臺大學術典藏 |
2022-03-22T08:29:15Z |
Succinic acid fermentation with immobilized Actinobacillus succinogenes using hydrolysate of carbohydrate-rich microalgal biomass
|
Chiang Y.-Y;Nagarajan D;Lo Y.-C;Chen C.-Y;Ng I.-S;Chang C.-H;Lee D.-J;Chang J.-S.; Chiang Y.-Y; Nagarajan D; Lo Y.-C; Chen C.-Y; Ng I.-S; Chang C.-H; Lee D.-J; Chang J.-S.; DUU-JONG LEE |
臺大學術典藏 |
2022-03-22T08:29:15Z |
Succinic acid fermentation with immobilized Actinobacillus succinogenes using hydrolysate of carbohydrate-rich microalgal biomass
|
Chiang Y.-Y;Nagarajan D;Lo Y.-C;Chen C.-Y;Ng I.-S;Chang C.-H;Lee D.-J;Chang J.-S.; Chiang Y.-Y; Nagarajan D; Lo Y.-C; Chen C.-Y; Ng I.-S; Chang C.-H; Lee D.-J; Chang J.-S.; DUU-JONG LEE |
臺大學術典藏 |
2022-03-22T08:29:15Z |
Succinic acid fermentation with immobilized Actinobacillus succinogenes using hydrolysate of carbohydrate-rich microalgal biomass
|
Chiang Y.-Y;Nagarajan D;Lo Y.-C;Chen C.-Y;Ng I.-S;Chang C.-H;Lee D.-J;Chang J.-S.; Chiang Y.-Y; Nagarajan D; Lo Y.-C; Chen C.-Y; Ng I.-S; Chang C.-H; Lee D.-J; Chang J.-S.; DUU-JONG LEE |
臺大學術典藏 |
2022-03-22T08:29:15Z |
Succinic acid fermentation with immobilized Actinobacillus succinogenes using hydrolysate of carbohydrate-rich microalgal biomass
|
Chiang Y.-Y;Nagarajan D;Lo Y.-C;Chen C.-Y;Ng I.-S;Chang C.-H;Lee D.-J;Chang J.-S.; Chiang Y.-Y; Nagarajan D; Lo Y.-C; Chen C.-Y; Ng I.-S; Chang C.-H; Lee D.-J; Chang J.-S.; DUU-JONG LEE |
臺大學術典藏 |
2022-03-22T08:26:24Z |
Succinic acid fermentation with immobilized Actinobacillus succinogenes using hydrolysate of carbohydrate-rich microalgal biomass
|
Chiang Y.-Y;Nagarajan D;Lo Y.-C;Chen C.-Y;Ng I.-S;Chang C.-H;Lee D.-J;Chang J.-S.; Chiang Y.-Y; Nagarajan D; Lo Y.-C; Chen C.-Y; Ng I.-S; Chang C.-H; Lee D.-J; Chang J.-S.; DUU-JONG LEE |
臺大學術典藏 |
2022-03-22T08:26:24Z |
Succinic acid fermentation with immobilized Actinobacillus succinogenes using hydrolysate of carbohydrate-rich microalgal biomass
|
Chiang Y.-Y;Nagarajan D;Lo Y.-C;Chen C.-Y;Ng I.-S;Chang C.-H;Lee D.-J;Chang J.-S.; Chiang Y.-Y; Nagarajan D; Lo Y.-C; Chen C.-Y; Ng I.-S; Chang C.-H; Lee D.-J; Chang J.-S.; DUU-JONG LEE |
國立成功大學 |
2022 |
Prospective and challenges of live bacterial therapeutics from a superhero Escherichia coli Nissle 1917
|
Effendi, S.S.W.;Ng, I.-S. |
國立成功大學 |
2022 |
Adaptive laboratory evolution and metabolic regulation of genetic Escherichia coli W3110 toward low-carbon footprint production of 5-aminolevulinic acid
|
Ting, W.-W.;Ng, I.-S. |
國立成功大學 |
2021 |
Stepwise optimization of genetic RuBisCO-equippedEscherichia colifor low carbon-footprint protein and chemical production
|
Tan, S.-I.;Ng, I.-S. |
國立成功大學 |
2021 |
Molecular mechanism of arachidonic acid biosynthesis in Porphyridium purpureum promoted by nitrogen limitation
|
