Ryden Peter, Efthymiou Maria-Nefeli, Tindyebwa Teddy A M, Elliston Adam, Wilson David R, Waldron Keith W, Malakar Pradeep K
The Biorefinery Centre, Quadram Institute Bioscience, Colney, Norwich Research Park, Norwich, NR4 7UA UK.
School of Biological Sciences, College of Natural Sciences, Makerere University, P.O. Box 7062, Kampala, Uganda.
Biotechnol Biofuels. 2017 Aug 4;10:195. doi: 10.1186/s13068-017-0880-3. eCollection 2017.
In Uganda, the chaff remaining from threshed panicles of millet and sorghum is a low value, lignocellulose-rich agricultural by-product. Currently, it is used as a substrate for the cultivation of edible Oyster mushrooms (). The aim of this study was to assess the potential to exploit the residual post-harvest compost for saccharification and fermentation to produce ethanol.
Sorghum and millet chaff-derived spent oyster mushroom composts minus large mycelium particles were assessed at small-scale and low substrate concentrations (5% w/v) for optimal severity hydrothermal pre-treatment, enzyme loading and fermentation with robust yeasts to produce ethanol. These conditions were then used as a basis for larger scale assessments with high substrate concentrations (30% w/v). Millet-based compost had a low cellulose content and, at a high substrate concentration, did not liquefy effectively. The ethanol yield was 63.9 g/kg dry matter (DM) of original material with a low concentration (19.6 g/L). Compost derived from sorghum chaff had a higher cellulose content and could be liquefied at high substrate concentration (30% w/v). This enabled selected furfural-resistant yeasts to produce ethanol at up to 186.9 g/kg DM of original material and a concentration of 45.8 g/L.
Spent mushroom compost derived from sorghum chaff has the potential to be an industrially useful substrate for producing second-generation bioethanol. This might be improved further through fractionation and exploitation of hemicellulosic moieties, and possibly the exploitation of the mycelium-containing final residue for animal feed. However, spent compost derived from millet does not provide a suitably high concentration of ethanol to make it industrially attractive. Further research on the difficulty in quantitatively saccharifying cellulose from composted millet chaff and other similar substrates such as rice husk is required.
在乌干达,小米和高粱脱粒穗轴剩余的谷壳是一种价值较低、富含木质纤维素的农业副产品。目前,它被用作栽培可食用平菇的基质。本研究的目的是评估利用收获后剩余堆肥进行糖化和发酵以生产乙醇的潜力。
对去除大的菌丝体颗粒的高粱和小米谷壳来源的平菇废堆肥进行小规模和低底物浓度(5% w/v)评估,以确定最佳强度的水热预处理、酶负载量以及与强壮酵母发酵以生产乙醇的条件。然后将这些条件作为高底物浓度(30% w/v)大规模评估的基础。基于小米的堆肥纤维素含量低,在高底物浓度下不能有效液化。乙醇产量为每千克原始物料干物质(DM)63.9克,浓度较低(19.6克/升)。高粱谷壳衍生的堆肥纤维素含量较高,在高底物浓度(30% w/v)下可以液化。这使得选定的抗糠醛酵母能够以每千克原始物料高达186.9克的产量和45.8克/升的浓度生产乙醇。
高粱谷壳衍生的平菇废堆肥有潜力成为生产第二代生物乙醇的工业有用底物。通过对半纤维素部分进行分馏和利用,以及可能将含菌丝体的最终残渣用于动物饲料,这一潜力可能会进一步提高。然而,小米衍生的废堆肥不能提供足够高浓度的乙醇使其在工业上具有吸引力。需要进一步研究从堆肥后的小米谷壳和其他类似底物(如稻壳)中定量糖化纤维素的困难。
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