To Explore Potential Natural Inhibitors of Cysteine Proteases to Combat Human African Trypanosomiasis and Chagas Disease.

BACKGROUND: Human African Trypanosomiasis (HAT), also known as sleeping sickness, and Chagas disease are neglected tropical diseases caused by Trypanosoma brucei and Trypanosoma cruzi, respectively. These diseases present significant challenges in treatment due to the toxicity, low efficacy, and drug-resistant strains associated with current therapies. INTRODUCTION: Cysteine proteases play vital roles in the life cycles of these parasites, making them potential targets for therapeutic intervention. Natural inhibitors sourced from plants, marine organisms, and microorganisms show promise for developing novel therapies. METHODS: This review surveys the potential of natural inhibitors as therapeutic agents against HAT and Chagas disease. It compiles PubMed and PubChem information from various studies to provide an overview of their activities and characteristics, including their ability to inhibit cysteine proteases, modulate the host immune response, and interfere with other parasite proteins. RESULTS: Several natural inhibitors, such as berberine, curcumin, and tannins, have been identified and characterized. These inhibitors have demonstrated encouraging outcomes in both in vitro and in vivo experiments, indicating their potential as therapeutic agents for HAT and Chagas disease. CONCLUSION: Natural inhibitors of cysteine proteases offer a promising avenue for developing novel therapies against HAT and Chagas disease. Further research is needed to identify additional natural inhibitors and optimize their efficacy and safety for human use. The significance of this study lies in its potential to contribute to the discovery of effective, safe, and affordable treatments for these neglected tropical diseases.

Novel PLGA-encapsulated-nanopiperine promotes synergistic interaction of p53/PARP-1/Hsp90 axis to combat ALX-induced-hyperglycemia.

The present study predicts the molecular targets and druglike properties of the phyto-compound piperine (PIP) by in silico studies including molecular docking simulation, druglikeness prediction and ADME analysis for prospective therapeutic benefits against diabetic complications. PIP was encapsulated in biodegradable polymer poly-lactide-co-glycolide (PLGA) to form nanopiperine (NPIP) and their physico-chemical properties were characterized by AFM and DLS. ∼ 30 nm sized NPIP showed 86.68% encapsulation efficiency and - 6 mV zeta potential, demonstrated great interactive stability and binding with CT-DNA displaying upsurge in molar ellipticity during CD spectroscopy. NPIP lowered glucose levels in peripheral circulation by > 65 mg/dL compared to disease model and improved glucose influx in alloxan-induced in vivo and in vitro diabetes models concerted with 3-folds decrease in ROS production, ROS-induced DNA damage and 27.24% decrease in nuclear condensation. The 25% increase in % cell viability and inhibition in chromosome aberration justified the initiation of p53 and PARP DNA repairing protein expression and maintenance of Hsp90. Thus, the experimental study corroborated well with in silico predictions of modulating the p53/PARP-1/Hsp90 axis, with predicted dock score value of - 8.72, - 8.57, - 8.76 kcal/mol respectively, validated docking-based preventive approaches for unravelling the intricacies of molecular signalling and nano-drug efficacy as therapeutics for diabetics.

To Explore Potential Inhibitors Against Various Enzymatic Targets of Human African Trypanosomiasis.

Synthetic drugs currently prescribed for the treatment of Human African Trypanosomiasis (HAT) are non-specific, toxic, demand extended therapeutic regimes and are of varying efficacy. Along with the challenging demographic and socio-economic hurdles, the everincreasing risk of drug resistance is another major problem to be addressed. Cysteine protease, Heat shock proteins (HSP-90), Trypanothione reductase (TR), Farnesyl diphosphate synthase, Glucose-6-phosphate dehydrogenase, UP-4-galactose epimerase, and Cytidine triphosphate synthetase are potential enzymatic targets for the development of novel inhibitors against HAT which are the main focus of this review. The potential enzymatic targets of Trypanosoma brucei, especially small molecules like cysteine proteases and heat shock proteins are identified as major candidates for the sustenance of the parasite, their proliferation, infection, and spread of the disease. The development of new compounds to combat the disease by thorough ligand modification has been explored in the current review. Extracting these compounds and studying their efficacy, toxicity, and target mechanism extensively, this review has proposed a list of different compounds, including some synthetic and natural compounds along with multi-target inhibitors such as acoziborole, fexinidazole, etc. Potential inhibitors against these enzymatic targets of the T. brucei are important candidates for designing novel therapeutics against HAT. Multi-target inhibitors have also been identified as crucial molecules because of their potential advantage against the development of drug resistance.

