Synthesis of Fluorescent Cross-linked Stabilized Polymeric Micelles Based on Salicylidene Schiff Base/Zn2+ Complexes and Sensor for Cu2+ Detection

doi:10.11944/j.issn.1000-0518.2016.06.150413

Chinese Journal of Applied Chemistry ›› 2016, Vol. 33 ›› Issue (6): 701-709.DOI: 10.11944/j.issn.1000-0518.2016.06.150413

• Full Papers • Previous Articles Next Articles

Synthesis of Fluorescent Cross-linked Stabilized Polymeric Micelles Based on Salicylidene Schiff Base/Zn²⁺ Complexes and Sensor for Cu²⁺ Detection

HE Qiangfang^a^b^c^*(),WU Yinghong^a,CAI Zhijian^a,XIE Wang^a

^a Department of Chemistry,Guangdong University of Education,Guangzhou 510303,China
^b State Key Laboratory of Medicinal Chemical Biology,Nankai University,Tianjin 300071,China
^c State Key Laboratory of Molecular Engineering of Polymers,Fudan University,Shanghai 200433,China

Received:2015-11-24 Accepted:2016-01-20 Published:2016-06-01 Online:2016-06-01
Contact: HE Qiangfang
Supported by:
Supported by Guangdong Natural Science Foundation of China(No.2015A030310228), the Open Fund of State Key Laboratory of Medicinal Chemical Biology(Nankai University, No.20140535), the Open Fund of State Key Laboratory of Molecular Engineering of Polymers(Fudan University, No.K2015-16), Doctoral Scientific Research and College Students Innovation Training(Guang Dong University of Education, No.2013ARF06 , No.1427815052)

Abstract

Abstract:

A well-defined polymer with pendant salicylaldehyde groups(PHVB) was achieved by reversible addition-fragmentation chain transfer(RAFT) polymerization with S-1-dodecyl-S'-(α,α'-dimethyl-α″-acetic acid) trithiocarbonate as the RAFT agent and a salicylaldehyde-functionalized vinyl monomer, 2-hydroxy-5-vinylbenzaldehyde(HVB) in THF at 65 ℃. The resulting well-defined polymer with pendant salicylaldehyde groups can react directly with monoamine-terminated PEG(PEG-NH₂, number-average relative molecular mass 2000 g/mL, 0.5 stoichiometric number of the —CHO group in PolyHVB) to afford an amphiphilic graft copolymer bearing a pendant salicylidene Schiff base PHVB-graft-PEG with 50% grafting density. These new polymers were characterized by GPC and ¹HNMR. Owing to the presence of hydrophilic PEG pendants, PHVB-graft-PEG is capable of self-assembling into nano-sized micelles with salicylidene Schiff base functioned cores, PEG coronas in ethanol. Coordination of the pre-assembled PHVB-graft-PEG micelles with Zn(OAc)₂ will endow the polymeric micelles with fluorescence features, and simultaneously the resulting luminescent micelles may be stabilized by ionic cross-linking in consequence of the complex reaction at the core. Thus, the luminescence properties and form of the obtained micelles were investigated by UV-Vis spectra(UV-Vis), fluorescence spectra(FLL), dynamic light scattering(DLS), transmission electron microscopy(TEM) .After removing ethanol by drying, the resultant Zn²⁺ coordinated particles can be re-dispersed readily in water or common organic solvent to form a micellar solution, which display blue fluorescence with maximum emission peak around 460 nm, indicating the same aggregate size(nearly 100 nm) as before re-dispersion. The obtained luminescent nanoparticles can be used as a highly selective fluorescent probe for Cu²⁺ ion over other metal ions such as Cd^{2 +}, Mg²⁺, Ni²⁺, Pb²⁺, Ca²⁺, Hg²⁺, Al³⁺, Mn²⁺ in aqueous solution, and exhibit a linear range of 0~50 μmol/L and detection limit of 0.05 μmol/L Cu²⁺, respectively.

Key words: reversible addition-fragmentation chain transfer polymerization, aldehyde-amine condensation, salicylaldimine/Zn²⁺ complexes polymers, ionic cross-linking, sensor for Cu²⁺ detection

HE Qiangfang, WU Yinghong, CAI Zhijian, XIE Wang. Synthesis of Fluorescent Cross-linked Stabilized Polymeric Micelles Based on Salicylidene Schiff Base/Zn²⁺ Complexes and Sensor for Cu²⁺ Detection[J]. Chinese Journal of Applied Chemistry, 2016, 33(6): 701-709.

