of the raw material and maintained the fragrance of fresh fruit. These results show that peach pomace can be effectively utilized as a component of TMR.

Silages with high concentrations of lactic acid or WSC are prone to deterioration in the presence of air (McDonald et al., 1991). Recent studies have shown that lactate-assimilating yeasts are generally the main initiators of the aerobic spoilage of silages; under aerobic conditions, they utilize lactic acid, causing an increase in silage temperature and pH (Pahlow et al., 2003). With the increase of pH, bacilli and other aerobic bacteria start growing quickly, increasing the temperature further. Finally, molds complete the deterioration of the silage (Muck, 2013). In this study, yeasts were not suppressed effectively even when ensiling was prolonged to 56 d. There was no significant difference (p>0.05) in the number of yeast between TMR and TMR silages; in all cases, the yeast population was above 104 cfu/g FM. These large populations were probably due to the high WSC content of peach pomace. Our results contrast with earlier reports in which the number of yeast was 102 cfu/g FM or less in the later stage of ensiling (Nishino et al., 2004; Nishino and Hattori, 2007; Wang and Nishino, 2008). Despite the large yeast populations in this study, the TMR silages had higher (p<0.05) aerobic stability than the TMR. Although the number of yeast was not reduced by ensiling, the time of beginning to proliferate during aerobic stability test was obviously extended. This shows that the yeast populations at silo opening had less effect on aerobic stability, and yeast species may play a more important role in this stability.

For each TMR formulation, there was no significant difference (p>0.05) in pH between 28-d and 56-d silages. On the other hand, the concentrations of lactic and acetic acids were higher (p<0.05) in 56-d ATMR silage than in 28-d ATMR silage, while no significant differences (p>0.05) were observed between 28 and 56 d for LTMR silage. Since there was a difference in aerobic stability between 28-d and 56-d ATMR silages, there appears to be a relationship between undissociated acids and aerobic stability. Undissociated acids are known to exhibit antifungal activity during ensiling and upon exposure to air, but in this study, the increased acetic acid concentration did not significantly reduce the number of yeast in 28-d and 56-d ATMR silage.

Previous studies have suggested that the high stability of TMR silages could be attributed to the activity of L. buchneri; these bacteria always appeared in long-stored TMR silages, but it is unknown whether they were present in the ensiled materials or appeared during fermentation (Wang and Nishino, 2009). In this study, L. buchneri was isolated from TMR before ensiling, and although it was present in relatively small numbers, it multiplied rapidly after 28 d of ensiling. Although L. buchneri was not the predominant species in 28-d TMR silages, it grew rapidly during the middle stage of aerobic deterioration and became dominant. In 56-d TMR silages, L. buchneri constituted the majority of LAB. Overall, L. buchneri could be observed in TMR before ensiling and in TMR silages subjected to aerobic deterioration, which is consistent with the results of Wang and Nishino (2013).

In addition to L. buchneri, it is worth noting that P. acidilactici was also predominant during ensiling and aerobic deterioration in TMR silages. P. acidilactici is a common LAB found on plants. In recent years, the pediocin produced by P. acidilactici has received widespread attention, and Pediococcus species are often used to preserve foods and feeds and can be utilized as probiotics. Gonzalez and Kunka (1987) reported that P. acidilactici PAC 1.0 showed activity against different strains of P. acidilactici, P. pentosaceus, L. plantarum, L. casei, L. bifermentans, and Leuconostoc mesenteroides subsp. dextranicum. Digaitiene (2012) isolated P. acidilactici KTU05-7 from rye sourdoughs, and this strain showed antibacterial activity against other LAB. Furthermore, P. acidilactici KTU05-7 produced bacteriocin-like inhibitory substances unlike any other known bacteriocins, which were shown to have good antimicrobial activity against Bacillus subtilis and some fungi. Mandal (2013) also reported that P. acidilactici LAB5 can inhibit the growth of many food-spoilage fungi, and this wide inhibitory spectrum against food-spoilage and plant-pathogenic fungi enriched its applicability in food preservation. In this study, P. acidilactici and L. buchneri were the predominant LAB in the later stage of ensiling and during aerobic deterioration of TMR silages. P. acidilactici might produce bacteriocin during ensiling that inhibits certain LAB and other harmful microorganisms, and this bacteriocin can be effective during aerobic deterioration. Most previous studies have focused on the inhibition of yeast and harmful bacteria by organic acids and ignored the antagonism between microorganisms caused by bacteriocins. In future research, the roles of P. acidilactici in the ensiling process and aerobic stability are worth examining.

