Services on Demand
Journal
Article
Indicators
- Cited by SciELO
- Access statistics
Related links
- Similars in SciELO
Share
Revista de Ciências Agrárias
Print version ISSN 0871-018X
Rev. de Ciências Agrárias vol.42 no.4 Lisboa Dec. 2019
https://doi.org/10.19084/rca.17723
ARTIGO
Carbohydrate fractionation, fermentation and aerobic stability of silages with different maize hybrids
Fracionamento de hidratos de carbono, fermentação e estabilidade aeróbia da silagem de diferentes híbridos de milho
Egon H. Horst1,*,, Valter H. Bumbieris Junior1, Mikal Neumann2, André M. Souza2, Edelmir S. Stadler Junior2 and André Dochowat2
1 Department of Animal Science, State University of Londrina (UEL), 86057-970, Londrina, PR, Brazil
2 Department of Veterinary Medicine, State University of the Middle-West (UNICENTRO), 85040-080, Guarapuava, PR, Brazil
(*E-mail: egonhh@yahoo.com.br)
ABSTRACT
The objective of this study was to evaluate the chemical composition and the fermentative variables of different maize hybrids and their interference in the aerobic stability of silage. The hybrids used were the Maximus VIP3, Defender VIP and Feroz VIP, being simple, triple and double hybrids, respectively. The chemical composition and the aerobic stability were evaluated 60 days after the silos were sealed. One kilo of sample from each replicate was placed in polypropylene containers lined with plastic bags and transferred to a climatic chamber at 25 ± 2°C, and the silage temperatures were measured three times a day for seven days. In the chemical composition, only the fraction A of the non-fibrous carbohydrates presented a difference between the treatments. The Maximus VIP3 hybrid was superior in relation to the others for acetic acid production and did not differ from the Defender VIP hybrid in lactic acid concentration. A longer time was required for the Maximus VIP3 silage temperature to increase by 2°C (125.3 hours), while the other silages did not differ significantly (53.3 and 45.3 hours for Defender VIP and Feroz VIP). The hybrid Maximus VIP3 is recommended for silage production due to its characteristics, including a high concentration of sugars and a greater aerobic stability.
Keywords:bromatology, deterioration, organic acids, temperature, Zea mays L.
RESUMO
O objetivo do trabalho foi avaliar a composição química e variáveis fermentativas de diferentes híbridos de milho e sua interferência na estabilidade aeróbia da silagem. Os híbridos utilizados foram o Maximus VIP3, Defender VIP e Feroz VIP, sendo híbridos simples, triplo e duplo, respectivamente. A composição química e a estabilidade aeróbia foi avaliada 60 dias após a vedação dos silos. Amostras de um quilo foram colocadas em recipientes de polipropileno revestido com saco plástico e transferidos para câmara climática à temperatura de 25 ± 2 °C, e as temperaturas das silagens foram medidas três vezes ao dia durante sete dias. Na composição química, apenas a fração A dos hidratos de carbono não fibrosos apresentou diferença entre os tratamentos. O híbrido Maximus VIP3 foi superior em relação aos demais para produção de ácido acético, e não diferiu do híbrido Defender VIP na concentração de ácido lático. Tempo significativamente mais longo foi necessário para que a temperatura da silagem de Maximus VIP3 aumentasse em 2°C (125,3 horas), enquanto as outras silagens não diferiram entre si (53,3 e 45,3 horas para Defender VIP e Feroz VIP). O híbrido Maximus VIP3 apresentou alta concentração de açucares e maior estabilidade aeróbia, sendo recomendado para produção de silagem pelas suas características.
Palavras-chave:ácidos orgânicos, bromatologia, deterioração, temperatura, Zea mays L.
INTRODUCTION
The use of deteriorated silage in ruminant feed can result in decreased dry matter intake and animal performance (Dolci et al., 2011), which compromises production. The most commonly observed indicators of deterioration are the development of molds, loss of dry matter, increase of pH, ammonia nitrogen and fiber concentrations and reduction in nutrient digestibility, as well as spontaneous heating, which is translated to a loss of aerobic stability.
By definition, aerobic stability is the resistance that the ensiled mass gives to deterioration after being exposed to air (Tres et al., 2014a), and according to the same authors, several factors interfere with this stability and, consequently, the maintenance of the quality of silage, thereby emphasizing the forage species, the dry matter and soluble sugars content, the concentration and species of aerobic and anaerobic microorganisms, as well as the concentration of organic acids.