References

[1]	Plaquet A,Guillaume M,Champagne B,et al.Investigation on the Second-order Nonlinear Optical Responses in the Ketoenol Equilibrium of Anil Derivatives[J]. J Phys Chem C,2008,112(14):5638-5645.
[2]	Baleizão C,Garcia H. Chiral Salen Complexes:An Overview to Recoverable and Reusable Homogeneous and Heterogeneous Catalysts[J]. Chem Rev,2006,106(9):3987-4043.
[3]	Lahiri D,Majumdar R,Mallick D,et al.Remarkable Photocytotoxicity in Hypoxic HeLa cells by a Dipyridophenazine Copper(Ⅱ) Schiff Base Thiolate[J]. J Inorg Biochem,2011,105(8):1086-1094.
[4]	Cimerman Z,Galic N,Bosner B. The Schiff Bases of Salicylaldehyde and Aminopyridines as Highly Sensitive Analytical Reagent[J]. Anal Chim Acta,1997,343(1/2):145-153.
[5]	Sytnik A, Del Valle J C. Steady-state and Time-resolved Study of the Proton-transfer Fluorescence of 4-Hydroxy-5-azaphenanthrenein Model Solvents and in Complexes with Human Serum Albumin[J]. J Phys Chem,1995,99(34):13028-13032.
[6]	Zapata F,Caballero A,Espinosa A,et al.A Simple but Effective Ferrocene Derivative as a Redox, Colorimetric, and luorescent Receptor for Highly Selective Recognition of Zn2+ Ions[J]. Org Lett,2007,9(12):2385-2388.
[7]	Li N,Xiang Y,Chen X,et al.Salicylaldehyde Hydrazones as Fluorescent Probes for Zinc Ion in Aqueous Solution of Physiological pH[J]. Talanta,2009,79(2):327-332.
[8]	Xu Z,Yoon J,Spring D R. Fluorescent Chemosensors for Zn2+[J]. Chem Soc Rev,2010,39(6):1996-2006.
[9]	Wang L N,Qin W W,Tang X L,et al.Development and Applications of Fluorescent Indicators for Mg2+ and Zn2+[J]. J Phys Chem A,2011,115(9):1609-1616.
[10]	Safin D A,Babashkina M G,Garcia Y. Crown Ether-containing Schiff Base as a Highly Efficient “turn-on” Fluorescent Sensor for Determination and Separation of Zn2+ in Water[J]. Dalton Trans,2013,42(6):1969-1972.
[11]	Khatua S,Choi S H,Lee J,et al.Highly Selective Fluorescence Detection of Cu2+ in Water by Chiral Dimeric Zn2+ Complexes Through Direct Displacement[J]. Inorg Chem,2009,48(5):1799-1801.
[12]	Khatua S,Kang J,Churchill D G. Direct Dizinc Displacement Approach for Efficient Detection of Cu2+ in Aqueous Media:Acetate Versus Phenolate Bridging Platforms[J]. New J Chem,2010,34(6):1163-1169.
[13]	Gou C,Qin S H,Wu H Q,et al.A HighlySelective Chemosensor for Cu2+ and Al3+ in Two Different Ways Based on Salicylaldehyde Schiff[J]. Inorg Chem Commun,2011,14(10):1622-1625.
[14]	Sinha S,Koner R R,Kumar S,et al.Imine Containing Benzophenone Scaffold as an Efficient Chemical Device to Detect Selectively Al3+[J]. RSC Adv,2013,3(2):345-351.
[15]	Upadhyay K K,Kumar A. Pyrimidine Based Highly Sensitive Fluorescent Receptor for Al3+ Showing Dual Signalling Mechanism[J]. Org Biomol Chem,2010,8(21):4892-4897.
[16]	Zhou L,Feng Y,Cheng J H,et al.Simple, Selective, and Sensitive Colorimetric and Ratiometric Fluorescence/Phosphorescence Probes for Platinum(Ⅱ) Based on Salen-type Schiff Bases[J]. RSC Adv,2012,2(28):10529-10536.
[17]	Xu Y,Meng J,Meng L X,et al.A Highly Selective Fluorescence-Based Polymer Sensor Incorporating an (R,R)-Salen Moiety for Zn2+ Detection[J]. Chem-Eur J,2010,16(43):12898-12903.
[18]	Song F Y,Ma X,Hou J L,et al.(R,R)-Salen/salan-based Polymer Fluorescence Sensors for Zn2+ Detection[J]. Polymer,2011,52(26):6029-6036.
[19]	Hou J L,Song F Y,Wang L,et al.In Situ Generated 1:1 Zn(Ⅱ)-containing Polymer Complex Sensor for Highly Enantioselective Recognition of N-Boc-protected Alanine[J]. Macromolecules,2012,45(19):7835-7842.
[20]	Li J F,Wu Y Z,Song F Y,et al.A Highly Selective and Sensitive Polymer-based OFF-ON Fluorescent Sensor for Hg2+ Detection Incorporating Salen and Perylenyl Moieties[J]. J Mater Chem,2012,22(2):478-482.
[21]	Song F Y,Wei G,Wang L,et al.Salen-based Chiral Fluorescence Polymer Sensor for Enantioselective Recognition of α-Hydroxyl Carboxylic Acids[J]. J Org Chem,2012,77(10):4759-4764.
[22]	Xu Y,Zheng L F,Huang X B,et al.Fluorescence Sensors Based on Chiral Polymer for Highly Enantioselective Recognition of Phenylglycinol[J]. Polymer,2010,51(5):994-997.
[23]	Cho Y S,Ihn C S,Lee H K,et al.Synthesis and Properties of Ruthenium-Coordinated Block Copolymers of 2-Vinylpyridine and Carbazole Derivatives[J]. Macromol Rapid Commun,2001,22(15):1249-1253.
[24]	Smith A P,Fraser C L. Luminescent Polymeric Ruthenium Complexes with Polystyrene-b-poly(methyl methacrylate) Macroligands:The Sequential Activation of Initiator Sites for Blocks Generated by Parallel Polymerization Mechanisms[J]. J Polym Sci Part A:Polym Chem,2002,40(23):4250-4255.
[25]	Cong Y,Fu J,Cheng Z,et al.Self-organization and Luminescent Properties of Nanostructured Europium(Ⅲ)-block Copolymer Complex Thin Films[J]. J Polym Sci Part B:Polym Phys,2005,43(16):2181-2189.
[26]	Chen B,Sleiman H F. Ruthenium Bipyridine-Containing Polymers and Block Copolymers via Ring-Opening Metathesis Polymerization[J]. Macromolecules,2004,37(16):5866-5872.
[27]	Wulff G,Akelah A. Synthesis of 5-Vinylsalicylaldehyde and a Simplified Synthesis of Some Divinyl Derivatives[J]. Makromol Chem,1979,179:2647-2651.
[28]	Lai J T,Filla D,Shea R. Functional Polymers from Novel Carboxyl-terminated Trithiocarbonates as Highly Efficient RAFT Agents[J]. Macromolecules,2002,35(18):6754-6756.
[29]	Wang Y,Goethals E J, Du Prez F E. Association Behavior between End-Functionalized Block Copolymers PEO-PPO-PEO and Poly(acrylic acid)[J]. Macromol Chem Phys,2004,205(13):1774-1781.
[30]	Xin Y,Yuan J Y. Schiff's Base as a Stimuli-responsive Linker in Polymer Chemistry[J]. Polym Chem,2012,3(11):3045-3055.
[31]	Zhao L Y,Sui D,Chai J,et al.Digital Logic Circuit Based on a Single Molecular System of Salicylidene Schiff Base[J]. J Phys Chem B,2006,110(48):24299-24304.
[32]	Wu J,Liu W,Zhuang X,et al.Fluorescence Turn on of Coumarin Derivatives by Metal Cations:A New Signaling Mechanism Based on C=N Isomerization[J]. Org Lett,2007,9(1):33-36.