Targeting Cysteine Proteases and their Inhibitors to Combat Trypanosomiasis.

BACKGROUND: Trypanosomiasis, caused by protozoan parasites of the Trypanosoma genus, remains a significant health burden in several regions of the world. Cysteine proteases play a crucial role in the pathogenesis of Trypanosoma parasites and have emerged as potential therapeutic targets for the development of novel antiparasitic drugs. INTRODUCTION: This review article aims to provide a comprehensive overview of the role of cysteine proteases in trypanosomiasis and their potential as therapeutic targets. We discuss the biological significance of cysteine proteases in Trypanosoma parasites and their involvement in essential processes, such as host immune evasion, cell invasion, and nutrient acquisition. METHODS: A comprehensive literature search was conducted to identify relevant studies and research articles on the role of cysteine proteases and their inhibitors in trypanosomiasis. The selected studies were critically analyzed to extract key findings and provide a comprehensive overview of the topic. RESULTS: Cysteine proteases, such as cruzipain, TbCatB and TbCatL, have been identified as promising therapeutic targets due to their essential roles in Trypanosoma pathogenesis. Several small molecule inhibitors and peptidomimetics have been developed to target these proteases and have shown promising activity in preclinical studies. CONCLUSION: Targeting cysteine proteases and their inhibitors holds great potential for the development of novel antiparasitic drugs against trypanosomiasis. The identification of potent and selective cysteine protease inhibitors could significantly contribute to the combat against trypanosomiasis and improve the prospects for the treatment of this neglected tropical disease.

Multi-target Polypharmacology of 4-aminoquinoline Compounds against Malaria, Tuberculosis and Cancer.

BACKGROUND: Polypharmacology means drugs having interactions with multiple targets of a unique disease or many disease pathways. This concept has been greatly appreciated against complex diseases, such as oncology, CNS disorders, and anti-infectives. METHODS: The integration of diverse compounds available on public databases initiates polypharmacological drug discovery research. Immunocompromised patients may suffer from complex diseases. Multiple-component drug formulations may produce side effects and resistance issues due to unintended drug-target interactions. RESULTS: Polypharmacology remains a novel avenue to propose a more effective and less toxic treatment. The 4-amino quinoline scaffold has become an important construction motif for the development of new drugs against lifestyle diseases like cancer and infectious diseases like tuberculosis and malaria. CONCLUSION: The present study is an attempt to explore the polypharmacological effects of 4- aminoquinoline drugs to combat malaria, cancer, and tuberculosis.

Stem Cell Therapy in Combination with Naturopathy: Current Progressive Management of Diabetes and Associated Complications.

