Phytotherapeutics in Cancer: From Potential Drug Candidates to Clinical Translation.

Annually, a significant number of individuals succumb to cancer, an anomalous cellular condition characterized by uncontrolled cellular proliferation and the emergence of highly perilous tumors. Identifying underlying molecular mechanism(s) driving disease progression has led to various inventive therapeutic approaches, many of which are presently under pre-clinical and/or clinical trials. Over the recent years, numerous alternative strategies for addressing cancer have also been proposed and put into practice. This article delineates the modern therapeutic drugs employed in cancer treatment and their associated toxicity. Due to inherent drug toxicity associated with most modern treatments, demand rises for alternative therapies and phytochemicals with minimal side effects and proven efficacy against cancer. Analogs of taxol, Vinca alkaloids like vincristine and vinblastine, and podophyllotoxin represent a few illustrative examples in this context. The phytochemicals often work by modifying the activity of molecular pathways that are thought to be involved in the onset and progression of cancer. The principal objective of this study is to provide an overview of our current understanding regarding the pharmacologic effects and molecular targets of the active compounds found in natural products for cancer treatment and collate information about the recent advancements in this realm. The authors' interest in advancing the field of phytochemical research stems from both the potential of these compounds for use as drugs as well as their scientific validity. Accordingly, the significance of herbal formulations is underscored, shedding light on anticancer phytochemicals that are sought after at both preclinical and clinical levels, with discussion on the opportunities and challenges in pre-clinical and clinical cancer studies.

Piperidine Nucleus as a Promising Scaffold for Alzheimer's Disease: Current Landscape and Future Perspective.

Heterocycles and their derivatives hold an important place in medicinal chemistry due to their vast therapeutic and pharmacological significance and wider implications in drug design and development. Piperidine is a nitrogen-containing heterocyclic moiety that exhibits an array of pharmacological properties. This review discusses the potential of piperidine derivatives against the neurodegenerative disease Alzheimer's. The incidences of Alzheimer's disease are increasing nowadays, and constant efforts are being made to develop a medicinal agent for this disease. We have highlighted the advancement in developing piperidine-based anti-neuronal disease compounds and the profound activities of some major piperidine-bearing drug molecules with their important target site. This review focuses on advancements in the field of natural and synthetic occurring piperidines active against Alzheimer's disease, with emphasis on the past 6 years. The discussion also includes the structure-activity relationship, the structures of the most promising molecules, and their biological activities against Alzheimer's disease. The promising activities revealed by these piperidinebased scaffolds undoubtedly place them at the forefront of discovering prospective drug candidates. Thus, it would be of great interest to researchers working on synthesizing neuroprotective drug candidates.

Exploring the Multitarget Potential of Iridoids: Advances and Applications.

Iridoids are secondary plant metabolites that are multitarget compounds active against various diseases. Iridoids are structurally classified into iridoid glycosides and non-glycosidic iridoids according to the presence or absence of intramolecular glycosidic bonds; additionally, iridoid glycosides can be further subdivided into carbocyclic iridoids and secoiridoids. These monoterpenoids belong to the cyclopentan[c]-pyran system, which has a wide range of biological activities, including antiviral, anticancer, antiplasmodial, neuroprotective, anti-thrombolytic, antitrypanosomal, antidiabetic, hepatoprotective, anti-oxidant, antihyperlipidemic and anti-inflammatory properties. The basic chemical structure of iridoids in plants (the iridoid ring scaffold) is biosynthesized in plants by the enzyme iridoid synthase using 8-oxogeranial as a substrate. With advances in phytochemical research, many iridoid compounds with novel structure and outstanding activity have been identified in recent years. Biologically active iridoid derivatives have been found in a variety of plant families, including Plantaginaceae, Rubiaceae, Verbenaceae, and Scrophulariaceae. Iridoids have the potential of modulating many biological events in various diseases. This review highlights the multitarget potential of iridoids and includes a compilation of recent publications on the pharmacology of iridoids. Several in vitro and in vivo models used, along with the results, are also included in the paper. This paper's systematic summary was created by searching for relevant iridoid material on websites such as Google Scholar, PubMed, SciFinder Scholar, Science Direct, and others. The compilation will provide the researchers with a thorough understanding of iridoid and its congeners, which will further help in designing a large number of potential compounds with a strong impact on curing various diseases.

LC and LC-MS/MS studies for identification and characterization of degradation products of d-tubocurarine chloride.

