Microstructure Manipulation of Covalent Organic Frameworks (COFs)-based Membrane for Efficient Separations

Highly Efficient Chiral Separation Based on Alkali-proof Protein Immobilization by Covalent Organic Frameworks

Chiral separation plays a pivotal role in both practical applications and industrial productions. However, traditional chiral stationary phases (CSPs) exhibit inherent instability in alkaline environments, presenting a significant challenge despite their importance. Herein, basophilic alcalase is creatively developed to fabricate ultrastable protein-based CSPs that can efficiently work under alkaline conditions. An in-depth theoretical simulation is conducted to unveil the unique three-dimensional conformation of alcalase, showing selective affinity towards various enantiomers of chiral amino acids and drugs, especially acidic substrates. Subsequently, an in situ assembly strategy is used to immobilize alcalase within a hydrazone-linked covalent organic framework (COF) platform. The generated protein-based CSPs enable successful baseline separation (Rs≥1.50) for various value-added compounds (e.g., non-steroidal drug, RS-flurbiprofen; nucleotide analog, RS-tenofovir) via high-performance liquid chromatography, surpassing the commercial chiral column. Furthermore, a systematic study reveals that increasing hydrophilicity and pore sizes of COFs can enhance the separation performance. Remarkably, the obtained CSPs demonstrated exceptional durability, maintaining performance for >2,400 runs. This study provides a new member to the protein library for CSPs, and represents an innovative and effective platform for CSPs with immense potential for the enantioseparation of acidic drugs.

Room temperature sensing of CO2 using C3-symmetry pyridinium-based porous ionic polymers with triazine or benzene cores

A new class of ionic polymers tethering triazine (benzene) core hybrids with three dipyridinium as cationic counterparts combined with bromide and/or chloride anions PPyBz-OBr and PPyTri-OCl were successfully prepared via the alkylation of 4,4'-dipyridyl derivatives 4,4'-bp-O with 1,3,5-tris(bromomethyl)benzene BB and/or cyanuric chloride CC. The precursor, 4,4'-bp-O,was synthesized through the condensation of 4-pyridine carboxaldehyde and 4,4'-oxydianiline. The resulting ionic polymers, PPyBz-OBr and PPyTri-OCl, underwent metathetical anion exchange, forming new ionic polymers bearing LiTFSI and KPF6 as anions. Characterization of the synthesized hybrid molecules was performed through FTIR, 1H NMR, and 13C NMR analyses. PXRD and SEM showed semi-crystalline structures and a homogenous distribution of micro-/or nanoparticles. TGA and DTA displayed high thermal stability of the synthesized polymer. The sensing activity of the modified ionic polymers was examined using a quartz crystal nanobalance (QCN) for CO2 detection. The resulting sensor demonstrated the ability to provide precise, selective, and reproducible CO2 measurements.

Covalent Organic Frameworks: Recent Progress in Biomedical Applications

Covalent organic frameworks (COFs) are a type of crystalline organic porous material with specific features and interesting structures, including porosity, large surface area, and biocompatibility. These features enable COFs to be considered as excellent candidates for applications in various fields. Recently, COFs have been widely demonstrated as promising materials for biomedical applications because of their excellent physicochemical properties and ultrathin structures. In this review, we cover the recent progress of COF materials for applications in photodynamic therapy, gene delivery, photothermal therapy, drug delivery, bioimaging, biosensing, and combined therapies. Moreover, the critical challenges and further perspectives with regards to COFs for future biology-facing applications are also discussed.