BACKGROUND: Diabetes is a chronic metabolic disorder having a global prevalence of nearly doubled over the last 30 years and has become one of the major health concerns worldwide. The number of adults with diabetes increased to 537 million in 2021. INTRODUCTION: The overarching goal of diabetic research and treatment has always been to restore insulin independence and an average blood glucose level. Chemotherapeutic antidiabetic agents can manage diabetes but often show toxicity and drug resistance. Natural phytomedicines may be useful along with stem cell therapy for diabetes management. Even if the whole pancreatic organ and islet transplantation, are becoming benchmark techniques for diabetes management and control, a considerable scarcity of eligible donors of pancreatic tissues and organs severely limits their use. Stem cell treatment provides a bunch of possibilities for treating people with diabetes. METHODS: For this purpose, comprehensive article searching was conducted, with relevant material obtained using search engines such as Scopus, PubMed, MEDLINE, Google, and others, using appropriate keywords. RESULTS: Stem cell therapies, including induced pluripotent stem cells and mesenchymal stem cells, are now becoming a popular area of investigation. Recent advancements in stem cell therapy might provide a feasible treatment option. Furthermore, in recent years, some novel bioactive compounds derived from plants have demonstrated antidiabetic action with higher potency than oral hypoglycaemic medications. Recent regenerative medicine and stem cell treatment advancements might subsequently provide a feasible diabetic management option. On the other hand, medicinal herbs have been considered a better choice for the extensive treatment of diabetes. CONCLUSION: If proper attention is not given to control diabetes by antidiabetic chemotherapeutic agents, natural phytomedicine, and sophisticated treatment like stem cell therapy, then the lifespan of patients will be decreased, and some associated secondary problems will also arise. So, the present review attempts to discuss naturopathy as an alternative resource in combination with stem cell therapy for the progressive management of diabetes and associated disorders.

To Investigate Growth Factor Receptor Targets and Generate Cancer Targeting Inhibitors.

Receptor tyrosine kinase (RTK) regulates multiple pathways, including Mitogenactivated protein kinases (MAPKs), PI3/AKT, JAK/STAT pathway, etc. which has a significant role in the progression and metastasis of tumor. As RTK activation regulates numerous essential bodily processes, including cell proliferation and division, RTK dysregulation has been identified in many types of cancers. Targeting RTK is a significant challenge in cancer due to the abnormal upregulation and downregulation of RTK receptors subfamily EGFR, FGFR, PDGFR, VEGFR, and HGFR in the progression of cancer, which is governed by multiple RTK receptor signalling pathways and impacts treatment response and disease progression. In this review, an extensive focus has been carried out on the normal and abnormal signalling pathways of EGFR, FGFR, PDGFR, VEGFR, and HGFR and their association with cancer initiation and progression. These are explored as potential therapeutic cancer targets and therefore, the inhibitors were evaluated alone and merged with additional therapies in clinical trials aimed at combating global cancer.

Selected Phytochemicals to Combat Lungs Injury: Natural Care.

The human has two lungs responsible for respiration and drug metabolism. Severe lung infection caused by bacteria, mycobacteria, viruses, fungi, and parasites may lead to lungs injury. Smoking and tobacco consumption may also produce lungs injury. Inflammatory and pain mediators are secreted by alveolar macrophages. The inflammatory mediators, such as cytokines, interleukin (IL)-1, IL-6, IL-8, IL-10, and tumor necrosis factor (TNF)-α, neutrophils, and fibroblasts are accumulated in the alveoli sac, which becomes infected. It may lead to hypoxia followed by severe pulmonary congestion and the death of the patient. There is an urgent need for the treatment of artificial respiration and ventilation. However, the situation may be the worst for patients suffering from lung cancer, pulmonary tuberculosis, and acute pneumonia caused by acute respiratory distress syndrome (ARDS). Re-urgency has been happening in the case of coronavirus disease of 2019 (COVID-19) patients. Therefore, it is needed to protect the lungs with the intake of natural phytomedicines. In the present review, several selected phyto components having the potential role in lung injury therapy have been discussed. Regular intake of natural vegetables and fruits bearing these constituents may save the lungs even in the dangerous attack of SARS-CoV-2 in lung cancer, pulmonary TB, and pneumatic patients.

Natural Inhibitors against Potential Targets of Cyclooxygenase, Lipoxygenase and Leukotrienes.

