Contact Information

  • Name:Tianbin Ren
  • Phone:
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  • Email: rtb002@163.com
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  • Title:

Research Fields:

1)Functional Adhesives and Coatings
2)Biomaterials/Targeted and Sustained Release Drugs
3)Therapeutic vaccine nanocarriers
4)Analysis Method for Complex Material Systems  

 

Current Courses:

Nanocomposites
Material Technology Design
Theory and Practice of material innovation
 
 

 

Projects:

1) National Natural Science Foundation Project (31971323): Black cell target-regulating tumor  oxidative stress microenvironment for improved photothermal therapy (2020.1-2023.12)
2) National Natural Science Foundation Project (81571801) Suppression of Immune Response of Therapeutic Vaccine Carrier by Nano-engineering Technology (2016.1-2019.12)
3) National Natural Science Foundation Project (8167 1944) Study on the Mechanism of Subarea Isolation of Nanovaccine against Pan-resistant Klebsiella pneumoniae (2017.1-2020.12)
4) Key projects of fundamental scientific research funds in universities “Experimental study on the mechanism of sequential and highly effective killing of drug-resistant triple-negative breast cancer by nanocyclopatamine combined with PD-L1” (2017-2019)  

 

 

Publications:

1) Shun Luo, Lin Fan, Kai Yang, Zhen Zhong, Xiaojian Wu and Tianbin Ren*. In situ and controllable synthesis of Ag NPs in tannic acid-based hyperbranched waterborne polyurethanes to prepare antibacterial polyurethanes/Ag NPs composites. RSC Adv., 2018,8, 36571-36578  
2) Shun Luo, Kai Yang, Zhen Zhong, Xiaojian Wu and Tianbin Ren*. Facile preparation of degradable multi-arm-star-branched waterborne polyurethane with bio-based tannic acid. RSC Adv., 2018,8, 37765-37773
3) Kun Wang, Shuman Wen, Lianghua He, Ang Li, Yan Li, Haiqing Dong, Wei Li, Tianbin Ren, Donglu Shi, Yongyong Li* “Minimalist” Nanovaccine Constituted from Near Whole Antigen for Cancer Immunotherapy ACS Nano, 2018, 12 (7), 6398–6409
4) Yan Li, Lianghua He, Haiqing Dong, Yiqiong Liu, Kun Wang, Ang Li, Tianbin Ren, Donglu Shi, Yongyong Li*. Fever‐Inspired Immunotherapy Based on Photothermal CpG Nanotherapeutics: The Critical Role of Mild Heat in Regulating Tumor Microenvironment. Advanced Science2018,5,6:1700805 ( 2018-03-25)
5) Xiaoqi Yan,  Jianbo Li* and  Tianbin Ren. Synthesis of well-defined star, star-block, and miktoarm star biodegradable polymers based on PLLA and PCL by one-pot azide–alkyne click reaction. RSC Advances. 2018,8, 51:29464-29475
6) Xiaoqi Yan, Jianbo Li, Tianbin Ren. Synthesis of Miktoarm Star-shaped and Inverse Star-block Copolymers by Combination of Ring-opening Polymerization and Click Chemistry. e-Polymers. 2018,18,6:559-568
7) Zhen Zhong, Shun Luo, Kai Yang, Xiaojian Wu, Tianbin Ren*. High-performance anionic waterborne polyurethane/Ag nanocomposites with excellent antibacterial property via in situ synthesis of Ag nanoparticles.RSC Advances. 2017,7, 67: 42296-42304
8) Min Tang, Haiqing Dong, Yongyong Li, Tianbin Ren*. Harnessing the PEG-cleavable strategy to balance cytotoxicity, intracellular release and the therapeutic effect of dendrigraft poly-L-lysine for cancer gene therapy. Journal of Materials Chemistry B. 2016,4,7 1284-1295  
9) Min Tang, Haiqing Dong, Xiaojun Cai, Haiyan Zhu, Tianbin Ren, Yongyong Li. Disulfide-Bridged Cleavable PEGylation of Poly- l -Lysine for SiRNA Delivery. Methods of Molecular Biology. 2016, 1364, 49-61
10) Zhou JS, Li Y, Dong HQ, Yuan H, Ren TB*, Li YY*. Effect of monomer sequence of poly(histidine/ lysine) catiomers on gene packing capacity and delivery efficiency. RSC Advances . 2015,5(19): 14138-14146
11) Dong HQ, Dong HY, Xia WJ, Li YY , Ren TB*. Self-assembled, Redox-sensitive, H-shaped   Pegylated Methotrexate Conjugates with High Drug-carrying Capability for Intracellular Drug Delivery. MedChemComm, 2014,5, 147-152
