Imprinted polymer-modified hanging mercury drop electrode for differential pulse cathodic stripping voltammetric analysis of creatine

“…In the second, hanging mercury drop electrodes were modified with molecularly imprinted polymers (MIP) for increased selectivity and specificity in the analysis of diquat herbicide [82], creatinine [83] and creatine [84]. No reports of modification of solid electrode substrates by MIP for stripping voltammetry have been found.…”

Strategies, Development and Applications of Polymer-Modified Electrodes for Stripping Analysis

“…In the second, hanging mercury drop electrodes were modified with molecularly imprinted polymers (MIP) for increased selectivity and specificity in the analysis of diquat herbicide [82], creatinine [83] and creatine [84]. No reports of modification of solid electrode substrates by MIP for stripping voltammetry have been found.…”

Strategies, Development and Applications of Polymer-Modified Electrodes for Stripping Analysis

“…Creatine is an important diagnostic substance in the assay of renal, thyroid, and muscular functions, and testing its clearance could also offer a quick and relatively simple biomedical diagnosis of acute myocardial infarction. Therefore determination of creatine in biological fluids is of great interest in clinical diagnosis (Kim et al 1999, Wang et al 2006, Stefan et al 2003, Lakshmi et al 2007, Karakus et al 2006. The typical human reference range for serum/plasma creatine is between 35-140 mM; it can rise to greater than 1000 mM during kidney dysfunction (Stefan et al 2003, Sena et al 1988, Lad et al 2008, Pan et al 2011.…”

Novel creatine biosensors based on all solid-state contact ammonium-selective membrane electrodes

“…Moreover, MIPs are also used for many purposes such as adsorption of 17␤-estradiol (Wei and Mizaikoff, 2007), reflectometric interference spectroscopic sensing of atrazine (Belmont et al, 2007), separation of ephedrine enantiomers (Guerreiro et al, 2008), hanging mercury drop MIP modified electrode for differential pulse cathodic stripping voltammetric analysis of creatine (Lakshmi et al, 2007), fructosyl valine recognition (Rajkumar et al, 2007), solid phase extraction of photosynthesisinhibiting herbicides (Breton et al, 2007), biorecognition solvent extraction agents (Castell et al, 2006), recognition of atrazine (Lavignac et al, 2006), fabrication of bilirubin-specific sensor (Huang et al, 2007), adsorption study of dansylated amino acids by surface plasmon resonance (Li and Husson, 2006), cholesterol recognition (Boonpangrak et al, 2006), recognition of copper (Baghel et al, 2007) recognition of chemical warfare agent sulfur mustard (Boopathi et al, 2006), recognition of ochratoxin A (Turner et al, 2004) and also in catalysing a trans esterification process (Meng et al, 2004).…”

Molecularly imprinted nanopatterns for the recognition of biological warfare agent ricin