BACKGROUND: Cyclooxygenase (COX) and Lipoxygenase (LOX) enzymes catalyze the production of pain mediators like Prostaglandins (PGs) and Leukotrienes (LTs), respectively from arachidonic acid. INTRODUCTION: The COX and LOX enzyme modulators are responsible for the major PGs and LTs mediated complications like asthma, osteoarthritis, rheumatoid arthritis, cancer, Alzheimer's disease, neuropathy and Cardiovascular Syndromes (CVS). Many synthetic Nonsteroidal Anti- Inflammatory Drugs (NSAIDs) used in the treatment have serious side effects like nausea, vomiting, hyperacidity, gastrointestinal ulcers, CVS, etc. Methods: The natural inhibitors of pain mediators have great acceptance worldwide due to fewer side effects on long-term uses. The present review is an extensive study of the advantages of plantbased vs synthetic inhibitors. RESULTS: These natural COX and LOX inhibitors control inflammatory response without causing side-effect-related complicacy. CONCLUSION: Therefore, the natural COX and LOX inhibitors may be used as alternative medicines for the management of pain and inflammation due to their less toxicity and resistivity.

Naturally Sourced CDK Inhibitors and Current Trends in Structure-Based Synthetic Anticancer Drug Design by Crystallography.

Cyclin-Dependent Kinases (CDKs) are the chief regulators in cell proliferation; the kinase activities are largely regulated by their interactions with CDK Inhibitors (CKIs) and Cyclins. The association of different CDKs with CDKIs and Cyclins at the cell-cycle checkpoints of different stages of mitotic cell cycle function act more likely as the molecular switches that regulate different transcriptional events required for progression through the cell cycle. A fine balance in response to extracellular and intracellular signals is highly maintained in the orchestrated function of CDKs along with Cyclins and CDKIs for normal cell proliferation. This fine-tuning in mitotic cell cycle progression sometimes gets lost due to dysregulation of CDKs. The aberrant functioning of the CDKIs is therefore studied for its contributions as a vital hallmark of cancers. It has attracted our focus to maneuver cancer therapy. Hence, several synthetic CDKIs and their crystallography-based drug design have been explained to understand their mode of action with CDKs. Since most of the synthetic drugs function by inhibiting the CDK4/6 kinases by competitively binding to their ATP binding cleft, these synthetic drugs are reported to attack the normal, healthy growing cells adjacent to the cancer cells leading to the decrease in the life span of the cancer patients. The quest for traditional natural medicines may have a great impact on the treatment of cancer. Therefore, in the present studies, a search for naturally sourced CDK inhibitors has been briefly focused. Additionally, some synthetic crystallography-based drug design has been explained to elucidate different avenues to develop better anticancer chemotherapeutics, converting natural scaffolds into inhibitors of the CDK mediated abnormal signal transduction with lesser side effects.

Natural Sourced Inhibitors of EGFR, PDGFR, FGFR and VEGFRMediated Signaling Pathways as Potential Anticancer Agents.

The molecular mechanisms of mitotic cell cycle progression involve very tightly restricted types of machinery which are highly regulated by a fine balance between the positive and negative accelerators (or regulators). These regulators include several checkpoints that have proteins acting as enzymes and their activating partners. These checkpoints incessantly monitor the external as well as internal environments such as growth signals, favorable conditions for growth, cell size, DNA integrity of the cell and hence function to maintain the highly ordered cell cycle progression by sustaining cell homeostasis and promoting error-free DNA replication and cell cycle division. To progress through the mitotic cell cycle, the cell has to successfully drive past the cell cycle checkpoints. Due to the abnormal behavior of some cell cycle proteins, the cells tend to divide continuously overcoming the tight regulation of cell cycle checkpoints. Such anomalies may lead to unwanted cell division, and this deregulation of cell cycle events is considered as one of the main reasons behind tumor development, and thus, cancer progression. So the understanding of the molecular mechanisms in cancer progression might be insightful for designing several cancer treatment strategies. The deregulation in the checkpoints is caused due to the changes in the tyrosine residues of TPKs via PDGFR, EGFR, FGFR, and VEGFR-mediated signaling pathways. Therefore, the inhibitors of PDGFR, EGFR, FGFR, and VEGFR-mediated signaling pathways could be potential anticancer agents. The resistance and toxicity in the existing synthetic anticancer chemotherapeutics may decrease the life span of a patient. For long, natural products have played an essential alternative source of therapeutic agents due to having least or no side effect and toxicity. The present study is an attempt to promote natural anticancer drug development focusing on the updated structural information of PDGFR, EGFR, FGFR, and VEGFR inhibitors isolated from the plant sources. The data used in this review has been collected from internet resources, viz. GOOGLE Web, GOOGLE SCHOLAR, and PubMed Central. The citation of each report was first checked, after which the articles were selected as an authentic reference for the present study. Around 200 journal articles were initially selected, of which around 142 were finally chosen for presenting the study on the natural sourced inhibitors of EGFR, PDGFR, FGFR, and VEGFR-mediated signaling pathways which may help to enhance the potential cancer treatment.

