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[1]    Liu Z., Wang W., Xie R.^*, Ju X.J., Chu L.Y.^*, 2016. Stimuli-responsive smart gating membranes. Chemical Society Reviews, 45(3): 460-475. (2022 IF = 46.2)

       This work has been featured as the Inside Front Cover

[2]    Xie R., Chu L.Y.^*, Deng J.G., 2008. Membranes and membrane processes for chiral resolution. Chemical Society Reviews, 37(6): 1243-1263. (2022 IF = 46.2)

[3]    Wang W., Zhang M.J., Chu L.Y.^*, 2014. Functional polymeric microparticles engineered from controllable microfluidic emulsions. Accounts of Chemical Research, 47(2): 373-384. (2022 IF = 18.3)

[4]    Shah R.K., Shum H.C., Rowat A.C., Lee D., Agresti J.J., Utada A.S., Chu L.Y., Kim J.W., Fernandez-Nieves A., Martinez C.J., Weitz D.A., 2008. Designer emulsions using microfluidics. Materials Today, 11(4): 18-27. (2022 IF = 24.2)

       Cover Story;

       Invited Review;

       Ranked No.11 in Top 25 Hottest Articles during 04/2008-06/2008

[5]    Wang W., Li P.F., Xie R., Ju X.J., Liu Z., Chu L.Y.^*, 2022. Designable Micro-/Nano-Structured Smart Polymeric Materials. Advanced Materials, 34(46): 2107877. (2022 IF = 29.4)

       Invited Paper

       This work has been featured in the Inside Back Cover

[6]    Chu L.Y., Yamaguchi T., Nakao S., 2002. A molecular recognition microcapsule for environmental stimuli-responsive controlled-release. Advanced Materials, 14(5): 386-389. (2022 IF = 29.4)

       This work was featured in the Front Cover

[7]    Liu Z.^*, Zhai Y.M., Zhou K.G., Chu L.Y.^*, 2021. Advanced membranes with responsive two-dimensional nanochannels. Advanced Membranes, 1(1): 100012.

       Invited Paper

       This work has been featured in the Back Cover

[8]    Xia L.W., Xie R., Ju X.J., Wang W., Chen Q.M., Chu L.Y.^*, 2013. Nano-structured smart hydrogels with rapid response and high elasticity. Nature Communications, 4: 2226, doi: 10.1038/ncomms3226.   (2022 IF = 16.6)

       Most-Read Articles of Nature Communications, ranked No.18 in the Top Content of Most-Read Articles on August 6, 2013; No.16 on August 7, 2013; No.14 on August 8, 2013; No.10 on August 9, 2013; No.8 on August 10, 2013; No.8 on August 11, 2013; No.8 on August 12, 2013; No.8 on August 14, 2013; No.5 on August 15, 2013.

[9]    Zhao H., Guo X., He S., Zeng X., Zhou X., Zhang C., Hu J., Wu X., Xing Z., Chu L.Y., He Y., Chen Q.M., 2014. Complex self-assembly of pyrimido[4,5-d]pyrimidine nucleoside supramolecular structures. Nature Communications, 5: 3108, doi: 10.1038/ncomms4108.  (2022 IF = 16.6)

[10] Zhou X.L., Shen Z., Ma B.B., Xia Z.Q., Chai Y.Y., Ju X.J., Chu L.Y., Huang R.D., Chen H., Li W.M.^*, He Y.^*, 2019, Acyclic Janus-AT Nucleoside Host Channels Precisely Lock Water into Single-File Wires with Local Rotational Flexibility. Angewandte Chemie International Edition (2022 IF = 16.6), 58(28): 9601-9610.

[11] Wang W., Zhang M.J., Xie R., Ju X.J., Yang C., Mou C.L., Weitz D.A., Chu L.Y.^*, 2013. Hole-shell microparticles from controllably evolved double emulsions. Angewandte Chemie International Edition, 52(31): 8084-8087. (2022 IF = 16.6)

       Front Cover Story

[12] Chu L.Y.^*, Utada A.S., Shah R.K., Kim J.W., Weitz D.A.^*, 2007. Controllable monodisperse multiple emulsions. Angewandte Chemie International Edition, 46(47): 8970-8974. (2022 IF = 16.6)

       This work has been featured in the Frontispiece;

       Materials Today;

       ½ñÈÕ²ÄÁÏ;

       Chemical & Engineering News;

       SEAS (School of Engineering and Applied Science) Soft Matter Wiki of Harvard University;

       Poster for ¡°New Concept in Microfluidics: Theory and Application (April 20, 2007, Harvard)¡±;

       Poster (background image) for ¡°32nd New England Complex Fluids Meeting (September 28, 2007, University of Connecticut)¡±;

       ¡°Complex Fluids¡± T-Shirt (image on the back) for ¡°32nd New England Complex Fluids Meeting (September 28, 2007, University of Connecticut)¡±;

       Flyer (optical micrographs for New England States fill) for ¡°33rd New England Complex Fluids Meeting¡± (Harvard University, November 30, 2007);

       Flyer (optical micrographs for New England States fill) for ¡°37th New England Complex Fluids Meeting¡± (Harvard University, December 5, 2008);

       Flyer (optical micrographs for New England States fill) for ¡°49th New England Complex Fluids Meeting¡± (Harvard University, December 2, 2011);

       Flyer (optical micrographs for New England States fill) for ¡°53th New England Complex Fluids Workshop¡± (Harvard University, November 30, 2012);

       Flyer (optical micrographs for New England States fill) for ¡°61st New England Complex Fluids Meeting¡± (Harvard University, December 5, 2014);

       Flyer (optical micrographs for New England States fill) for ¡°69th New England Complex Fluids Workshop¡± (Harvard University, December 2, 2016);

       Flyer (optical micrographs for New England States fill) for ¡°73rd New England Complex Fluids Workshop¡± (Harvard University, December 1, 2017);

       Flyer (optical micrographs for New England States fill) for ¡°77th New England Complex Fluids Workshop¡± (Harvard University, November 30, 2018);

       Flyer (optical micrographs for New England States fill) for ¡°93rd New England Complex Fluids Workshop¡± (Harvard University, December 2, 2022)

[13] Chu L.Y.^*, Li Y., Zhu J.H., Chen W.M., 2005. Negatively thermoresponsive membranes with functional gates driven by zipper-type hydrogen-bonding interactions. Angewandte Chemie International Edition, 44(14): 2124-2127. (2022 IF = 16.6)

[14] Yao C., Liu Z.^*, Yang C., Wang W., Ju X.J., Xie R., Chu L.Y.^*, 2015. Poly(N-isopropylacrylamide)-clay nanocomposite hydrogels with responsive bending property as temperature-controlled manipulators. Advanced Functional Materials, 25(20): 2980-2991. (2022 IF = 19.0)

       This work has been featured in the Back Cover

[15] Wei J., Ju X.J.^*, Zou X.Y., Xie R., Wang W., Liu Y.M., Chu L.Y.^*, 2014. Multi-stimuli-responsive microcapsules for adjustable controlled-release. Advanced Functional Materials, 24(22): 3312-3323. (2022 IF = 19.0)

       This work has been featured in the Inside Front Cover

[16] Liu Z., Luo F., Ju X.J.^*, Xie R., Luo T., Sun Y.M., Chu L.Y.^*, 2012. Positively K⁺-responsive membranes with functional gates driven by host-guest molecular recognition. Advanced Functional Materials, 22(22): 4742-4750. (2022 IF = 19.0)

       This work has been featured in the Frontispiece

[17] Yang M., Chu L.Y.^*, Wang H.D., Xie R., Song H., Niu C.H., 2008. A thermo-responsive membrane for chiral resolution. Advanced Functional Materials, 18(4): 652-663. (2022 IF = 19.0)

[18] Chu L.Y.^*, Kim J.W., Shah R.K., Weitz D.A.^*, 2007. Monodisperse thermo-responsive microgels with tunable volume-phase transition kinetics. Advanced Functional Materials, 17(17): 3499-3504. (2022 IF = 19.0)

       This work has been featured in the Front Cover

[19] Qu J.B., Chu L.Y.^*, Yang M., Xie R., Hu L., Chen W.M., 2006. A pH-responsive gating membrane system with pumping effects for improved controlled-release. Advanced Functional Materials, 16(14): 1865-1872. (2022 IF = 19.0)

       This work has been featured in the Front Cover; and

       High-Tech Materials Alert

[20] Xiao X.C., Chu L.Y.^*, Chen W.M., Wang S., Li Y., 2003. Positively thermo-sensitive monodisperse core-shell microspheres. Advanced Functional Materials, 13(11): 847-852. (2022 IF = 19.0)

