研究成果

第 1 到 88 筆結果,共 88 筆。

公開日期標題作者來源出版物scopusWOS全文
12024Size-selective adhesion of calcium oxalate monohydrate crystals to lipid membranesCui, Ziyu; Chin, Che Lun; Kurniawan, Akhtar Fikri; Huang, Ching-Chun; Huang, Ling Ting; LING CHAO Journal of Materials Chemistry B
22023Using the Water Absorption Ability of Dried Hydrogels to Form Hydrogel-Supported Lipid BilayersChin, Che Lun; Huang, Lu Jan; Lu, Zheng Xian; Weng, Wei Chun; LING CHAO Gels00
32023Non-Electroneutrality Generated by Bacteriorhodopsin-Incorporated Membranes Enhances the Conductivity of a Gelatin Memory DeviceChiu, U-Ting; Lee, Bo-Fan; Ko, Ling-Ning; CHII-SHEN YANG ; LING CHAO Gels (Basel, Switzerland)00
42022Label-free detection of transport kinetics and inhibitor binding of membrane transport proteins with a two-mode plasmonic sensorCHIA-WEI KUO; Kuo, Tse Han; Lee, Hui An; Lin, Yu Ting; Kuo, Cheng Jung; Hsiao, Kai Hung; Yang, Meng Hua; Tanady, Kevin; Chang, Shu Yu; Lin, Tzy Rong; LING CHAO Biosensors and Bioelectronics: X10
52019Active Transport of Membrane Components by Dynamic Min Protein WavesShih, Yu-Ling; Huang, Ling-Ting; Tu, Yu-Ming; Lee, Bo-Fan; Bau, Yu-Chiuan; Hong, Chia Yee; Lee, Hsiao-Lin; Shih, Yan-Ping; Hsu, Min-Feng; Chen, Jui-Szu; Lu, Zheng-Xin; Chao, Ling; LING CHAO Biophysical Journal1
62019Sensing Ability and Formation Criterion of Fluid Supported Lipid Bilayer Coated Graphene Field-Effect TransistorsHu, S.-K.; Lo, F.-Y.; Hsieh, C.-C.; Chao, L. ; CHIH-CHEN HSIEH ACS Sensors
72019Active Transport of Membrane Components by Self-Organization of the Min ProteinsShih Y.-L.; Huang L.-T.; Tu Y.-M.; Lee B.-F.; Bau Y.-C.; Hong C.Y.; Lee H.-L.; Shih Y.-P.; Hsu M.-F.; Lu Z.-X.; Chen J.-S.; Chao L. Biophysical Journal98
82019Electron transfer through protein-bound water and its bioelectronic applicationChiu U.-T.; Chao L. Biosensors and Bioelectronics55
92019Graphene Memory Based on a Tunable Nanometer-Thin Water LayerChiu U.-T.; Lee B.-F.; Hu S.-K.; Yu T.-F.; Lee W.-Y.; Chao L. Journal of Physical Chemistry C88
102019Constructing Supported Cell Membranes with Controllable OrientationLyu S.-W.; Wang J.-F.; Chao L. Scientific Reports22
112017Controlling membrane protein topology on a supported plasma membrane platformShao-Wei Lyu; Ling Chao 
122017Using cell membrane blebs induced by hypertonic buffer to form supported membrane platforms with native membrane proteinsShao-Wei Lyu; Ling Chao 
132017Construction and control of 3D porous structure based on vapor deposition on sublimation solidsTung H.-Y.; Sun T.-P.; Sun H.-Y.; Guan Z.-Y.; Hu S.-K.; Chao L. ; HSIEN-YEH CHEN Applied Materials Today1617
142017Using a Light-Driven Proton Pump Protein to Develop a Reduction-Oxidation Reaction CellChiu, U.-Ting; Chao, Ling; LING CHAO Biophysical Journal0
152017Using Magnetic Field to Purify Membrane Proteins in Supported Cell Plasma MembranesHsiao, Kai-Hung; Chao, Ling; LING CHAO Biophysical Journal0
162017Using a Light-Driven Proton Pump Protein to Develop Devices for Photocurrent GenerationU-Ting Chiu; Ling Chao 
172017Rupturing Giant Plasma Membrane Vesicles to Form Micron-sized Supported Cell Plasma Membranes with Native Transmembrane ProteinsChiang P.-C.; Tanady K.; Huang L.-T.; Chao L. Scientific Reports1815