The organic acids that were produced, which were predominantly lactic acid and acetic acid, are dependent on the genre of epiphytic bacteria that is present in the plant (Aoki et al., 2013), knowing that the predominance of homofermentative bacteria results in the low aerobic stability of silage, and those rich in heterofermentative bacteria generate relatively stable silages (Holzer et al., 2003).
Another factor of importance is related to the chemical quality of the plant, mainly due to the concentrations of soluble carbohydrates through which these organic acids are produced during the initial fermentation process, which contribute to a reduction of the pH values of silage (Santos et al., 2010).
Regarding the fermentation characteristics, the maize crop can be considered ideal because it presents high concentrations of soluble carbohydrates and low buffering power (Bernardes et al., 2012). However, Santos et al. (2013) indicate that the composition of a microbiological community of silage directly affects its fermentation standard and its aerobic stability. Liu et al. (2012) stated that different maize genotypes have different microorganisms coexisting in plants and that the nutritional composition is mainly responsible for this distinction.
Diver studies have been conducted to compare the potential of different maize genotypes (Emygdio et al., 2010), but these studies are still scarce in the field of silage production. Therefore, this study compares different hybrid maize genotypes through aerobic stability assessments.
MATERIALS AND METHODS
The experiment was conducted at the Animal Production Center (NUPRAN) of the Agrarian and Environmental Sciences Sector of the State University of the Middle-West (UNICENTRO, Guarapuava PR), in partnership with the State University of Londrina (UEL, Londrina PR).
The hybrids Maximus VIP3, Defender VIP and Feroz VIP (Syngenta®) were single, triple and double hybrids, respectively, and were implanted with a density of 65,000 plants ha-1 under the recommendations of soil analysis (CQFS RS/SC, 2004). The harvesting of silage occurred when the plants reached approximately 35% dry matter. Subsequently, the silage was ensiled in experimental PVC tubes that were 20 cm in diameter and 40 cm in height and then were compressed to obtain compaction of 600 kg fresh matter m-3.
The silos were stored in a covered area for a period of 60 days, and after opening, a 10-cm layer was discarded. A 500-g sample of each replicate was collected, which were weighed and pre-dried in a forced air oven at 55°C until a constant weight for determination of the dry matter (DM), according to AOAC (1995). Afterwards, the samples were milled in a "Wiley" type mill with a 1-mm mesh sieve.
The total dry matter was determined in an oven at 105°C, the crude protein (CP) by the micro Kjeldahl method, mineral matter (MM) and ethereal extract (EE), according to AOAC (1995). The neutral detergent fiber (NDF) contents were determined using thermostable α-amylase (Termamyl 120 L, Novozymes Latin America Ltda.) according to Van Soest et al. (1991), and the acid detergent fiber (ADF) contents were determined according to Goering and Van Soest (1970). The non-fibrous carbohydrates were obtained through the equation proposed by Sniffen et al. (1992). The soluble sugar contents were determined according to Hall (2000), and the organic acids were determined according to Silva and Queiroz (2009). The determination of the starch content was performed according to the methodology described by Walter et al. (2005). The total digestible nutrient contents (NDT) were obtained from the equation of Bolsen et al. (1992). The determination of ammoniacal nitrogen (NH-3N) was obtained by using the methodology described by Bolsen et al. (1992).
Immediately after opening the silos, one kilo of samples were deposited in polypropylene containers lined with plastic bags and transferred to a climatic chamber at a temperature of 25 ± 2°C. Silage temperatures were measured three times a day for seven days, with a thermometer inserted at 10 cm in the center of the mass. The loss of aerobic stability was defined as the time required for the silage to show an elevation of 2°C relative to the ambient temperature (Taylor and Kung Jr., 2002). As a physical measure, the aerobic dry matter loss was evaluated at the end of the seven days.
Another group of containers with one kilo of silage each was transferred to the climatic chamber with the objective to determine the pH changes according to Silva and Queiroz (2009), with measurements taken every eight hours.
The experimental design was completely randomized, with three replications. The data were submitted to the Shapiro-Wilk and Bartlett tests in order to verify the assumptions of normality and the homogeneity of variance, respectively. The F test was applied to a 5% probability of confidence using an analysis of variance (ANOVA) and then the Tukey test of the comparison of multiples means at 5% of significance. For the pH data of the aerobic stability, a polynomial regression analysis was also performed through the "proc reg" procedure of the statistical SAS program (v. 9.2; SAS Institute Inc., Cary, NC).