CONCLUSION

The data presented here confirm that peach pomace can be utilized effectively by incorporating it into TMR silages. The TMR silages with peach pomace showed good fermentation quality, nutritional value, and aerobic stability. Yeast populations at silo opening had a marginal effect on aerobic stability. Although marked changes were seen in the LAB community during ensiling and aerobic deterioration, L. buchneri and P. acidilactici may play a major role in the aerobic stability, and further study is necessary to evaluate the effect of P. acidilactici.

ACKNOWLEDGMENTS

Financial support for this research was provided by National Natural Science Foundation of China (31172240) and special fund for Agro-scientific Research in the Public Interest (201003023, 201303061).

References

AOAC. 1990. Official Methods of Analysis 15th edth ed. Association of Official Analytical Chemists. Arlington, VA, USA:
Adil IH, Çetin HI, Yener ME, Bayindirli A. 2007;Subcritical (carbon dioxide + ethanol) extraction of polyphenols from apple and peach pomaces, and determination of the antioxidant activities of the extracts. J Supercrit Fluids 43:55–63.
Abdollahzadeh F, Pirmohammadi R, Fatehi F, Bernousi I. 2010;The effect of feeding ensiled mixed tomato and apple pomace on performance of Holstein dairy cows. Slovak J Anim Sci 1:31–35.
Cao Y, Takahashi T, Horiguchi K. 2009;Effects of addition of food by-products on the fermentation quality of a total mixed ration with whole crop rice and its digestibility, preference, and rumen fermentation in sheep. Anim Feed Sci Technol 151:1–11.
Digaitiene A, Hansen ÅS, Juodeikiene G, Eidukonyte D, Josephsen J. 2012;Lactic acid bacteria isolated from rye sourdoughs produce bacteriocin-like inhibitory substances active against Bacillus subtilis and fungi. J Appl Microbiol 112:732–742.
Faravash RS, Ashtiani FZ. 2008;The influence of acid volume, ethanol-to-extract ratio and acid-washing time on the yield of pectic substances extraction from peach pomace. Food Hydrocoll 22:196–202.
Gonzalez CF, Kunka BS. 1987;Plasmid-Associated bacteriocin production and sucrose fermentation in Pediococcus acidilacticl. Appl Environ Microbiol 53:2534–2538.
Gao L, Yang H, Wang X, Huang Z, Ishii M, Igarashi Y, Cui Z. 2008;Rice straw fermentation using lactic acid bacteria. Bioresour Technol 99:2742–2748.
Kim WK, Mauthe W, Hausner G, Klassen G. 1990;Isolation of high molecular weight DNA and double-stranded RNAs from fungi. Can J Bot 68:1898–1902.
McDonald P, Henderson AR, Heron SJE. 1991. The Biochemistry of Silage 2nd edth ed. Chalcombe Publ., Cambrian Prrinters, Ltd.. Merlow, Bucks, Aberystwyth, Wales, UK:
Mandal V, Sen SK, Mandal NC. 2013;Production and partial characterization of an inducer-dependent novel antifungal compound(s) by pediococcus acidilactici LAB 5. J Sci Food Agric 93:2445–2453.
Muck RE. 2013;Recent advances in silage microbiology. Agric Food Sci 22:3–15.
Nishino N, Wade H, Yoshida M, Shiota H. 2004;Microbial counts, fermentation products, and aerobic stability of whole crop corn and a total mixed ration ensiled with and without inoculation of Lactobacillus casei or Lactobacillus buchneri. J Dairy Sci 87:2563–2570.
Nishino N, Hattori H. 2007;Resistance to aerobic deterioration of total mixed ration silage inoculated with and without homofermentative or heterofermentative lactic acid bacteria. J Sci Food Agric 87:2420–2426.
Pahlow G, Muck RE, Driehuis F, Oude Elferink SJWH, Spoelstre SF. 2003. Microbiology of ensiling. Silage Science and Technology In : Buxton DR, Muck RE, Harrison JH, eds. American Society of Agronomy, Crop Science Society of America, Soil Society of America. Madison, WI, USA: p. 31–93.
Simone C, Edgard G. 2011;Protein extraction from biomass in bioethanol refinery-Possible dietary application: Use as animal feed and potential extension to human consumption. Bioresour Technol 102:427–436.
Van Soest PJ, Robertson JB, Lewis BA. 1991;Methods for dietary fiber, neutral detergent fiber, and non-starch polysaccharides in relation to animal nutrition. J Dairy Sci 74:3583–3597.
Wang C, Nishino N. 2013;Effects of storage temperature and ensiling period on fermentation products, aerobic stability and microbial communities of total mixed ration silage. J Appl Microbiol 114:1687–1695.
Wang F, Nishino N. 2008;Resistance to aerobic deterioration of total mixed ration silage: Effect of ration formulation, air infiltration and storage period on fermentation characteristics and aerobic stability. J Sci Food Agric 88:133–140.
Wang F, Nishino N. 2009;Association of Lactobacillus buchneri with aerobic stability of total mixed ration containing wet brewers grains preserved as a silage. Anim Feed Sci Technol 149:265–274.
Wang RR, Wang HL, Liu X, Xu CC. 2011;Effects of different additives on fermentation characteristics and protein degradation of green tea grounds silage. Asian Australas J Anim Sci 24:616–622.
Xu CC, Cai Y, Zhang JG, Ogawa M. 2007a;Fermentation quality and nutritive value of a total mixed ration silage containing coffee grounds at ten or twenty percent of dry matter. J Anim Sci 85:1024–1029.
Xu C, Cai Y, Moriya N, Ogawa M. 2007b;Nutritive value for ruminants of green tea grounds as a replacement of brewers’ grains in totally mixed ration silage. Anim Feed Sci Technol 138:228–238.
Xu C, Cai Y, Zhang J, Matsuyama H. 2010;Feeding value of total mixed ration silage with spent mushroom substrate. Anim Sci J 81:194–198.
Yang J, Cao Y, Cai Y, Terada F. 2010;Natural populations of lactic acid bacteria isolated from vegetable residues and silage fermentation. J Dairy Sci 93:3136–3145.

