Sulfated glycosaminoglycans (SGAGs), such as heparin, are complex linear polysaccharides attached to core proteins via covalent bonds to form proteoglycans. SGAGs are crucial in assembling extracellular matrix, the regulation of cell signaling and cell behavior, hemostasis, development, and various diseases, including thrombosis, cancer, infectious diseases, and neurodegenerative disorders, through their binding with diverse proteins. Despite the abundant SGAG-protein interactions provided by nature, the development of small SGAG-like molecules remains underexplored. However, sulfonated penta-galloyl glucose (SPGG) represents a promising, easily synthesized, small-molecule mimetic of SGAGs, capable of harnessing these interactions. This minireview discusses the chemical synthesis and characterization of SPGG, along with its pharmacological effects derived from modulating the SGAG-protein interface.

Pyrazolic chalcone exhibits diverse therapeutic activities, including anti-inflammatory, antioxidant, antimicrobial, antitumor, and anti-diabetic properties. Structural activity relationship (SAR) studies play a crucial role in understanding the molecular aspects governing their biological effects, guiding the rational design of derivatives with enhanced efficacy and reduced side effects. This review provides an overview of pyrazolic chalcone derivatives, emphasizing their synthesis through both conventional and green methods. In comparison, conventional synthesis methods have been widely employed in the past for the production of pyrazolic chalcones, often relying on traditional chemical processes that may involve the use of hazardous reagents and generate significant waste. On the other hand, green synthesis methods, in harmony with the growing emphasis on sustainable practices in drug discovery, offer a more environmentally friendly alternative. Green synthesis typically involves the use of eco-friendly reagents, solvents, and energy-efficient processes, resulting in reduced environmental impact and improved resource efficiency. Overall, pyrazolic chalcone derivatives represent a promising class of compounds with significant potential for therapeutic applications.

Photodynamic Therapy (PDT) has emerged as a highly efficient and non-invasive cancer treatment, which is crucial considering the significant global mortality rates associated with cancer. The effectiveness of PDT primarily relies on the quality of the photosensitizers employed. When exposed to appropriate light irradiation, these photosensitizers absorb energy and transition to an excited state, eventually transferring energy to nearby molecules and generating Reactive Oxygen Species (ROS), including singlet oxygen [1O2]. The ability to absorb light in visible and nearinfrared wavelengths makes porphyrins and derivatives useful photosensitizers for PDT. Chemically, Porphyrins, composed of tetra-pyrrole structures connected by four methylene groups, represent the typical photosensitizers. The limited water solubility and bio-stability of porphyrin photosensitizers and their non-specific tumor-targeting properties hinder PDT effectiveness and clinical applications. Therefore, a wide range of modification and functionalization techniques have been used to maximize PDT efficiency and develop multidimensional porphyrin-based functional materials. Recent progress in porphyrin-based functional materials has been investigated in this review paper, focusing on two main aspects including the development of porphyrinic amphiphiles that improve water solubility and biocompatibility, and the design of porphyrin-based polymers, including block copolymers with covalent bonds and supramolecular polymers with noncovalent bonds, which provide versatile platforms for PDT applications. The development of porphyrin-based functional materials will allow researchers to significantly expand PDT applications for cancer therapy by opening up new opportunities. With these innovations, porphyrins will overcome their limitations and push PDT to the forefront of cancer treatment options.

