Tik:Publications: Difference between revisions
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==Journal Publications== | ==Journal Publications== | ||
#Müller J., MacEachran D., Burd H., '''Sathitsuksanoh N.''', Bi C., Yeh Y.C., Lee TS., Hillson N., Chhabra S., Singer S., and Beller H. 2013. Engineering of Ralstonia eutropha H16 for Autotrophic and Heterotrophic Production of Methyl Ketones. Metab. Eng. (in press) | #Müller J., MacEachran D., Burd H., '''Sathitsuksanoh N.''', Bi C., Yeh Y.C., Lee TS., Hillson N., Chhabra S., Singer S., and Beller H. 2013. Engineering of Ralstonia eutropha H16 for Autotrophic and Heterotrophic Production of Methyl Ketones. '''''Metab. Eng.''''' (in press) | ||
#You C., Chen HG., Myung S.,'''Sathitsuksanoh N.''', Ma H., Zhang XZ., Li J., Zhang YHP. 2013. Enzymatic Transformation of Non-Food Cellulosic Materials to Value-Added Amylose. PNAS. (in press) | #You C., Chen HG., Myung S.,'''Sathitsuksanoh N.''', Ma H., Zhang XZ., Li J., Zhang YHP. 2013. Enzymatic Transformation of Non-Food Cellulosic Materials to Value-Added Amylose. '''''PNAS.''''' (in press) | ||
#Sun N., Liu H., '''Sathitsuksanoh N.''', Sawant M., Bonito A., Tran K.,Stavila V., George A., Sale K., Singh S., Simmons B. and Holmes B. 2013. Acid Catalyzed Hydrolysis of Switchgrass in Ionic Liquid and Separation of Sugars Using Liquid-Liquid Extraction. Biotechnol. Biofuels. (in press) | #Sun N., Liu H., '''Sathitsuksanoh N.''', Sawant M., Bonito A., Tran K.,Stavila V., George A., Sale K., Singh S., Simmons B. and Holmes B. 2013. Acid Catalyzed Hydrolysis of Switchgrass in Ionic Liquid and Separation of Sugars Using Liquid-Liquid Extraction. '''''Biotechnol. Biofuels.''''' (in press) | ||
#Groff D., George A., Sun N., '''Sathitsuksanoh N.''', Bokinsky G., Simmons B., Holmes B., Keasling J. 2013. Acid Enhanced Ionic Liquid Pretreatment of Biomass. Green Chem. (in press) | #Groff D., George A., Sun N., '''Sathitsuksanoh N.''', Bokinsky G., Simmons B., Holmes B., Keasling J. 2013. Acid Enhanced Ionic Liquid Pretreatment of Biomass. '''''Green Chem.''''' (in press) | ||
#Xu B., '''Sathitsuksanoh N.''', Tang Y., Udvardi M., Zhang J., Shen Z., Balota M., Harich K., Zhang YHP, Zhao B. 2012. Over-expressing LOV1 induced erect leaf, altered cell wall content and increased water use efficiency in switchgrass. PLOS One. 7(12): e47399 | #Xu B., '''Sathitsuksanoh N.''', Tang Y., Udvardi M., Zhang J., Shen Z., Balota M., Harich K., Zhang YHP, Zhao B. 2012. Over-expressing LOV1 induced erect leaf, altered cell wall content and increased water use efficiency in switchgrass. '''''PLOS One.''''' 7(12): e47399 | ||
#Hastrup AC, Howell C., Larsen FH, '''Sathitsuksanoh N.''', Goodell B., and Jellison J. 2012. Differences in crystalline cellulose modification due to degradation by brown and white rot fungi. Fungal Biol. 116(10): 1052-1063 | #Hastrup AC, Howell C., Larsen FH, '''Sathitsuksanoh N.''', Goodell B., and Jellison J. 2012. Differences in crystalline cellulose modification due to degradation by brown and white rot fungi. '''''Fungal Biol.''''' 116(10): 1052-1063 | ||
#'''Sathitsuksanoh N.''', Zhu Z., Zhang YHP. 2012. Cellulose Solvent-Based Pretreatment for Corn Stover and Avicel: Concentrated Phosphoric Acid versus Ionic Liquid [BMIM]Cl. Cellulose. 19(4) 1161-1172 | #'''Sathitsuksanoh N.''', Zhu Z., Zhang YHP. 2012. Cellulose Solvent-Based Pretreatment for Corn Stover and Avicel: Concentrated Phosphoric Acid versus Ionic Liquid [BMIM]Cl. '''''Cellulose.''''' 19(4) 1161-1172 | ||
#'''Sathitsuksanoh N.''', Zhu Z., and Zhang YHP. 2012. Cellulose solvent- and organic solvent-based lignocellulose fractionation enabled efficient sugar release from a variety of lignocellulosic feedstocks. Biores. Technol. 117: 228-233 | #'''Sathitsuksanoh N.''', Zhu Z., and Zhang YHP. 2012. Cellulose solvent- and organic solvent-based lignocellulose fractionation enabled efficient sugar release from a variety of lignocellulosic feedstocks. '''''Biores. Technol.''''' 117: 228-233 | ||
#You C., Zhang XZ., '''Sathitsuksanoh N.''', Lynd LR., Zhang YHP. 2012. Ex vivo cellulosome-microbe complexes expedite microbial cellulose utilization rate greatly especially on low-accessibility recalcitrant cellulose. Appl. Environ. Microbiol. 78(5):1437-1444 | #You C., Zhang XZ., '''Sathitsuksanoh N.''', Lynd LR., Zhang YHP. 2012. Ex vivo cellulosome-microbe complexes expedite microbial cellulose utilization rate greatly especially on low-accessibility recalcitrant cellulose. '''''Appl. Environ. Microbiol.''''' 78(5):1437-1444 | ||
#Xue B., Escamilla-Treviño L.L., '''Sathitsuksanoh N.''', Shen Z., Shen H., Zhang YHP, Dixon R., Zhao B., 2011. Silencing of 4-Coumarate: Coenzyme A ligase in switchgrass leads to reduced lignin content and improved fermentable sugar yields for biofuel production. '''''New Phytologist''''' (in press) | #Xue B., Escamilla-Treviño L.L., '''Sathitsuksanoh N.''', Shen Z., Shen H., Zhang YHP, Dixon R., Zhao B., 2011. Silencing of 4-Coumarate: Coenzyme A ligase in switchgrass leads to reduced lignin content and improved fermentable sugar yields for biofuel production. '''''New Phytologist''''' (in press) | ||
#Zhang XZ, '''Sathitsuksanoh N.''', Zhu ZG, Zhang YHP., 2011. One-Step Production of Lactate from Cellulose as Sole Carbon Source without Any Other Organic Nutrient by Recombinant Cellulolytic Bacillus subtilis. '''''Metabolic Engineering''''' (in press) | #Zhang XZ, '''Sathitsuksanoh N.''', Zhu ZG, Zhang YHP., 2011. One-Step Production of Lactate from Cellulose as Sole Carbon Source without Any Other Organic Nutrient by Recombinant Cellulolytic Bacillus subtilis. '''''Metabolic Engineering''''' (in press) |
Revision as of 21:07, 11 June 2013
Journal Publications
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