Signalling molecular recognition nanocavities with multiple functional groups prepared by molecular imprinting and sequential post-imprinting modifications for prostate cancer biomarker glycoprotein detection.

Fluorescent-signalling molecularly-imprinted nanocavities possessing orthogonal dual interaction sites for the detection of prostate cancer biomarker glycoprotein were constructed through molecular imprinting and sequential multistep post-imprinting modifications (PIMs) using a newly designed multi-functionalised PIM reagent (PIR). The PIR, possessing an interaction site and dual reaction sites for PIMs, enabled us to introduce multiple functions including interaction sites and fluorescent reporter groups in a single PIM site, leading to the sensitive fluorescent detection of target glycoproteins with a high signal-to-noise ratio. Prostate specific antigen (PSA), used as a biomarker for prostate-related diseases, was selected as a target glycoprotein. Surface-initiated atom transfer radical polymerisation from template PSA immobilised the substrate with a functional monomer possessing a phenyl boronic acid group, where the template PSA was designed to possess polymerisation groups aligned with disulphide linkage. Using the thiol groups left after removing templates, PIR could be introduced as the 1st PIM. An evaluation of the effect of crosslinking density and blocking treatment on selective detection indicated that highly selective and sensitive detection of PSA was achieved. Furthermore, the 2nd PIM to introduce fluorescent molecules into the nanocavities led to the fluorescent detection of PSA. The new sequential PIM strategy using multi-functional PIR can potentially create various sophisticated artificial molecular recognition materials.

A Programmable Signaling Molecular Recognition Nanocavity Prepared by Molecular Imprinting and Post-Imprinting Modifications.

Inspired by biosystems, a process is proposed for preparing next-generation artificial polymer receptors with molecular recognition abilities capable of programmable site-directed modification following construction of nanocavities to provide multi-functionality. The proposed strategy involves strictly regulated multi-step chemical modifications: 1) fabrication of scaffolds by molecular imprinting for use as molecular recognition fields possessing reactive sites for further modifications at pre-determined positions, and 2) conjugation of appropriate functional groups with the reactive sites by post-imprinting modifications to develop programmed functionalizations designed prior to polymerization, allowing independent introduction of multiple functional groups. The proposed strategy holds promise as a reliable, affordable, and versatile approach, facilitating the emergence of polymer-based artificial antibodies bearing desirable functions that are beyond those of natural antibodies.