Repositioning of RdRp Inhibitors Against HCV NS5B Polymerase Utilizing Structure-Based Molecular Docking.

OBJECTIVE: Hepatitis C Virus (HCV) is very dreadful as it can attack an estimated 71 million people around the world. The World Health Organization (WHO) reported that every year about 399000 people die due to HCV caused by chronic cirrhosis and liver cancer globally. There are many drugs available for the treatment of HCV. But drug resistance and toxicity are major issues. The quest for potential drugs utilizing repositioning would be a very useful and economical method to combat HCV. METHODS: One of the most common HCV targets is RNA-dependent RNA polymerase (RdRp). The RdRp is common in HCV, Dengue virus (DENV), Zika virus (ZIKV), and Yellow fever virus (YFV) belonging to the same family of Flaviviridae. An attempt has been made in the present study to reposition different DENV, ZIKV, and YFV RdRp inhibitors against HCV NS5B polymerase utilizing structure-based molecular docking which explores the affinity and mode of binding of these RdRp inhibitors. RESULTS: Several 87 compounds having dengue, yellow fever and zika RdRp inhibitory activities have been taken into consideration for the screening of potential RdRp leads utilizing docking simulation, which focuses on the affinity and mode of binding of sofosbuvir diphosphate, a standard HCV, RdRp inhibitor. CONCLUSION: The compounds 6 (N-sulfonylanthranilic acid derivative), 17 (R1479), 20 (DMB220), 23 (FD-83-KI26), 40 (CCG-7648), 50 (T-1106), 65 (mycophenolic acid), and 69 (DMB213) exhibited docking score within the range of -7.602 to -8.971 Kcal/Mol having almost same mode of interaction as compared to the reference drug molecule. The drugs mentioned above possess satisfactory affinity to bind the hepatitis C viral RdRp and thus may be used to treat the disease. Therefore, these predicted compounds may be potential leads for further testing of anti HCV activity and can be repurposed to combat HCV. The high throughput shotgun of drug repurposing utilizing structure-based docking simulation freeware would be a cost-effective way to screen the potential anti-HCV leads.

Optimization and Quest of HPMC loaded Stavudine Controlled Release Dosage Development by Central Composite Design utilizing Reduced Factorial Screening Technique

Abstract The current research focused on screening and finding the significant independent variables in stavudine loaded tablet, followed by optimizing the best formulation using central composite design. The objective of the study to develop stavudine loaded controlled release tablet utilizing reduced factorial design, followed by optimization technique as well as characterization of prepared tablets. Preliminary trial batches were prepared using different grades of hydroxypropyl methylcellulose. The resolution-IV reduced factorial design was selected to screen the significant independent variables in the dosage form design. A total number of eight runs were prepared and responses were recorded. The signified factors identified by half-normal and Pareto chart. The prepared tablets are evaluated for various physiochemical characterizations. Three dependent responses such as hardness, dissolution at 6 hour and 12 hours are considered in optimization process. Later on, drug-polymer interaction study was carried out. The principal of the study design based on finding the best formulation with prefixed set parameter values utilizing the concept of screening technique. It observed that HPMC K15M (57.18 %), HPMC K100 (66.32 %) and PVP K30 (7.97 %) as best composition in a formulation batch would fulfill the predetermined parameter with specific values.