       This work was featured in the Front Cover

[21] Mou C.L., Wang W.^*, Li Z.L., Ju X.J., Xie R., Deng N.N., Wei J., Liu Z., Chu L.Y.^*, 2018. Trojan-Horse-Like Stimuli-Responsive Microcapsules. Advanced Science, 5(6): 1700960. (2022 IF = 15.1)

[22] Li J.C., Xu W.J., Huang W.H., Long J., Liu J., Luo H., Zhang Y.P.^*, Chu L.Y., 2021. Stable covalent cross-linked polyfluoro sulfonated polyimide membranes with high proton conductance and vanadium resistance for application in vanadium redox flow batteries. Journal of Materials Chemistry A, 9(43): 24704-24711. (2022 IF = 11.9)

[23] Liu Z., Luo F., Ju X.J.^*, Xie R., Sun Y.M., Wang W., Chu L.Y.^*, 2013. Gating membranes for water treatment: Detection and removal of trace Pb²⁺ ions based on molecular recognition and polymer phase transition. Journal of Materials Chemistry A, 1(34): 9659-9671. (2022 IF = 11.9)

       This work has been featured as Inside Front Cover Story

[24] Chen C., Cai Q.W., Zhan C.Z., Wang B.C., Li P.F., Xie R., Ju X.J., Liu Z., Wang W.^*, Chu L.Y.^*, 2023. Controllable Fabrication of Highly Uniform Sub-10 nm Nanoparticles from Spontaneous Confined Nanoemulsification. Small, 19(34): 2300801. (2022 IF = 13.3)

      This work has been featured in the Inside Back Cover

[25] Xie R., Luo F., Zhang L., Guo S.F., Liu Z.^*, Ju X.J., Wang W., Chu L.Y.^*, 2018. A Novel Thermo-responsive Catalytic Membrane with Multi-scale Pores Prepared via Vapor-induced Phase Separation. Small, 14(18): 1703650. (2022 IF = 13.3)

       Invited Paper for the Special Issue of ¡°Multi-Scale Pores and Channels¡±

[26] Lin S., Wang W.^*, Ju X.J., Xie R., Liu Z., Yu H.R., Zhang C., Chu L.Y.^*, 2016. Ultrasensitive microchip based on smart microgel for real-time on-line detection of trace threat analytes. Proceedings of the National Academy of Sciences of the United States of America (PNAS), 113(8): 2023-2028. (2022 IF = 11.1)

       ÈëÑ¡¡¶ÃÀ¹ú¿ÆѧԺѧ±¨¡·£¨PNAS£©ÖØÒªÐÂÎÅ·¢²¼ÕªÒª

[27] Wen G.Y., Zhou X.L., Tian X.Y., Xie R., Ju X.J., Liu Z., Faraj Y., Wang W.^*, Chu L.Y.^*, 2022. Smart Hydrogels with Wide-Visible-Color Tunability. NPG Asia Materials, 14: 29. (2022 IF = 9.7)

[28] Wen G.Y., Zhou X.L., Tian X.Y., Hu T.Y., Xie R., Ju X.J., Liu Z., Pan D.W., Wang W.^*, Chu L.Y.^*, 2022. Real-Time Quantitative Detection of UV Radiation Dose Based on Photochromic Hydrogel and Photo-Resistance. Chemistry of Materials, 34(17): 7947-7958. (2022 IF = 8.6)

[29] Wang W., Li B.Y., Zhang M.J., Su Y.Y., Pan D.W., Liu Z., Ju X.J., Xie R., Faraj Y., Chu L.Y.^*, 2023. Microfluidic Emulsification Techniques for Controllable Emulsion Production and Functional Microparticle Synthesis. Chemical Engineering Journal, 452: 139277. (2022 IF = 15.1)

       Invited Paper for the Special Issue on Mechanisms and Control of Mesoscales in Chemical Engineering

[30] Li J.C., Liu J., Xu W.J., Long J., Huang W.H., Zhang Y.P.^*, Chu L.Y., 2022. Highly ion-selective sulfonated polyimide membranes with covalent self-crosslinking and branching structures for vanadium redox flow battery. Chemical Engineering Journal, 437: 135414. (2022 IF = 15.1)

[31] Zhang T.X., Tao C., Ge S.X., Pan D.W.^*, Li B., Huang W.X., Wang W., Chu L.Y., 2022. Interfaces coupling deformation mechanisms of liquid-liquid-liquid three-phase flow in a confined microchannel. Chemical Engineering Journal, 434: 134769. (2022 IF = 15.1)

[32] Xu W.J., Long J., Liu J., Luo H., Duan H.R., Zhang Y.P.^*, Li J.C.^*, Qi X.J., Chu L.Y., 2022. A novel porous polyimide membrane with ultrahigh chemical stability for application in vanadium redox flow battery. Chemical Engineering Journal, 428: 131203. (2022 IF = 15.1)

[33] Peng J.^#, Zhao N.^#, Lin S., Wang W.^*, Zhang M.J., Su Y.Y., Xie R., Ju X.J., Liu Z., Chu L.Y., 2021. Smart microfluidic analogue of Wheatstone-bridge for real-time continuous detection with ultrasensitivity and wide dynamic range. Chemical Engineering Journal, 407: 127138. (^#Contributed equally) (2022 IF = 15.1)

[34] Cai Q.W., Ju X.J.^*, Chen C., Faraj Y., Jia Z.H., Hu J.Q., Xie R., Wang W., Liu Z., Chu L.Y.^*, 2019. Fabrication and flow characteristics of monodisperse bullet-shaped microparticles with controllable structures. Chemical Engineering Journal, 370: 925-937. (2022 IF = 15.1)

[35] Zhang L., Liu Z.^*, Wang Y., Xie R., Ju X.J., Wang W., Lin L.G., Chu L.Y.^*, 2017. Facile immobilization of Ag nanoparticles on microchannel walls in microreactors for catalytic applications. Chemical Engineering Journal, 309: 691-699. (2022 IF = 15.1)

[36] Mei L., Xie R.^*, Yang C., Ju X.J., Wang W., Wang J.Y., Chu L.Y.^*, 2013. pH-responsive Ca-alginate-based capsule membranes with grafted poly(methacrylic acid) brushes for controllable enzyme reaction. Chemical Engineering Journal, 232: 573-581. (2022 IF = 15.1)

[37] Mou C.L., He X.H., Ju X.J.^*, Xie R., Liu Z., Liu L., Zhang Z., Chu L.Y.^*, 2012. Change in size and structure of monodisperse poly(N-isopropylacrylamide) microcapsules in response to varying temperature and ethyl gallate concentration. Chemical Engineering Journal, 210: 212-219. (2022 IF = 15.1)

[38] Wang Z.B., Chu L.Y.^*, Chen W.M., Wang S.G., 2008. Experimental investigation of the motion trajectory of solid particles inside the hydrocyclone by a Lagrange method. Chemical Engineering Journal, 138(1-3): 1-9. (2022 IF = 15.1)

[39] Dai G.Q., Chen W.M., Li J.M., Chu L.Y., 1999. Experimental study of solid-liquid two-phase flow in a hydrocyclone. Chemical Engineering Journal, 74(3): 211-216. (2022 IF = 15.1)

[40] Chu L.Y.^*, Li Y., Zhu J.H., Wang H.D., Liang Y.J., 2004. Control of pore size and permeability of a glucose-responsive gating membrane for insulin delivery. Journal of Controlled Release, 97(1): 43-53. (2022 IF = 10.8)

[41] Pu X.Q., Ju X.J.^*, Zhang L., Cai Q.W., Liu Y.Q., Peng H.Y., Xie R., Wang W., Liu Z., Chu L.Y.^*, 2021. Novel multifunctional stimuli-responsive nanoparticles for synergetic chemo-photothermal therapy of tumors. ACS Applied Materials & Interfaces, 13(24): 28802-28817. (2022 IF = 9.5)

[42] Mu X.T., Li Y., Ju X.J.^*, Yang X.L., Xie R., Wang W., Liu Z., Chu L.Y., 2020. Microfluidic Fabrication of Structure-controlled Chitosan Microcapsules via Interfacial Crosslinking of Droplet Templates. ACS Applied Materials & Interfaces, 12(51): 57514-57525. (2022 IF = 9.5)

[43] Lv X.B., Xie R.^*, Ji J.Y.^*, Liu Z., Wen X.Y., Liu L.Y., Hu J.Q., Ju X.J., Wang W., Chu L.Y., 2020. A Novel Strategy to Fabricate Cation-Cross-linked Graphene Oxide Membrane with High Aqueous Stability and High Separation Performance. ACS Applied Materials & Interfaces, 12(50): 56269-56280. (2022 IF = 9.5)

