Your search keyword '"BHAGIA, Samarthya"' showing total 8 results

1. Effects of dilute acid and flowthrough pretreatments and BSA supplementation on enzymatic deconstruction of poplar by cellulase and xylanase.

Author

Bhagia, Samarthya, Kumar, Rajeev, and Wyman, Charles E.

Subjects

*CELLULASE, *XYLANASES, *LIGNOCELLULOSE, *ALBUMINS, *LIGNINS

Abstract

To help understand factors controlling the recalcitrance of lignocellulosic biomass to deconstruction to sugars, poplar was pretreated with liquid hot water (LHW) and extremely dilute acid (EDA) at 140 °C and 180 °C in batch and flowthrough reactors. The resulting solids were then subjected to enzymatic hydrolysis by eight combinations of cellulase, xylanase, and bovine serum albumin (BSA). Co-addition of xylanase to cellulase resulted in up to 11 percentage points higher overall sugar yield than their sequential addition. In general, supplementation of BSA to enzymes had a larger impact on flowthrough solids with reduced lignin content than batch solids with high lignin content. BSA did not affect xylan yields and while it had low impact on LHW solids, it caused large increases in sugar yields from EDA solids. Flowthrough pretreatment produced less recalcitrant solids than did batch operation, but using very dilute acid reduced recalcitrance even more. [ABSTRACT FROM AUTHOR]

Published

2017

2. Flowthrough pretreatment with very dilute acid provides insights into high lignin contribution to biomass recalcitrance.

Author

Bhagia, Samarthya, Hongjia Li, Xiadi Gao, Kumar, Rajeev, and Wyman, Charles E.

Subjects

*LIGNINS, *PLANT biomass, *HOT water, *PHOTOSYNTHESIS, *SUGAR

Abstract

Background: Flowthrough pretreatment is capable of removing much higher quantities of hemicellulose and lignin from lignocellulosic biomass than batch pretreatment performed at otherwise similar conditions. Comparison of these two pretreatment configurations for sugar yields and lignin removal can provide insights into lignocellulosic biomass deconstruction. Therefore, we applied liquid hot water (LHW) and extremely dilute acid (EDA, 0.05%) flowthrough and batch pretreatments of poplar at two temperatures and the same pretreatment severity for the solids. Composition of solids, sugar mass distribution with pretreatment, sugar yields, and lignin removal from pretreatment and enzymatic hydrolysis were measured. Results: Flowthrough aqueous pretreatment of poplar showed between 63 and 69% lignin removal at both 140 and 180 °C, while batch pretreatments showed about 20 to 33% lignin removal at similar conditions. Extremely dilute acid slightly enhanced lignin removal from solids with flowthrough pretreatment at both pretreatment temperatures. However, extremely dilute acid batch pretreatment did realize greater than 70% xylan yields largely in the form of monomeric xylose. Close to 100% total sugar yields were measured from LHW and EDA flowthrough pretreatments and one batch EDA pretreatment at 180 °C. The high lignin removal by flowthrough pretreatment enhanced cellulose digestibility compared to batch pretreatment, consistent with lignin being a key contributor to biomass recalcitrance. Furthermore, solids from 180 °C flowthrough pretreatment were much more digestible than solids pretreated at 140 °C despite similar lignin and extensive hemicellulose removal. Conclusions: Results with flowthrough pretreatment show that about 65-70% of the lignin is solubilized and removed before it can react further to form low solubility lignin rich fragments that deposit on the biomass surface in batch operations and hinder enzyme action. The leftover 30-35% lignin in poplar was a key player in biomass recalcitrance to enzymatic deconstruction and it might be more difficult to dislodge from biomass with lower temperature of pretreatment. These results also point to the possibility that hemicellulose removal is more important as an indicator of lignin disruption than in playing a direct role in reducing biomass recalcitrance. [ABSTRACT FROM AUTHOR]

Published

2016

3. Natural genetic variability reduces recalcitrance in poplar.

Author

Bhagia, Samarthya, Muchero, Wellington, Kumar, Rajeev, Tuskan, Gerald A., and Wyman, Charles E.