Green tea (GT) is rich in Phyto-active compounds such as epigallocatechin gallate (EGCG), epigallocatechin (EGC), epicatechin gallate (ECG), epicatechin (EC), catechin, and tannic acid, which exhibit synergistic effects when combined. Preclinical studies demonstrate that GT and its compounds can reduce reactive oxygen species (ROS), enhance antioxidant capacity, and alleviate aging-related issues such as memory impairments, cognitive decline, and shortened lifespan. Clinical trials corroborate the efficacy of topical GT formulations in improving skin tone, texture, and elasticity and reducing wrinkles. The present manuscript summarizes the recent update on the anti-aging potential of GT and its possible mechanisms. The literature survey suggested that GT consumption is linked to improved cognition, reduced depression levels, and activation of pathways in model organisms like C. elegans. Additionally, tea polyphenols enhance fibroblast mitophagy, boost hippocampal synaptic plasticity in rodents, and mitigate age-related cognitive decline. Moreover, EGCG exhibits anti-aging properties by reducing TNF-induced MMP-1 expression, suppressing ERK signaling, and inhibiting MEK and Src phosphorylation in human dermal fibroblasts. In the context of skin permeation and deposition, optimized transpersonal formulation (TF) incorporating EGCG and hyaluronic acid (HA) demonstrated significantly increased skin permeation and deposition of EGCG compared to plain EGCG. Furthermore, EGCG protects cardiomyocytes via the PPARγ pathway and combats age-related muscle loss through miRNA-486-5p regulation, AKT activation, and FoxO1a-mediated expression of MuRF1 and Atrogin-1. In conclusion, the regular consumption of GT holds promise for promoting physical and mental health, delaying brain and skin aging, and improving overall health by enhancing total antioxidant capacity.

The B-cell lymphoma-2 (Bcl-2) protein family plays a crucial role as a regulator in the process of apoptosis. There is a substantial body of evidence indicating that the upregulation of antiapoptotic Bcl-2 proteins is prevalent in several cancer cell lines and original tumour tissue samples. This phenomenon plays a crucial role in enabling tumour cells to avoid apoptosis, hence facilitating the development of resistant cells against chemotherapy. Therefore, the success rate of chemotherapy for cancer can be enhanced by the down-regulation of anti-apoptotic Bcl-2 proteins. Furthermore, the indole structural design is commonly found in a variety of natural substances and biologically active compounds, particularly those that possess anti-cancer properties. Due to its distinctive physicochemical and biological characteristics, it has been highly regarded as a fundamental framework in the development and production of anti-cancer drugs. As a result, a considerable range of indole derivatives, encompassing both naturally occurring and developed compounds, have been identified as potential candidates for the treatment of cancer. Several of these derivatives have advanced to clinical trials, while others are already being used in clinical settings. This emphasizes the significant role of indole in the field of research and development of anti-cancer therapeutics. This study provides an overview of apoptosis and the structural characteristics of Bcl-2 family proteins, and mainly examines the present stage and recent developments in Bcl-2 inhibitors with an indole scaffold embedded in their structure.

Analysis of the biochemical differences in the energy metabolism among bi-dimensional (2D) and tri-dimensional (3D) cultured cancer cell models and actual human tumors was undertaken. In 2D cancer cells, the oxidative phosphorylation (OxPhos) fluxes range is 2.5-19 nmol O2/min/mg cellular protein. Hypoxia drastically decreased OxPhos flux by 2-3 times in 2D models, similar to what occurs in mature multicellular tumor spheroids (MCTS), a representative 3D cancer cell model. However, mitochondrial protein contents and enzyme activities were significantly different between both models. Moreover, glycolytic fluxes were also significantly different between 2D and MCTS. The glycolytic flux range in 2D models is 1-34 nmol lactate/min/mg cellular protein, whereas in MCTS the range of glycolysis fluxes is 60-80 nmol lactate/min/mg cellular. In addition, sensitivity to anticancer canonical and metabolic drugs was greater in MCTS than in 2D. Actual solid human tumor samples show lower (1.6-4.5 times) OxPhos fluxes compared to normoxic 2D cancer cell cultures. These observations indicate that tridimensional organization provides a unique microenvironment affecting tumor physiology, which has not been so far faithfully reproduced by the 2D environment. Thus, the analysis of the resemblances and differences among cancer cell models undertaken in the present study raises caution on the interpretation of results derived from 2D cultured cancer cells when they are extended to clinical settings. It also raises awareness about detecting which biological and environmental factors are missing in 2D and 3D cancer cell models to be able to reproduce the actual human tumor behavior.