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Figure 1

The time of increases in temperature and aerobic deterioration of TMR and TMR silages. The time between silo opening to increases in temperature and between increases in temperature to aerobic deterioration were marked by , respectively. TMR, total mixed ration.

Figure 2

Microbial composition, pH and organic acids of ATMR and ATMR silages in the processing of aerobic deterioration. TMR were marked by ●, TMR silages after 28 d of ensiling were marked by ■, and TMR silages after 56 d of ensiling were marked by ▲. ATMR, total mixed ration with alfalfa hay; TMR, total mixed ration.

Figure 3

Microbial composition, pH and organic acids of LTMR and LTMR silage in the processing of aerobic deterioration. TMR were marked by ●, TMR silages after 28 d of ensiling were marked by ■, and TMR silages after 56 d of ensiling were marked by ▲. LTMR, total mixed ration with Leymus chinensis hay; TMR, total mixed ration.

Table 1

Ingredient, chemical and microbial composition of peach pomace and TMR

Item Peach pomace ATMR LTMR
Ingredient (% DM)
 Peach residue 6.0 6.0
Leymus chinensis hay 0 34.0
 Alfalfa hay 34.0 0
 Maize meal 44.4 44.4
 Soybean meal 7.0 7.0
 Cotton meal 5.0 5.0
 Limestone 2.5 2.5
 Vitamin-mineral supplement1 1.0 1.0
 Salt 0.1 0.1
Chemical composition (% DM)
 DM (%) 5.9±0.32 51.1±0.18 51.9±0.26
 OM 95.1±0.13 92.9±0.15 93.1±0.23
 CP 7.36±0.10 15.1±0.12 12.3±0.08
 EE 4.71±0.36 8.06±0.19 7.78±0.21
 NDF 20.0±0.74 29.7±0.34 35.4±0.25
 ADF 11.9±0.60 16.7±0.51 17.8±0.39
 WSC 25.9±0.22 17.7±0.36 17.4±0.32
Microbial counts (log cfu/g fresh matter)
 Lactic acid bacteria ND 4.20±0.12 4.02±0.16
 Yeasts ND 4.37±0.20 4.25±0.12