"Pelargonidin mediated selective activation of p53 and parp proteins in preventing food additive induced genotoxicity: an in vivo coupled in silico molecular docking study".

Food-additive toxicity has become a major health hazard issue globally. Alloxan (ALX), a food-additive, intaken daily through flour causes diabetes and genotoxicity by inducing chromosomal-aberration and DNA-damage. The use of phytochemicals as a protective measure of health hazards has become quite evident because of their least side effects. Pelargonidin (PG), one such phyto-product, have an anti-genotoxic and anti-diabetic effect. In this study, the possibility of PG to inhibit alloxan-induced chromosomal-aberration and DNA-damage was assessed in mice model in vivo and the experimental outcome was validated theoretically through in silico structure-based molecular docking study. Results of the mitotic-index observed from the PG-pre-treated-alloxan-administered (PG+ALX) mice group revealed a significant reduction in chromosomal-anomaly, DNA-damage, and an upregulation of the p53 and PARP protein expression when compared to the ALX-treated mice group. Additionally, the in silico molecular docking study predicted the biochemical mechanism of actions of pelargonidin by identifying the two important amino acid residues p53 and PARP as the active bio-targets of pelargonidin. Therefore, results of our present in vivo and silico studies implicate that pelargonidin could effectively restrict DNA-damage and chromosomal-aberration by modulating PARP and p53 repair proteins showing its ability for possible protein-drug interaction, an effective therapeutic tool in future drug discovery.

Atranorin, an antimicrobial metabolite from lichen Parmotrema rampoddense exhibited in vitro anti-breast cancer activity through interaction with Akt activity.

Atranorin (ATR), lichenized secondary metabolite and depside molecule with several biological potentials such as antimicrobial, anticancer, anti-inflammatory, antinociceptive, wound healing and photoprotective activities. Cytotoxic reports of ATR are documented in several cancer cells and in vivo models but its molecular interaction studies are poorly understood. Therefore, in this present investigation, we have used the in silico studies with biological validation of the molecular targets for the anti-breast cancer mechanism of ATR. The molecular docking studies with the breast cancer oncoproteins such as Bcl-2, Bax, Akt, Bcl-w and Bcl-xL revealed the highest interaction was observed with the Akt followed by Bax, Bcl-xL and Bcl-2 & least with the Bcl-w proteins. The cytotoxicity studies showed ATR selectively inhibited MDA MB-231 and MCF-7 breast cancer cells in differential and dose-dependent manner with the IC50 concentration of 5.36 ± 0.85 µM and 7.55 ± 1.2 µM respectively. Further mechanistic investigations revealed that ATR significantly inhibited ROS production and significantly down-regulated the anti apoptotic Akt than Bcl-2, Bcl-xL and Bcl-w proteins with a significant increase in the Bax level and caspases-3 activity in the breast cancer cells when comparison with Akt inhibitor, ipatasertib. In vitro biological activities well correlated with the molecular interaction data suggesting that atranorin had higher interaction with Akt than Bax and Bcl-2 but weak interaction with Bcl-w and Bcl-xL. In this present study, the first time we report the interactions of atranorin with molecular targets for anti-breast cancer potential. Hence, ATR represents the nature-inspired molecule for pharmacophore moiety for design in targeted therapy.Communicated by Ramaswamy H. Sarma.

To Explore the Potential Targets and Current Structure-based Design Strategies Utilizing Co-crystallized Ligand to Combat HCV.