Glioblastoma (GBM) is the most prevalent and deadly primary brain tumor. The current treatment for GBM includes adjuvant chemotherapy with temozolomide (TMZ), radiation therapy, and surgical tumor excision. There is still an issue because 50% of patients with GBM who get TMZ have low survival rates due to TMZ resistance. The activation of several DNA repair mechanisms, such as Base Excision Repair (BER), DNA Mismatch Repair (MMR), and O-6- Methylguanine-DNA Methyltransferase (MGMT), is the main mechanism via which TMZ resistance develops. The zinc-finger DNA-binding enzyme poly (ADP-ribose) polymerase-1 (PARP1), which is activated by binding to DNA breaks, affects the activation of the MGMT, BER, and MMR pathway deficiency, which results in TMZ resistance in GBM. PARP inhibitors have been studied recently as sensitizing medications to increase TMZ potency. The first member of the PARP inhibitor family to be identified was Olaparib. It inhibits PARP1 and PARP2, which causes apoptosis in cancer cells and DNA strand break. Olaparib is currently investigated as a radio- and/or chemo-sensitizer in addition to being used as a single agent because it may increase the cytotoxic effects of other treatments. This review addresses Olaparib and its significance in treating TMZ resistance in GBM.

Considerable advancements have been made in breast cancer therapeutics in the past few decades. However, the advent of chemo-resistance and adverse drug reactions coupled with tumor metastasis and recurrence posed a serious threat to combat this lethal disease. Novel anti-cancer agents, as well as new therapeutic strategies, are needed to complement conventional breast cancer therapies. The quest for developing novel anti-cancer drugs caused an upsurge in exploring and harnessing natural compounds, especially phytochemicals. Various research groups have explored and documented the anti-cancer potential of wide variety of phytochemical groups including flavonoids (curcumin, kaempferol, myricetin, quercetin, naringenin, apigenin, genistein epigallocatechin gallate), stilbenes (resveratrol), carotenoids (crocin, lycopene, lutein), and anthraquinone (Emodin). However, low chemical stability, poor water solubility, and short systemic half-life impede their clinical utility. The implication of nano-technological approaches to decode the pharmacokinetic challenges associated with phytochemical usage, as well as selective drug targeting, have markedly enhanced the pre-clinical anti-cancer activity, thus aiding in their clinical translation. This review documented the recent advances in utilizing phytochemicals for breast cancer prevention and lipidbased nanotechnological approaches for circumventing their pharmacokinetic concerns to enhance their systemic availability, cytotoxicity, and targeted delivery against breast cancer alone as well as in combination with conventional therapeutic agents.

This review article delves into the critical role of Enoyl acyl carrier protein Reductase (InhA; ENR), a vital enzyme in the NADH-dependent acyl carrier protein reductase family, emphasizing its significance in fatty acid synthesis and, more specifically, the biosynthesis of mycolic acid. The primary objective of this literature review is to elucidate diverse scaffolds and their developmental progression targeting InhA inhibition, thereby disrupting mycolic acid biosynthesis. Various scaffolds, including thiourea, piperazine, thiadiazole, triazole, quinazoline, benzamide, rhodanine, benzoxazole, and pyridine, have been systematically explored for their potential as InhA inhibitors. Noteworthy findings highlight thiadiazole and triazole derivatives, demonstrating promising IC50 values within the nanomolar concentration range. The review offers comprehensive insights into InhA's structure, structure-activity relationships, and a detailed overview of distinct scaffolds as effective inhibitors of InhA.

The statistical data related to cancer in recent years has shown a great increase in the number of cases and is likely to further increase in the future. Even after seeking thorough knowledge on the aetiology of cancer and related disorders and attempting to cure it by various methods like gene therapy, T cell therapy, chemotherapy, surgery, hormone therapy, and photodynamic therapy, there has always been disappointment concerning the survival rate. Hence, there is still a great urge for the discovery of novel drugs for the treatment of cancer. Chemotherapy being one of the widely used methods, several drug entities possessing anticancer properties are already in the market but none of them is known to show good efficacy which necessitates researchers to design newer drugs for the treatment of cancer. The urge to synthesize novel anticancer entities directed researchers towards molecular hybridization as one of the novel methods for designing newer drugs. Literature reveals wide research carried out on quinolin-2-one hybrids, possessing anticancer properties through different mechanisms. Tipifarnib and Dovitinib are quinolin-2-one hybrids used to treat cancer, possessing imidazole and benzimidazole heterocyclic rings. Different heterocyclic scaffolds such as pyrone, pyrrole, pyrimidine, pyridine, thiazole, and pyrazole in combination with heterocyclic quinolin-2-one have shown high potential to become lead for newer anticancer agents with better and wider therapeutic properties and lesser side effects. The current review presents information on the different quinolin-2-one hybrids and their effect on different cancer cell lines. It also imparts knowledge of the structural requirements for designing novel anticancer agents.

