Core-Shell Molecularly Imprinted Polymer Nanocomposites for Biomedical and Environmental Applications

Molecularly imprinted polymer composite membranes: From synthesis to diverse applications

This review underscores the fundamentals of MIP-CMs and systematically summarizes their synthetic strategies and applications, and potential developments. MIP-CMs are widely acclaimed for their versatility, finding applications in separation, filtration, detection, and trace analysis, as well as serving as scaffolds in a range of analytical, biomedical and industrial contexts. Also characterized by extraordinary selectivity, remarkable sensitivity, and outstanding capability to bind molecules, those membranes are also cost-effective, highly stable, and configurable in terms of recognition and, therefore, inalienable in various application fields. Issues relating to the potential future for the paper are discussed in the last section with the focus on the improvement of resource practical application across different areas. Hence, this review can be seen as a kind of cookbook for the design and fabrication of MIP-CMs with an intention to expand the scope of their application.

Enhanced Antibacterial Activity of Highly Biocompatible Polymeric Core-Shell Levofloxacin Gold Nanocomposite Formulation Against Pseudomonas aeruginosa

Using natural and synthetic polymers as the components for the core-shell nanocomposite preparation has received recent attention in biomedicine due to their high biocompatibility, high efficacy, and biodegradability. In this present investigation, chitosan-polyvinyl alcohol core-shell gold nanocomposite was synthesised adopting green science principles followed by fabrication with fluoroquinolone antibiotic levofloxacin (LE-CS-PVA-AuNC). Core-shell nanocomposite was prepared from biogenic gold nanoparticles, chitosan, polyvinyl alcohol polymer mixture, and levofloxacin under optimum conditions, and the synthesised nanocomposite exhibited a highly stable nanoarchitecture. Enhancement of antibacterial activity of the nanocomposite was evaluated against the clinical strain of Pseudomonas aeruginosa by determination of growth inhibition, survival rate parameters, and biofilm inhibition rate. Levofloxacin-fabricated core-shell nanocomposite brought about higher growth inhibition than the free levofloxacin, which was confirmed by a notable zone of inhibition, growth inhibition at a lower concentration, rapid biofilm inhibitory rate, and changes in survival growth parameters. In vitro drug release pattern was studied by continuous dialysis, which reveals that the nanocomposite exhibited controlled, sustained release pattern and cumulative release reached almost 98.0% at 72 h. Biocompatibility was studied with human keratinocytes (HaCaT cell line), which was studied by measuring cell viability, oxidative stress marker protein, and genotoxicity. The tested nanocomposite was not inducing any sign of toxicity which was confirmed by no marked impact on cell viability, intracellular reduced glutathione, lipid peroxidase, and lactate dehydrogenase activity. In addition, the nanocomposite has not shown any toxic effect on DNA, and all findings indicate that the synthesised nanocomposite was compatible with human keratinocytes. LE-CS-PVA-AuNC synthesised in the present system adopting green science principles can be used in modern biomedicine as an effective and safe antimicrobial agent due to its high antimicrobial action against wound infection pathogens and its best compatibility with human keratinocytes.

Overview of polyethylene glycol-based materials with a special focus on core-shell particles for drug delivery application

Polyethylene glycols (PEG) are water-soluble nonionic polymeric molecules. PEG and PEG-based materials are used for various important applications such as solvents, adhesives, adsorbents, drug delivery agents, tissue engineering scaffolds, etc. The coating of nanoparticles with PEG forms core-shell nanoparticles. The PEG-based core-shell nanoparticles are synthesized for the development of high-quality drug delivery systems. In the present review, we first explained the basics and various applications of PEGs and PEG-based composites materials and then concentrated on the PEG-based core-shell nanoparticles for biomedical applications specifically their use in drug delivery.