Rational Design of Photochromic Analogues of Tricyclic Drugs

Riefolo, Fabio; Sortino, Rosalba; Matera, Carlo; Claro, Enrique; Vitiello, Simone; Traserra, Sara; Jiménez, Marcel; Gorostiza, Pau

doi:10.1021/acs.jmedchem.1c00504

Cited by 11 publications

(8 citation statements)

References 38 publications

(120 reference statements)

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“…Atypical tricyclic azosteres were explored very recently for the first time, during the development of photoswitchable antagonists of M 1 mAChR. [152] The design stemmed from a ligand-based hypothesis, i.e., the shape similarity between (Z)-azobenzene and the fused tricyclic scaffold of pirenzepine. Such hidden bioisosteric replacement was termed "crypto-azologization", because a bond needed to be broken to carve the (Z)-like azostere out of the scaffold (Figure 20).…”

Section: Atypical Systems (Class 6)mentioning

confidence: 99%

Rational Design in Photopharmacology with Molecular Photoswitches

et al. 2023

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Photopharmacology is an attractive approach for achieving targeted drug action with the use of light. In photopharmacology, molecular photoswitches are introduced into the structure of biologically active small molecules to allow for the optical control of their potency. Going beyond trial and error, photopharmacology has progressively applied rational drug design methodologies to devise light-controlled bioactive ligands. In this review, we categorize photopharmacological efforts from the standpoint of medicinal chemistry strategies, focusing on diffusible photochromic ligands modified with photoswitches that operate through E-Z bond isomerization. In the vast majority of cases, photoswitchable ligands are designed as analogs of existing compounds, through a variety of approaches. By analyzing in detail a comprehensive list of instructive examples, we describe the state of the art and discuss future opportunities for rational design in photopharmacology.

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Section: Atypical Systems (Class 6)mentioning

confidence: 99%

Rational Design in Photopharmacology with Molecular Photoswitches

et al. 2023

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“…In all cases discussed to this point, a conformational change of the molecular switch is used to release a drug payload by distorting the structure of its carrier. An attractive, atypical approach to minimise toxicity and focus the APIs potency to the tumorous site is to incorporate the photochromic mechanism into the structure of the therapeutic API itself, thus mimicking the drug with a photochromic agent ( Riefolo et al, 2021 ). A method employed by Sheldon et al was to use the core of an azobenzene to engineer a photochromic analogue of combretastatin A-4 (CA4) ( Sheldon et al, 2016 ).…”

Section: Ddss With Switches—controlled By Lightmentioning

confidence: 99%

Molecular Switches—Tools for Imparting Control in Drug Delivery Systems

2022

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Cancer is a globally prevalent cause of premature mortality. Of growing interest is the development of novel anticancer therapies and the optimisation of associated risks. Major issues presently facing conventional anticancer therapies include systemic toxicity, poor solubility, membrane permeability, and multidrug resistance Nanocarriers have been employed to address these issues. Nanocarriers encapsulate anticancer drugs, enabling them to bypass biological barriers and minimise their adverse side effects. These drug delivery systems offer extensive benefits as they can be modified to gravitate towards specific environmental conditions. To further enhance the safety and efficacy of these drug carriers, modern developments have included incorporating a molecular switching mechanism into their structure. These molecular switches are responsive to endogenous and exogenous stimuli and may undergo reversible and repeatable conformational changes when activated. The incorporation of molecular switches can, therefore, impart stimuli-responsive drug-release control on a DDS. These stimuli can then be manipulated to offer precise dosage control over the drug release at a specific target site. This review discusses recent developments in the design of DDSs incorporating light and pH-responsive molecular switches as drug release controllers.

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“…Noticeably, changes in the molecular structure, alters the physical property such as fluorescence, electrical conductivity, refractive index, polarizability, and magnetism etc [41] . In recent years, these type of appealing molecules has gained a prominent attention of the scientific community globally because of their unique physiochemical signatures and diverse potential applications for instance, photo‐responsive self‐assemblies, [42] information manipulation, [43] medicinal chemistry, [44] logic gates, [45] molecular switches, [46] and fluorescent chemosensors [47] etc. Remarkably, in recent past, a plethora of photochromic systems have successfully been designed, synthesized and studied worldwide by numerous research groups.…”

Section: Synthesis and Applications Of Various Types Of Ion‐pair Rece...mentioning

confidence: 99%

Recent Advancements in Ion‐Pair Receptors

Wagay

Khan

Ali

2022

Chemistry An Asian Journal

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Over the past two decades, non‐covalent chemistry has introduced various promising artificial receptors and revolutionized the host‐guest chemistry. These versatile receptors have particularly been entertained in sensing and recognizing of diverse neutral molecules and/or ionic entities (e. g. anions, cations and ion‐pair) of particular interest. Notably, supramolecular chemistry had given birth to a plethora of important molecules, explored in the chemical, biological, environmental, and pharmacological world to resolve the critical issues related to the human health while keeping environmental concerns in mind. Amongst the various types of supramolecular monotopic receptors (anions, cations, and neutral molecules), heteroditopic receptors (ion‐pair receptors) consisting of distinct binding sites in one system for both cation and anion, have gained much interest from the scientific community in recent past because of their unique binding abilities. Interestingly, these promising artificial receptors have shown potential applications in sensing, recognition, transport and extraction processes besides their uses in salt/waste purification. Bearing the importance of these systems in mind, we intended to report the recent developments in ion‐pair chemistry. Herein, we divided the whole document into three main sections; first one describes the introduction and history of the ion‐pairs receptors. The second portion highlights the synthesis and applications of ion‐pair receptors in sensing, recognition, molecular machines, photoswitching behaviour, extraction and transport properties, whereas the last part of this manuscript provides concluding remarks as well as future prospects of ion‐pair receptors. We hope that this manuscript will be helpful to stimulating researchers around the globe to find out the hidden opportunities in this and related areas.

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Rational Design of Photochromic Analogues of Tricyclic Drugs

Cited by 11 publications

References 38 publications

Rational Design in Photopharmacology with Molecular Photoswitches

Rational Design in Photopharmacology with Molecular Photoswitches

Molecular Switches—Tools for Imparting Control in Drug Delivery Systems

Recent Advancements in Ion‐Pair Receptors

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