[44] Chen L., Zhang M.J.,^* Zhang S.-Y., Shi L., Yang Y.-M., Liu Z., Ju X.J., Xie R., Wang W.^*, Chu L.Y., 2020. Simple and continuous fabrication of self-propelled micromotors with photocatalytic MOF for enhanced synergistic environmental remediation. ACS Applied Materials & Interfaces, 12(31): 35120-35131. (2022 IF = 9.5)

[45] Cai Q.W., Ju X.J.^*, Zhang S.Y., Chen Z.H., Hu J.Q., Zhang L.P., Xie R., Wang W., Liu Z., Chu L.Y.^*, 2019. Controllable Fabrication of Functional Microhelices with Droplet Microfluidics. ACS Applied Materials & Interfaces, 11(49): 46241-46250. (2022 IF = 9.5)

[46] Wen X.Y., Liu Z.^*, Wang J., Tang X.Y., Wang W., Ju X.J., Xie R., Chu L.Y., 2019. Nanocomposite hydrogels with optic-sonic transparency and hydroacoustic-sensitive conductivity for potential anti-scouting sonar. ACS Applied Materials & Interfaces, 11(22): 20386-20393. (2022 IF = 9.5)

[47] Zhang L., Liu Z.^*, Liu L.Y., Pan J.L., Luo F., Yang C., Xie R., Ju X.J., Wang W., Chu L.Y.^*, 2018. Nanostructured Thermo-responsive Surfaces Engineered via Stable Immobilization of Smart Nanogels with Assistance of Polydopamine. ACS Applied Materials & Interfaces, 10(50): 44092-44101. (2022 IF = 9.5)

[48] Yan P.J., He F., Wang W.^*, Zhang S.Y., Zhang L., Li M., Liu Z., Ju X.J., Xie R., Chu L.Y.^*, 2018. A Novel Membrane Detector Based on Smart Nanogels for Ultrasensitive Detection of Trace Threat Substances. ACS Applied Materials & Interfaces, 10(42): 36425-36434. (2022 IF = 9.5)

[49] Zhang L., Liu Z.^*, Liu L.Y., Ju X.J., Wang W., Xie R., Chu L.Y.^*, 2017. Novel Smart Microreactors Equipped with Responsive Catalytic Nanoparticles on Microchannels. ACS Applied Materials & Interfaces, 9(38): 33137-33148. (2022 IF = 9.5)

[50] Shi K., Liu Z.^*, Yang C., Li X.Y., Sun Y.M., Deng Y., Wang W., Ju X.J., Xie R., Chu L.Y.^*, 2017. Novel Biocompatible Thermoresponsive Poly(N-vinyl Caprolactam)/Clay Nanocomposite Hydrogels with Macroporous Structure and Improved Mechanical Characteristics. ACS Applied Materials & Interfaces, 9(26): 21979-21990. (2022 IF = 9.5)

[51] You X.R., Ju X.J.,^*, He F., Wang Y., Liu Z., Wang W., Xie R., Chu L.Y., 2017. Polymersomes with Rapid K⁺-Triggered Drug Release Behaviors. ACS Applied Materials & Interfaces, 9(22): 19258-19268. (2022 IF = 9.5)

[52] Yang C., Liu Z.^*, Chen C., Shi K., Zhang L., Ju X.J., Wang W., Xie R., Chu L.Y.^*, 2017. Reduced Graphene Oxide-Containing Smart Hydrogels with Excellent Electro-Response and Mechanical Property for Soft Actuators. ACS Applied Materials & Interfaces, 9(18): 15758-15767. (2022 IF = 9.5)

[53] Ma B., Ju X.J.^*, Luo F., Liu Y.Q., Wang Y., Liu Z., Wang W., Xie R., Chu L.Y.^*, 2017. Facile Fabrication of Composite Membranes with Dual Thermo- and pH-Responsive Characteristics. ACS Applied Materials & Interfaces, 9(16): 14409-14421. (2022 IF = 9.5)

[54] Yao C., Liu Z.^*, Yang C., Wang W., Ju X.J., Xie R., Chu L.Y.^*, 2016. Smart hydrogels with inhomogeneous structures assembled using nanoclay-crosslinked hydrogel subunits as building blocks. ACS Applied Materials & Interfaces, 8(33): 21721-21730. (2022 IF = 9.5)

[55] Xi Y.H.^#, Hu J.Q.^#, Liu Z.^*, Xie R., Ju X.J., Wang W., Chu L.Y.^*, 2016. Graphene oxide membranes with strong stability in aqueous solutions and controllable lamellar spacing. ACS Applied Materials & Interfaces, 8(24): 15557-15566. (^#Contributed equally) (2022 IF = 9.5)

[56] Yang X.L., Ju X.J.^*, Mu X.T., Wang W., Xie R., Liu Z., Chu L.Y., 2016. Core-shell chitosan microcapsules for programmed sequential drug release. ACS Applied Materials & Interfaces, 8(16): 10524-10534. (2022 IF = 9.5)

[57] He F., Wang W.^*, He X.H., Yang X.L., Li M., Xie R., Ju X.J., Liu Z., Chu L.Y.^*, 2016. Controllable multi-compartmental capsules with distinct cores and shells for synergistic release. ACS Applied Materials & Interfaces, 8(13): 8743-8754. (2022 IF = 9.5)

[58] Shi K., Liu Z.,^* Wei Y.Y., Wang W., Ju X.J., Xie R., Chu L.Y.^*, 2015, Near-infrared light-responsive poly(N-isopropylacrylamide)/graphene oxide nanocomposite hydrogels with ultrahigh tensibility. ACS Applied Materials & Interfaces, 7(49): 27289-27298. (2022 IF = 9.5)

[59] He X.H., Wang W.^*, Liu Y.M., Jiang M.., Wu F., Deng K., Liu Z., Ju X.J., Xie R., Chu L.Y.^*, 2015. Microfluidic fabrication of bio-inspired microfibers with controllable magnetic spindle-knots for 3D assembly and water collection. ACS Applied Materials & Interfaces, 7(31): 17471-17481. (2022 IF = 9.5)

[60] Zhang M.J., Wang W.^*, Yang X.L., Ma B., Liu Y.M., Xie R., Ju X.J., Liu Z., Chu L.Y.^*, 2015.  Uniform microparticles with controllable highly-interconnected hierarchical porous structures. ACS Applied Materials & Interfaces, 7(25): 13758-13767. (2022 IF = 9.5)

       This work has been featured as the Cover Story

[61] Jiang M.Y., Ju X.J.^*, Fang L., Liu Z., Yu H.R., Jiang L., Wang W., Xie R., Chen Q.M., Chu L.Y.^*, 2014. A novel smart microsphere with K⁺-induced shrinking and aggregating property based on responsive host-guest system. ACS Applied Materials & Interfaces, 6(21): 19405-19415. (2022 IF = 9.5)

[62] Liu Y.M., Ju X.J.^*, Xin Y., Zheng W.C., Wang W., Wei J., Xie R., Liu Z., Chu L.Y.^*, 2014. A novel smart microsphere with magnetic core and ion-recognizable shell for Pb²⁺ adsorption and separation. ACS Applied Materials & Interfaces, 6(12): 9530-9542. (2022 IF = 9.5)

[63] Mei L., He F., Zhou R.Q., Wu C.D., Liang R., Xie R., Ju X.J., Wang W., Chu L.Y.^*, 2014. A novel intestinal-targeted Ca-alginate-based carrier for pH-responsive protection and release of Lactic acid bacteria. ACS Applied Materials & Interfaces, 6(8): 5962-5970. (2022 IF = 9.5)

[64] Deng N.N., Sun J., Wang W., Ju X.J., Xie R., Chu L.Y.^*, 2014. Wetting-induced coalescence of nanoliter drops as microreactors in microfluidics. ACS Applied Materials & Interfaces, 6(6): 3817-3821. (2022 IF = 9.5)

[65] Liu Y.M., Wang W.^*, Zheng W.C., Ju X.J., Xie R., Zerrouki D., Deng N.N., Chu L.Y.^*, 2013. Hydrogel-based micro-actuators with remote-controlled locomotion and fast Pb²⁺-response for micromanipulation. ACS Applied Materials & Interfaces, 5(15): 7219-7226. (2022 IF = 9.5)

[66] Xu W.J., Long J., Liu J., Wang Y.L., Luo H., Zhang Y.P.^*, Li J.C.^*, Chu L.Y., Duan H., 2021, Novel highly efficient branched polyfluoro sulfonated polyimide membranes for application in vanadium redox flow battery. Journal of Power Sources, 485: 229354. (2022 IF = 9.2)