182017Using Magnetic Field to Move Membrane Proteins in Supported Cell Plasma MembranesKai-Hung Hsiao; Ling Chao 
192017Using Magnetic Field to Move Membrane Proteins in Supported Cell Plasma MembranesKai-Hung Hsiao; Ling Chao 
202017Development of a Surface Plasmon Resonance and Plasmon-Waveguide Resonance Combined Chip for Studying the Transport Behaviors of Cell Membrane TransportersLin, Yu-Ting; Chao, Ling; LING CHAO Biophysical Journal0
212016Development of lipid bilayer platforms for performing various separation processes to purify cell membrane bound speciesLing Chao 
222016Cytosolic Transport of Nanoparticles through Pressurized Plasma Membranes for Molecular Delivery and Amplification of Intracellular FluorescenceKaizuka Y.; Ura T.; Lyu S.; Chao L. ; Henzie J.; Nakao H.Langmuir11
232016Development of Cell Plasma Membrane Platforms to Study Membrane ProteinsJou-Fang Wang; Ling Chao 
242016The flow patterning capability of localized natural convectionHuang L.-T.; Chao L. Physical Chemistry Chemical Physics22
252016Pattern Resolution of Flow Induced by Spatially-Designed Nature ConvectionLing-Ting Huang; Ling Chao 
262016Using plasma waveguide resonance spectroscopy to study the conformational change of membrane proteinsTing-Chun Lu; Ling Chao 
272016Using Magnetic Field to Purify Membrane Proteins in Supported Cell Plasma MembranesKai-Hung Hsiao; Ling Chao 
282016BIOLOGIC SENSING PLATFORMS AND METHODS OF FABRICATING THE SAMEChung-Ta Han; LING CHAO 
292016Membrane species mobility under in-lipid-membrane forced convectionHu S.-K.; Huang L.-T.; Chao L. Soft Matter67
302016Nonspecific Binding Domains in Lipid Membranes Induced by Phospholipase A2Hong C.Y.; Han C.-T.; Chao L. Langmuir1818
312016Using Cell Membrane Blebs Induced by Hypertonic Buffer to Form Supported Membrane Platforms with Native Membrane ProteinsShao-Wei Lyu; Ling Chao 
322016Development of lipid bilayer platforms for performing various separation processes to purify cell membrane bound speciesLing Chao 
332016Development of a surface plasmon resonance and plasmon-waveguide resonance combinbed chip for studying the transport behaviors of cell membrane transport proteinsYu-Ting Lin; Cheng-Jung Kuo; Ling Chao 
342016Using Giant Plasma Membrane Vesicles from Cells to form Supported Lipid BilayersPo-Chieh Chiang; Ling Chao 
352016Non-Specific Binding Site on Lipid Membrane Induced by Phospholipase A2Hong-Chia Yee; Ling Chao 
362016Development of a surface plasmon resonance and plasmon-waveguide resonance combined chip for studying the transport behaviors of cell membrane transport proteinsYu-Ting Lin; Cheng-Jung Kuo; Ling Chao 
372015Developing Supported Lipid Bilayer Platforms as a Drug Screening ToolLing Chao 
382015Resolving Ability of a Patterned Flow System Induced by Spatailly-Desinged Natural convectionLing-Ting Huang; Ling Chao 
392015CHIP FOR MONITORING TRANSPORTATION BEHAVIOR AND METHOD FOR MONITORING TRANSPORTATION BEHAVIOR WITH THE SAMECheng-Rung Kuo; LING CHAO 
402015Resolving Power of Flow Patterns Induced by Natural ConvectionLing-Ting Huang; Ling Chao 
412015Studying Hydrodynamic and Induced Drag Forces on Cell Membrane Embedded Species in Supported Lipid Bilayers.Shu-Kai Hu; Ling Chao 
