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Item Metadata only Biogas upgrading towards acetic acid production using Clostridium thailandense supplemented with granular activated carbon (GAC) and L-arginine: A genomic analysis approach(2024-12-01) Chaikitkaew S.; Wongfaed N.; Mamimin C.; O-Thong S.; Reungsang A.; Chaikitkaew S.; Mahidol UniversityThis study explores the impact of granular activated carbon (GAC) and L-arginine supplementation on biogas upgrading and acetic acid production employing Clostridium thailandense. GAC and L-arginine concentrations ranged from 0 to 20 g/L and 0 to 5Publication Metadata only Hydrogen sulfide removal using granular activated carbon biofiltration inoculated with Alcaligenes faecalis T307 isolated from concentrated latex wastewater(2010-08-01) Cheerawit Rattanapan; Duangporn Kantachote; Rong Yan; Piyarat Boonsawang; Mahidol University; Prince of Songkla University; Nanyang Technological UniversityA novel biofiltration of pure culture was developed for H2S removal from synthetic biogas using Alcaligenes faecalis T307 immobilized on granular activated carbon (GAC) as packing materials. The effect of operating parameters, including inlet H2SItem Metadata only Using alginate-based granular activated carbon hybridized with silica derived from sugarcane bagasse residues for adsorption of uremic toxins in dialysate(2025-09-01) Arpasopana N.; Boontanon S.K.; Abdulroman N.; Rasmee T.; Prachakittikul P.; Sutthasupa S.; Worasuwannarak N.; Srifa A.; Koo-amornpattana W.; Klaitong P.; Chaiwat W.; Arpasopana N.; Mahidol UniversityIn a wearable artificial kidney system, regeneration of spent dialysate solution, containing major uremic toxins such as creatinine and uric acid, is necessary for waste mitigation. In this study, hybrid granular activated carbons (GACs) of powderedItem Metadata only Advancing Organ-on-Chip Models With a Sacrificial Granular Hydrogel Strategy for Enhanced Permeability and Biomimicry(2025-01-01) Caires H.R.; Castillo-Fernández Ó.; Sima N.; Magalhães M.V.; Benavent-Claró A.; Masó-Castro N.; Roobsoong W.; Fernandez-Becerra C.; Hernández-Machado A.; del Portillo H.A.; Barrias C.C.; Caires H.R.; Mahidol University, their small mesh size may restrict pathogen migration and cell–pathogen interactions, both critical for establishing infection on-chip. To overcome this limitation, this work develops a “reversed” granular hydrogel strategy that creates interconnectedPublication Metadata only Modification of tapioca starch by non-chemical route using jet atmospheric argon plasma(2014-02-15) Rungtiwa Wongsagonsup; Panakamol Deeyai; Weerawut Chaiwat; Sawanee Horrungsiwat; Kesini Leejariensuk; Manop Suphantharika; Asira Fuongfuchat; Somsak Dangtip; Mahidol University; Thailand National Science and Technology Development Agency; South Carolina Commission on Higher EducationNon-chemical modification of tapioca starch was investigated using jet atmospheric argon plasma treatment. Two forms of starch slurry, i.e. granular starch (G) and cooked starch (C), were jet-treated by argon plasma generated by supplying input