[67] Wen S., Ju X.J.^*, Liu W.Y., Liu Y.Q., Pu X.Q., Liu Z., Wang W., Xie R., Faraja Y., Chu L.Y., 2023. Ca-alginate-based Janus capsules with pumping effect for intestinal-targeted controlled-release. Engineering, in press. (2022 IF = 12.8)

[68] Liu W.Y., Ju X.J.^*, Pu X.Q., Cai Q.W. , Liu Y.Q., Liu Z., Wang W., Xie R., Chu L.Y.^*, 2021. Functional Capsules Encapsulating Molecular-Recognizable Nanogels for Facile Removal of Organic Micro-Pollutants from Water. Engineering, 7(5): 636-646. (2022 IF = 12.8)

       Invited Paper for the Special Issue on ¡°Soft Materials for Green Chemical Engineering¡±

       This work has been featured in the Back Cover

[69] Jiang Q.R., Pu X.Q., Deng C.F., Wang W., Liu Z., Xie R., Pan D.W., Zhang W.J.^*, Ju X.J.^*, Chu L.Y., 2023. Microfluidic controllable preparation of iodine-131-labeled microspheres for radioembolization therapy of liver tumors. Advanced Healthcare Materials, in press. (2022 IF = 10.0)

[70] Li D.Y., Wang W., Chu L.Y., Deng N.N.^*, 2023. Tunable Structural Coloration in Eccentric Water-in-Oil-in-Water Droplets. Nano Letters, in press. (2022 IF = 10.8)

[71] Li X.J.^#, Li Y.^#, Meng Y, Pu X.Q., Qin J.W., Xie R., Wang W., Liu Z., Jiang L.^*, Ju X.J.^*, Chu L.Y., 2022. Composite dissolvable microneedle patch for therapy of oral mucosal diseases. Biomaterials Advances, 139: 213001. (^#Contributed equally)

[72] Liu Z., Liu L., Ju X.J.^*, Xie R., Zhang B., Chu L.Y.^*, 2011. K⁺-recognition capsules with squirting release mechanisms. Chemical Communications, 47(45): 12283-12285. (2022 IF = 4.9)

       This work has been featured in Back Cover;

       Chemistry World;

       Nano News Net; and

       ChemRar

[73] Zhao H., He S.L., Yang M.L., Guo X.R., Xin G., Zhang C.Y., Ye L., Chu L.Y., Xing Z.H., Huang W., Chen Q.M., He Y., 2013. Micro-flowers changing to nano-bundle aggregates by translocation of the sugar moiety in Janus TA nucleosides. Chemical Communications, 49(36): 3742-3744. (2022 IF = 4.9)

[74] Yu H.R., Ju X.J.^*, Xie R., Wang W., Zhang B., Chu L.Y.^*, 2013. Portable diagnosis method of hyperkalemia using potassium-recognizable poly(N-isopropylacrylamide-co-benzo-15-crown-5-acrylamide) copolymers. Analytical Chemistry, 85(13): 6477-6484. (2022 IF = 7.4)

[75] Deng C.F., Su Y.Y., Yang S.H., Jiang Q.R., Xie R., Ju X.J., Liu Z., Pan D.W., Wang W.^*, Chu L.Y.^*, 2022. Designable microfluidic ladder networks from backstepping microflow analysis for mass production of monodisperse microdroplets. Lab on a Chip (2022 IF = 6.1), 22(24): 4962-4973.

[76] Deng N.N., Wang W., Ju X.J., Xie R., Chu L.Y.^*, 2016. Spontaneous transfer of droplets across microfluidic laminar interfaces. Lab on a Chip, 16(22): 4326-4332. (2022 IF = 6.1)

       This work has been featured as Front Cover Story

[77] Meng Z.J., Wang W.^*, Xie R., Ju X.J., Liu Z., Chu L.Y.^*, 2016. Microfluidic generation of hollow Ca-alginate microfibers. Lab on a Chip, 16(14): 2673-2681. (2022 IF = 6.1)

[78] Meng Z.J., Wang W.^*, Liang X., Zheng W. C., Deng N.N., Xie R., Ju X.J., Liu Z., Chu L.Y.^*, 2015. Plug-n-play microfluidic systems from flexible assembly of glass-based flow-control modules. Lab on a Chip, 15(8): 1869-1878.. (2022 IF = 6.1)

[79] Sun Y.M., Wang W.^*, Wei Y.Y., Deng N.N., Liu Z., Ju X.J., Xie R., Chu L.Y.^*, 2014. In situ fabrication of temperature- and ethanol-responsive smart membrane in microchip. Lab on a Chip, 14(14): 2418-2427. (2022 IF = 6.1)

       This paper has been featured as ¡°HOT Article¡± in Lab on a Chip Blog

[80] Lin S., Wang W.^*, Ju X.J., Xie R., Chu L.Y.^*, 2014. A simple strategy for in situ fabrication of smart hydrogel microvalve within microchannels for thermostatic control. Lab on a Chip, 14(15): 2626-2634. (2022 IF = 6.1)

       This paper has been featured in Inside Front Cover; and as

       ¡°HOT Article¡± in Lab on a Chip Blog

[81] Deng N.N., Wang W., Ju X.J., Xie R., Weitz D.A., Chu L.Y.^*, 2013. Wetting-induced formation of controllable monodisperse multiple emulsions in microfluidics. Lab on a Chip, 13(20): 4047-4052. (2022 IF = 6.1)

       This work has been featured in Back Cover

[82] Deng N.N., Sun S.X., Wang W., Ju X.J., Xie R., Chu L.Y.^*, 2013. A novel surgery-like strategy for droplet coalescence in microchannels. Lab on a Chip, 13(18): 3653-3657. (2022 IF = 6.1)

[83] Wang W., Xie R.^*, Ju X.J., Luo T., Liu L., Weitz D.A., Chu L.Y.^*, 2011. Controllable microfluidic production of multicomponent multiple emulsions. Lab on a Chip, 11(9): 1587-1592. (2022 IF = 6.1)

       This work has been featured in Back Cover;

       Chemistry World;

       Micronews;

       Lab on a Chip Blog;

       Chemistry in Our Life;

       I-Micronews; and

       Most Read Articles in May 2011.

[84] Deng N.N., Meng Z.J., Xie R.^*, Ju X.J., Mou C.L., Wang W., Chu L.Y.^*, 2011. Simple and cheap microfluidic devices for preparation of monodisperse emulsions. Lab on a Chip, 11(23): 3963-3969. (2022 IF = 6.1)

       This work has been featured in Back Cover; and

       Lab on a Chip Blog

[85] Wang F., Liu Z.^*, Zou L.B., Xie R., Ju X.J., Wang W., Pan D.W., Chu L.Y.^*, 2023. A universal model for describing responsive performances of both positively and negatively responsive smart gating membranes. Journal of Membrane Science, 668: 121235. (2022 IF = 9.5)

[86] Zhang C., Xie R.^*, Liu Z., Ju X.J., Wang W., Chu L.Y.^*, 2022. 3D Helical Membranes for Process Intensification of Membrane Separation via Generation of Dean Vortices. Journal of Membrane Science, 662: 120969. (2022 IF = 9.5)

[87] Long J., Xu W.J., Xu S.B., Liu J., Wang Y.L., Luo H., Zhang Y.P.^*, Li J.C.^*, Chu L.Y., 2021. A novel double branched sulfonated polyimide membrane with ultra-high proton selectivity for vanadium redox flow battery. Journal of Membrane Science, 628: 119259. (2022 IF = 9.5)

[88] Liu W.Y., Ju X.J.^*, Yousef F., He F., Peng H.Y., Liu Y.Q., Liu Z., Wang W., Xie R., Chu L.Y.^*, 2020. Capsule membranes encapsulated with smart nanogels for facile detection of trace lead(II) ions in water. Journal of Membrane Science, 613: 118523. (2022 IF = 9.5)

[89] Xu M.H., Xie R.^*, Ju X.J., Wang W., Liu Z., Chu L.Y.^*, 2020. Antifouling membranes with bi-continuous porous structures and high fluxes prepared by vapor-induced phase separation. Journal of Membrane Science, 611: 118256. (2022 IF = 9.5)

[90] Chen Z.H., Liu Z.^*, Hu J.Q., Cai Q.W., Li X.Y., Wang W., Faraj Y., Ju X.J., Xie R., Chu L.Y.^*, 2020. ¦Â-Cyclodextrin-modified graphene oxide membranes with large adsorption capacity and high flux for efficient removal of bisphenol A from water. Journal of Membrane Science, 595: 117510. (2022 IF = 9.5)