TMR, total mixed ration; ATMR, total mixed ration with alfalfa hay; LTMR, total mixed ration with Leymus chinensis hay; DM, dry matter; OM, organic matter; CP, crude protein; EE, ether extracts; NDF, neutral detergent fiber; ADF, acid detergent fiber; WSC, water soluble carbohydrate; ND, not detected; SD, standard deviation.

1

Containing 1.2% Zn, 1.0% Mn, 0.5% Fe, 0.2% Cu, and a minimum of 5,000 IU vitamin A/g and 600 IU of vitamin D/g.

Data of chemical composition and microbial counts are presented as mean±SD of 3 replicates.

Table 2

Changes in chemical composition, fermentation quality and microbial composition during ensiling of ATMR silage and LTMR silage

Item Days of ensiling

1 3 7 14 28 56
Chemical composition (% DM)
 DM (%) ATMR 50.7a±0.67 50.6a±0.37 49.4b±0.16 49.3b±0.52 49.0b±1.07 48.8b±0.13
LTMR 51.1a±0.85 50.2b±0.59 49.5bc±0.05 49.3c±0.07 49.5bc±0.19 49.1c±0.09
 CP ATMR 15.2b±0.14 15.2b±0.09 15.7a±0.12 15.6a±0.12 15.7a±0.32 15.8a±0.31
LTMR 12.6b±0.23 13.4a±0.10 13.4a±0.69 13.4a±0.36 13.4a±0.16 13.4a±0.53
 WSC ATMR 15.3a±1.43 12.9b±1.25 10.5c±1.29 9.12c±0.32 9.02c±0.06 8.90c±0.00
LTMR 16.9a±0.88 15.7b±0.45 11.8c±0.54 9.32d±0.16 9.44d±0.32 8.63e±0.03
 NDF ATMR 30.1±0.85 31.0±0.86 30.0±2.97 29.5±1.14 30.2±1.12 29.8±1.89
LTMR 34.5±2.06 35.7±0.22 35.2±0.64 35.5±0.22 34.9±0.32 34.7±0.16
 ADF ATMR 17.7±1.33 17.8±0.57 17.3±0.88 18.4±0.87 18.3±1.63 18.4±1.56
LTMR 17.2±0.19 18.0±1.23 17.4±0.70 17.7±0.59 17.8±0.33 17.9±0.32
Fermentation quality
 pH ATMR 5.25a±0.30 4.61b±0.05 4.63b±0.09 4.39c±0.04 4.29c±0.00 4.29c±0.01
LTMR 4.91a±0.17 4.81a±0.04 4.52b±0.12 4.56b±0.13 4.36bc±0.25 4.24c±0.02
 Lactic acid (% DM) ATMR 1.43e±0.06 3.77d±0.12 5.24c± 0.24 6.53b± 0.08 6.54b± 0.08 7.11a± 0.10
LTMR 2.40e±0.07 2.64d±0.10 5.48c± 0.16 5.94b± 0.14 6.24a± 0.17 6.21a± 0.04
 Acetic acid (% DM) ATMR 0.60d±0.08 0.83c±0.03 1.07b± 0.06 1.16b±0.06 1.18b± 0.08 1.38a± 0.07
LTMR 0.84b±0.10 0.88b±0.08 1.09a± 0.11 0.96ab±0.05 0.96ab±0.02 0.90b± 0.10
 NH3-N (% TN) ATMR 1.01d±0.16 1.53c±0.08 2.13b±0.19 3.39a±0.14 3.18a±0.11 3.21a±0.14
LTMR 2.32c±0.16 2.62c±0.34 3.80b±0.34 4.69a±0.26 4.49a±0.40 4.39a±0.00
Microbial counts (log cfu/g fresh matter)
 Lactic acid bacteria ATMR 8.64ab±0.40 9.05a±0.34 8.89ab±0.11 8.55b±0.21 7.25c±0.15 6.74d±0.23
LTMR 6.94c±0.21 8.80a±0.30 8.45a±0.20 8.67a±0.22 7.94b±0.16 6.63c±0.33
 Yeasts ATMR 5.72b±0.28 6.73a±0.18 6.86a±0.30 5.73b±0.27 4.56c±0.18 4.21c±0.21
LTMR 5.88a±0.29 6.75a±0.32 5.98a±0.14 5.83a±0.26 4.86c±0.14 4.27d±0.10

