Benzimidazole as a Privileged Scaffold in Drug Design and Discovery.

Benzimidazole is a privileged drug design and discovery scaffold with various phar-macological activities, including antimicrobial, anticancer, antitubercular, anti-inflammatory, an-tidiabetic, antihypertensive, antimalarial, and many more. This scaffold can be observed in the structure of numerous FDA-approved drugs and employed in medicinal chemistry to develop novel bioactive compounds through rational drug design. Its broad pharmacological significance is due to physicochemical attributes, including H-bond donor-acceptor efficiency, π-π stacking interactions, and hydrophobic interactions; these characteristics enable benzimidazole derivatives to bind with macromolecules efficiently. This article emphasizes mechanisms, SAR, and docking studies to unveil benzimidazole's various active hybrids accountable for diversified activities. It will assist researchers in strategically designing various novel benzimidazole-endowed hybrids to develop clinically active therapeutic candidates.

Mechanistic insights into the potential role of dietary polyphenols and their nanoformulation in the management of Alzheimer's disease.

Alzheimer's disease (AD) is a very common neurodegenerative disorder associated with memory loss and a progressive decline in cognitive activity. The two major pathophysiological factors responsible for AD are amyloid plaques (comprising amyloid-beta aggregates) and neurofibrillary tangles (consisting of hyperphosphorylated tau protein). Polyphenols, a class of naturally occurring compounds, are immensely beneficial for the treatment or management of various disorders and illnesses. Naturally occurring sources of polyphenols include plants and plant-based foods, such as fruits, herbs, tea, vegetables, coffee, red wine, and dark chocolate. Polyphenols have unique properties, such as being the major source of anti-oxidants and possessing anti-aging and anti-cancerous properties. Currently, dietary polyphenols have become a potential therapeutic approach for the management of AD, depending on various research findings. Dietary polyphenols can be an effective strategy to tackle multifactorial events that occur with AD. For instance, naturally occurring polyphenols have been reported to exhibit neuroprotection by modulating the Aß biogenesis pathway in AD. Many nanoformulations have been established to enhance the bioavailability of polyphenols, with nanonization being the most promising. This review comprehensively provides mechanistic insights into the neuroprotective potential of dietary polyphenols in treating AD. It also reviews the usability of dietary polyphenol as nanoformulation for AD treatment.

Orchestration and theranostic applications of synthetic genome with Hachimoji bases/building blocks.

Synthetic genomics is a novel field of chemical biology where the chemically modified genetic alphabets have been considered in central dogma of life. Tweaking of chemical compositions of natural nucleotide bases could be developed as novel building blocks of DNA/RNA. The modified bases (dP, dZ, dS, and dB etc.) have been demonstrated to be adaptable for replication, transcription and follow Darwinism law of evolution. With advancement of chemical biology especially nucleotide chemistry, synthetic genetic codes have been discovered and Hachimoji nucleotides are the most important and significant one among them. These additional nucleotide bases can form orthogonal base-pairing, and also follow Darwinian evolution and other structural features. In the Hachimoji base pairing, synthetic building blocks are formed using eight modified nucleotide (DNA/RNA) letters (hence the name "Hachimoji"). Their structural conformations, like polyelectrolyte backbones and stereo-regular building blocks favor thermodynamic stability and confirm Schrodinger aperiodic crystal. From the structural genomics aspect, these synthetic bases could be incorporated into the central dogma of life. Researchers have shown Hachimoji building blocks were transcribed to its RNA counterpart as a functional fluorescent Hachimoji aptamer. Apart from several unnatural nucleotide base pairs maneuvered into its in vitro and in vivo applications, this review describes future perspective towards the development and therapeutic utilization of the genetic codes, a primary objective of synthetic and chemical biology.

Antibody-drug conjugates in cancer therapy: innovations, challenges, and future directions.