Forced degradation studies of d-tubocurarine (DTC) was carried out in hydrolytic (acidic, alkaline and neutral), thermal, photolytic and oxidative degradation conditions as per International Conference on Harmonization (ICH) guideline Q1A (R2). The present study revealed that DTC is highly sensitive to oxidative degradation conditions even at room temperature whereas the drug was found to be stable in hydrolytic, photolytic and thermal stress conditions. Separation of DTC and its four degradation products (DPs) (DP-I to DP-IV) formed during stress degradation conditions were achieved on Waters Acquity CSH C18 (1.7 µm, 2.1 mm × 100 mm) column using gradient elution with a mobile phase consisting of Eluent-A: 0.1 % Formic acid Eluent-B: acetonitrile achieved successfully. The detection was carried out at 210 nm wavelength and the flow rate was kept at 0.3 mL/min with a 5 µL injection volume. Also, a highly sensitive and robust HRMS/MS/TOF method was established for the identification and characterization of four DPs formed during the stress study. ESI +ve mode was used throughout the study for ionization of all the DPs. The degradation pathway was also established in the study that is never reported earlier.

Current Developments in the Pyran-Based Analogues as Anticancer Agents.

Heterocyclic compounds offer an enormous area for new lead molecules for drug discovery. Till today, efforts are being continuously made to find appropriate treatment for the management of the deadly disease of cancer. Amongst the large number of heterocycles that are found in nature, heterocycles having oxygen obtained noteworthy attention due to their distinctive and pharmacological activities.'Pyran' is one of the most significant non-aromatic, sixmembered ring composed of one oxygen atom and five carbon atoms. It is considered a privileged structure since pyran and its related derivatives exhibit a wide spectrum of biological activities. Pyran derivatives are found to have excellent anti-cancer properties against various types of cancer. The present review focussed on the current advances in different types of pyran-based derivatives as anti-cancer agents. Various in vitro (cell based testing), in vivo (animal based testing) models as well as molecular docking along with results are also covered. A subsection describing briefly natural pyran containing anticancer compounds is also incorporated in the review.

Potential role of nicotinamide analogues against SARS-COV-2 target proteins.

BACKGROUND AND OBJECTIVE: Coronavirus 2019 (COVID-19) is caused by 'severe acute respiratory syndrome coronavirus 2' (SARS-CoV-2), first reported in Wuhan, China in December 2019, which eventually became a global disaster. Various key mediators have been reported in the pathogenesis of COVID-19. However, no effective pharmacological intervention has been available to combat COVID-19 complications. The present study screens nicotinamide riboside (NR) and nicotinamide mononucleotide (NMN) as potential inhibitors of this present generation coronavirus infection using an in-silico approach. MATERIALS AND METHODS: The SARS-CoV-2 proteins (nucleocapsid, proteases, post-fusion core, phosphatase, endoriboruclease) and ACE-2 protein were selected. The 2D structure of nicotinamide ribonucleoside and nicotinamide ribonucleotide was drawn using ChemDraw 14.0 and saved in .cdx format. The results were analyzed using two parameters: full fitness energy and binding free energy (ΔG). RESULTS: The full fitness energy and estimated ΔG values from docking of NM, and NMN with selected SARS-CoV-2 target proteins, ADMET prediction and Target prediction indicate the interaction of NR and NMN in the treatment of COVID-19. CONCLUSIONS: Based on full fitness energy and estimated ΔG values from docking studies of NM and NAM with selected SARS-CoV-2 target proteins, ADME prediction, target prediction and toxicity prediction, we expect a possible therapeutic efficacy of NR in the treatment of COVID-19.

LC-MS/MS studies for identification and characterization of new forced degradation products of dabrafenib and establishment of their degradation pathway.