422015Transport Phenomena of Membrane Species in 2-D Lipid Membranes under Hydrodynamic Force above the MembraneShu-Kai Hu; Ling Chao 
432015Using a patterned grating structure to create lipid bilayer platforms insensitive to air bubblesHan C.-T.; Chao L. Lab on a Chip22
442015Study of Min Protein-Induced Membrane Waves in vitroTu, Yu-Ming; Chao, Ling; Shih, Yu-Ling; Lee, Hsiao-Lin; LING CHAO Biophysical Journal0
452015Mobile lipid bilayers on gold surfaces through structure-induced lipid vesicle rupturePeng P.-Y.; Chiang P.-C.; Chao L. Langmuir1010
462015Studying Template Formation on Supported Lipid Bilayers Induced by Phospholipase A2Hong Chia Yee; Ling Chao 
472015Non-Specific Binding Site on Lipid Membranes Induced by Phospholipase A2Hong Chia Yee; Ling Chao 
482015Studying Hydrodynamic and Induced Drag Forces on Cell Membrane Embedded Species in Supported Lipid BilayersShu-Kai Hu; Ling Chao 
492015Using Surface Plasmon Resonance and Plasmon Waveguide Resonance to Study Glucose Transporter BehaviorLing Chao 
502015Studying Hydrodynamic and Induced Drag Forces on Cell Membrane Embedded Species in Supported Lipid Bilayers.Shu-Kai Hu; Ling Chao 
512014Creating Air-Stable Supported Lipid Bilayers by Physical Confinement Induced by Phospholipase A(2)Han, Chung-Ta; LING CHAO Acs Applied Materials & Interfaces1414
522014Mechanism Study of Min Protein-Induced Membrane Waves in vitroYu-Ming Tu; Hsiao-Lin Lee; Yu-Ling Shih; Ling Chao 
532014Using Surface Plasmon Resonance to Study Species Transport across Lipid MembranesCheng-Jung Guo; Ling Chao 
542014Using Giant Plasma Membrane Vesicles from Cells to form Supported Lipid BilayersPo-Chieh Chiang; Ling Chao 
552014Phase segregation of polymerizable lipids to construct filters for separating lipid-membrane-embedded speciesHu S.-K.; Chen Y.-M.; Chao L. Biomicrofluidics22
562014Controlling lipid membrane conformations on nanograting structured supportsLing Chao 
572014Min Proteins from E-coil Induce Membrane Waves on Supported Lipid BilayersYu-Ming Tu; Hsiao-Lin Lee; Yu-Ling Shih; Ling Chao 
582014Controlling lipid membrane conformations on nanograting structured supportsPeng, Po-Yu; Chiang, Po-Chieh; Chao, Ling; LING CHAO Abstracts of Papers of the American Chemical Society
592014Creating Free-Standing Lipid Bilayers on Fused Silica Substrates with Nanograting StructurePeng, Po-Yu; Chiang, Po-Chieh; Chao, Ling; LING CHAO Biophysical Journal0
602014Controlling Lipid Membrane Conformation on Solid SupportsLing Chao 
612014Study of Min Protein-Induced Membrane Waves in vitroYu-Ming Tu; Hsiao-Lin Lee; Yu-Ling Shih; Ling Chao 
622014Phase segregation of polymerizable lipids to construct sieves for separating lipid-membrane-embedded speciesShu-Kai Hu; Ling Chao 
632014Min Protein-Induced Membrane Waves in vitroYu-Ming Tu; Hsiao-Lin Lee; Yu-Ling Shih; Ling Chao 
642014Controllable occurrence of free-standing lipid membranes on nanograting structured supportsPeng P.-Y.; Chiang P.-C.; Chao L. ACS Applied Materials and Interfaces76
652014Resolving Power of Flow Patterns Induced by Natural ConvectionLing-Ting Huang; Ling Chao 
662014The Transport Phenomena of Membrane Species in 2-D Lipid Membranes under Hydrodynamic Force above the MembraneShu-Kai Hu; Ling Chao 
