Current Topics in Medicinal Chemistry - Volume 21, Issue 30, 2021

Respiratory viruses continue to afflict mankind. Among them, pathogens such as coronaviruses [including the current pandemic agent known as severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2)] and the one causing influenza A (IAV) are highly contagious and deadly. These can evade the immune system defenses while causing a hyperinflammatory response that can damage different tissues/organs. Simultaneously targeting several immunomodulatory proteins is a plausible antiviral strategy since it could lead to the discovery of indirect-acting pan-antiviral (IAPA) agents for the treatment of diseases caused by respiratory viruses. In this context, computational approaches, which are an essential part of the modern drug discovery campaigns, could accelerate the identification of multi-target immunomodulators. This perspective discusses the usefulness of computational multi-target drug discovery for the virtual screening (drug repurposing) of IAPA agents capable of boosting the immune system through the activation of the toll-like receptor 7 (TLR7) and/or the stimulator of interferon genes (STING) while inhibiting key inflammation-related proteins such as caspase-1 and tumor necrosis factor-alpha (TNF-α).

Pyrazolines are five-membered heterocyclic compounds containing two nitrogen atoms that represent a privileged scaffold for various bioactive compounds with diverse pharmacological activities. Chalcones and hydrazine derivatives are excellent precursors for pyrazolines, which provide easy access for fabricating the pyrazoline ring at N1, C3 and C5 positions that give rise to a wide range of pyrazoline designs. In addition, this method institutes a new asymmetric center at C5 position and extent of the conjugation between phenyl group at C3 position to N1 that could greatly enhance the physicochemical and pharmacological properties towards the target enzymes and hence they are reported to have a wide spectrum of biological activities such as anti-cancer, antiinflammatory, etc. Most importantly, they have remarkable effects on the central nervous system (CNS). Several reports show that the pyrazoline derivatives have a significant inhibitory effect towards the monoamine oxidase enzymes (MAOs), which are known to be responsible for neurodegenerative disorders. These enzymes have two isoforms, namely MAO-A and MAO-B which are, in particular, responsible for psychiatric and neurological disorders, respectively. Chalcones are generally potential and more selective inhibitors towards MAO-B isoform whereas pyrazolines derived from chalcones mostly turned into selective inhibitors of MAO-A isoform may be due to the presence of two nitrogen heteroatoms. Therefore, these two derivatives have received much attention from medicinal chemists as they could solve entire CNS-related issues; however pyrazolines have not been studied as much as chalcones. Our group already documented the importance of pyrazolines towards MAO-A inhibition in 2013. With their growing importance, several studies on pyrazolines have constantly been reported for their MAO inhibitions. Therefore, in this review, we report up-to-date developments (after 2014) on pyrazolines as potential MAO inhibitors.

Currently, black pepper commands the leading position among all the spices as a spice of great commercial importance in all the world trade and finds its way into the dietary habits of millions of people worldwide. Black pepper is biologically known as Piper nigrum and contains piperine as the main active chemical constituent. This paper highlights various general methods for extracting piperine from the crude drug such as maceration extraction, hydrotropic extraction, accelerated solvent extraction, thin-layer chromatography, and extraction with ethanol & dichloromethane Ionic fluid-based ultrasonic-assisted extraction, etc. In this review, piperine and its analogs exhibit numerous pharmacological activities and synthetic schemes of insecticidal activity, anti-cancer activity, anti-inflammatory activity, anti-diabetic activity, anti-hyperlipidemic activity, antifungal activity, narcotic activity, etc. and its structure-activity relationship. The biochemistry of piperine has also been summarized in the presented article. This very exhaustive review details the complete information about piperine, its derivatives, and further processing. Furthermore, the current study summarises recent research that has linked piperine to its use as a treatment for a variety of ailments.

For the last two decades, there has been research interest on the design of molecules possessing dual inhibitory potential on cholinesterase and monoamine oxidase enzymes, particularly for the treatment of two major neurodegenerative diseases, Alzheimer’s Disease (AD) and Parkinson’s disease (PD). Many compounds have been synthesized for this purpose, and some of them have been shown to display activities comparable or superior to the activities of current drugs used for the treatment of AD and PD. Within the concept of this review study, we have aimed to present the current drugs used for the treatment of AD and PD, their mechanism of action, the discussion behind the theory of designing dual inhibitor agents, and the presentation of the most active compounds with diverse heterocyclic scaffolds displayed in research studies published in the recent period.