Fermentation characteristics of different purpose sorghum silage

Neto, Arthur Behling; Reis, Rafael Henrique Pereira dos; Cabral, Luciano da Silva; Abreu, Joadil Gonçalves de; Sousa, Daniel de Paula; Pedreira, B. C. e; Mombach, M. A.; Balbinot, Ernando; Carvalho, Perivaldo; Carvalho, Ana Paula da Silva

doi:10.5433/1679-0359.2017v38n4supl1p2607

Cited by 6 publications

(2 citation statements)

References 15 publications

(12 reference statements)

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“…These results are consistent with the ones reported in maize (El Hage et al, 2018; Legland et al, 2017) and advocate for the development of higher throughput histological methods to facilitate breeding efforts. In terms of breeding optimization, our results also highlight the need for different sorghum stem ideotypes for methane and animal feed (as reported in maize (Rath et al, 2013)), as there is a critical need to increase sugar soluble content for methane production, whereas it needs to be controlled for animal feed to avoid elevated ethanol production in silage composition (Behling Neto et al, 2017). Whether the in vitro dry matter digestibility, or the methane potential ideotypes identified in this work need to be prioritized in the context of second‐generation ethanol cultivar development for sorghum remains to be defined.…”

Section: Discussionsupporting

confidence: 54%

Mobilizing sorghum genetic diversity: Biochemical and histological‐assisted design of a stem ideotype for biomethane production

et al. 2021

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Sorghum currently contributes to the species portfolio that is supporting bioenergy production including anaerobic digestion. Although agro‐morphological ideotypes maximizing biogas production have been recently proposed, there is a crucial need to refine our understanding of the impacts of the stem composition and structure on this processing trait in order to ensure genetic gains in the mid to long terms. This study aims to assess the potential of Sorghum bicolor ssp bicolor stem genetic diversity to maximize genetic gains for biogas production and define a biogas stem ideotype. In this context, a panel of 57 genotypes, encompassing most of the stem composition variability available in cultivated sorghum, was characterized over five sites. Simultaneous histological and biochemical characterizations were performed. A high broad sense heritability associated with a moderate genetic variability was detected for stem biogas potential ensuring significant genetic gains in the future. In addition, the development of a stem histological phenotyping pipeline made it possible to describe the genetic diversity available for the internode anatomy and the repartition of key cell wall components. Consistently with previous studies, moderate to high heritability was observed for stem biochemical components. Genetic correlation, hierarchical clustering, and multiple stepwise regression analyses identified soluble sugar content as the first main driver of biogas potential genetic variability. Nevertheless, breeding programs should anticipate that biogas yield improvement will also rely on the monitoring of the cell wall components and their distribution in the stem jointly with the soluble sugar content. According to the assets of sorghum in terms of adaptation to environmental stresses and the present results regarding the identification of stem ideotypes suitable for different value chains, this species will surely play a key role to optimize the economic and environmental sustainability of the agrosystems that are currently facing the effects of climate change.

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Section: Discussionsupporting

confidence: 54%

Mobilizing sorghum genetic diversity: Biochemical and histological‐assisted design of a stem ideotype for biomethane production

et al. 2021

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“…Silages produced from fresh biomass with 0% and 100% fruit had the highest ammonia nitrogen (N-NH 3 ) levels, indicating a lower degree of proteolysis during the fermentation process. These values were lower than the recommended levels, suggesting that excessive protein breakdown did not occur [37]. The N-NH 3 reflects the degradation of protein during fermentation, and silages can be classified based on the content of ammonia nitrogen relative to total nitrogen.…”

Section: Losses Dm Recovery and Fermentation Indicatorsmentioning

confidence: 94%

Characterization of Melon, (Cucumis melo L.) Silage with Different Biomass Mixtures and Dry Matter Contents

Nascimento,

Edvan,

Nascimento

et al. 2023

Agriculture

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The objective of this study was to obtain different dry matter contents and proportions of melon plant biomass for silage making. A completely randomized design with factorial arrangement (3 × 2) and four replications was adopted. The first factor consisted of three melon biomass mixtures based on as-fed composition of plant (branches + leaves) and harvested melon (fruits)—100% plant (0% fruit), 90% plant + 10% fruit, and 100% fruit. The second factor corresponded to the ensiled material, which was either fresh or dehydrated in the field after harvest (40% dry matter). Silages produced from dehydrated biomass after fruit harvest, containing 0% and 10% fruit, showed the highest dry matter contents: 297 g/kg and 293 g/kg, respectively. Silages produced from fresh biomass containing 0% and 10% fruit showed high concentrations of acetic acid, reaching 14.9 g/kg and 14.1 g/kg, respectively. Silages produced from dehydrated biomass containing 10% and 100% fruit showed better results in terms of the indicators associated with high-quality silage. Dehydration improves the fermentative profile and overall quality of melon silage.

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Determination of Nutritional Quality and Aerobic Stability of Sorghum, Maize, and Sorghum-Maize Mixture Silages

Esen

Okuyucu

Koç

et al. 2022

Tekirdağ Ziraat Fakültesi Dergisi

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The current study aimed to determine the nutritional quality and aerobic stability of sorghum, maize, and their mixture silages without any additives. Sorghum and maize were harvested at dough stage from a local farm in Tekirdağ. Fresh plant materials were chopped to a length of 2-3 cm and packed into polythene bags, and vacuumed. A total of 12 vacuum-packed silos (4 replications in each treatment) were prepared with sorghum (S), maize (M), and a mixture of sorghum-maize (SM) forage (w:w, 50:50 according to dry matter) and stored at room temperature for 60 days. The chemical and microbiological composition of silages with the rate of aerobic deterioration upon aerobic exposure were evaluated. Based on the pH and ammonia nitrogen concentration, all silages could be classified as good quality. The water-soluble carbohydrate level of the SM group increased due to mixing S and M forages, leading to improved lactic acid content. The NDF and ADF values of silages varied between 520.52-588.32 and 234.98-309.01 g kg -1 , and the differences between silages were significant (P<0.01). The Hemicellulose/Cellulose ratio of S, M, and SM silages were found 0.94, 1.49, and 1.18, respectively. The lactobacilli and yeast content of silages were significant and varied between 5.18-7.41 and 5.18-7.29 log cfu g -1 , and the highest and lowest values were observed in SM and S silages, respectively (P<0.01). No visible mold was detected in all silages after 5 days of aerobic exposure (P>0.05). The pH, CO2, and yeast numbers were varied in groups between 4. 88-6.74, 55.71-119.33 g kg -1 , and 8.40-9.01 log cfu g -1 . It was concluded that it is possible to improve the nutritional and fermentation characteristics of sorghum and maize silage by ensiling their mixture. However, it is highly recommended that silage additives should be used to guarantee and strengthen the fermentation and aerobic stability of silage mostly made by a mixture of these two energetic forage crops.

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Fermentation characteristics of different purpose sorghum silage

Cited by 6 publications

References 15 publications

Mobilizing sorghum genetic diversity: Biochemical and histological‐assisted design of a stem ideotype for biomethane production

Mobilizing sorghum genetic diversity: Biochemical and histological‐assisted design of a stem ideotype for biomethane production

Characterization of Melon, (Cucumis melo L.) Silage with Different Biomass Mixtures and Dry Matter Contents

Determination of Nutritional Quality and Aerobic Stability of Sorghum, Maize, and Sorghum-Maize Mixture Silages

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