Bioconversion of spent passion fruit rind to ethanol: Integrating hemicellulose hydrolysis and detoxification

Q1 Environmental Science

Bioresource Technology Reports Pub Date : 2025-06-23 DOI:10.1016/j.biteb.2025.102193

Kakali Borah , Vaibhav V. Goud

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Abstract

Effective fermentation of the hemicellulosic fraction, which constitutes approximately one-third of lignocellulosic biomass, is essential for the advancing of second-generation bioethanol production. This study optimizes the dilute sulfuric acid pretreatment by response surface methodology (RSM) to increase xylose release and minimize fermentation inhibitors from spent passion fruit rind (SPFR) residue. The optimized parameters (114 °C, 9.8 min, and 0.2 M H₂SO₄) yielded a xylose concentration of 121.8 mg/g db, accompanied by 2.3 mg/g db furfural production. Detoxification with overliming (Ca(OH)₂, pH 11) further reduced inhibitory chemicals by 12–23 %, improving fermentative compatibility. Subsequent fermentation of detoxified hydrolysate using Pichia (Scheffersomyces) stipitis produced an ethanol concentration of 9.7 g/L, achieving a yield of 0.42 g/g. The batch fermentation of SPFR-derived xylose rich hydrolysate demonstrates effective bioethanol production from the hemicellulosic fraction, supporting its potential use in second-generation bioethanol.

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废西番莲果皮生物转化为乙醇：整合半纤维素水解和解毒

半纤维素组分（约占木质纤维素生物量的三分之一）的有效发酵对于推进第二代生物乙醇生产至关重要。以百香果皮渣为原料，利用响应面法（RSM）优化稀硫酸预处理，提高木糖的释放量，减少发酵抑制剂。优化条件为：114℃，9.8 min, 0.2 M H2SO4，木糖浓度为121.8 mg/g db，糠醛产量为2.3 mg/g db。过碱解毒（Ca(OH)2, pH 11）进一步降低了12 - 23%的抑制化学物质，改善了发酵相容性。随后使用毕赤酵母（scheffersomces） stipitis对解毒水解产物进行发酵，产生浓度为9.7 g/L的乙醇，产量为0.42 g/g。spfr衍生的富含木糖的水解液分批发酵表明，从半纤维素部分有效地生产生物乙醇，支持其在第二代生物乙醇中的潜在应用。

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