12) Li YY, Lei X, Dong HQ, Ren TB*.Sheddable, degradable, cationic micelles enabling drug and gene delivery. RSC Advances, 2014,4, 8165-8176
13) Zhu HY,Dong CY,Dong HQ, Ren TB,Wen XJ, Su JS, Li YY. Cleavable PEGylation and Hydrophobic Histidylation of Polylysine for siRNA Delivery and Tumor Gene Therapy. ACS Appl. Mater. Interfaces, 2014,6(13), 10393–10407
14) Dong HQ, Dong CY, Ren TB, Li YY, Shi DL.Surface-Engineered Graphene-Based Nanomaterials for Drug Delivery. Journal of Biomedical Nanotechnology. 2014, 10(9), 2086-2106
15) Jia MH, Ren TB, Wang A, Yuan WZ, Ren J. Amphiphilic star-shaped poly(ε-caprolactone)- block-poly(l-lysine) copolymers with porphyrin core: Synthesis, self-assembly, and cell viability assay, Journal of Applied Polymer Science 2014,131(7), 40097
16) Ren TB, Wu W, Jia MH, Dong HQ, Li YY, Ou ZL. Reduction-Cleavable Polymeric Vesicles with Efficient Glutathione-Mediated Drug Release Behavior for Reversing Drug Resistance/ACS Appl. Mater. Interfaces  2013, 5 (21), 10721–10730
17) Ren TB*, Liu CJ, Wu W, Ye K, YuanWZ*. Synthesis, characterization, crystalline morphologies and hydrophilicity of A4BA4 nonlinear block copolymers. Polymer  International, 2013, 62 (10) :1500–1506
18) Li YY, Li Lan, Dong HQ*, Cai XJ, Ren TB *. Pluronic F127 nanomicelles engineered with nuclear localized functionality for targeted drug delivery. Materials Science and Engineering: C,  2013, 33(5): 2698–2707
19) Chu M, Dong CY, Zhu HY, Cai XJ , Dong HQ, Ren TB,  et al. Biocompatible polyethylenimine-graft-dextran catiomer for highly efficient gene delivery assisted by a nuclear targeting ligand. Polymer. Chemisty, 2013,4, 2528-2539
20) Ren TB, Li L, Cai XJ et al. Engineered polyethylenimine/graphene oxide nanocomposite for nuclear localized gene delivery. Polymer chemistry,2012,9:1759-9954.
21) Ren TB, Liu QM, Lu H et al. Multifunctional Polymer Vesicles for Ultrasensitive Magnetic Resonance Imaging and Drug Delivery, Journal of materials chemistry 2012, 22, 12329-12338.
22) Ren TB, Lei X, Yuan WZ. Synthesis and self-assem bly of double-hydrophilic pentablock copolymer with pH and temperature responses via sequential atom transfer radical polymerization. Materials letters, 2012,67(1):383-386.
23) Lu H, Fan L, Liu QM, Wei JR,  Ren TB et al. Preparation of water-dispersible silver-decorated polymer vesicles and micelles with excellent antibacterial efficacy. POLYMER CHEMISTRY  2012,3(8): 2217-2227.
24) Ren TB, Feng Y, Zhang ZH, et al. Shell-sheddable micelles based on star-shaped poly(epsilon-caprolactone)-SS-poly(ethyl glycol) copolymer for intracellular drug release Soft matter. 2011, 7(6): 2329-2331. ESI highly cited paper,  top ten most-read article
25) Ren TB, Wang A, Yuan WZ, et al. Synthesis, Self-Assembly, Fluorescence, and Thermosensitive Properties of Star-Shaped Amphiphilic Copolymers with Porphyrin Core. Journal of polymer science part a-polymer chemistry. 2011,49(10):2303-2313.
26) Ren TB; Xia WJ; Dong HQ. Sheddable micelles based on disulfide-linked hybrid PEG-polypeptide copolymer for intracellular drug delivery. Polymer. 2011,20(52): 3580-3586.
27) Ren TB, Feng Y, Dong HQ, et al. Sheddable Nanoparticles for Biomedical Application. Progress in chemistry. 2011, 23(1): 213-220.
28) Ren TB, Xu N, Cao CH, et al. Preparation and Therapeutic Efficacy of Polysorbate-80-Coated Amphotericin B/PLA-b-PEG Nanoparticles. Journal of biomaterials science- polymer edition. 2009, 20(10): 1369-1380.
29) Ren J, Fu HY, Ren TB, et al.Preparation, characterization and properties of binary and ternary blends with thermoplastic starch, poly(lactic acid) and poly(butylene adipate-co-terephthalate) Carbohydrate polymers,2009,77(3)576-582
30) Ren TB, Weigel T, Groth T et al. Microwave plasma surface modification of silicone elastomer with Allylamine for improvement of biocompatibility. Journal of biomedical materials research part A. 2008,86A(1): 209-219.

 

 

 


 

 

 

 

 

 

 

 

 

Pre:Chuncai Zhou

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