[91] Hu J.Q., Liu Z.^*, Deng K., Chen Z.H., Cai Q.W., Faraj Y., Xie R., Ju X.J., Wang W., Chu L.Y.^*, 2019. A novel membrane with ion-recognizable copolymers in graphene-based nanochannels for facilitated transport of potassium ions. Journal of Membrane Science, 591: 117345. (2022 IF = 9.5)

[92] Mu X. T., Ju X. J.^*, Zhang L., Huang X. B., Faraj Y., Liu Z., Wang W., Xie R., Deng Y., Chu L.Y., 2019. Chitosan Microcapsule Membranes with Nanoscale Thickness for Controlled Release of Drugs. Journal of Membrane Science, 590: 117275. (2022 IF = 9.5)

[93] Li X.Y., Xie R.^*, Zhang C., Chen Z.H., Hu J. Q., Ju X.J., Wang W., Liu Z., Chu L.Y., 2019. Effects of hydrophilicity of blended submicrogels on the microstructure and performance of thermo-responsive membranes. Journal of Membrane Science, 584: 202-215. (2022 IF = 9.5)

[94] Wang Y., Liu Z.^*, Luo F., Peng H.Y., Zhang S.G., Xie R., Ju X.J., Wang W., Faraj Y., Chu L.Y.^*, 2019. A novel smart membrane with ion-recognizable nanogels as gates on interconnected pores for simple and rapid detection of trace lead(II) ions in water. Journal of Membrane Science, 575: 28-37. (2022 IF = 9.5)

[95] Zhang L.P., Liu Z.^*, Faraj Y., Zhao Y., Zhuang R., Xie R., Ju X.J., Wang W., Chu L.Y.^*, 2019. High-flux efficient catalytic membranes incorporated with iron-based Fenton-like catalysts for degradation of organic pollutants. Journal of Membrane Science, 573: 493-503. (2022 IF = 9.5)

[96] Fan X.X., Xie R.^*, Zhao Q., Li X.Y., Ju X.J., Wang W., Liu Z., Chu L.Y.^*, 2018. Dual pH-Responsive Smart Gating Membranes. Journal of Membrane Science, 555: 20-29. (2022 IF = 9.5)

[97] Xi Y.H., Liu Z.^*, Ji J.Y., Wang Y., Faraj Y., Zhu Y.D., Xie R., Ju X.J., Wang W., Lu X.H., Chu L.Y.^*, 2018. Graphene-based membranes with uniform 2D nanochannels for precise sieving of mono-/multi-valent metal ions. Journal of Membrane Science, 550: 208-218. (2022 IF = 9.5)

[98] Zhao Q., Xie R.^*, Luo F., Faraj Y., Liu Z., Ju X.J., Wang W., Chu L.Y., 2018. Preparation of high strength poly(vinylidene fluoride) porous membranes with cellular structure via vapor-induced phase separation. Journal of Membrane Science, 549: 151-164. (2022 IF = 9.5)

[99] Yang B.X., Yang X., Liu B.C.^*, Chen Z.Q.^*, Chen C., Liang S.M., Chu L.Y., Crittenden J., 2017. PVDF blended PVDF-g-PMAA pH-responsive membrane: Effect of additives and solvents on membrane properties and performance. Journal of Membrane Science, 541: 558-566. (2022 IF = 9.5)

[100]           Deng K., Liu Z.^*, Luo F., Xie R., He X.H., Jiang M.Y., Ju X.J., Wang W., Chu L.Y.^*, 2017. Controllable fabrication of polyethersulfone hollow fiber membranes with a facile double co-axial microfluidic device. Journal of Membrane Science, 526: 9-17. (2022 IF = 9.5)

[101]           Luo F., Zhao Q., Xie R.,^*, Cao Y., Ju X.J., Wang W., Liu Z., Chu L.Y.^*, 2016. Effects of fabrication conditions on the microstructures and performances of smart gating membranes with in situ assembled nanogels as gates. Journal of Membrane Science, 519: 32-44. (2022 IF = 9.5)

[102]           Liu Z., Ju X.J., Huang Y.H., Xie R., Wang W., Lee K.R., Chu L.Y.^*, 2016. Diffusional permeability characteristics of positively K⁺-responsive membranes caused by spontaneously changing membrane pore size and surface wettability. Journal of Membrane Science, 497: 328-338. (2022 IF = 9.5)

[103]           He F., Mei L., Ju X.J.^*, Xie R., Wang W., Liu Z., Wu F., Chu L.Y.^*, 2014. pH-Responsive controlled release characteristics of solutes with different molecular weights diffusing across membranes of Ca-alginate/protamine/silica hybrid capsules. Journal of Membrane Science, 474: 233-243. (2022 IF = 9.5)

[104]           Luo T., Lin S., Xie R.^*, Ju X.J., Liu Z., Wang W, Mou C.L., Zhao C.S., Chen Q.M., Chu L.Y.^*, 2014. pH-Responsive poly(ether sulfone) composite membranes blended with amphiphilic polystyrene-block-poly(acrylic acid) copolymers. Journal of Membrane Science, 450: 162-173. (2022 IF = 9.5)

[105]           Chen Y.C., Xie R., Chu L.Y.^*, 2013. Stimuli-responsive gating membranes responding to temperature, pH, salt concentration and anion species. Journal of Membrane Science, 442: 206-215. (2022 IF = 9.5)

[106]           Mei L., Xie R.^*, Yang C., Ju X.J., Wang J.Y., Zhang Z., Chu L.Y.^*, 2013. Bio-inspired mini-eggs with pH-responsive membrane for enzyme immobilization. Journal of Membrane Science, 429: 313-322. (2022 IF = 9.5)

[107]           Meng T., Xie R.^*, Ju X.J., Cheng C. J., Wang S., Li P.F., Liang B., Chu L.Y.^*, 2013. Nano-structure construction of porous membranes by depositing nanoparticles for enhanced surface wettability. Journal of Membrane Science, 427: 63-72. (2022 IF = 9.5)

[108]           Yang M., Xie R., Wang J.Y. Ju X.J., Yang L., Chu L.Y.^*, 2010. Gating characteristics of thermo-responsive and molecular- recognizable membranes based on poly(N-isopropylacrylamide) and ¦Â-cyclodextrin. Journal of Membrane Science, 355(1-2): 142-150. (2022 IF = 9.5)

[109]           Meng T., Xie R., Chen Y.C., Cheng C.J., Li P.F., Ju X.J., Chu L.Y.^*, 2010. A thermo-responsive affinity membrane with nano-structured pores and grafted poly(N-isopropylacrylamide) surface layer for hydrophobic adsorption. Journal of Membrane Science, 349(1-2): 258-267. (2022 IF = 9.5)

[110]           Li P.F., Xie R., Jiang J.C., Meng T., Yang M., Ju X.J., Yang L., Chu L.Y.^*, 2009. Thermo-responsive gating membranes with controllable length and density of poly(N-isopropylacrylamide) chains grafted by ATRP method. Journal of Membrane Science, 337(1-2): 310-317. (2022 IF = 9.5)

[111]           Xie R., Zhang S.B., Wang H.D., Yang M., Li P.F., Zhu X.L., Chu L.Y.^*, 2009. Temperature-dependent molecular-recognizable membranes based on poly(N-isopropylacrylamide) and ¦Â-cyclodextrin. Journal of Membrane Science, 326(2): 618-626. (2022 IF = 9.5)

[112]           Yang W.C., Xie R., Pang X.Q., Ju X.J., Chu L.Y.^*, 2008. Preparation and characterization of dual stimuli-responsive microcapsules with a superparamagnetic porous membrane and thermo-responsive gates. Journal of Membrane Science, 321(2): 324-330. (2022 IF = 9.5)

[113]           Xie R., Li Y., Chu L.Y.^*, 2007. Preparation of thermo-responsive gating membranes with controllable response temperature. Journal of Membrane Science, 289(1-2): 76-85. (2022 IF = 9.5)

[114]           Wang H.D., Chu L.Y.^*, Song H., Yang J.P., Xie R., Yang M., 2007. Preparation and enantiomer separation characteristics of chitosan/¦Â-cyclodextrin composite membranes. Journal of Membrane Science, 297(1-2): 262-270. (2022 IF = 9.5)

[115]           Wang G.J., Chu L.Y.^*, Zhou M.Y., Chen W.M., 2006. Effects of preparation conditions on the microstructure of porous microcapsule membranes with straight open pores. Journal of Membrane Science, 284(1-2): 301-312. (2022 IF = 9.5)

[116]           Wang G.J., Chu L.Y.^*, Chen W.M., Zhou M.Y., 2005. A porous microcapsule membrane with straight pores for the immobilization of microbial cells. Journal of Membrane Science, 252(1-2): 279-284. (2022 IF = 9.5)

