Abstract
Nanostructured bupivacaine-selective molecularly imprinted 3-aminophenylboronic acid-p-phenylenediamine co-polymer (MIP) films have been prepared on gold-coated quartz (Au/quartz) resonators by electrochemical synthesis under cyclic voltammetric conditions in a liquid crystalline (LC) medium (triton X-100/water). Films prepared in water and in the absence of template were used for control studies. Infrared spectroscopic studies demonstrated comparable chemical compositions for LC and control polymer films. SEM studies revealed that the topologies of the molecularly imprinted polymer films prepared in the LC medium (LC-MIP) exhibit discernible 40 nm thick nano-fiber structures, quite unlike the polymers prepared in the absence of the LC-phase. The sensitivity of the LC-MIP in a quartz crystal microbalance (QCM) sensor platform was 67.6 ± 4.9 Hz/mM under flow injection analysis (FIA) conditions, which was ≈250% higher than for the sensor prepared using the aqueous medium. Detection was possible at 100 nM (30 ng/mL), and discrimination of bupivacaine from closely related structural analogs was readily achieved as reflected in the corresponding stability constants of the MIP-analyte complexes. The facile fabrication and significant enhancement in sensor sensitivity together highlight the potential of this LC-based imprinting strategy for fabrication of polymeric materials with hierarchical architectures, in particular for use in surface-dependent application areas, e.g., biomaterials or sensing.
Highlights
In this study we have explored a bottom-up strategy where liquid crystalline (LC) structures are used to impart nano-scale structuring in molecularly imprinted polymer films and we have examined the impact of the resulting morphological features on the performance of films imprinted with the local anesthetic bupivacaine when used in a quartz crystal microbalance (QCM) platform
Thin polymer film coatings of molecularly imprinted materials have become of increasing interest in this area due to their stability, possibilities of regulating their thickness during fabrication and the broad range of structures that are amenable for use as a template
Nanostructured bupivacaine-selective molecularly imprinted 3-aminophenylboronic acid-pphenylenediamine co-polymer films have been prepared on gold-coated quartz (Au/quartz) resonators by electrochemical synthesis under cyclic voltammetric conditions in a liquid crystalline (LC) medium (Triton X-100)
Summary
In surface-based sensing technologies such as quartz crystal microbalance (QCM), surface plasmon resonance (SPR), total internal reflectance fluorescence spectroscopy (TIRF) and electrochemical sensing, the proximity of the analyte to the transducer surface is critical for the sensor response [1,2,3,4,5,6]. Imprinted polymer (MIP) [10,11,12,13,14] films have attracted significant interest for use in such sensor platforms due to the possibility of tailoring the ligand recognition characteristics of the material through the templating process, together with the advantages described above [15,16,17,18]. In this study we have explored a bottom-up strategy where liquid crystalline (LC) structures are used to impart nano-scale structuring in molecularly imprinted polymer films and we have examined the impact of the resulting morphological features on the performance of films imprinted with the local anesthetic bupivacaine when used in a QCM platform
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