Cuproptosis, An Emerging Concept In The Field Of Diabetes Research, Presents A Novel And Promising Perspective For The Effective Management Of Diabetes Mellitus And Its Associated Complications. Diabetes, Characterized By Chronic Hyperglycemia, Poses A Substantial Global Health Burden, With An Increasing Prevalence Worldwide. Despite Significant Progress In Our Understanding Of This Complex Metabolic Disorder, Optimal Therapeutic Strategies Still Remain Elusive. The Advent Of Cuproptosis, A Term Coined To Describe Copper-Induced Cellular Cell Death And Its Pivotal Role In Diabetes Pathogenesis, Opens New Avenues For Innovative Interventions. Copper, An Indispensable Trace Element, Plays A Pivotal Role In A Myriad Of Vital Biological Processes, Encompassing Energy Production, Bolstering Antioxidant Defenses, And Altered Cellular Signaling. However, In The Context Of Diabetes, This Copper Homeostasis Is Perturbed, Driven By A Combination Of Genetic Predisposition, Dietary Patterns, And Environmental Factors. Excessive Copper Levels Act As Catalysts For Oxidative Stress, Sparking Intricate Intracellular Signaling Cascades That Further Exacerbate Metabolic Dysfunction. In This Review, We Aim To Explore The Interrelationship Between Copper And Diabetes Comprehensively, Shedding Light On The Intricate Mechanisms Underpinning Cuproptosis. By Unraveling The Roles Of Copper Transporters, Copper-Dependent Enzymes, And Cuproptotic Signaling Pathways, We Seek To Elucidate Potential Therapeutic Strategies That Harness The Power Of Copper Modulation In Diabetes Management. This Insight Sets The Stage For A Targeted Approach To Challenge The Complex Hurdles Posed By Diabetes, Potentially Transforming Our Therapeutic Strategies In The Ongoing Fight Against This Pervasive Global Health Concern.

Taxol is a compound with a rigid, tetracyclic structure of diterpene, which is characterized by significant antitumor properties. Firstly, Taxol has been isolated by extraction from the bark of the yew tree. However, the low level of availability obligated the researchers' world to uncover alternative techniques of Taxol obtainment. In the last few years, many synthetic and semi-synthetic methodologies have been elaborated. Nowadays, many novel biotechnological approaches using cell suspension cultures and biotransformation are initiated and expanded. These processes are very beneficial. The reason is that both the final product and the yield of the process have high levels. Such approaches are very distinctive and they help achieve significant quantities of natural compounds, which often exist in small amounts in plants. Moreover, a very important aspect of Taxol development is nanotechnology. The use of this method has many benefits - the retention time is protracted and the concentration of a drug in tumor tissue is raised. This is due to the specific targeting of nanomolecules. What is essential for patients is that systemic side effects are reduced and the healthy biological systems and tissues do not damage. Also, the paper presents new directions with the application of Artificial Intelligence methods. Every year, new concepts are created for obtaining Taxol and developing methods to significantly increase its bioavailability.