[117]           Xie R., Chu L.Y.^*, Chen W.M., Xiao W., Wang H.D., Qu J.B., 2005. Characterization of microstructure of poly(N-isopropylacrylamide)-grafted polycarbonate track-etched membranes prepared by plasma-graft pore-filling polymerization. Journal of Membrane Science, 258(1-2): 157-166. (2022 IF = 9.5)

[118]           Chu L.Y.^*, Park S.H., Yamaguchi T., Nakao S., 2001. Preparation of thermo-responsive core-shell microcapsules with a porous membrane and poly(N-isopropylacrylamide) gates. Journal of Membrane Science, 192(1-2): 27-39. (2022 IF = 9.5)

[119]           Zhou X.L., Zhou C.H., Gong J.Y., Yu Q.W., He Y.^*, Ju X.J.^*, Chu L.Y., 2023. Novel Thermo and Ion-responsive Copolymers Based on Metallo-Base Pair Directed Host-Guest Complexation for Highly Selective Recognition of Hg²⁺ in Aqueous Solution. Journal of Hazardous Materials, 445: 130610. (2022 IF = 13.6)

[120]           Tian X.Y., Sun M.W., Wen G.Y., Cao M., Pan D.W., Xie R., Ju X.J., Liu Z., Wang W.^*, Chu L.Y.^*, 2023. Ultrasensitive Hydrogel Grating Detector for Real-Time Continuous-Flow Detection of Trace Threat Pb²⁺. Journal of Hazardous Materials, 443: 130289. (2022 IF = 13.6)

[121]           Liu Y.Q., Ju X.J.^*, Zhou X.L., Mu X.T., Tian X.Y., Zhang L., Liu Z., Wang W., Xie R., Chu L.Y., 2022. A novel chemosensor for sensitive and facile detection of strontium ions based on ion-imprinted hydrogels modified with guanosine derivatives. Journal of Hazardous Materials, 421: 126801. (2022 IF = 13.6)

[122]           Liu Y.Q., Ju X.J.^*, Pu X.Q., Wen S., Liu W.Y., Liu Z., Wang W., Xie R., Chu L.Y., 2021. Visual detection of trace lead(II) using a forward osmosis-driven device loaded with ion-responsive nanogels. Journal of Hazardous Materials, 404: 124157. (2022 IF = 13.6)

[123]           Yu H.R., Hu J.Q., Liu Z.^*, Ju X.J., Xie R., Wang W., Chu L.Y.^*, 2017. Ion-recognizable hydrogels for efficient removal of cesium ions from aqueous environment. Journal of Hazardous Materials, 323: 632-640. (2022 IF = 13.6)

[124]           Ju X.J., Zhang S.B., Zhou M.Y., Xie R., Yang L., Chu L.Y.^*, 2009. Novel heavy-metal adsorption material: Ion-recognition P(NIPAM-co-BCAm) hydrogels for removal of lead(II) ions. Journal of Hazardous Materials, 167(1-3): 114-118. (2022 IF = 13.6)

[125]           Peng H.Y., Wang W.^*, Gao F.H., Lin S., Liu L.Y., Pu X.Q., Liu Z., Ju X.J., Xie R., Chu L.Y.^*, 2018. Ultrasensitive diffraction gratings based on smart hydrogel for high-selective and rapid detection of trace heavy metal ions. Journal of Materials Chemistry C, 6(42): 11356-11367. (2022 IF = 6.4)

[126]           Liu L., Wu F., Ju X.J., Xie R., Wang W., Niu C.H., Chu L.Y.^*, 2013. Preparation of monodisperse calcium alginate microcapsules via internal gelation in microfluidic-generated double emulsions. Journal of Colloid and Interface Science, 404: 85-90. (2022 IF = 9.9)

[127]           Yue L.L., Xie R.^*, Wei J., Ju X.J., Wang W., Chu L.Y.^*, 2012. Nano-gel containing thermo-responsive microspheres with fast response rate owing to hierarchical phase-transition mechanism. Journal of Colloid and Interface Science, 377(1): 137-144. (2022 IF = 9.9)

[128]           Yu Y.L., Zhang M.J., Xie R.^*, Ju X.J., Wang J.Y., Pi S.W., Chu L.Y.^*, 2012. Thermo-responsive monodisperse core-shell microspheres with PNIPAM core and biocompatible porous ethyl cellulose shell embedded with PNIPAM gates. Journal of Colloid and Interface Science, 376(1): 97-106. (2022 IF = 9.9)

[129]           Wei J., Ju X.J.^*, Xie R., Mou C.L., Lin X., Chu L.Y.^*, 2011. Novel cationic pH-responsive poly(N,N-dimethylaminoethyl methacrylate) microcapsules prepared by a microfluidic technique. Journal of Colloid and Interface Science, 357(1): 101-108. (2022 IF = 9.9)

[130]           Wang J.Y., Jin Y., Xie R.^*, Liu J.Y., Ju X.J., Meng T., Chu L.Y.^*, 2011. Novel calcium-alginate capsules with aqueous core and thermo-responsive membrane. Journal of Colloid and Interface Science, 353(1): 61-68. (2022 IF = 9.9)

[131]           Pi S.W., Ju X.J.^*, Wu H.G., Xie R., Chu L.Y.^*, 2010. Smart responsive microcapsules capable of recognizing heavy metal ions. Journal of Colloid and Interface Science, 349(2): 512-518. (2022 IF = 9.9)

[132]           Xia L.W., Ju X.J., Liu J.J., Xie R., Chu L.Y.^*, 2010. Responsive hydrogels with poly(N-isopropylacrylamide-co-acrylic acid) colloidal spheres as building blocks. Journal of Colloid and Interface Science, 349(1): 106-113. (2022 IF = 9.9)

[133]           Yu Y.L., Xie R.^*, Zhang M.J., Li P.F., Yang L., Ju X.J., Chu L.Y.^*, 2010. Monodisperse microspheres with poly(N-isopropylacrylamide) core and poly(2-hydroxyethyl methacrylate) shell. Journal of Colloid and Interface Science, 346(2): 361-369. (2022 IF = 9.9)

[134]           Chen G., Niu C.H., Zhou M.Y., Ju X.J., Xie R., Chu L.Y.^*, 2010. Phase transition behaviors of poly(N-isopropylacrylamide) microgels induced by tannic acid. Journal of Colloid and Interface Science, 343(1): 168-175. (2022 IF = 9.9)

[135]           Ren P.W., Ju X.J., Xie R., Chu L.Y.^*, 2010. Monodisperse alginate microcapsules with oil core generated from a microfluidic device. Journal of Colloid and Interface Science, 343(1): 392-395. (2022 IF = 9.9)

[136]           Zhang H., Ju X.J., Xie R., Cheng C.J., Ren P.W., Chu L.Y.^*, 2009. A microfluidic approach to fabricate monodisperse hollow or porous poly(HEMA-MMA) microspheres using single emulsions as templates. Journal of Colloid and Interface Science, 336(1): 235-243. (2022 IF = 9.9)

[137]           Zhou M.Y., Xie R., Yu Y.L., Chen G., Ju X.J., Yang L., Liang B., Chu L.Y.^*, 2009. Effects of surface wettability and roughness of microchannel on flow behaviors of thermo-responsive microspheres therein during the phase transition. Journal of Colloid and Interface Science, 336(1): 162-170. (2022 IF = 9.9)

[138]           Liu L., Yang J.P., Ju X.J., Xie R., Yang L., Liang B., Chu L.Y.^*, 2009. Microfluidic preparation of monodisperse ethyl cellulose hollow microcapsules with non-toxic solvent. Journal of Colloid and Interface Science, 336(1): 100-106. (2022 IF = 9.9)

[139]           Cheng C.J., Chu L.Y.^*, Ren P.W., Zhang J., Hu L., 2007. Preparation of monodisperse thermo-sensitive poly(N-isopropylacrylamide) hollow microcapsules. Journal of Colloid and Interface Science, 313(2): 383-388. (2022 IF = 9.9)

[140]           Hu L., Chu L.Y.^*, Yang M., Wang H.D., Niu C.H., 2007. Preparation and characterization of novel cationic pH-responsive poly(N,N'-dimethylamino ethyl methacrylate) microgels. Journal of Colloid and Interface Science, 311(1): 110-117. (2022 IF = 9.9)

[141]           Cheng C.J., Chu L.Y.^*, Xie R., 2006. Preparation of highly monodisperse W/O emulsions with hydrophobically modified SPG membranes. Journal of Colloid and Interface Science, 300(1): 375-382. (2022 IF = 9.9)

[142]           Chu L.Y.^*, Xie R, Zhu J.H., Chen W.M., Yamaguchi T, Nakao S, 2003. Study on SPG Membrane Emulsification Processes for the Preparation of Monodispersed Core-Shell Microcapsules. Journal of Colloid and Interface Science, 265(1): 187-196. (2022 IF = 9.9)