RESULTS AND DISCUSSION
The methodology used in selecting a favorable harvesting time for dry matter contents was similar between the treatments, according to Rabelo et al. (2014), which is ideal, because there is no interference of the different osmotic pressures. From this, it was observed that the silages stabilized their fermentation process with very close pH values.
Table 1 shows the values of chemical composition and the fermentation products of silages with different maize hybrids. In general, the data presented values that were similar to those described by Tres et al. (2014b), which highlighted the high productive potential of simple hybrids in comparison to double and triple hybrids, but without significant differences in chemical composition. Emygdio et al. (2010) emphasized the trend of superiority in the grain production of the simple hybrids, which may explain the starch values found in the present study (P = 0.0620), with 37.27% for the Maximus VIP3 hybrid, compared to 34.33% and 34.09% for the Defender VIP and Feroz VIP hybrids, respectively.
In the chemical composition, only fraction A of non-fibrous carbohydrates, which are composed of soluble sugars and organic acids, presented a difference between the silages (P <0.05). After the silo fence, the lactic acid bacteria preferentially consume glucose and fructose, converting them to organic acids; with higher concentrations of these sugars, there is a greater the tendency to produce lactic and acetic acid (Bernardes et al., 2012). This affirmation is confirmed by the fact that the Maximus VIP3 hybrid had the highest value of soluble sugars and, consequently, a higher value of organic acids (4.55% and 6.25%, respectively).
The Maximus VIP3 hybrid was superior (P <0.05) in relation to the others for acetic acid production; however, it did not differ statistically from the Defender VIP hybrid in lactic acid concentration, which, according to Liu et al. (2012), may be due to the profiles of epiphytic microbiota for each material. Nishino et al. (2012) corroborate that the microbiological community standard of silage also provides different ratios of acids. It is worth adding that the value of acetic acid that was obtained for this hybrid resembles the findings by Szucs et al. (2012) in silages inoculated with Lactobacillus buchneri (3x105 cfu g FM-1), and other treatments that were approximate to those found by the same authors in their control treatment.
The ratio of lactic acid: acetic acid was 0.94, 1.77 and 1.52 for Maximus VIP3, Defender VIP and Feroz VIP silages, respectively (Table 1). These results suggest that not only higher concentrations of acetic acid, but lower lactic acid: acetic ratios may be related to the higher aerobic stability of silage (Table 2; Figure 1).
Table 2 summarizes the parameters related to the aerobic stability of maize silages. Significantly longer time was required for the Maximus VIP3 silage temperature to increase by 2°C (125.3 hours), which is a value similar to that described by Szucs et al. (2012). The other silages did not differ significantly among themselves (53.3 and 45.3 hours for Defender VIP and Feroz VIP).
The long aerobic stabilities highlighted here might not occur in field conditions due to unavoidable environmental contaminations; tests performed under laboratory conditions may not provide accurate aerobic stability values in practice, but it is an appropriate procedure for comparing different treatments in a controlled environment.
The pH values after aerobic stability test, which lasted 152 hours, were different (P <0.05), and the silages with a loss of faster stability ended up with the highest pH values (7.0 and 7.1 to Defend VIP and Feroz VIP). Similar values were described by Rabelo et al. (2012). Balieiro Neto et al. (2009) already verified higher pH values in sugarcane silage, approximately 8.3 after 152 hours of exposure to oxygen, probably due to the different characteristics of the materials studied by the authors.
These results allow us to affirm that silages with good aerobic stability do not necessarily result from silages that present a more adequate fermentation profile. According to criteria suggested by Santos et al. (2010), the Maximus VIP hybrid silage was classified as good (85), while the Defender VIP and Feroz VIP hybrids silages were excellent (90), because the authors took into account only the maleic effects of acetic acid, such as their correlation with dry matter and energy losses.
Figure 2 shows the behavior of the pH values of silages during the aerobic stability test. Maximus VIP3 silage, which had the highest aerobic stability, showed a lower increase in pH values with an hourly advance (0.0009 pH points hour-1), while the silages of Defender VIP and Feroz VIP hybrids added 0.0249 and 0.0263 pH points hour-1, respectively.
It is possible to observe that the pH curves, for all the silages, beginning with their advances being near to those that registered a loss stability for temperature. Similar behavior can be observed in the study of Silva et al. (2016), with high moisture grain silage indicating that a pH should be considered as a complement to the tests on the aerobic stability of the temperature increase.