Subjects

*POPLARS, *FATTY alcohols, *FATTY acids, *LIGNINS, *LIGNOCELLULOSE, *COMPARATOR circuits

Abstract

Background: Fatty alcohols are important oleochemicals widely used in detergents, surfactants and personal care products. Bio-synthesized fatty alcohol provides a promising alternative to traditional fatty alcohol industry. Harnessing oleaginous microorganisms for fatty alcohol production may offer a new strategy to achieve a commercially viable yield that currently still seems to be a remote target. Results: In this study, we introduced functional fatty acyl-CoA reductase (FAR), TaFAR1 to direct the conversion from fatty acyl-CoA to fatty alcohol in Yarrowia lipolytica (Y. lipolytica), an oleaginous non-conventional yeast showing great lipid-producing capability. Tri-module optimizations including eliminating fatty alcohol degradation pathway, enhancing TaFAR1 expression, and increasing fatty acyl-CoA supply were furtherly conducted, resulting in 63-fold increase in intracellular fatty alcohol-producing capability compared to the starting strain. Thus, this work demonstrated successful construction of first generation of Y. lipolytica fatty alcohol-producing cell factory. Through the study of effect of environmental nutrition on fatty alcohol production, up to 636.89 mg/L intracellular hexadecanol (high fatty alcoholretaining capability) and 53.32 mg/L extracellular hexadecanol were produced by this cell factory through batch fermentation, which was comparable to the highest production of Saccharomyces cerevisiae under the similar condition. Conclusion: This work preliminarily explored fatty alcohol-producing capability through mobilization of FAR and fatty acid metabolism, maximizing the intracellular fatty alcohol-producing capability, suggesting that Y. lipolytica cell factory potentially offers a promising platform for fatty alcohol production. [ABSTRACT FROM AUTHOR]

Published

2016

4. Effects of the advanced organosolv pretreatment strategies on structural properties of woody biomass.

Author

Meng, Xianzhi, Bhagia, Samarthya, Wang, Yunxuan, Zhou, Yang, Pu, Yunqiao, Dunlap, John R., Shuai, Li, Ragauskas, Arthur J., and Yoo, Chang Geun

Subjects

*LIGNOCELLULOSE, *LIGNINS, *PLANT cell walls, *BIOMASS chemicals, *LIQUID fuels, *MOLECULAR weights, *CELL morphology

Abstract

• How different organosolv pretreatments affected biomass recalcitrance is revealed. • A side-by-side comparison of GVL, CELF, and EtOH pretreatment is provided. • GVL pretreatment triggered the most damage to crystalline cellulose. • CELF lignin has extremely high free phenolic OH groups. • All pretreatments led to delamination and changes in the shape of plant cell walls. Plants have evolved their lignocellulosic cell walls through complex structural and chemical mechanisms to protect itself against microbial attacks, which makes native lignocellulosic biomass recalcitrant to enzymatic deconstruction. Pretreatment is a crucial step in the biological conversion of biomass as it can render structural changes in the plant cell wall to reduce the biomass recalcitrance, thus enhancing its sugar release performance. There have been many efforts to develop effective pretreatment technologies to overcome the biomass recalcitrance with a primary focus on the efficient conversion of biomass carbohydrates to liquid fuels, while lignin is significantly underutilized despite its bulk amount and high-value opportunities. In this study, the effects of two recent organosolv pretreatment strategies, co-solvent enhanced lignocellulosic fractionation (CELF) and γ-Valerolactone (GVL) pretreatments, on physicochemical properties of poplar were investigated and compared with the effects of conventional ethanol organosolv pretreatment. Diverse physicochemical properties of biomass including chemical compositions, molecular weights of cellulose and lignin, aromatics and inter-unit linkages of lignin, lignin hydroxyl group contents, cellulose crystallinity, and accessible surface area of cellulose were analyzed before and after pretreatments. The results revealed how each organic solvent pretreatment system affected biomass structural characteristics and recalcitrance. [ABSTRACT FROM AUTHOR]

Published

2020

5. 3D printed lignin/polymer composite with enhanced mechanical and anti-thermal-aging performance.

Author

Zhang, Shuyang, Meng, Xianzhi, Bhagia, Samarthya, Ji, Anqi, Dean Smith, Micholas, Wang, Yun-yan, Liu, Bo, Yoo, Chang Geun, Harper, David P., and Ragauskas, Arthur J.