The emergence of antibody-drug conjugates (ADCs) as a potential therapeutic avenue in cancer treatment has garnered significant attention. By combining the selective specificity of monoclonal antibodies with the cytotoxicity of drug molecules, ADCs aim to increase the therapeutic index, selectively targeting cancer cells while minimizing systemic toxicity. Various ADCs have been licensed for clinical usage, with ongoing research paving the way for additional options. However, the manufacture of ADCs faces several challenges. These include identifying suitable target antigens, enhancing antibodies, linkers, and payloads, and managing resistance mechanisms and side effects. This review focuses on the strategies to overcome these hurdles, such as site-specific conjugation techniques, novel antibody formats, and combination therapy. Our focus lies on current advancements in antibody engineering, linker technology, and cytotoxic payloads while addressing the challenges associated with ADC development. Furthermore, we explore the future potential of personalized medicine, leveraging individual patients' molecular profiles, to propel ADC treatments forward. As our understanding of the molecular mechanisms driving cancer progression continues to expand, we anticipate the development of new ADCs that offer more effective and personalized therapeutic options for cancer patients.

Oxidative Stress and Natural Antioxidants: Back and Forth in the Neurological Mechanisms of Alzheimer's Disease.

Alzheimer's disease (AD) is characterized by the progressive degeneration of neuronal cells. With the increase in aged population, there is a prevalence of irreversible neurodegenerative changes, causing a significant mental, social, and economic burden globally. The factors contributing to AD are multidimensional, highly complex, and not completely understood. However, it is widely known that aging, neuroinflammation, and excessive production of reactive oxygen species (ROS), along with other free radicals, substantially contribute to oxidative stress and cell death, which are inextricably linked. While oxidative stress is undeniably important in AD, limiting free radicals and ROS levels is an intriguing and potential strategy for deferring the process of neurodegeneration and alleviating associated symptoms. Therapeutic compounds from natural sources have recently become increasingly accepted and have been effectively studied for AD treatment. These phytocompounds are widely available and a multitude of holistic therapeutic efficiencies for treating AD owing to their antioxidant, anti-inflammatory, and biological activities. Some of these compounds also function by stimulating cholinergic neurotransmission, facilitating the suppression of beta-site amyloid precursor protein-cleaving enzyme 1, α-synuclein, and monoamine oxidase proteins, and deterring the occurrence of AD. Additionally, various phenolic, flavonoid, and terpenoid phytocompounds have been extensively described as potential palliative agents for AD progression. Preclinical studies have shown their involvement in modulating the cellular redox balance and minimizing ROS formation, displaying them as antioxidant agents with neuroprotective abilities. This review emphasizes the mechanistic role of natural products in the treatment of AD and discusses the various pathological hypotheses proposed for AD.

4-Bromo-4'-chloro pyrazoline analog of curcumin augmented anticancer activity against human cervical cancer, HeLa cells: in silico-guided analysis, synthesis, and in vitro cytotoxicity.

Inspired by the synergistic effects of hetero-aromatic scaffolds on curcumin, a novel array of pyrazoline substituted curcumin analogs was designed. Multi-scale computational studies were carried out to target the proposed analogs on human kinase ß (IKK-ß), a potential anti-cancer target. In molecular docking analysis, all the eleven molecules were observed to bind the target site and 4-bromo-4'-chloro analog displayed three hydrogen bond interactions with a docking score of -11.534 kcal/mol higher than parent molecule, curcumin (docking score = -7.12 kcal/mol) as the propellant shaped of analogs aided in proper binding with Kinase Domain binding pocket. The molecular dynamics and simulations studies revealed that the stable complexes of lead molecule were developed as the minimal deviations per residue of protein found within the range of 0.11 to 0.92 Å. The proposed compounds were synthesized, characterized and biologically evaluated against human cervical cancer cell line, HeLa, using standard MTT cell assay. Bio-evaluation studies exhibited superior cytotoxic profile for many analogs as Chloro bromo analog with IC50 value (8.7 µg/mL) exhibited fivefolds improvement in the potency in comparison to curcumin (IC50 = 42.4 µg/mL) but was less potent than the standard drug, paclitaxel (IC50 = 0.008µg/mL). The apoptotic effect was evaluated in the terms of caspase-3 enzyme cleavage and exhibited 70.5% of apoptosis significantly (p < 0.05) higher than 19.9% induced by curcumin. In short, 4-bromo-4'-chloro analog was the potent cytotoxic agent in this structural class and must be evaluated further under a set of stringent parameters for transforming in to a clinically viable therapeutic molecule.Communicated by Ramaswamy H. Sarma.