BACKGROUND: Hepatitis C Virus (HCV) belongs to the Hepacivirus family. HCV has been designated as a very dreadful virus as it can attack the liver, causing inflammation and even may lead to cancer in chronic conditions. It was estimated that 71 million people around the world have chronic HCV infection. World Health Organization (WHO) reported that about 399000 people died because of chronic cirrhosis and liver cancer globally. In spite of the abundance of availability of drugs for the treatment of HCV, however, the issue of drug resistance surpasses all the possibilities of therapeutic management of HCV. Therefore, to address this issue of 'drug-resistance', various HCV targets were explored to quest the evaluation of the mechanism of the disease progression. METHODS: An attempt has been made in the present study to explore the various targets of HCV involved in the mechanism(s) of the disease initiation and progression and to focus on the mode of binding of ligands, which are co-crystallized at the active cavity of different HCV targets. CONCLUSION: The present study could predict some crucial features of these ligands, which possibly interacted with various amino acid residues responsible for their biological activity and molecular signaling pathway(s). Such binding mode may be considered as a template for the high throughput screening and designing of active congeneric ligands to combat HCV.

Phyto-chlorophyllin Prevents Food Additive Induced Genotoxicity and Mitochondrial Dysfunction via Cytochrome c Mediated Pathway in Mice Model.

OBJECTIVES: The issue of food-additive-toxicity causing several health hazards needs to be therapeutically managed with an immediate effect. Alloxan, a food additive, is used for whitening and shining flour. It is capable of inducing genotoxicity, diabetes, and associated mitochondrial dysfunction. Therefore, to explore a non-toxic, phyto-based compound that can delay the onset of diabetes and prevent the multitude of damage associated, Chlorophyllin (CHL) was selected for our study, having been reported to exhibit anti-cancer, anti-diabetes, and antiinflammatory responses. Therefore, the objective of the present study is to evaluate the protective role of CHL in controlling genotoxicity, glucose imbalance, and associated cytochrome c mediated mitochondrial signaling dysfunction against food-additive-induced genotoxicity, diabetic state, and its complexities in mice model in vivo. METHODS: Mice were pre-treated with CHL through oral gavage before they were exposed to alloxan. Diabetic markers, anti-oxidant enzyme profile, chromosomal study, mitochondrial functioning factors, and expression of proteins were checked against food-additive injected mice. RESULTS: The results revealed that CHL pre-treatment could delay the onset of diabetes, restrict alloxan-induced elevation of blood glucose, reduce DNA-damage and chromosomal aberration, optimize enzymatic profile (glucokinase, pyruvate, insulin), and modulates protein expression (insulin, IRS1, IRS2, GLUT2). Further, CHL-pre-treatment could stabilize mitochondrial-membrane-potential, intracellular calcium ion, ATP/ADP ratio, ATPase activity, thereby maintaining optimum functioning of cytochrome-c, bcl2, and caspase3 mitochondrial protein. CONCLUSION: Therefore, the present study reports, for the first time, the screening of phytobased bioactive CHL for preventing/limiting the extent of food-additive-induced genotoxicity and mitochondrial dysfunction and serves as an advanced therapeutic tool in the management of diabetes.

Exploring the Potential Inhibition of Candidate Drug Molecules for Clinical Investigation Based on their Docking or Crystallographic Analyses against M. tuberculosis Enzyme Targets.

Tuberculosis (TB) is a devastating disease responsible for millions of humans' deaths worldwide. It is caused by a mycobacterial organism, the tubercle bacillus or Mycobacterium tuberculosis. Although TB can be treated, cured and can be prevented if patients take prescribed medicines, scientists have never come close to wiping it out due to a sharp rise in the incidence of multidrug-resistant (MDR) and extensively drug-resistant (XDR) mycobacterium strains. Due to long regimen treatment and emergence of MDR and XDR-TB, it is urgent to re-engineer and reposition old drugs for developing new antimycobacterial entities with novel mechanisms of action to achieve effective TB control even against the resistant forms of TB. To combat the dreadful MDR and XDR-TB, potential targets are being extensively searched for the last couple of years for the design and discovery of active potential antitubercular chemotherapeutics. To explore the disease virulence, potential new tubercular target enzymes such as InhA, MmpL3, ATP synthase, DprE1, QcrB and MenA have been taken into consideration in the present study and the structure-based design of the corresponding target inhibitors which are under clinical investigation has been attempted to identify structural features for the discovery of new chemical entities (NCEs) having specificity towards MDR and XDR Mycobacterium tuberculosis (M. tuberculosis).

