A Molecularly Imprinted Copolymer Designed for Enantioselective Recognition of Glutamic Acid

Ouyang, Ruizhuo; Lei, Jianping; Ju, Huangxian; Xue, Yadong

doi:10.1002/adfm.200700143

Cited by 102 publications

(63 citation statements)

References 37 publications

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“…rendering hydrophobic surface cell adhesive [17] to building blocks in biosensing platforms e.g. as matrix polymer for molecular imprinting [18], and for life cell encapsulation [19]. PDA capsules have been considered using particles [20][21][22][23] or oil emulsion droplets [24] as templates.…”

Section: Introductionmentioning

confidence: 99%

Myoblast Cell Interaction with Polydopamine Coated Liposomes

et al. 2012

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Liposomes are widely used, from biosensing to drug delivery. Their coating with polymers for stability and functionalization purposes further broadens their set of relevant properties. Poly(dopamine) (PDA), a eumelanin-like material deposited via the “self”-oxidative polymerization of dopamine at mildly basic pH, has attracted considerable interest in the past few years due to its simplicity, flexibility yet fascinating properties. Herein, we characterize the coating of different types of liposomes with PDA depending on the presence of oleoyldopamine in the lipid bilayer and the dopamine hydrochloride concentration. Further, the interaction of these coated liposomes in comparison to their uncoated counterparts with myoblast cells is assessed. Their uptake/association efficiency with these cells is determined. Further, their dose-dependent cytotoxicity with and without entrapped hydrophobic cargo (thiocoraline) is characterized. Taken together, the reported results demonstrate the potential of PDA coated liposomes as a tool in biomedical applications. Supplementary Material 13758_2011_8_MOESM1_ESM.doc (83KB)

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Section: Introductionmentioning

confidence: 99%

Myoblast Cell Interaction with Polydopamine Coated Liposomes

et al. 2012

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“…et al, 2003), which were used to detect many different analytes (Augisto et al, 2010) such as barbituric acid (Mirsky et al, 1999), amino acid derivatives (Panasyuk et al, 1999), morphine , atrazine (Kim Y. et al, 2007), benzyltriphenylphosphonium chloride , thiophenol (Kröger et al, 1999), glutamic acid (Ouyang et al, 2007), folic acid (Prasad et al, 2010a;Prasad et al, 2010c), tolazoline (Zhang Z. et al, 2010a), tryptophan (Prasad et al, 2010d;Kong Y. et al, 2010), clindamycin , 2,4-dichlorophenoxy acetic acid (Xie et al, 2010), histamine (Bongaers et al, 2010) Despite the application of MIPs as sensor matrices or separation materials, they suffer from basic limitations associated with the limited concentration of imprinted sites, and the bulk volume of the polymer matrices that requires long diffusion paths of the imprinted host molecules. These limitations lead to inefficient sensing or separation processes .…”

Section: Mips In Chemical Sensingmentioning

confidence: 99%

Carbon Nanotubes – Imprinted Polymers: Hybrid Materials for Analytical Applications

Cirillo¹,

Hampel²,

Puoci³

et al. 2012

Materials Science and Technology

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“…Recently electrosynthesized polymers such as poly(dopamine) (PDA) and poly(ophenylendiamine) (Po-PD) have been prepared to form a novel well-defined structure MIP at an electrode. The designed copolymer film could be used for the recognition of the enantiomer, as a capacitive sensor (Ouyang et al, 2007) On the other hand some authors have focused their studies on the "gate effect" which is a phenomenon where solute permeability of the molecularly imprinted polymer membrane changes with specific binding with the template . The "gate effect" is probably caused by a morphological change in the polymer matrix due to specific binding with the template, similar to the "induced fit" of the natural receptors.…”

Section: Enantioselective Electrochemical Sensorsmentioning

confidence: 99%