Synthesis of Fluorescent Cross-linked Stabilized Polymeric Micelles Based on Salicylidene Schiff Base/Zn²⁺ Complexes and Sensor for Cu²⁺ Detection

RichHTML

PDF

Knowledge

Cited

Abstract

Cite this article

share this article

References

Related Articles 3

Recommended Articles

Metrics

Comments

[1]	XU Chenxi, CAO Minghan, PENG Jing, LI Jiuqiang, ZHAI Maolin. Modification of Cellulose Triacetate Membranes with Glycidyl Methacrylate via γ-Ray Initiated Controlled Grafting [J]. Chinese Journal of Applied Chemistry, 2020, 37(3): 293-300.
[2]	XU Chenxi, CAO Minghan, PENG Jing, LI Jiuqiang, ZHAI Maolin. Modification of Cellulose Triacetate Membranes with Glycidyl Methacrylate via γ-Ray Initiated Controlled Grafting [J]. Chinese Journal of Applied Chemistry, 2020, 37(3): 0-0.
[3]	SUN Tingting1,2, LI Wenliang1, XIE Zhigang1*, JING Xiabin1. Preparation and Application of Heterogeneous Photocatalysts Based on New Cross-Linked Polymers [J]. Chinese Journal of Applied Chemistry, 2014, 31(05): 548-552.