[143]           Cheng C.J., Chu L.Y.^*, Zhang J., Zhou M.Y., Xie R., 2008. Preparation of monodisperse poly(N-isopropylacrylamide) microspheres and microcapsules via Shirasu-porous-glass membrane emulsification. Desalination, 234(1-3): 184-194. (2022 IF = 9.9)

[144]           Sun M.W.^#, Li Z.^#, Wang Q.Y.^#, Zhang N.^*, Xie R., Ju X.J., Wang W., Liu Z.^*, Chu L.Y., 2023. MoS₂ laminate membranes with structural-phase-dependent permeation for molecular separation. Cell Reports Physical Science, 4(2): 101239. (^#Contributed equally) (2022 IF = 8.9)

[145]           Utada A.S., Chu L.Y., Fernandez-Nieves A., Link D.R., Holtze C., Weitz D.A., 2007. Dripping, jetting, drops and wetting: The magic of microfluidics. MRS Bulletin, 32(9): 702-708. (2022 IF = 5.0)

       ¡°Technical Features¡± article;

       This work was featured in the Front Cover

[146]           Wahrmund J., Kim J.W., Chu L.Y., Wang C., Li Y., Fernandez-Nieves A., Weitz D.A., Krokhin A., Hu Z., 2009. Swelling kinetics of a microgel shell. Macromolecules, 42(23): 9357-9365. (2022 IF = 5.5)

[147]           Wan L.Y., Yuan W.F., Ai W.B., Ai Y.W., Wang J.J., Chu L.Y., Zhang Y.Q.^*, Wu J.F.^*, 2019, An exploration of aptamer internalization mechanisms and their applications in drug delivery. Expert Opinion on Drug Delivery, 16(3): 207-218. (2022 IF = 6.6)

      Invited Paper

[148]           Fang Z., Wan L.Y., Chu L.Y., Zhang Y.Q., Wu J.F., 2015. ¡°Smart¡± nanoparticles as drug delivery systems for applications in tumor therapy. Expert Opinion on Drug Delivery, 12(12): 1943-1953. (2022 IF = 6.6)

[149]           Chen T., Wang S., He F., Guo Z.J., Hu P., Zhao R., Huang Y.D., Chen Q.M., Ji P., Chu L.Y.^*, Zou S.J.^*, 2018. Promotion of Osseointegration Using Protamine/Alginate/Bone Morphogenic Protein 2 Biofunctionalized Composite Coating on Nanopolymorphic Titanium Surfaces. Journal of Biomedical Nanotechnology, 14(5): 933-945. (2022 IF = 2.9)

[150]           He F., Zhang M.J., Wang W.^*, Cai Q.W., Su Y.Y., Liu Z., Faraj Y., Ju X.J., Xie R., Chu L.Y.^*, 2019. Designable Polymeric Microparticles from Droplet Microfluidics for Controlled Drug Release. Advanced Materials Technologies, 4: 1800687. (2022 IF = 6.8)

      Invited Paper for the Special Issue of ¡°Microfluidics¡±

[151]           Luo F., Xie R.^*, Liu Z., Ju X.J., Wang W., Lin S., Chu L.Y.^*, 2015. Smart gating membranes with in situ self-assembled responsive nanogels as functional gates. Scientific Reports, 5: 14708; doi: 10.1038/srep14708. (2022 IF = 4.6)

[152]           Yang C., Wang W.^*, Yao C., Xie R., Ju X.J., Liu Z., Chu L.Y.^*, 2015. Hydrogel walkers with electro-driven motility for cargo transport. Scientific Reports, 5: 13622; doi: 10.1038/srep13622. (2022 IF = 4.6)

[153]           Qiu Y., Wang F., Liu Y.M., Wang W., Chu L.Y., Wang H.L., 2015. Microfluidic-based fabrication, characterization and magnetic functionalization of microparticles with novel internal anisotropic structure. Scientific Reports, 5: 13060; doi:10.1038/srep13060. (2022 IF = 4.6)

[154]           Jia Z.H., Xie R.^*, Hu Y.Q., Ju X.J., Wang W., Liu Z., Chu L.Y., 2023. Thermochromic photonic crystal microspheres with uniform color display and wide coloration range. Macromolecular Rapid Communications, 44(5): 2200800. (2022 IF = 4.6)

[155]           Qin H.Y., Liu Z.^*, Yang X.D., Liu Y.Q., Xie R., Ju X.J., Wang W., Chu L.Y.^*, 2022. Pseudo Polyampholytes with Sensitively Ion-Responsive Conformational Transition Based on Positively Charged Host-Guest Complexes. Macromolecular Rapid Communications, 43(11): 2200127. (2022 IF = 4.6)

[156]           Jia Z.H., Xie R.^*, Qiu Y., Lv X.B., Ju X.J., Wang W., Liu Z., Chu L.Y., 2021. Magnetically Assembled Photonic Crystal Gels with Wide Thermochromic Range and High Sensitivity . Macromolecular Rapid Communications, 42(15): 2100200. (2022 IF = 4.6)

[157]           Wang W., He X.H., Zhang M.J., Tang M.J., Xie R., Ju X.J., Liu Z., Chu L.Y.^*, 2017. Controllable microfluidic fabrication of microstructured materials from nonspherical particles to helices. Macromolecular Rapid Communications, 38(23): 1700429. (2022 IF = 4.6)

       Invited Paper for the Sichuan University Special Issue

[158]           Wang Y.M., Ju X.J.^*, Liu Z., Xie R., Wang W., Wu J.F., Zhang Y.Q., Chu L.Y., 2014. Competitively molecular-/ion-recognition responsive characteristics of poly(N-isopropylacrylamide-co-benzo-12-crown-4-acrylamide) copolymers with benzo-12-crown-4 as both guest and host units. Macromolecular Rapid Communications, 35(14): 1280-1286. (2022 IF = 4.6)

       This work has been featured in the Back Cover

[159]           Mi P., Chu L.Y.^*, Ju X.J., Niu C.H., 2008. A smart polymer with ion-induced negative shift of the lower critical solution temperature for phase-transition. Macromolecular Rapid Communications, 29(1): 27-32. (2022 IF = 4.6)

       Front Cover;

       Ranked No.12 the Most-Accessed Articles in 01/2008

[160]           Ju X.J., Chu L.Y.^*, Mi P., Song H., Lee Y.M., 2006. Synthesis and characterization of a novel thermo-sensitive copolymer of N-isopropylacrylamide and dibenzo-18-crown-6-diacrylamide. Macromolecular Rapid Communications, 27(24): 2072-2077. (2022 IF = 4.6)

       Front Cover

       Ranked No.6 and No.9 the Most-Accessed Articles in Dec. 2006 and Jan. 2007 respectively

[161]           Jiang M.Y., Ju X.J.^*, Deng K., Fan X.X., He X.H., Wu F., He F., Liu Z., Wang W., Xie R., Chu L.Y.^*, 2016. Microfluidic synthesis of composite hollow microfibers for K⁺-responsive controlled release based on host-guest system. Journal of Materials Chemistry B, 4(22): 3925-3935. (2022 IF = 7.0)

[162]           Wu F., Ju X.J.^*, He X.H., Jiang M.Y., Wang W., Liu Z., Xie R., He B.^*, Chu L.Y.^*, 2016. A novel synthetic microfiber with controllable size for cell encapsulation and culture. Journal of Materials Chemistry B, 4(14): 2455-2465. (2022 IF = 7.0)

[163]           Wu F., Wang W.^*, Liu L., Ju X.J., Xie R., Liu Z., Chu L.Y.^*, 2015. Monodisperse hybrid microcapsules with ultrathin shell of submicron thickness for rapid enzyme reaction. Journal of Materials Chemistry B, 3(5): 796-803. (2022 IF = 7.0)

[164]           Wang W., Zhang M.J., Chu L.Y.^*, 2014. Microfluidic approach for encapsulation via double emulsions. Current Opinion in Pharmacology (Special Issue on ¡°New Technologies for Encapsulation¡±), 18: 35-41. (2022 IF = 4.0)

       Invited Paper

       This work has been featured in Cover

[165]           Mou C.L., Wang W.^*, Ju X.J., Xie R., Liu Z., Chu L.Y.^*, 2019. Dual-Responsive Microcarriers with Sphere-in-Capsule Structures for Co-Encapsulation and Sequential Release. Journal of the Taiwan Institute of Chemical Engineers, 98: 63-69. (2022 IF = 5.7)