CONCLUSION
The variation of the maize hybrid and the genotype can affect the chemical composition of silage, the fermentation profile and the aerobic stability. Among the evaluated materials, the Maximus VIP hybrid is recommended because of its quality and high aerobic stability.
References
Aoki, Y.; Oshita, T.; Namekawa, H.; Nemoto, E. & Aoki, M. (2013) - Effect of cutting height on the chemical composition, nutritional value and yield, fermentative quality and aerobic stability of corn silage and relationship with plant maturity at harvest. Grassland Science, vol. 59, n. 4, p. 211-220. https://doi.org/10.1111/grs.12033 [ Links ]
AOAC (1995) - Official methods of analysis. 16th ed. Association of Official Analytical Chemists, Washington, DC. 2000 p. [ Links ]
Balieiro Neto, G.; Junior, E.F.; Nogueira, J.R.; Possenti, R.; Paulino, V.T. & Sartori, M.B. (2009) - Perdas fermentativas e estabilidade aeróbia de silagens de cana de-açúcar aditivadas com cal virgem. Revista Brasileira de Saúde e Produção Animal, vol. 10, n. 1, p. 24-33. [ Links ]
Bernardes, T.F.; Nussio, L.G. & Amaral, R.C. (2012) - Top spoilage losses in maize silage sealed with plastic films with different permeabilities to oxygen. Grass and Forage Science, vol. 67, n. 1, p. 34-42. https://doi.org/10.1111/j.1365-2494.2011.00823.x [ Links ]
Bolsen, K.K.; Lin, C.; Brent, B.E.; Feyerherm, A.M.; Urban, J.E. & Aimutis, W.R. (1992) - Effect of Silage Additives on Microbial Succession and Fermentation Process of Alfalfa and Corn Silages. Journal of Dairy Science, vol. 75, n. 11, p. 3066-3083. https://doi.org/10.3168/jds.S0022-0302(92)78070-9 [ Links ]
Dolci, P.; Tabacco, E.; Cocolin, L. & Borreani, G. (2011) - Microbial dynamics during aerobic exposure of corn silage stored under oxygen barrier or polyethylene films. Applied and Environmental Microbiology, vol. 77, n. 21, p. 7499-7507. https://doi.org/10.1128/AEM.05050-11 [ Links ]
Emygdio, B.M.; Ignaczak, J.C. & Cargnelutti Filho, A. (2010) - Potencial de rendimento de grãos de híbridos comerciais simples, triplos e duplos de milho. Revista Brasileira de Milho e Sorgo, vol. 6, n. 1, p. 95-103. https://doi.org/10.18512/1980-6477/rbms.v6n1p95-103 [ Links ]
Goering, H.K. & Van Soest, P.J. (1970) - Forage fiber analysis: apparatus reagents, procedures and some applications. [s.n.], Agricultural Handbook, p.379. [ Links ]
Holzer, M.; Mayrhuber, E.; Danner, H. & Braun, R. (2003) - The role of Lactobacillus buchneri in forage preservation. Trends in Biotechnology, vol. 21, n. 6, p. 282-287. https://doi.org/10.1016/S0167-7799(03)00106-9 [ Links ]
Liu, Y.; Zuo, S.; Xu, L.; Zou, Y. & Song, W. (2012) - Study on diversity of endophytic bacterial communities in seeds of hybrid maize and their parental lines. Archives of Microbiology, vol. 194, n. 12, p. 1001-1012. https://doi.org/10.1007/s00203-012-0836-8 [ Links ]
Nishino, N.; Li, Y.; Wang, C. & Parvin, S. (2012) - Effects of wilting and molasses addition on fermentation and bacterial community in guinea grass silage. Letters in Applied Microbiology, vol. 54, n. 3, p. 175-181. https://doi.org/10.1111/j.1472-765X.2011.03191.x [ Links ]
Rabelo, C.H.S.; de Rezende, A.V.; Rabelo, F.H.S.; Nogueira, D.A.; Senedese, S.S.; de Figueiredo Vieira, P. & Carvalho, A. (2014) - Silagens de milho inoculadas microbiologicamente em diferentes estádios de maturidade: perdas fermentativas, composição bromatológica e digestibilidade in vitro. Ciência Rural, vol. 44, n. 2, p. 368-373. https://doi.org/10.1590/S0103-84782014000200028 [ Links ]
