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£¨ 2 £© Ò»ÖÖÁ×Ëữëĸ»¼¯²ÄÁϼ°ÆäÖƱ¸·½·¨ÓëÓ¦ÓÃ, ·¢Ã÷, 2016, µÚ 3 ×÷Õß, רÀûºÅ: 201611019827.2
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£¨ 5 £© »ùÓÚ¶þëĵľۺÏÎï²ÄÁϼ°ÆäÔÚÌÇ·ÖÀëºÍÌÇëĸ»¼¯ÖеÄÓ¦ÓÃ, ·¢Ã÷, 2015, µÚ 3 ×÷Õß, רÀûºÅ: 201510688901.9
£¨ 6 £© Ò»ÖÖÓÃÓÚ¼ì²âÁ×Ëἡ´¼µÄ¶à¿×Ĥ²ÄÁϼ°ÆäÖƱ¸Óë¼ì²â·½·¨, ·¢Ã÷, 2018, µÚ 1 ×÷Õß, רÀûºÅ: 201611019314.1
£¨ 7 £© Ò»ÖÖ¸»¼¯¼ì²âÁ×Ëữµ°°×µÄ·½·¨, ·¢Ã÷, 2018, µÚ 1 ×÷Õß, רÀûºÅ: 201611018830.2
£¨ 8 £© º¬ÓжþôÇ»ù±½»ùµÄ»¯ºÏÎïÐÞÊεÄÁò»¯ÍÄÉÃײÄÁϼ°ÆäÔÚÌÇëĸ»¼¯ÖеÄÓ¦ÓÃ, ·¢Ã÷, 2017, µÚ 1 ×÷Õß, רÀûºÅ: 201710305583.2
£¨ 9 £© Ò»ÖÖ¶àëÄÀàÓ«¹â̽Õë¼°ÆäÖƱ¸·½·¨ÓëÓ¦ÓÃ, ·¢Ã÷, 2018, µÚ 1 ×÷Õß, רÀûºÅ: 201710152658.8
£¨ 10 £© Ò»ÖÖ´ÅÐԿǺ˽ṹÄÉÃ×Á£×Ó¼°ÆäÖƱ¸·½·¨ÓëÓ¦ÓÃ, ·¢Ã÷, 2016, µÚ 1 ×÷Õß, רÀûºÅ: 201610906821.0
£¨ 11 £© Ò»ÖÖ¶þëľÛÒÒÏ©ÑÇ°·¾ÛºÏÎï¼°ÆäÖƱ¸·½·¨ÓëÓ¦ÓÃ, ·¢Ã÷, 2017, µÚ 1 ×÷Õß, רÀûºÅ: ZL201510697730.6
£¨ 12 £© Ò»Öֲⶨµ¥ÌǶÔÓ³Ìå¹ýÁ¿ÖµµÄ·½·¨, ·¢Ã÷, 2016, µÚ 1 ×÷Õß, רÀûºÅ: ZL201510688055.0
£¨ 13 £© Ò»ÖÖÖÇÄÜÏìÓ¦ÐÔ¾ÛºÏÎïÐÞÊεĶà¿×Ĥ²ÄÁϼ°ÆäÖƱ¸·½·¨ºÍÓ¦ÓÃ, ·¢Ã÷, 2019, µÚ 1 ×÷Õß, רÀûºÅ: 201910071825.5
£¨ 14 £© Ò»ÖÖÖÇÄܾۺÏÎïÐÞÊζà¿×Ĥ²ÄÁϵÄÖƱ¸¼°ÆäÔÚ¸ÆÀë×Ó¼ì²âÖеÄÓ¦ÓÃ, ·¢Ã÷, 2019, µÚ 1 ×÷Õß, רÀûºÅ: 201910071850.3
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£¨ 16 £© Ò»¶ÔÓÐЧÒÖÖÆA¦Â£¨1-40£©¾Û¼¯ºÍÏËά»¯µÄÊÖÐÔÁ×Ö¬·Ö×Ó¼°ÆäÖƱ¸·½·¨ºÍÓ¦ÓÃ, ·¢Ã÷, 2019, µÚ 1 ×÷Õß, רÀûºÅ: 201910287626.8
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£¨1£© Smart Polymer¨CBased Calcium Ion-Actuated Nanochannel by Mimicking Biological Ca2+¨Cinduced Ca2+ Release Process, NPG Asia Materials, 2019, ͨѶ×÷Õß
£¨2£© CAMP-Modulated Biomimetic Ionic Nanochannels based on Smart Polymer, J. Mater. Chem. B, 2019, ͨѶ×÷Õß
£¨3£© Circularly polarized light modulated supramolecular self-assembly for an azobenzenebased chiral gel, RSC Advances, 2019, ͨѶ×÷Õß
£¨4£© Excellent Chemoselectivity of Pristine Nanocrystalline Cellulose Films Driven by Carbohydrate¨CCarbohydrate Interactions, ACS Appl. Mater. Interfaces, 2019, ͨѶ×÷Õß
£¨5£© Recent Advances in Hydrophilic Interaction Liquid Interaction Chromatography Materials for Glycopeptide Enrichment and Glycan Separation, TRAC Trends in Anal. Chem., 2019, µÚ 1 ×÷Õß
£¨6£© A biomimetic design for sialylated glycan-specific smart polymer., NPG Asia Materials, 2018, µÚ 1 ×÷Õß
£¨7£© New opportunities and challenges of smart polymers in post-translational modification proteomics., Adv. Mater., 2017, µÚ 1 ×÷Õß
£¨8£© Hydrogen bond based smart polymer for highly selective and tunable capture of multiply phosphorylated peptides., Nature Communications, 2017, µÚ 1 ×÷Õß
£¨9£© Developing an inositol phosphate-actuated nanochannel system by mimicking biological calcium ion channels., ACS Appl. Mater. Interfaces, 2017, ͨѶ×÷Õß
£¨10£© Exploring the role of molecular chirality in the photo-responsiveness of dipeptide-based gels., J. Mater. Chem. B, 2017, ͨѶ×÷Õß