       Invited Paper for the Special Issue of ¡°Microreactors¡±

[166]           Li X.Y., Xie R.^*, Luo F., Jia Z.H., Shi K., Ju X.J., Wang W., Liu Z., Chu L.Y., 2019. CO₂-Responsive Poly(N,N-dimethylaminoethyl methacrylate) Hydrogels with Fast Responsive Rate. Journal of the Taiwan Institute of Chemical Engineers, 94: 135-142. (2022 IF = 5.7)

       Invited Paper for the WFC12 Special Issue on ¡°Toward Fouling Mitigation¡±

[167]           Ju X.J., Xie R., Yang L., Chu L.Y.^*, 2009. Biodegradable ¡°intelligent¡± materials in response to physical stimuli for biomedical applications. Expert Opinion on Therapeutic Patents, 19(4): 493-507. (2022 IF = 6.6)

       Invited Review

[168]           Ju X.J., Xie R., Yang L., Chu L.Y.^*, 2009. Biodegradable ¡°intelligent¡± materials in response to chemical stimuli for biomedical applications. Expert Opinion on Therapeutic Patents, 19(5): 683-696. (2022 IF = 6.6)

       Invited Review

[169]           Chu L.Y.^*, 2005. Controlled release systems for insulin delivery. Expert Opinion on Therapeutic Patents, 15(9): 1147-1155. (2022 IF = 6.6)

       Invited Review

[170]           Yang X.D., Chen W.^*, Ren Y.^*, Chu L.Y.^*, 2022. Exploration of the adsorption kinetics of surfactants at the water-oil interface via Grand-canonical molecular dynamics simulations. Langmuir, 38(3): 1277-1286. (2022 IF = 3.9)

[171]           Mou C.L., Ju X.J.^*, Zhang L., Xie R., Wang W., Deng N.N., Wei J., Chen Q.M., Chu L.Y.^*, 2014. Monodisperse and fast-responsive poly(N-isopropylacrylamide) microgels with open-celled porous structure. Langmuir, 30(5): 1455-1464. (2022 IF = 3.9)

[172]           Xiao X.C., Chu L.Y.^*, Chen W.M., Wang S., Xie R., 2004. Preparation of submicron-sized monodispersed thermoresponsive core-shell hydrogel microspheres. Langmuir, 20(13): 5247-5253. (2022 IF = 3.9)

[173]           Chu L.Y., Park S.H., Yamaguchi T., Nakao S., 2002. Preparation of micron-sized monodispersed thermo-responsive core-shell microcapsules. Langmuir, 18(5): 1856-1864. (2022 IF = 3.9)

[174]           Jgamadze D., Liu L., Vogler S., Chu L.Y., Pautot S.^*, 2015. Thermo-switching microgel carriers improve neuronal cell growth and cell release for cell transplantation, Tissue Engineering Part C: Methods, 21(1): 65-76. (2022 IF = 3.0)

[175]           Yin W.H., Zhou C.H., Ju X.J.*, Deng Y., Zhang L., Xie R., Wang W., Liu Z., Chu L.Y., 2022. Dual-functional polyetheretherketone surface with programmed sequential drug release coating. Colloids and Surfaces B: Biointerfaces, 219: 112806. (2022 IF = 5.8)

[176]           Chu L.Y.^*, Liang Y.J., Chen W.M., Ju X.J., Wang H.D., 2004. Preparation of glucose-sensitive microcapsules with a porous membrane and functional gates. Colloids and Surfaces B: Biointerfaces, 37(1-2): 9-14. (2022 IF = 5.8)

       This work has been featured in Obesity & Diabetes Week

[177]           Zhang M.J., Chen T., Zhang P., Li Z.L., Chen L., Su Y.Y., Qiu L.D., Peng G., Wang W.^*, Chu L.Y., 2020. Magnetic hierarchical porous SiO₂ microparticles from droplet microfluidics for water decontamination. Soft Matter, 16(10): 2581-2593. (2022 IF = 3.4)

[178]           Zhang M.J., Wang W.^*, Xie R., Ju X.J., Liu L., Gu Y.Y., Chu L.Y.^*, 2013. Microfluidic fabrication of monodisperse microcapsules for glucose-response at physiological temperature. Soft Matter, 9(16): 4150-4159. (2022 IF = 3.4)

       This work has been featured in Inside Front Cover

[179]           Liu L., Yang J.P., Ju X.J., Xie R., Liu Y.M., Wang W., Zhang J.J., Niu C.H., Chu L.Y.^*, 2011. Monodisperse core-shell chitosan microcapsules for pH-responsive burst release of hydrophobic drugs. Soft Matter, 7(10): 4821-4827. (2022 IF = 3.4)

[180]           Liu L., Wang W., Ju X.J., Xie R., Chu L.Y.^*, 2010. Smart thermo-triggered squirting capsules for nanoparticle delivery. Soft Matter, 6(16): 3759-3763. (2022 IF = 3.4)

       This work has been featured in Front Cover;

      Nature Materials;

      Highlights in Chemical Science; and

       Ranked No.3 in Top Ten most-read Soft Matter articles of August 2010, and No.1 in Top Ten most-read Soft Matter articles of September 2010.

[181]           Bremond N., Santanach-Carreras E., Chu L.Y., Bibette J., 2010. Formation of liquid-core capsules having a thin hydrogel membrane: liquid pearls. Soft Matter, 6(11): 2484-2488. (2022 IF = 3.4)

[182]           Shah R.K., Kim J.W., Agresti J.J., Weitz D.A.^*, Chu L.Y.^*, 2008. Fabrication of monodisperse thermosensitive microgels and gel capsules in microfluidic devices. Soft Matter, 4(12): 2303-2309. (2022 IF = 3.4)

       Invited ¡°Highlight" paper

[183]           Jiang Z.Y., Chu L.Y., Wu X.M., Wang Z., Jiang X.B., Ju X.J., Ruan X.H., He G.H.^*, 2020. Membrane-based separation technologies: from polymeric materials to novel process: an outlook from China. Reviews in Chemical Engineering, 36(1): 67-105. (2022 IF = 4.7)

      Invited Paper for the Special Issue of ¡°Chemical Engineering in China¡±

[184]           Yan S., Wan L.Y., Ju X.J.^*, Wu J.F.^*, Zhang L., Li M., Liu Z., Wang W., Xie R., Chu L.Y., 2017. K⁺-Responsive Block Copolymer Micelles for Targeted Intracellular Drug Delivery. Macromolecular Bioscience, 17, 1700143. (2022 IF = 4.6)

       This work has been featured as Front Cover Story;

       This work has been featured in the Advanced Science News;

       http://www.advancedsciencenews.com/drug-loaded-micelles-responding-k/

[185]           Mi P., Ju X.J., Xie R., Wu H.G., Ma J., Chu L.Y.^*, 2010. A novel stimuli-responsive hydrogel for K⁺-induced controlled-release. Polymer, 51(7): 1648-1653. (2022 IF = 4.6)

[186]           Zhang J., Xie R., Zhang S.B., Cheng C.J., Ju X.J., Chu L.Y.^*, 2009. Rapid pH/temperature-responsive cationic hydrogels with dual stimuli-sensitive grafted side chains. Polymer, 50(11): 2516-2525. (2022 IF = 4.6)

[187]           Ju X.J., Liu L., Xie R., Niu C.H., Chu L.Y.^*, 2009. Dual thermo-responsive and ion-recognizable monodisperse microspheres. Polymer, 50(3): 922-929. (2022 IF = 4.6)

[188]           Zhang J., Chu L.Y.^*, Cheng C.J., Mi D.F., Zhou M.Y., Ju X.J., 2008. Graft-type poly(N-isopropylacrylamide-co-acrylic acid) microgels exhibiting rapid thermo- and pH-responsive properties. Polymer, 49(10): 2595-2603. (2022 IF = 4.6)

[189]           Zhang J., Chu L.Y.^*, Li Y.K., Lee Y. M. 2007. Dual thermo- and pH-sensitive poly(N-isopropylacrylamide-co-acrylic acid) hydrogels with rapid response behaviors. Polymer, 48(6): 1718-1728. (2022 IF = 4.6)

[190]           Xiao X.C., Chu L.Y.^*, Chen W.M., Zhu J.H., 2005. Monodispersed thermoresponsive hydrogel microspheres with a volume phase transition driven by hydrogen bonding. Polymer, 46(9): 3199-3209. (2022 IF = 4.6)

[191]           Liu L.Y., Liu Z.^*, Wang Q.Y., Wang F., Li J., Xie R., Ju X.J., Wang W., Pan D.W., Chu L.Y.^*, 2023. Porous functional materials with excellent solar-thermal and electro-thermal properties for desalination of saline water. Separation and Purification Technology, 310: 123184. (2022 IF = 8.6)