Bridged benzocyclotrimers: concepts, synthesis, and applications

: Bridged polycyclic frameworks represent a unique tool to form curved units, the bicyclo[2.2.1]hepta-2,5-diene system being widely exploited to design and induce concave topologies. In particular, bridged benzocyclotrimers (BCTs) are characterized by a flat aromatic base decorated with bridged polycyclic motifs which provide the suitable curvature underlying the concave-convex topology. In the 1960s, these molecules attracted interest for their own chemical and physical properties. Later, the improvements of synthetic procedures to produce bridged BCTs have paved the way for their utilization to design and prepare molecular containers, bowls, cages, and baskets that are able to accommodate target molecules, recognize them, and modulate their functions. In this frame, we aim to describe the historical evolution of the concept, from the first bridged BCTs explored to confirm the existence of strained alkynes, and the phenomenon of bond alternation (Mills-Nixon hypothesis), to the most recent gated molecular baskets developed as dynamic synthetic receptors for molecular delivery. The main synthetic approaches which have been used to perform cyclotrimerization of bridged polycyclic alkenes, and related mechanisms, are also examined and discussed, with a specific focus on the syn/anti stereoselectivity issue and its consequences at a mechanistic level. The present review covers literature contributions published until mid 2021.

The Evolution and Recent Progress in the Field of Synthetic Immunology

Synthetic immunology is a field in which researchers design constructs that will help immune cells battle pathogens, most commonly cancer cells. This is particularly crucial for human health due to the considerable number of ways that invaders (to the body) possess to minimize the effectiveness of the immune system. Frequently, these changes take place in the form of developing more advanced synthetic receptors for better recognition of pathogens so that T-cells can execute more precise functions in the body. Other changes are also made to give researchers more control over the advancements that have been inserted into the body, heightening the level of safety for the patients who receive them. Considering the newfound research that has been conducted, this paper focuses on the significance of upgrading various parts of the immune system in terms of the way that they can help protect the body. It also highlights the extensive potential this field has in the future considering the adaptability and functionality of the current, newly-designed systems in place.

Recognition of Chiral Carboxylates by Synthetic Receptors

Recognition of anionic species plays a fundamental role in many essential chemical, biological, and environmental processes. Numerous monographs and review papers on molecular recognition of anions by synthetic receptors reflect the continuing and growing interest in this area of supramolecular chemistry. However, despite the enormous progress made over the last 20 years in the design of these molecules, the design of receptors for chiral anions is much less developed. Chiral recognition is one of the most subtle types of selectivity, and it requires very precise spatial organization of the receptor framework. At the same time, this phenomenon commonly occurs in many processes present in nature, often being their fundamental step. For these reasons, research directed toward understanding the chiral anion recognition phenomenon may lead to the identification of structural patterns that enable increasingly efficient receptor design. In this review, we present the recent progress made in the area of synthetic receptors for biologically relevant chiral carboxylates.

Electrochemical Biosensors for Tracing Cyanotoxins in Food and Environmental Matrices

The adoption of electrochemical principles to realize on-field analytical tools for detecting pollutants represents a great possibility for food safety and environmental applications. With respect to the existing transduction mechanisms, i.e., colorimetric, fluorescence, piezoelectric etc., electrochemical mechanisms offer the tremendous advantage of being easily miniaturized, connected with low cost (commercially available) readers and unaffected by the color/turbidity of real matrices. In particular, their versatility represents a powerful approach for detecting traces of emerging pollutants such as cyanotoxins. The combination of electrochemical platforms with nanomaterials, synthetic receptors and microfabrication makes electroanalysis a strong starting point towards decentralized monitoring of toxins in diverse matrices. This review gives an overview of the electrochemical biosensors that have been developed to detect four common cyanotoxins, namely microcystin-LR, anatoxin-a, saxitoxin and cylindrospermopsin. The manuscript provides the readers a quick guide to understand the main electrochemical platforms that have been realized so far, and the presence of a comprehensive table provides a perspective at a glance.

Helix-Like Receptors for Perrhenate Recognition Forming Hydrogen Bonds with All Four Oxygen Atoms

Supramolecular recognition of perrhenate is a challenging task due to therelatively large size and low charge density of this anion. In this work, we design and synthesize a family of helix-like synthetic receptors that can bind perrhenate by forming hydrogen bonds with all four oxygen atoms of the anion. Among the investigated rigid helix-forming subunit derived from 1,1′-ferrocenedicarboxylic acid, 1,3-phenylenediacetic acid and 2,2′-(ethyne-1,2-diyl)dibenzoic acid, the latter one shows the best selectivity for perrhenate recognition. However, the receptor based on 1,1′-ferrocenedicarboxylic acid demonstrates selectivity to bind chloride in a 1:2 fashion. The properties of the receptors are investigated in the acetonitrile solution by using NMR, UV–Vis, and in the solid state by single crystal X-ray analysis.

Imprinted Polymers as Synthetic Receptors in Sensors for Food Safety

Foodborne illnesses represent high costs worldwide in terms of medical care and productivity. To ensure safety along the food chain, technologies that help to monitor and improve food preservation have emerged in a multidisciplinary context. These technologies focus on the detection and/or removal of either biological (e.g., bacteria, virus, etc.) or chemical (e.g., drugs and pesticides) safety hazards. Imprinted polymers are synthetic receptors able of recognizing both chemical and biological contaminants. While numerous reviews have focused on the use of these robust materials in extraction and separation applications, little bibliography summarizes the research that has been performed on their coupling to sensing platforms for food safety. The aim of this work is therefore to fill this gap and highlight the multidisciplinary aspects involved in the application of imprinting technology in the whole value chain ranging from IP preparation to integrated sensor systems for the specific recognition and quantification of chemical and microbiological contaminants in food samples.