Dabrafenib (Tafinlar) is used for the treatment of patients with BRAF V600 mutation positive unresectable or metastatic melanoma. Forced degradation study of the drug product and drug substance is very much important in drug development and drug discovery to establish the intrinsic stability and understand its behaviors towards different stress conditions. In the current study, compressive stress testing of dabrafenib has been performed as per the recommendation of ICH guidelines to identify and characterize all major degradation products of dabrafenib (DPD) formed. Drug substances were exposed to different stressed conditions as per ICH recommendations. The present study observed that the dabrafenib drug substance is very much sensitive when exposed to oxidative degradation conditions at 80 °C temperature conditions and also sensitive to photolytic degradation conditions. Dabrafenib is stable when treated in acidic, alkaline, neutral and thermal degradation environments as there is no degradation observed in signification percentage under these stressed conditions. The best separation of eight degradation products and dabrafenib drug substance was obtained in Waters BEH (Ethylene Bridge Hybrid) C-18 column (1.7 µm, 100 mm × 2.1 mm) having mobile phase composed of Formic acid (0.1%) and methanol as Eluent A and Eluent B respectively using 225 nm wavelengths. The volume of injection (5 µL) and flow rate (0.3 mL/min) was set throughout the study. Dabrafenib is highly unstable to oxidative stressed conditions as five major degradation products (DPD-II, DPD-III, DPD-IV, DPD-V and DPD-VII) were obtained when exposed to hydrogen peroxide. When dabrafenib is treated under photolytic degradation conditions, three major DPs were formed (DPD-I, DPD-VI and DP-VIII). These DPs were further identified and characterized on sophisticated HRMS/MS/TOF technique for accurate mass measurement. Characterization of all the degradation products was carried out in the ESI positive mode of ionization. The establishment of the degradation pathway of drug substance and fragmentation pathway of DPs were explained in the present study which was never reported in any literature.

LC and LC-MS/MS studies for identification and characterization of new degradation products of ibrutinib and elucidation of their degradation pathway.

Forced degradation/stress degradation studies of ibrutinib drug were done in hydrolytic (acidic, alkaline and neutral), thermal, photolytic and oxidative degradation conditions in different temperature conditions as per International Conference on Harmonization (ICH) guideline Q1A(R2) in order to identify and characterize degradation products (DPs) of ibrutinib. The study revealed that ibrutinib is extremely sensitive to oxidative degradation even at room temperature. The drug substance is highly sensitive to alkaline hydrolysis and susceptible to acidic hydrolysis at 80 °C temperature condition, whereas found stable in neutral, photolytic and thermal stress conditions. Successful separation of ibrutinib and its ten degradation products formed during stress degradation condition were observed using Waters Acquity UPLC C-18 stationary phase (100 mm × 2.1 mm, 1.7 µm) with gradient elution using mobile phase consisting of Eluent-A: ammonium acetate (20 mm, pH-6) and Eluent-B: acetonitrile. The detection was carried out at 215 nm wavelength. Flow rate was set at 0.3 mL/min with injection volume of 5 µL. The drug substance degraded to one degradation product (DP-I) in acidic hydrolysis, five DPs (DP-I, DP-II, DP-V, DP-VIII and DP-IX) in basic hydrolysis and five DPs (DP-III, DP-IV, DP-VI, DP-VII and DP-X) in oxidative degradation condition. A novel and highly sensitive HRMS/MS/TOF method was developed to identify and characterize all the ten DPs formed during stress study. All the DPs were characterized using ESI positive mode. Except DP-I, all the degradation products formed were found to be new degradation impurities and their fragmentation pathways have never been reported earlier. The proposed mechanism and pathway of degradation products of ibrutinib were discussed and outlined.

Natural and grafted cyclotides in cancer therapy: An insight.

Cyclotides is a rapidly growing class of plant-derived cyclic peptides exhibiting several bioactivities with potential applications in the agricultural and pharmaceutical sectors. Both natural and grafted cyclotides have shown promise in cancer therapy. Approximately 70 natural cyclotides belonging to three plant families (Fabaceae, Rubiaceae, and Violaceae) have shown cytotoxicity against several cancer cell lines. Cyclotides exhibit considerable stability against thermal and enzymatic proteolysis, owing to their unique structure with knotted topology and head to tail cyclization. Further, their small size, high stability, oral bioavailability, and tolerance to amino acid substitution in structural loops make them an ideal platform for designing peptide-based drugs for cancer. Thus, cyclotides provide ideal scaffolds for bioactive epitope grafting and facilitating drug delivery in cancer treatment. Many anticancer linear peptides have been grafted in cysteine knotted cyclic framework of cyclotide for enhancing their cell permeability across cellular membranes, thereby improving their delivery and pharmacokinetics. The present review comprehensively discusses the distribution, toxicity, and anticancer bioactivity of natural cyclotides. Further, it systematically elaborates on the role and action of epitopes' into grafted cyclotides in targeting cancer. The review also encompasses related patents landscape study and future challenges in peptide-based cancer therapy.