Your search keyword '"Warathorn Chumchoochart"' showing total 3 results

1. Important Role and Properties of Granular Nanocellulose Particles in an In Vitro Simulated Gastrointestinal System and in Lipid Digestibility and Permeability

Author

Warathorn Chumchoochart, Nopakarn Chandet, Chalermpong Saenjum, and Jidapha Tinoi

Subjects

emulsion, free fatty acid, gastrointestinal tract, granular nanocellulose, in vitro digestion, lipid digestibility, Microbiology, QR1-502

Abstract

This research evaluated the role and feasibility of the granular nanocellulose particles (GNC) from sugarcane bagasse obtained from enzymatic hydrolysis in reducing lipid digestibility and permeability in an in vitro simulated gastrointestinal (GI) system. GNC concentration (0.02%, w/v) had significantly affected the released free fatty acids (FFA), with a reduction of approximately 20%. Pickering emulsion of a GNC and olive oil simulation mixture revealed higher oil droplet size distribution and stability in the initial stage than the vortexed mixture formation. The difference in particle size distribution and zeta potential of the ingested GNC suspension and GNC–olive oil emulsion were displayed during the in vitro gastrointestinal simulation. GNC particles interacted and distributed surrounding the oil droplet, leading to interfacial emulsion. The GNC concentration (0.01–0.10%, w/v) showed low toxicity on HIEC-6 cells, ranging from 80.0 to 99% of cell viability. The release of FFA containing the ingested GNC suspension and GNC–olive oil emulsion had about a 30% reduction compared to that without the GNC digestion solution. The FFA and triglyceride permeability through the HIEC-6 intestinal epithelium monolayer were deceased in the digesta containing the ingested GNC and emulsion. This work indicated that GNC represented a significantly critical role and properties in the GI tract and reduced lipid digestion and absorption. This GNC could be utilized as an alternative food additive or supplement in fatty food for weight control due to their inhibition of lipid digestibility and assimilation.

Published

2023

2. Anti-obesity potential of glutinous black rice bran extract: Anti-adipogenesis and lipolysis induction in 3T3-L1 adipocyte model

Author

Warathorn Chumchoochart and Khaetthareeya Sutthanut

Subjects

anti-obesity, anti-adipogenesis, lipolysis induction, antioxidation, glutinous black rice bran, Technology, Technology (General), T1-995, Science, Science (General), Q1-390

Abstract

An ethanolic glutinous black rice bran extract (RBE) was prepared and used in the experiments to determine the phenolic and flavonoid contents, antioxidation using DPPH and TBARS assay, anti-adipogenesis, and lipolysis induction in a 3T3-L1 pre-adipocyte model to discover its anti-obesity potential. The results showed that RBE was composed of phenolics, flavonoids, and anthocyanins and showed antioxidative activities (8.58±0.14 mg Vit C eq/g extract and 6.06±0.49 mg BHT eq/g extract). Interestingly, its anti-obesity potential was demonstrated in the interruption of the adipocyte life cycle, i.e. a significant anti-adipogenesis effect in the reduction of lipid accumulation (50.86±3.26 to 97.06±8.09% of the negative control, and triglyceride content in 3T3-L1 pre-adipocytes (36.89±2.08 to 90.56±0.67% of the negative control), and lipolysis induction (relative glycerol content 117.62±1.44 and 163.72±10.18% of control). Therefore, implementation into obesity therapy requires further research.

Published

2020

3. Integrated Biobased Processes for Nanocellulose Preparation from Rice Straw Cellulose

Author

Sirirat Jirathampinyo, Warathorn Chumchoochart, and Jidapha Tinoi

Subjects

nanocellulose, rice straw, ultrasonication, oxalic acid hydrolysis, biobased process, amorphous nanocellulose, cellulose, Process Chemistry and Technology, Chemical Engineering (miscellaneous), Bioengineering

Abstract

High-potential nanomaterials were derived from rice straw using the integrated biobased processes of enzymatic hydrolysis with green organic acid hydrolysis assisted with ultrasonication pretreatment. The optimization condition of nanocellulose preparation by enzymatic hydrolysis via central composite design (CCD) achieved a maximum nanocellulose content of 32.37 ± 0.47% using a cellulase concentration of 107.06 U/mL and 0.13% (w/w) of rice straw cellulose. The ultrasonication-assisted pretreatment prior to enzymatic hydrolysis improved nanocellulose preparation to 52.28 ± 1.55%. Integration with oxalic acid hydrolysis increased the nanocellulose content to 64.99 ± 0.16%. Granular nanocellulose was obtained and consisted of a 105–825 nm nanosize with a zeta potential value of −34.5 mV, and nanocellulose suspension showed high stability without aggregation. In addition, the remaining rice straw cellulose after oxalic acid was microcrystalline nanocellulose. All prepared nanocellulose represented a functional group as original cellulose but had a low crystallinity index (CrI) of 15.68% that could be classified as amorphous nanocellulose. Based on their characteristics, all nanocellose could be further applied in food, cosmetics, and pharmaceuticals. Moreover, the results indicated that the rice straw could be an alternative non-edible cellulose source for preparing potential nanocellulose via a controlled hydrolysis process.

Published

2023