Essential oils (EOs) are a volatile mixture of bioactive compounds extracted from aromatic plants. The composition of EOs varies, which majorly depends on the extraction methods and plant parts. Aromatherapy using EOs has been reported for its several beneficial effects in humans. Aromatherapy is considered a complementary and/ or adjuvant therapeutic approach for treating several illnesses, especially to improve mental health and well-being. The incidence of sleep disorders, specifically insomnia, is nowadays increased, possibly due to urbanization and lifestyle. The studies showed that EOs-based treatments using lavender EO, bergamot EO, cinnamon EO, and rosemary EO (alone or in combinations) could improve sleep quality, duration, and deprivation in healthy subjects and patients, those who suffer from sleep-related issues. The current manuscript details the outcomes of EO-based treatments on the sleep quality of humans and the possible mechanisms associated with the health-promoting properties of EOs. Also, the toxicity and adverse effects of EOs have been discussed. The study indicated that EOs are potent adjuvant therapeutic candidates to manage mood-associated complications in humans. Moreover, the aromatherapeutic field requires detailed studies on toxicity and dose determination, which could provide safe and effective therapeutic results.

This analytical mini-review focuses on the effects of trace elements, which includes Cu, Mn, Zn, and Se, as well as some rarer microelements, on the regulation of oxidative stress in the body and of certain diseases associated with it. Synergism and competition between certain microelements have been considered a hot topic in the applied molecular pharmacology of these specific bio-effects. Some ideas for further possible directions of research are expressed. Noteworthy, metal coordinating catalytical sites of certain enzymes function as pharmacophore-forming and connecting nanostructures. These sites can be regarded as targets for various effectors, making them pharmacologically significant contributors to biocatalysis.

Flu is an acute respiratory disease caused by influenza viruses. The influenza viruses are classified as Alphainfluenzavirus (influenza A virus, IAV), Betainfluenzavirus (influenza B virus, IBV), Gammainfluenzavirus (influenza C virus, ICV), and Deltainfluenzavirus (influenza D virus, IDV) according to the antigenicity of nucleoproteins (NPs) and matrix (M) proteins in vivo. It is estimated that the seasonal influenza epidemics will cause about 3-5 million cases of serious illness and 290,000-650,000 deaths in the world every year, while influenza A virus is the leading cause of infection and death. Neuraminidase (NA) is one of the most critical targets for the development of anti-influenza virus drugs, and the main drugs clinically applied for the treatment of flu are neuraminidase inhibitors. However, various mutant strains have developed resistance to these inhibitors (For example, the substrains of H274Y in H1N1, H5N1, and E119V in H3N2 have developed resistance to Oseltamivir). Influenza viruses mutate frequently, and new substrains emerge constantly, and the pandemics caused by the new substrains will break out at any time. Therefore, it is urgent to develop new and wide-spectrum influenza virus inhibitors for overcoming the emerging influenza pandemic. Here, we focus on describing the progress of influenza virus inhibitors in clinics and clinical trials to provide a comprehensive reference for the researchers.

Sodium-Glucose Co-transporter-1/2 (SGLT1/2) inhibitors (also called glifozins) are a class of glucose-decreasing drugs in adults with Type 2 Diabetes (T2D). SGLT2 inhibitors diminish sodium and glucose reabsorption in the renal proximal convoluted tubule. Recent clinical trials have revealed that SGLT2 inhibitors might be beneficial for treating diseases other than diabetes, including chronic renal disease and Heart Failure (HF). Currently, SGLT2 inhibitors are recommended not only for the glycemic management of T2D but also for cardiovascular protection. SGLT2 inhibitors have become one of the foundational drugs for HF with reduced Ejection Fraction (HFrEF) treatment and the first medications with proven prognostic benefit in HF with preserved Ejection Fraction (HFpEF). At present, 11 SGLT1/2 inhibitors have been approved for clinical use in different countries. Beyond their anti-hyperglycemic effect, these inhibitors have shown clear cardio- and nephroprotective properties. A growing body of research studies suggests that SGLT1/2 inhibitors may provide potential clinical benefits in metabolic as well as oncological, hematological, and neurological disorders.