ATMR, total mixed ration with alfalfa hay; LTMR, total mixed ration with Leymus chinensis hay; DM, dry matter; CP, crude protein; WSC, water soluble carbohydrate; NDF, neutral detergent fiber; ADF, acid detergent fiber; NH3-N, ammonia-N; SD, standard deviation.

Data are presented as mean±SD of 3 replicates. Within a row, means without a common superscript letter differ (p<0.05).

Table 3

The composition of dominant lactic acid bacteria at different fermentation time of ATMR silages and LTMR silage

Treatment Days Lactic acid bacteria
ATMR 0, 1, 3, 7 Pediococcus pentosaceus, Lactobacillus plantarum, Weissella paramesenteroides
14, 28 Pediococcus acidilactici, Lactobicillus brevis, Lactobacillus plantarum
56 Pediococcus acidilactici, Lactobacillus buchneri
LTMR 0, 1, 3, 7, 14 Pediococcus pentosaceus, Pediococcus acidilactici, Lactobicillus brevis
28 Pediococcus acidilactici, Lactobicillus brevis
56 Pediococcus acidilactici, Lactobacillus buchneri

ATMR, total mixed ration with alfalfa hay; LTMR, total mixed ration with Leymus chinensis hay.

Table 4

The composition of dominant lactic acid bacteria at different time of aerobic deterioration in ATMR, LTMR, ATMR silages and LTMR silage

Treatment Hours Lactic acid bacteria
ATMR 0, 6, 12, 24 Pediococcus pentosaceus, Lactobicillus plantarum, Weissella paramesenteroides
48, 72, 120, 168 Pediococcus pentosaceus, Lactobicillus plantarum
LTMR 0, 6, 12 Pediococcus pentosaceus, Pediococcus acidilactici, Lactobicillus brevis
24, 48, 72 Pediococcus pentosaceus, Pediococcus acidilactici, Lactobicillus brevis, Weissella paramesenteroides
120, 168 Pediococcus pentosaceus, Lactobicillus brevis
28 d ATMR silage 0, 6, 12, 24, 48, 72, 120 Pediococcus acidilactici, Lactobicillus brevis, Lactobicillus plantarum
168 Pediococcus acidilactici, Lactobacillus buchneri, Lactobicillus plantarum
216, 264, 336 Pediococcus acidilactici, Lactobacillus buchneri
28 d LTMR silage 0, 6, 12, 24, 48, 72 Pediococcus acidilactici, Lactobicillus brevis
120, 168 Pediococcus acidilactici, Lactobacillus buchneri, Weissella paramesenteroides
216, 264, 336 Pediococcus acidilactici, Lactobacillus buchneri
56 d ATMR silage 0, 6, 12, 24, 48, 72, 120, 168 Lactobacillus buchneri, Pediococcus acidilactici
216, 264, 336 Lactobacillus buchneri, Pediococcus acidilactici, Weissella paramesenteroides
56 d LTMR silage 0, 6, 12, 24, 48, 72 Lactobacillus buchneri, Pediococcus acidilactici
120, 168 Lactobacillus buchneri, Pediococcus acidilactici, Weissella paramesenteroides
216, 264, 336 Lactobacillus buchnerii, Weissella paramesenteroides

ATMR, total mixed ration with alfalfa hay; LTMR, total mixed ration with Leymus chinensis hay.