Chitosan Anchored Nanoparticles in Current Drug Development Utilizing Computer-Aided Pharmacokinetic Modeling: Case Studies for Target Specific Cancer Treatment and Future Prospective.

BACKGROUND: Recently, in the medical and pharmaceutical fields, biopolymers are extensively used for chemical and mechanical modifications of pharmaceutical dosage forms, which add novel properties, functions, and applications. Structural modification of dosage form by polymers along with redesigning in pharmaceutical and tissue engineering fields, presently being the center of analysis for the modern research world, which utilizes the subtle instruments, precise research strategies and most significantly the excipients. METHOD: The polymer, chitosan, which is a natural linear polysaccharide composed of randomly distributed ß-(1- 4)-linked D-Glucosamine and N-acetyl-D-Glucosamine units. Chitosan has been used by researchers as a network forming or gelling agent as chitosan is economically available, possesses low immunogenicity, biocompatibility, non-toxicity, biodegradability, protects against secretion from irritation and does not suffer the danger of transmission animal infective agent. Recent studies have proved that the chitosan conjugated in various biopharmaceutical drug formulations, such as nanoparticles, have been used for the treatment of breast, skin, colon, pancreatic, prostate and lung cancer. The nanoparticles have gained significant attention of scientific groups for relevant cancer-targeting drugs and dosage form. In this connection, several articles been published on chitosan anchored nanoparticles by suitable techniques, such as ion gelation, complexation, solvent evaporation, emulsion droplet coalescence and polymerization. RESULTS: The most remarkable point is that chitosan-drug conjugated nanoparticles (CDNP) can target cancer affected cells with the least attempt to killing the neighbor host cell. It is already proved that the CDNP facilitate the more drugs uptaking or cytotoxicity to a cancerous cell. This overcomes the dosage form designing problems of complexity in the biological mechanism and cell specificity. A computer-aided pharmacokinetic study as well as in-silico design with model fitting can provide the possible finding related to target selectivity and interaction. The computer aided study also reduces time and could make the entire process much cheaper till today, very few research has been reported, such as PyRx with AutoDock, response surface methodology and molecular dynamic simulation in drug delivery for chitosan-drug conjugated nanoparticles. CONCLUSION: Therefore, cancer cell target-specific drug delivery using a natural biopolymer conjugate with a computer-aided pharmacokinetic model will be the thirst area of future research. To get successful anticancer drug formulation, in-silico pharmacokinetic modeling would minimize labor, and expenses, during and prior to the experiment has been extensively discussed in the present review.

Current Development on Chitosan-based Antimicrobial Drug Formulations for the Wound Healing.

BACKGROUND: Derived from polyose, chitosan is an outstanding natural linear polysaccharide comprised of random arrangement of ß-(1-4)-linked D-Glucosamine and N-acetyl-DGlucosamine units. OBJECTIVE: Researchers have been using chitosan as a network forming or gelling agent with economically available, present polyose, low immunogenicity, biocompatibility, non-toxicity, biodegradability, protects against secretion from irritation and don't suffer the danger of transmission animal infective agent. METHODS: Furthermore, recent studies gear up the chitosan used in the development of various biopharmaceutical formulations, including nanoparticles, hydrogels, implants, films, fibers, etc. Results: These formulations produce potential activities as antimicrobials, cancer treatment, medical aid, and wound healing, controlled unleash device or drug trigger retarding device and 3DBiomedical sponge, etc. Conclusion: The present article discusses the development of various drug formulations utilizing chitosan as biopolymers for the repairing of broken tissues and healing in case of wound infection.