£¨11£© Sialic acid-triggered macroscopic properties switching on a smart polymer surface., Appl. Surf. Sci., 2017, ͨѶ×÷Õß
£¨12£© Rapid and high-efficiency discrimination of different sialic acid species using dipeptide-based fluorescent sensors., Analyst, 2017, ͨѶ×÷Õß
£¨13£© Sialic Acid-Targeted Biointerface Materials and Bio-Applications., Polymers, 2017, ͨѶ×÷Õß
£¨14£© Sialic Acid-Responsive Polymeric Interface Material: From Molecular Recognition to Macroscopic Property Switching., Sci. Rep., 2017, ͨѶ×÷Õß
£¨15£© A novel aggregation-induced emission enhancement triggered by the assembly of a chiral gelator: from non-emissive nanofibers to emissive micro-loops., Chem. Commun., 2017, µÚ 1 ×÷Õß
£¨16£© Dipeptide-based carbohydrate receptors and polymers for glycopeptide enrichment and glycan discrimination., ACS Appl. Mater. Interfaces, 2016, µÚ 1 ×÷Õß
£¨17£© Bioinspired saccharide-saccharide interaction and smart polymer for specific enrichment of sialylated glycopeptides., ACS Appl. Mater. Interfaces, 2016, ͨѶ×÷Õß
£¨18£© Surface stiffness¡ªa parameter for Sensing the chirality of saccharides., ACS Appl. Mater. Interfaces, 2015, ͨѶ×÷Õß
£¨19£© Chiral effect at protein/ graphene interface: A bioinspired perspective to understand amyloid formation., J. Am. Chem. Soc., 2014, µÚ 1 ×÷Õß
£¨20£© Solvent-driven chiral- interaction reversion for organogel formation., Angew. Chem. Int. Ed., 2014, µÚ 1 ×÷Õß
£¨21£© Chirality-driven wettability switching and mass transfer., Angew. Chem. Int. Ed., 2014, µÚ 1 ×÷Õß
£¨22£© Transforming chiral signals into macroscopic properties of materials using chirality-responsive polymers., NPG Asia Materials, 2012, µÚ 1 ×÷Õß
£¨23£© Chirality triggered wettability switching on smart polymer surface., Adv. Mater., 2011, µÚ 1 ×÷Õß
£¨24£© Spatially controlled DNA nanopatterns by ¡°click¡± chemistry using oligonucleotides with different anchoring sites., J. Am. Chem. Soc., 2010, µÚ 1 ×÷Õß
£¨25£© Nucleotide responsive wettability on smart polymer surface., J. Am. Chem. Soc., 2009, µÚ 1 ×÷Õß
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£¨2£©Biomolecule-responsive polymer: From recognition to applications in post-translational modification proteomics µÚÊ®½ìÖйúµ°°×ÖÊ×éѧ´ó»á 2018-11-15
£¨3£©Biomolecule-responsive polymer: From recognition to applications in post-translational modification proteomics µÚ¾Å½ìÉϺ£¹ú¼Ê·ÖÎö»¯Ñ§ÑÐÌÖ»á 2018-10-31
£¨4£©ÖÇÄÜÉúÎï·ÖÀë½éÖÊ Öйú»¯Ñ§»áµÚ13½ìÈ«¹ú·ÖÎö»¯Ñ§Äê»á 2018-06-14
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£¨6£©ÉúÎï·Ö×ÓÏìÓ¦ÐÔ¾ÛºÏÎï 2017ÄêÈ«¹ú¸ß·Ö×ÓѧÊõÂÛÎı¨¸æ»á 2017-10-10
£¨7£©ÖÇÄܾۺÏÎïÔÚ·ÒëºóÐÞÊε°°×ÖÊ×éѧÖÐеĻúÓöÓëÌôÕ½ µÚ21½ìÈ«¹úÉ«Æ×ѧÊõ±¨¸æ»á¼°ÒÇÆ÷Õ¹ÀÀ»á 2017-05-19
£¨8£©ÖÇÄÜÉúÎï·ÖÀë½éÖÊ µÚÊ®¶þ½ìÈ«¹úÉúÎïÒ½Ò©É«Æ×¼°Ïà¹Ø¼¼ÊõѧÊõ½»Á÷»á 2017-04-16
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