Jiao, K.;Xiao, W.;Shi, X.;Ho, S.-H.;Chang, J.-S.;Ng, I.-S.;Tang, X.;Sun, Y.;Zeng, X.;Lin, Lin L. |
國立成功大學 |
2020 |
Effective purification of lysozyme from chicken egg white by tris(hydroxymethyl)aminomethane affinity nanofiber membrane
|
Liu, B.-L.;Ooi, C.W.;Ng, I.-S.;Show, P.L.;Lin, K.-J.;Chang, Y.-K. |
國立成功大學 |
2020 |
Development of chromosome-based T7 RNA polymerase and orthogonal T7 promoter circuit in Escherichia coli W3110 as a cell factory
|
Ting, W.-W.;Tan, S.-I.;Ng, I.-S. |
國立成功大學 |
2020 |
Efficient biotransformation of L-lysine into cadaverine by strengthening pyridoxal 5’-phosphate-dependent proteins in Escherichia coli with cold shock treatment
|
Xue, C.;Hsu, K.-M.;Ting, W.-W.;Huang, S.-F.;Lin, H.-Y.;Li, S.-F.;Chang, J.-S.;Ng, I.-S. |
國立成功大學 |
2020 |
Antibacterial efficacy of chitosan- and poly(hexamethylene biguanide)-immobilized nanofiber membrane
|
Ng, I.-S.;Ooi, C.W.;Liu, B.-L.;Peng, C.-T.;Chiu, Chiu C.-Y.;Chang, Y.-K. |
國立成功大學 |
2020 |
High-level L-lysine bioconversion into cadaverine with enhanced productivity using engineered Escherichia coli whole-cell biocatalyst
|
Leong, Y.K.;Chen, Chen C.-H.;Huang, S.-F.;Lin, H.-Y.;Li, S.-F.;Ng, I.-S.;Chang, J.-S. |
國立成功大學 |
2020 |
Optimization of three-phase fluidized bed cell disruptor for the release of alcohol dehydrogenase from baker's yeast
|
Chang, Y.-K.;Ooi, C.-W.;Liew, P.-E.;Ng, I.-S.;Huang, Y.-N.;Chen, Z.-H. |
國立成功大學 |
2020 |
Facilitating the enzymatic conversion of lysineto cadaverine in engineered Escherichia coli with metabolic regulation by genes deletion
|
Huang, C.-Y.;Ting, W.-W.;Chen, Y.-C.;Wu, P.-Y.;Dong, C.-D.;Huang, S.-F.;Lin, H.-Y.;Li, S.-F.;Ng, I.-S.;Chang, J.-S. |
國立成功大學 |
2019 |
Purification of lysozyme from chicken egg white using nanofiber membrane immobilized with Reactive Orange 4 dye
|
Ng, I.-S.;Song, C.P.;Ooi, C.W.;Tey, B.T.;Lee, Y.-H.;Chang, Y.-K. |
國立成功大學 |
2019 |
Enhancement of C-phycocyanin purity using negative chromatography with chitosan-modified nanofiber membrane
|
Ng, I.-S.;Tang, M.S.Y.;Show, P.L.;Chiou, Z.-M.;Tsai, J.-C.;Chang, Y.-K. |
國立成功大學 |
2019 |
Antibacterial activity of quaternized chitosan modified nanofiber membrane
|
Cheah, W.Y.;Show, P.-L.;Ng, I.-S.;Lin, G.-Y.;Chiu, Chiu C.-Y.;Chang, Y.-K. |
國立成功大學 |
2018 |
Biorefining of protein waste for production of sustainable fuels and chemicals
|
Li, S.-Y.;Ng, I.-S.;Chen, P.T.;Chiang, Chiang C.-J.;Chao, Y.-P. |
國立成功大學 |
2017 |
Enhanced integration of large DNA into E. coli chromosome by CRISPR/Cas9
|
Chung, M.-E.;Yeh, I.-H.;Sung, L.-Y.;Wu, M.-Y.;Chao, Y.-P.;Ng, I.-S.;Hu, Y.-C. |
國立成功大學 |
2017 |
5-Aminolevulinic acid promotes arachidonic acid biosynthesis in the red microalga Porphyridium purpureum
|
Jiao, K.;Chang, J.;Zeng, X.;Ng, I.-S.;Xiao, Z.;Sun, Y.;Tang, X.;Lin, Lin L. |