Improved fermentation strategies for enhancing polyhydroxybutyrate production from paper mill fiber rejects

Q1 Environmental Science

Bioresource Technology Reports Pub Date : 2024-10-20 DOI:10.1016/j.biteb.2024.101976

Linjing Jia , Gundeep Kaur , Ankita Juneja , Erica L.-W. Majumder , Bandaru V. Ramarao , Deepak Kumar

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Abstract

This study explores upcycling non-recyclable fiber rejects from recycled paper mills, rich in structural carbohydrates (∼50 %), into polyhydroxybutyrate (PHB), a biodegradable plastic alternative. The process involved biomass pre-cleaning, pretreatment, and fermentation to enhance PHB yields. Pre-cleaning, including repulping and screening, reduced ash content from 30.4 % to 20 %. Sequential hydrothermal pretreatment (150 °C for 10 min) followed by disk milling (3 cycles) was applied, achieving sugar yields exceeding 60 g/L during enzymatic hydrolysis. The hydrolysate was then used as the sole carbon source for PHB production by recombinant E. coli LSBJ. The study systematically optimized carbon source loading and inoculation size to maximize PHB production. Under optimal conditions, using 50 g/L reducing sugar and a 2.5 % inoculum, the highest PHB titer and yield achieved were 14.7 g/L and 0.29 g/g sugar, with a productivity of 0.2 g/L-h, surpassing previously reported titers from lignocellulosic materials at the shake-flask scale.

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改进发酵策略，提高造纸厂纤维废渣的聚羟丁酸产量

本研究探讨了将再生纸厂产生的不可回收纤维废料（富含结构碳水化合物（50%∼50%））升级回收为聚羟基丁酸（PHB），一种生物可降解塑料替代品。该工艺包括生物质预清洁、预处理和发酵，以提高 PHB 产量。预清洁（包括再制浆和筛选）可将灰分含量从 30.4% 降至 20%。采用顺序水热预处理（150 °C，10 分钟），然后进行圆盘研磨（3 个周期），在酶水解过程中，糖产量超过 60 克/升。水解产物被用作重组大肠杆菌 LSBJ 生产 PHB 的唯一碳源。该研究对碳源负载和接种量进行了系统优化，以最大限度地提高 PHB 产量。在最佳条件下，使用 50 克/升还原糖和 2.5 % 的接种量，PHB 的最高滴度和产量分别为 14.7 克/升和 0.29 克/克糖，生产率为 0.2 克/升-小时，超过了之前报道的在摇瓶规模下从木质纤维素材料中获得的滴度。

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