Most of the antiviral drugs in the market are designed to target viral proteins directly. They are generally considered safe for human use. However, they also suffer from several inherent limitations, in particular, narrow-spectrum antiviral profiles and liability to drug resistance. The other strategy for antiviral drug development is targeting host factors, which are highly involved at different stages in the viral life cycle. In contrast to direct-acting antiviral agents, host-targeting antiviral ones normally exhibit broad-spectrum antiviral properties along with a much higher genetic barrier to drug resistance. Cyclin-dependent kinases (CDKs) represent one such host factor. In this review, we summarized a number of CDK inhibitors (CDKIs) of varied chemical scaffolds with demonstrated antiviral activity. Challenges and issues associated with the repurposing of CDKIs as antiviral agents were also discussed.

While the use of plants in traditional medicine dates back to 1500 B.C., modern advancements led to the development of innovative therapeutic techniques. On the other hand, in the field of anti-infective agents, lack of efficacy and the onset of resistance stimulate the search for novel agents. Genus Artemisia is one of the most diverse among perennial plants with a variety of species, properties, and chemical components. The genus is known for its therapeutic values and, in particular, for its role in the origin of antimalarial agents derived from artemisinin. In this review, we aim to provide an updated overview of the evolution of natural and natureinspired compounds related to the genus Artemisia that have been proven, in vitro and in vivo, to possess antimalarial properties. An overview of the chemical composition and a description of the ethnopharmacological aspects will be presented, as well as an updated report on in vitro and in vivo evidence that allowed the translation of artemisinin and its derivatives from traditional chemistry into modern medicinal chemistry. The biological and structural properties will be discussed, also dedicating attention to the challenging tasks that still are open, such as the identification of optimal combination strategies, the routes of administration, and the full assessment of the mechanism of action.

Alzheimer's Disease (AD) is a progressive neurodegenerative disorder that leads to cognitive decline and memory impairment. It is characterized by the accumulation of Amyloid-beta (Aβ) plaques, the abnormal phosphorylation of tau protein forming neurofibrillary tangles, and is often accompanied by neuroinflammation and oxidative stress, which contribute to neuronal loss and brain atrophy. At present, clinical anti-AD drugs are mostly single-target, improving the cognitive ability of AD patients, but failing to effectively slow down the progression of AD. Therefore, research on effective multi-target drugs for AD has become an urgent problem to address. The main derivatives of hydroxycinnamic acid, caffeic acid, and ferulic acid, are widely present in nature and have many pharmacological activities, such as antimicrobial, antioxidant, anti-inflammatory, neuroprotective, anti-Aβ deposition, and so on. The occurrence and development of AD are often accompanied by pathologies, such as oxidative stress, neuroinflammation, and Aβ deposition, suggesting that caffeic acid and ferulic acid can be used in the research on anti-AD drugs. Therefore, in this article, we have summarized the multi-target anti-AD derivatives based on caffeic acid and ferulic acid in recent years, and discussed the new design direction of cinnamic acid derivatives as backbone compounds. It is hoped that this review will provide some useful strategies for anti-AD drugs based on cinnamic acid derivatives.

Accelerated aerobic glycolysis is one of the main metabolic alterations in cancer, associated with malignancy and tumor growth. Although glycolysis is one of the most studied properties of tumor cells, recent studies demonstrate that oxidative phosphorylation (OxPhos) is the main ATP provider for the growth and development of cancer. In this last regard, the levels of mRNA and protein of OxPhos enzymes and transporters (including glutaminolysis, acetate and ketone bodies catabolism, free fatty acid β-oxidation, Krebs Cycle, respiratory chain, phosphorylating system- ATP synthase, ATP/ADP translocator, Pi carrier) are altered in tumors and cancer cells in comparison to healthy tissues and organs, and non-cancer cells. Both energy metabolism pathways are tightly regulated by transcriptional factors, oncogenes, and tumor-suppressor genes, all of which dictate their protein levels depending on the micro-environmental conditions and the type of cancer cell, favoring cancer cell adaptation and growth. In the present review paper, variation in the mRNA and protein levels as well as in the enzyme/ transporter activities of the OxPhos machinery is analyzed. An integral omics approach to mitochondrial energy metabolism pathways may allow for identifying their use as suitable, reliable biomarkers for early detection of cancer development and metastasis, and for envisioned novel, alternative therapies.