Open Access Open Access  Restricted Access Subscription Access

Ph and Temperature Dual-sensitive Molecular Imprint Polymers for Bsa Based on Cu2+ Coordination


Affiliations
1 College of Environmental and Chemical Engineering, Xi′an Polytechnic University, Jinhua Nan Road 19#,Xi′an 710 048,, China
 

A novel kind of pH and temperature dual-sensitive Molecular imprint polymers (MIPs) combined with Cu2+ coordination (SiO2@CS/NIPAM-Cu2+-MIP) has been synthesized using glycidyl methacrylate-iminodiacetic acid (GMA-IDA) as a metalchelating ligand, with bovine serum albumin (BSA) as template protein, combined with pNIPAM and chiston (CS) as temperature and pH sensitive monomers, respectively. The coordination effect of GMA-IDA-Cu2+ has been shown to be beneficial to improve the adsorption capacity and adsorption specificity of BSA. The influence of pH not only changed the charge force between the polymer and protein in the imprinting system, but also deformed the imprinting cavity through the protonation of NH3+ on CS. Further, the thermo-sensitivity of the imprinted polymer was also found to be satisfactory. Withthe joint efforts of coordination, electrostatic action and good matching of imprinted sites, higher adsorption capacity (173.48 mg∙g-1) and imprinting factor (2.72) have been obtained at pH 4.6 and 35ºC. Although it took about 4 h to reach saturation adsorption, the cyclability of the SiO2@CS/NIPAM-Cu2+-MIP was found to be acceptable and the adsorptioncapacity was maintained at original 81.16% after six cycles. It is for the first time that GMA-IDA-Cu2+ has been used to prepare the pH and temperature dual-sensitive imprinted polymer for BSA.

Keywords

GMA-IDA-Cu2+, Molecular imprinting polymer, pH and temperature dual-sensitivity
User
Notifications
Font Size

  • Wulff A & Sarhan G, Angew Chemie Int Edn. English, 11 (1972) 334.
  • Xing R, Ma Y, Wang Y, Wen Y & Liu Z, Chem Sci, 10 (2019) 1831.
  • Ansari S & Masoum S, Anal Chem, 114 (2019) 29.
  • Luo J, Huang J, Cong J J, Wei W & Liu X Y, ACS Appl Mater Interfaces, 9 (2017) 7735.
  • Zhao Y J, Chen Y J, Fang M Y, Tian Y B, Bai G Y & Zhuo K L, Anal Bioanal Chem, 412 (2020) 5811.
  • Dabrowski M, Ziminska A, Kalecki J, Cieplak M, Lisowski W, Maksym R, Shao S, D’Souza F, Kuhn A & Sharma P S, ACS Appl Mater Interfaces, 11 (2019) 9265.
  • Hoshino Y, Koide H, Urakami T, Kanazawa H, Kodama T, Oku N & Shea K J, J Am Chem Soc, 132 (2010) 6644.
  • Yang H, Li L, Ding Y, Ye D, Wang Y, Cui S & Liao L, Biosens Bioelectron, 92 (2017) 748.
  • Zaidi S A, Drug Deliv, 23 (2016) 2262.
  • Chen L, Xu S & Li J, Chem Soc Rev, 40 (2011) 2922.
  • Li X, Zhou J, Tian L, Wang Y, Zhang B, Zhang H & Zhang Q, Sensor Actuat B-Chem, 241 (2017) 413.
  • Zuoting Yang, Junjie Chen, Ke Yang, Qiuyu Zhang & Baoliang Zhang, J Colloid Interface Sci, 570 (2020) 182.
  • Ali Jahanban-Esfahlan, Leila Roufegarinejad, Rana Jahanban-Esfahlan, Mahnaz Tabibiazar & Ryszard Amarowiczh, Talanta, 207 (2020) 120317.
  • Kaiguang Yang, Senwu Li, Jianxi Liu, Lukuan Liu, Lihua Zhang & Yukui Zhang, Anal Chem, 88 (2016) 5621.
  • Shiting Zhang, Zhiqiang Liu,Siyu Jin, Yufei Bai, Xingjia Feng & Guoqi Fu, Talanta, 234 (2021) 122690.
  • Zhou J, Wang Y, Ma Y, Zhang B & Zhang Q, Appl Surf Sci, 486 (2019) 265.
  • Lishuang Wang & Longshan Zhao, Colloids Surfaces A: Physicochem Eng Asp, 632 (2022) 127843.
  • Ertürk G, Berillo D, Hedström M & Mattiasson B, Biotechnol Rep, 3 (2014) 65.
  • Xia J, Cao X, Wang Z, Yang, M Zhang F, Lu B, Li F, Xia L, Li Y & Xia Y, Sens Actuators B Chem, 225 (2016) 305.
  • Ohno Y, Maehashi K, Yamashiro Y & Matsumoto K, Nano Lett, 9 (2009) 3318.
  • Murugan E, Rani D P G, Srinivasan K & Muthumary J, Expert Opin Drug Deliv, 10 (2013) 1319.
  • Yogaraj V, Gowtham G, Akshata C R, Manikandan R, Murugan E & Arumugam M, J Drug Deliv Sci Technol, 58 (2020) 101785.
  • Murugan E, Rani D P G & Yogaraj V, Colloids Surfaces B Biointerfaces, 114 (2014) 121.
  • Murugan E, Akshata C R, Yogaraj V, Sudhandiran G & Babu D, Ceram Int, 48 (2022) 16000.
  • Murugan E, Yogaraj V, Rani D P G & Sinha A K, RSC Adv, 5 (2015) 106461.
  • Yilin Wu, Li Chen, Tongfan Hao, Jian Lu, Jia Gao, Xinyu Lin, Jiuyun Cui, Chunxiang Li & Yongsheng Yan, J Colloid Interface Sci, 531 (2018) 1.
  • Chen H J, Zhang Z H & Luo L J, Senso Actuat B: Chem, 163 (2012) 76.
  • Deng Z, Zhen Z & Hu X, Biomaterials, 32 (2011) 4976.
  • Liu Y, Chen M M & Song L, J Luminescence, 134 (2013) 515.
  • Chen H, Kong J & Yuan D, Biosens Bioelectron, 53 (2014) 5.
  • El-Sharif H F, Yapati H & Kalluru S, Acta Biomater, 28 (2015) 121.
  • Liu M, Pi J & Wang X, Analytica Chimica Acta, 932 (2016) 29.
  • Qin L, He X W & Zhang W, Anal Chem, 81 (2009) 7206.
  • Li W, Sun Y & Yang C, JACS Appl Mater Interfaces, 7 (2015) 27188.
  • Dong X, Ma Y & Hou C, Polym Int, 2019 (2019) 955.
  • Xu J, Prost E & Haupt K, Sens Actuat B: Chem, 258 (2018) 10.
  • Li W, Sun Y & Yang C, JACS Appl Mater Interfaces, 7 (2015) 27188.
  • Wang P, Zhu H & Liu J, Chem Eng J, 358 (2019) 143.
  • Li X, Zhang B & Li W, Biosens Bioelectron, 51 (2014) 261.
  • Zhou J, Wang Y & Ma Y, Appl Surf Sci, 486 (2019) 265.
  • Wang Y, Zhou J & Zhang B, Chem Eng J, 327 (2017) 932.
  • El-Sharif H F, Yapati H, Kalluru S & Reddy S M, Acta Biomaterialia, 28 (2015) 121.
  • Huachang Chen, Juan Kong, Dongying Yuan & Guoqi Fu, Biosens Bioelectron, 53 (2014) 5.
  • Xiajuan Zou, Dan Liu, Lijun Zhong, Bin Yang, Yaxin Lou, Baihe Hu & Yuxin Yin, Anal Bioanal Chem, 401 (2011) 1251.
  • Wang S, Yang L, Cho H Y, Dean Chueng S T, Zhang H, Zhang Q & Lee K B, Biomaterials, 224 (2019) 119498.
  • Wang S, Zheng H, Zhou L, Cheng F, Liu Z, Zhang H, Wang L & Zhang Q, Nano Lett, 20 (2020) 5149.
  • Xu J, Prost E & Haupt K, Sens Actuat B: Chem, 258 (2018) 10.
  • Wang P, Zhu H & Liu J, Chem Eng J, 358 (2019) 143.
  • Zheng J, Lin Z & Lin G, J Mater Chem B, 3 (2015) 2185.
  • Wu J, Luan M & Zhao J, J Biol Macromol, 39 (2006) 185.