Subjects

*LIGNANS, *LIGNINS, *LIGNIN structure, *BIOPOLYMERS, *YOUNG'S modulus, *POLYMERS, *THREE-dimensional printing, *POLYAMIDES

Abstract

• Targeted phenolic hydroxyl is enriched on organosolv lignin by a mild modification. • Enhanced interfacial adhesion between the modified lignin and polymer was achieved. • Improved mechanical performance was reached due to enhanced interfacial adhesion. • Modified lignin also promotes the anti-aging of the lignin/polymer composites. Lignin is the most abundant natural aromatic polymer globally but is still underutilized as a renewable material, even with its versatile properties. One approach to using lignin is to incorporate it in polymer composites, but this application is often limited by the poor mechanical performance of the resultant composite due to the poor interfacial adhesion. Following the structure–property relationship, stronger interactions were designed to be enhanced by alternating the functional groups of lignin. This study applied a demethylation method to hardwood lignin (Ori-Lig) to introduce more phenolic hydroxyl groups. Research studies with rheology behavior and molecular simulations demonstrated that an increased phenolic hydroxyl content could improve the adhesion between the modified lignin (OH-Lig) and the polymer matrix at the interface. The tensile performance of the samples from the fused depositional modeling (FDM) 3D printing technique was also improved due to the improved interfacial adhesion. Specifically, by adding 10 wt% of the modified lignin, the tensile strength of the 3D printed samples could reach 46.1 MPa (40.2 MPa of Polyamide 12, PA12), and Young's Modulus could be improved to 1.73 GPa (1.48 GPa of PA12). OH-Lig also improved anti-aging performance so that the tensile strength of the OH-Lig composite after thermo-aging (100 h at 140 °C) remained ∼ 48 MPa. The enhanced mechanical performance with anti-aging properties indicated that the OH-Lig composite may replace PA12 to reduce the use of petrol-based materials. This work showed the method of purposefully designing and modifying lignin structures to fulfill the interaction requirements between lignin and polymer matrix. The as-prepared lignin could be used to prepare functional composites to achieve improved mechanical performance and targeted functions at the same time. [ABSTRACT FROM AUTHOR]

Published

2024

6. Natural deep eutectic solvents for lignocellulosic biomass pretreatment: Recent developments, challenges and novel opportunities.

Author

Satlewal, Alok, Agrawal, Ruchi, Bhagia, Samarthya, Sangoro, Joshua, and Ragauskas, Arthur J.

Subjects

*LIGNOCELLULOSE, *EUTECTIC reactions, *LIGNINS, *BIOMASS chemicals industry, *TOXICITY testing, *BIODEGRADABLE products

Abstract

Abstract Conversion of lignocellulosic biomass to fuels and chemicals has attracted immense research and development around the world. Lowering recalcitrance of biomass in a cost-effective manner is a challenge to commercialize biomass-based technologies. Deep eutectic solvents (DESs) are new 'green' solvents that have a high potential for biomass processing because of their low cost, low toxicity, biodegradability, easy recycling and reuse. This article discusses the properties of DESs and recent advances in their application for lignocellulosic biomass processing. The effectiveness of DESs in hydrolyzing lignin-carbohydrate complexes, removing lignin/hemicellulose from biomass as well as their effect on biomass deconstruction, crystallinity and enzymatic digestibility have been discussed. Moreover, this review presents recent findings on the compatibility of natural DESs with enzymes and microorganisms. Highlights • Physicochemical properties of deep eutectic solvents (DESs) and its application in biomass processing • DESs potential for improved saccharification of biomass and catalytic conversion of sugars into platform molecules • Present approaches for DESs recycling and reuse • Bio-compatibility of DESs with enzymes and microorganisms [ABSTRACT FROM AUTHOR]

Published

2018

7. Structure-property relationship between lignin structures and properties of 3D-printed lignin composites.

Author

Zhang, Shuyang, Ji, Anqi, Meng, Xianzhi, Bhagia, Samarthya, Yoo, Chang Geun, Harper, David P., Zhao, Xianhui, and Ragauskas, Arthur J.

Subjects

*LIGNINS, *LIGNIN structure, *SOFTWOOD, *DYNAMIC mechanical analysis, *HYDROGEN bonding interactions, *DEMETHYLATION, *YOUNG'S modulus, *INTERMOLECULAR interactions, *HYDROGEN bonding

