Browsing by Author "Zhou, Yang"

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    Promoting enzymatic hydrolysis of lignocellulosic biomass by inexpensive soy protein
    Luo, Xiaolin; Liu, Jing; Zheng, Peitao; Li, Meng; Zhou, Yang; Huang, Liulian; Chen, Lihui; Shuai, Li (2019-03-13)
    Background Liquid hot water (LHW) pretreatment has been considered as one of the most industrially viable and environment-friendly methods for facilitating the transformation of lignocelluloses into biofuels through biological conversion. However, lignin fragments in pretreatment hydrolysates are preferential to condense with each other and then deposit back onto cellulose surface under severe conditions. Particularly, lignin tends to relocate or redistribute under high-temperature LHW pretreatment conditions. The lignin residues on the cellulose surface would result in significant nonproductive binding of cellulolytic enzymes, and therefore negatively affect the enzymatic conversion (EC) of glucan in pretreated substrates. Although additives such as bovine serum albumin (BSA) and Tween series have been used to reduce nonproductive binding of enzymes through blocking the lignin, the high cost or non-biocompatibility of these additives limits their potential in industrial applications. Results Here, we firstly report that a soluble soy protein (SP) extracted from inexpensive defatted soy powder (DSP) showed excellent performance in promoting the EC of glucan in LHW-pretreated lignocellulosic substrates. The addition of the SP (80 mg/g glucan) could readily reduce the cellulase (Celluclast 1.5 L®) loading by 8 times from 96.7 to 12.1 mg protein/g glucan and achieve a glucan EC of 80% at a hydrolysis time of 72 h. With the same cellulase (Celluclast 1.5 L®) loading (24.2 mg protein/g glucan), the ECs of glucan in LHW-pretreated bamboo, eucalyptus, and Masson pine substrates increased from 57%, 54% and 45% (without SP) to 87%, 94% and 86% (with 80 mg SP/g glucan), respectively. Similar effects were also observed when Cellic CTec2, a newer-generation cellulase preparation, was used. Mechanistic studies indicated that the adsorption of soluble SP onto the surface of lignin residues could reduce the nonproductive binding of cellulolytic enzymes to lignin. The cost of the SP required for effective promotion would be equivalent to the cost of 2.9 mg cellulase (Celluclast 1.5 L®) protein (or 1.2 FPU/g glucan), if a proposed semi-simultaneous saccharification and fermentation (semi-SSF) model was used. Conclusions Near-complete saccharification of glucan in LHW-pretreated lignocellulosic substrates could be achieved with the addition of the inexpensive and biocompatible SP additive extracted from DSP. This simple but remarkably effective technique could readily contribute to improving the economics of the cellulosic biorefinery industry.
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    Synthesis of Polysaccharide-based Biomaterials for Drug Delivery
    Zhou, Yang (Virginia Tech, 2023-01-17)
    Synthetic strategies for polysaccharide-protein conjugates, pH-responsive hydrogels, and amorphous solid dispersion (ASD) polymers were developed. Conjugating a polysaccharide to a protein drug via a covalent bond may improve its medical properties including solubility, stability, immunogenicity, circulation time, and targeting ability. Regioselectivity of conjugation is still challenging. We developed a strategy for regioselective conjugation of amino acid esters to polysaccharides, by employing 6-Br-polysaccharides in SN2 substitution reactions with amino acid esters. This work provides a good starting point for the regioselective conjugation of polysaccharides to proteins. Polysaccharides can also serve as hydrogel drug carriers. Most hydrogels employed in drug delivery work by incorporating the drug physically. We synthesized sustained and pH-responsive hydrogels using oxidized hydroxypropyl cellulose (Ox-HPC)/carboxymethyl chitosan (CMCS) crosslinked by imine bond. Phenylalanine as a model amine-containing drug was chemically bonded to the Ox-HPC hydrogel component and was observed to release faster at the pH of a tumor microenvironment. These hydrogels show promise as targeting cancer drug carriers. ASDs are polymeric systems to disperse poorly soluble drugs amorphously and enhance permeation from the gastrointestinal tract (GI tract) to the bloodstream. We synthesized potentially zwitterionic cellulose derivatives by reductive amination of Ox-HPC with ω-aminoalkanoic acids and obtained products with the degree of substitution (cation and anion) up to 1.6, which is difficult to attain using previous methods. The products showed manipulated amphiphilicity and excellent thermostability, exhibiting potential application in ASDs. We anticipate that these strategies will benefit future polysaccharide chemistry research and permit synthesis of a broad variety of more functional biomedical materials.