672014Using Spatially-Designed Heat Source to Control FlowLing-Ting Huang; Ling Chao 
682013Constructing 2?D Packed Beds in Supported Lipid Bilayers for Separating Cell Membrane Associated SpeciesShu-Kai Hu; Hsun-Yen Mao; Ling Chao 
692013Using Spatially-Designed Heat Source to Control Flow Patterns Induced by Natural ConvectionLing-Ting Huang; Ling Chao 
702013Tunable Nucleation Time of Functional Sphingomyelinase¡VLipid ComplexCharng-Yu Lin; Ling Chao 
712013Devices for Sorting, Classifying, and Assaying Partition Behavior of Cell Membrane Biomolecules and Methods Based ThereonSusan Daniel; LING CHAO 
722013Using Crosslinkable Diacetylene Phospholipids to Construct Two-Dimensional Packed Beds in Supported Lipid Bilayer Separation PlatformsShu-Kai Hu; Hsun-Yen Mao; Ya-Ming Chen; Ling Chao 
732013Controlling Lipid Membrane Conformation over Nano-grating Structured SupportPo-Yu Peng; Po-Chieh Chiang; Ling Chao 
742013Using crosslinkable diacetylene phospholipids to construct two-dimensional packed beds in supported lipid bilayer separation platformsHu S.-K.; Hsiao S.-W.; Mao H.-Y.; Chen Y.-M.; Chang Y.; Chao L. Science and Technology of Advanced Materials64
752013Two-dimensional continuous extraction in multiphase lipid bilayers to separate, enrich, and sort membrane-bound speciesChao L. ; Richards M.J.; Hsia C.-Y.; Daniel S.Analytical Chemistry1110
762013Development of 2-d Packed-bed Lipid Bilayer Platforms to Purify Cell Membrane Associated SpeciesShu-Kai Hu; Hsun-Yen Mao; Ling Chao 
772013Using Crosslinkable Diacetylene Phospholipids to Construct Two-Dimensional Packed Beds in Supported Lipid Bilayer Separation PlatformsShu-Kai Hu; Hsun-Yen Mao; Ling Chao 
782013Using Phospholipase A2 to Create Air-stable Supported Lipid BilayersChung-Ta Han; Ling Chao 
792013Using Supported Lipid Bilayer Platforms to Study Phase Dynamics Induced by Phospholipase A2Chung-Ta Han; Ling Chao 
802013Using Phospholipase A2 to Create Air-stable Supported Lipid BilayersChung-Ta Han; Ling Chao 
812013Tunable Nucleation Time of Functional Enzyme-Lipid Complex Studied by Membrane Array Statistic ToolCharng-Yu Lin; Ling Chao 
822013Tunable nucleation time of functional sphingomyelinase-lipid features studied by membrane array statistic toolLin C.-Y.; Chao L. Langmuir66
832013Membrane Arrays to Study Phase Transformation Phenomena of Lipid Membranes Induced by EnzymesCharng-Yu Lin; Ling Chao 
842013Using Phospholipase A2 to Create Air-stable Supported Lipid BilayersChung-Ta Han; Ling Chao 
852011Two-dimensional solvent-mediated phase transformation in lipid membranes induced by sphingomyelinaseChao L. ; Chen F.; Jensen K.F.; Hatton T.A.Langmuir77
862011Measuring the partitioning kinetics of membrane biomolecules using patterned two-phase coexistant lipid bilayersChao L. ; Daniel S.Journal of the American Chemical Society2224
872011Supported lipid bilayer electrophoresis for separation and analytical studies of cell membrane biomoleculesDaniel S.; Chao L. ACS Symposium Series10
882010Sphingomyelinase-induced phase transformations: causing morphology switches and multiple-time-domain ceramide generation in modelMembranes R.; Chao L. ; Gast A.P.; Alan Hatton T.; Jensen K.F.Langmuir1923