Abstract

Lignin is a low-cost and renewable bioresource with a huge annual production promising to prepare sustainable materials. However, the poor interfacial adhesion between many lignin-polymer pairs deteriorates the mechanical performance of the composites, which seriously limits the application of lignin in 3D printing via fused depositional modeling. This work examined lignin-polyamide 12 (PA 12) intermolecular interactions (e.g., hydrogen bonding) to address the interface challenge. To realize this goal, the phenolic hydroxyl content was increased for a kraft softwood lignin using a LiBr/HBr demethylation procedure, increasing phenoxy content by 61.7%. Increased hydrogen bonding interactions between modified lignin (Pine-Lig-OH) and PA 12 demonstrated a significantly improved molten dynamic modulus by rheological analysis. Regarding mechanical properties, by adding 20 wt% of Pine-Lig-OH, the tensile strength and Young's modulus reached 46.6 MPa and 1.62 GPa, 30.2% and 33.9% higher than PA 12, respectively. Further morphological analysis proved the interfacial interactions are enhanced by showing the difference in the phase gaps. The dynamic mechanical analysis (DMA) supported the conclusion that Pine-Lig-OH could interact with polymer chains, alternating segmental movements due to the strong interaction. This study presents a method to enhance lignin composite properties by promoting interactions with the polymer matrix through modified functional groups, guiding future lignin composite research. [Display omitted] • More Phenolic structures were designed and modified on kraft softwood lignin by demethylation. • More phenolic hydroxyls improved interfacial adhesion in lignin/PA 12 composites. • Enhanced interaction improved tensile properties. • Phenolic-enhanced lignin altered polymer morphology and dynamic mechanical behaviors. [ABSTRACT FROM AUTHOR]

Published

2024

8. Salinity-driven changes in Salicornia cell wall nanomechanics and lignin composition.

Author

Cárdenas Pérez, Stefany, Strzelecki, Janusz, Piernik, Agnieszka, Rajabi Dehnavi, Ahmad, Trzeciak, Paulina, Puchałka, Radosław, Mierek-Adamska, Agnieszka, Chanona Pérez, Jorge, Kačík, František, Račko, Vladimír, Kováč, Ján, Bhagia, Samarthya, and Ďurkovič, Jaroslav

Subjects

*NANOMECHANICS, *BACTERIAL cell walls, *ATOMIC force microscopy, *LIGNINS, *SOIL salinization, *YOUNG'S modulus, *ENERGY crops

Abstract

Widespread increases in soil salinization significantly reduce agricultural lands. Nevertheless, salt-tolerant plants, such as Salicornia europaea L., can play a crucial role in the reclamation of these lands. We selected S. europaea for this study due to its potential to mitigate soil salinization and its numerous applications, such as intercropping in agriculture, biocompounds production and bioenergy. This work was designed to determine whether different salinities induce significant biophysical, anatomical, lignin and gene transcript changes in S. europaea. Through atomic force microscopy (AFM), we revealed that salinity stimulated an increase in cell wall elasticity (CWE) as an important physiological mechanism of adaptation known as cell's turgor conservation effect. Direct values of the cell wall stiffness subjected to salinity were obtained, with Young's modulus (E) ranging from low and high salinity 0.52 to 0.03 MPa. The softening of the cell wall properly correlated with an increase in cell size, plant cells under strong salinity 1000 mM NaCl, swelled 5.4 times. The best salinity range found for its optimum growth was 200–400 mM NaCl. At higher salinities, we identified increases in the lignified xylem, large calcium oxalate crystals, and in transcript amounts of SeSOS1 and SeNHX1 , which has a significant negative correlation with cell wall stiffness (−0.57 and −0.95 , respectively). The high syringyl and guaiacyl ratio (S/G) in lignin for 0–400 mM NaCl may have influenced the rigidity and hydrophobicity of the cell walls. A positive S/G ratio and sugar yields are associated with higher bioethanol production, these values may also be useful for agriculture, biorefinery, biocompounds and plant-breeding applications. We conclude that salinity indeed influenced the cell wall traits of S. europaea. This halophyte is capable of markedly softening its cell wall as a way of adapting to the high level of salinity. Our presented insights and correlations not only provide a better understanding of cell wall remodelling but are also considered vital traits of adaptation strategies that this halophyte holds under salinity environment. These inputs can also be applied in future research aiming to produce biomass and biofuel or to improve the salinity tolerance during the cultivation of non-tolerant plants, crops and glycophytes, which is a significant challenge in agriculture, particularly in arid and coastal regions. The unique properties of the S. europaea cell walls could also inspire the development of materials with enhanced nanomechanical elasticity for resistance to osmotic stress. [Display omitted] • AFM is a useful tool to evaluate cell wall biophysical dynamics under salinity. • Cell wall elasticity is an essential trait for salt resistance in S. europaea. • S. europaea increased CWE and cell size when coping with high salinity. • Thickening of xylem vessels diameter and lignin cell walls help in halophyte salt resistance. • A high SeNHX1 gene expression indicates Na+ sequestration in the vacuoles. [ABSTRACT FROM AUTHOR]

Published

2024