公開日期 | 標題 | 作者 | 來源出版物 | scopus | WOS | 全文 |
2022 | Silver nanoparticle-deposited whey protein isolate amyloid fibrils as catalysts for the reduction of methylene blue | Lai Y.-R; Lai J.-T; STEVEN SHENG-SHIH WANG ; Kuo Y.-C; Lin T.-H. | International Journal of Biological Macromolecules | 10 | 5 | |
2016 | Small angle x-ray scattering characterization of multifunctional iron oxide-pluronic nanocarriers: Effect of temperature and drug encapsulation | Dehvari, K.; Lin, K.-S.; Wang, S.S.-S.; STEVEN SHENG-SHIH WANG | Nanoscience and Nanotechnology Letters | | | |
2009 | Stability of hen egg white lysozyme during denaturation is enhanced by pretreatment with supercritical carbon dioxide | Wang, S.S.-S.; Chao, H.-S.; Liu, H.-L.; HWAI-SHEN LIU ; Wang S.S.-S. | Journal of Bioscience and Bioengineering | 18 | 15 | |
2006 | Step change of mobile phase flow rates to enhance protein folding in size exclusion chromatography | STEVEN SHENG-SHIH WANG ; Chang, Che-Kuei; HWAI-SHEN LIU | Biochemical Engineering Journal 29(2006), 2–11 | 12 | 21 | |
2014 | Structural characterization and adsorption properties of pluronic F127 onto iron oxides magnetic nanoparticles | Dehvari, K.; Lin, K.-S.; Wang, S.S.-S.; STEVEN SHENG-SHIH WANG | Journal of Nanoscience and Nanotechnology | | | |
2003 | A study on protein concentration by foam fractionation | Wang S.S.-S. ; Liu H.-S. | Journal of the Chinese Institute of Chemical Engineers | 2 | | |
2004 | A study on the refolding of lysozyme using fed-batch and step-addition strategies | Wang S.S.-S. ; Chang C.-K.; Liu H.-S. | Journal of the Chinese Institute of Chemical Engineers | 2 | | |
2014 | Suppression of Amyloid Fibril Formation of Lysozyme by Erioglaucine | Y. H. Chen S. S.-S. Wang | | | | |
2015 | Suppression of Amyloid Fibril Formation of Lysozyme by Erioglaucine, | Y. H. Chen; S. S.-S. Wang | | | | |
2014 | Synthesis and Characterization of Functional Component-Containing Lotion by Double Emulsion Method | H. Y. Duan; C.-Y. Kuo; M.Y. Chang; C. Shen; S.-J. Lin; C. A. Dai; S. S.-S. Wang ; W. Y. Chiu; J. T. Lai | | | | |
2014 | Synthesis and characterization of p(2-hydroxyethyl methacrylate-co-methacrylic acid) hydrogel | G. Chen; S. S.-S. Wang ; Meng-Jiy Wang | | | | |
2015 | Synthesis and characterization of p(2-hydroxyethyl methacrylate-co-methacrylic acid) hydrogel, | G. Chen; S. S.-S. Wang ; M. J. Wang | | | | |
2015 | Synthesis and Characterization of Resveratrol-Containing Lotion by Double Emulsion Method | H. Y. Duan; C. Y. Kuo; M. Y. Chang; C. S.; S. J. Lin; C. A. Dai; S. S.-S. Wang ; W. Y. Chiu; J. T. Lai | | | | |
2014 | Synthesis and Self-Assembly of Bioactive Saccharide-Conjugated Polypeptide Micelles for Acid-Triggered Drug Release | Y. D. Chen; Y. C. Huang; S. C. How; J. S. Jan; S. S.-S. Wang | | | | |
2014 | Synthesis and Self-assembly of Bioactive Saccharide-Conjugated Polypeptide Micelles for Acid-Triggered Drug Release | Y. D. Chen; Y. C. Huang; S. C. How; J. S. Jan; S. S.-S. Wang | | | | |
2023 | Ultrafine nitrogen-doped graphene quantum dot structure and antibacterial activities against Bacillus subtilis 3610 | Dwitya, Sat Septian; Hsueh, Yi Huang; STEVEN SHENG-SHIH WANG ; Lin, Kuen Song | Materials Chemistry and Physics | 4 | 5 | |
2015 | Understanding the Structure Transition and Possible Amyloid-Fibril Formation Mechanism of Human £^D-Crystallin Associated with Cataract | J. W. Wu; C. K. Chang; H. S. Liu; S. S.-S. Wang | | | | |
2015 | Using Doxorubicin-encapsulated poly(L-glutamic acid)-b-polyglycine-g-lactobionolactone micelles as therapeutic agents for Hepatocellular carcinoma | S. C. How; C. C. Chang; J. S. Jan; S. S.-S. Wang | | | | |
2015 | Using Doxorubicin-loaded poly(L-glutamic acid)-b-polyglycine-g-lactobionolactone micelles as potential therapeutic agents for Hepatocellular carcinoma | S. C. How; C. C. Chang; J. S. Jan; S. S.-S. Wang | | | | |
2011 | Using isothermal titration calorimetry to real-time monitor the heat of metabolism: A case study using PC12 cells and A£](1-40) | Wang S.S.-S. ; Lin M.-S.; Chen S.-L.; Chang Y.; Ruaan R.-C.; Chen W.-Y. | Colloids and Surfaces B: Biointerfaces | 2 | 2 | |