Physicochemical Characterization of Potassium Hydroxide Pretreated Chestnut Shell and Its Bioconversion to Lactic Acid by Lacticaseibacillus rhamnosus

Lee, Jeongho; Kim, Seunghee; Son, Hyerim; Lee, Kang Hyun; Park, Chulhwan; Yoo, Hah Young

doi:10.3390/pr11123340

Processes

2023

DOI: 10.3390/pr11123340

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Physicochemical Characterization of Potassium Hydroxide Pretreated Chestnut Shell and Its Bioconversion to Lactic Acid by Lacticaseibacillus rhamnosus

Jeongho Lee,

Seunghee Kim,

Hyerim Son

et al.

Abstract: Lactic acid (LA) is an important platform chemical with a wide range of applications, including bioplastic materials, and demand for it is growing rapidly. However, the high cost of feedstock for LA production is a major barrier to industrial production. This study designed a process to produce LA from chestnut shell (CS), a low-cost biomass. The entire process includes KOH pretreatment, enzymatic saccharification, and fermentation. This study investigated the chemical compositions and physicochemical properti… Show more

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Cited by 3 publications

References 34 publications

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Evaluation of sustainability of fabrication process and characterization studies of activated carbon nanocatalyst from waste chestnut peels

Singh,

Himanshu,

Verma

et al. 2025

Journal of Molecular Structure

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Evaluation of sustainability of fabrication process and characterization studies of activated carbon nanocatalyst from waste chestnut peels

Singh,

Himanshu,

Verma

et al. 2025

Journal of Molecular Structure

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Improved recovery of mannitol from Saccharina japonica under optimal hot water extraction and application to lactic acid production by Lacticaseibacillus rhamnosus

Lee,

Bae,

Shin

et al. 2024

GCB Bioenergy

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Brown algae are gaining traction as biorefinery feedstocks due to their advantages such as rapid growth and carbon dioxide sequestration. Saccharina japonica has high potential due to its high carbohydrate content, especially mannitol (26.7%). In this study, a biorefinery process for S. japonica was designed, with focusing on sugar conversion and bioconversion into lactic acid, a valuable platform chemical utilized in various industries. The existing sugar conversion process of S. japonica has been investigated by focusing on enzymatic or acid‐catalyzed hydrolysis, but not hot water extraction although mannitol can be easily recovered using water. The effect of temperature (60–120°C) on the mannitol yield from S. japonica was investigated, and a mannitol yield of 208 g/kg biomass was achieved at the optimal temperature of 100°C (about 78% of the theoretical maximum yield). This study emphasizes that this simple process has considerable potential for application as over 80% of the fermentable carbohydrates in S. japonica were mannitol. Then, S. japonica extract was applied to lactic acid production. First, lactic acid production of four bacterial strains was tested in a mannitol medium, and Lacticaseibacillus rhamnosus was selected as the superior producer, showing 1.93 to 2.92 times better lactic acid titer than others. Next, the optimal feeding concentration of mannitol was determined to be 20 g/L, which was all consumed by L. rhamnosus. Finally, S. japonica extract was applied to lactic acid production by L. rhamnosus, and the results showed similar fermentation profiles with the control medium: lactic acid production, 18.81 g/L (control: 18.97 g/L); lactic acid conversion, 95.1% (control: 95.9%); cell growth (OD600 nm), 8.9 (control: 7.4). The lactic acid yield in the designed biorefinery process was estimated to be 195.6 g/kg biomass, thus S. japonica has high potential as a biorefinery feedstock to produce valuable bioproducts, including lactic acid.

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Improved Sugar Recovery from Mandarin Peel under Optimal Enzymatic Hydrolysis Conditions and Application to Bioethanol Production

Son,

Lee,

Yoo

2024

Processes

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Mandarin peel (MP) has gained attention as a feedstock for flavonoid recovery via the extraction process based on the biorefinery concept, but residues remain after the extraction. Toward an integrated biorefinery concept, this study aimed to valorize extracted MP (eMP) by using it in bioethanol production. For efficient fermentable sugar production, the effect of enzymatic hydrolysis conditions on sugar conversion from eMP was investigated, and the results showed that combining cellulase and cellobiase resulted in a higher enzymatic glucose conversion (78.2%) than the use of the individual enzymes (37.5% and 45.6%). Pectinase played an essential role in enhancing enzymatic arabinose conversion, and the optimal conditions were determined to be pH 4 and 90 units of the three enzymes. Under optimal conditions, the sugar yield was 199 g glucose and 47 g arabinose/kg eMP, and the hydrolysate was used in bioethanol fermentation. The results showed that the bioethanol production was 3.78 g/L (73.9% yield), similar to the control medium (3.79 g/L; 74.2% yield), although the cell growth of the yeast was slightly delayed in the eMP hydrolysate medium. This study highlights the potential of eMP as a low-cost feedstock for sugar and bioethanol production.

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Physicochemical Characterization of Potassium Hydroxide Pretreated Chestnut Shell and Its Bioconversion to Lactic Acid by Lacticaseibacillus rhamnosus

Cited by 3 publications

References 34 publications

Evaluation of sustainability of fabrication process and characterization studies of activated carbon nanocatalyst from waste chestnut peels

Evaluation of sustainability of fabrication process and characterization studies of activated carbon nanocatalyst from waste chestnut peels

Improved recovery of mannitol from Saccharina japonica under optimal hot water extraction and application to lactic acid production by Lacticaseibacillus rhamnosus

Improved Sugar Recovery from Mandarin Peel under Optimal Enzymatic Hydrolysis Conditions and Application to Bioethanol Production

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