Rabelo, C.H.S.; Rezende, A.V.D.; Nogueira, D.A.; Rabelo, F.H.S.; Senedese, S.S.; Vieira, P.D.F. & Carvalho, A. (2012) - Perdas fermentativas e estabilidade aeróbia de silagens de milho inoculadas com bactérias ácido-láticas em diferentes estádios de maturidade. Revista Brasileira de Saúde e Produção Animal, vol. 13, n. 3, p. 656-668. http://dx.doi.org/10.1590/S1519-99402012000300006 [ Links ]
Santos, A.O.; Ávila, C.L.S. & Schwan, R.F. (2013) - Selection of tropical lactic acid bacteria for enhancing the quality of maize silage. Journal of Dairy Science, vol. 96, n. 12, p. 7777-7789. https://doi.org/10.3168/jds.2013-6782 [ Links ]
Santos, R.D.; Pereira, L.G.R.; Neves, A.L.A.; Araujo, G.G.L.; Voltolini, T.V.; Brandão, L.G.N. & Dórea, J.R.R. (2010) - Características de fermentação da silagem de seis variedades de milho indicadas para a região semiárida brasileira. Arquivo Brasileiro de Medicina Veterinária e Zootecnia, v. 62, n. 6, p. 1423-1429. http://dx.doi.org/10.1590/S0102-09352010000600019 [ Links ]
Silva, C.M.; Amaral, P.N.C.; Baggio, R.A.; Tubin, J.S.B.; Conte, R.A.; Pivo, J.C.D.; Krahl, G.; Zampar, A. & Paiano, D. (2016) - Estabilidade de silagens de grãos úmidos de milho e milho reidratado. Revista Brasileira de Saúde e Produção Animal, v. 17, n. 3, p. 331-343. http://dx.doi.org/10.1590/S1519-99402016000300001 [ Links ]
Silva, D.J. & Queiroz, A.C. (2009) - Análise de alimentos, métodos químicos e biológicos. 3ª reimpressão. Universidade Federal de Viçosa, 235p. [ Links ]
Sniffen, C.J.; O'connor, J.D.; Van Soest, P.J.; Fox, D.G. & Russell, J.B. (1992) - A net carbohydrate and protein system for evaluating cattle diets: II. Carbohydrate and protein availability. Journal of Animal Science, vol. 70, n. 11, p. 3562-3577. https://doi.org/10.2527/1992.70113562x [ Links ]
Szucs, J.P.; Suli, A.; Meszaros, A.; Bodnar, E.S. & Avasi, Z. (2012) - Use of Biological Additives with Grass Containing Medium and High Levels of WSC for Effective Conservation and Aerobic Stability. Animal Science and Biotechnologies, vol. 45, n. 1, p. 96-100. [ Links ]
Taylor, C.C. & Kung Junior, L. (2002) - The effect of Lactobacillus buchneri on fermentation and aerobic stability of high moisture corn in laboratory silos. Journal of Dairy Science, vol. 85, n. 6, p. 126-1532. https://doi.org/10.3168/jds.S0022-0302(02)74222-7 [ Links ]
Tres, T.; Jobim, C.C.; Pinto, B.R.J.; Souza Neto, I.L.; Scapim, C.A. & Silva, J.M.S. (2014a) - Composição nutricional e digestibilidade in vitro de genótipos de milho produzidos em dois anos agrícolas. Semina: Ciências Agrárias, vol. 35, n. 6, p. 3249-3261. https://doi.org/10.5433/1679-0359.2014v35n6p3249 [ Links ]
Tres, T.T.; Jobim, C.C.; Rossi, R.M.; Silva, M.S.D. & Poppi, E.C. (2014b) - Silagem de grãos de milho, com adição de soja: estabilidade aeróbia e desempenho de vacas leiteiras. Revista Brasileira de Saúde e Produção Animal, vol. 15, n. 1, p. 248-260. http://dx.doi.org/10.1590/S1519-99402014000100002 [ Links ]
Van Soest, P.V.; Robertson, J.B. & Lewis, B.A. (1991) - Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to nutrition animal. Journal of Dairy Science, vol. 74, p. 3583-3597. https://doi.org/10.3168/jds.S0022-0302(91)78551-2 [ Links ]
Walter, M.; Silva, L.P. & Emanuelli, T. (2005) - Amido resistente: características físico-químicas, propriedades fisiológicas e metodologias de quantificação. Ciência Rural, vol. 35, n. 4, p. 974-980. http://dx.doi.org/10.1590/S0103-84782005000400041 [ Links ]
Acknowledgments
To the Coordination of Improvement of Higher Education Personnel (CAPES).
Part of first author's thesis
Received/recebido: 2019.04.25
Accepted/aceite: 2019.09.26