Abstract Views: 120

PDF Views: 100




  • Ph and Temperature Dual-sensitive Molecular Imprint Polymers for Bsa Based on Cu2+ Coordination

Abstract Views: 120  |  PDF Views: 100

Authors

Xiangzhi Dong
College of Environmental and Chemical Engineering, Xi′an Polytechnic University, Jinhua Nan Road 19#,Xi′an 710 048,, China
Baoliang Zhang
College of Environmental and Chemical Engineering, Xi′an Polytechnic University, Jinhua Nan Road 19#,Xi′an 710 048,, China
Qiuyu Zhang
College of Environmental and Chemical Engineering, Xi′an Polytechnic University, Jinhua Nan Road 19#,Xi′an 710 048,, China

Abstract


A novel kind of pH and temperature dual-sensitive Molecular imprint polymers (MIPs) combined with Cu2+ coordination (SiO2@CS/NIPAM-Cu2+-MIP) has been synthesized using glycidyl methacrylate-iminodiacetic acid (GMA-IDA) as a metalchelating ligand, with bovine serum albumin (BSA) as template protein, combined with pNIPAM and chiston (CS) as temperature and pH sensitive monomers, respectively. The coordination effect of GMA-IDA-Cu2+ has been shown to be beneficial to improve the adsorption capacity and adsorption specificity of BSA. The influence of pH not only changed the charge force between the polymer and protein in the imprinting system, but also deformed the imprinting cavity through the protonation of NH3+ on CS. Further, the thermo-sensitivity of the imprinted polymer was also found to be satisfactory. Withthe joint efforts of coordination, electrostatic action and good matching of imprinted sites, higher adsorption capacity (173.48 mg∙g-1) and imprinting factor (2.72) have been obtained at pH 4.6 and 35ºC. Although it took about 4 h to reach saturation adsorption, the cyclability of the SiO2@CS/NIPAM-Cu2+-MIP was found to be acceptable and the adsorptioncapacity was maintained at original 81.16% after six cycles. It is for the first time that GMA-IDA-Cu2+ has been used to prepare the pH and temperature dual-sensitive imprinted polymer for BSA.

Keywords


GMA-IDA-Cu2+, Molecular imprinting polymer, pH and temperature dual-sensitivity

References