Search Results (236)

Sulfonamides represent a versatile class of biologically active compounds, best known for their antibacterial activity, but increasingly investigated for their potential in oncology. Free sulfonamides themselves display cytotoxic properties; however, coordination with metal ions often enhances both selectivity and potency, while also introducing new mechanisms of action. Although numerous studies have reported sulfonamide–metal complexes with anticancer activity, a systematic overview linking biological properties to the central metal atom has been lacking. This review summarizes current research on sulfonamide complexes with transition metals and selected main-group elements, focusing on their pharmacological potential as anticancer agents. The compounds discussed include complexes of titanium, chromium, manganese, rhenium, ruthenium, osmium, iridium, palladium, platinum, copper, silver, gold, iron, cobalt, nickel, uranium, calcium, magnesium and bismuth. For each group, representative structures are presented along with cytotoxicity data against cancer cell lines, comparisons with reference drugs such as for example cisplatin, and where relevant, studies on carbonic anhydrase inhibition. The survey of available data demonstrates that many sulfonamide–metal complexes show cytotoxic activity comparable to or greater than existing chemotherapeutic agents, while in some cases exhibiting reduced toxicity toward non-cancerous cells. These findings highlight the promise of sulfonamide–metal complexes as a fertile area for anticancer drug development and provide a framework for future design strategies. This review covers the research on anti-cancer activity of sulfonamide complexes during the years 2007–2025. Full article

The design of multitarget drugs is a growing strategy to address complex and multifactorial diseases, and heterocycles play a major role in this approach. This review aims to critically analyze the role of heterocyclic scaffolds in the development of human carbonic anhydrase inhibitors (hCAIs), emphasizing their versatility as core chemotypes, linkers, and secondary pharmacophores. By examining advances from the last 10 years, we highlight how heterocycle-based designs contribute to modulating potency and selectivity toward hCAs, as well as to the creation of hybrid molecules with enhanced therapeutic profiles. Understanding these strategies is essential for guiding future drug discovery efforts targeting hCAs and related pathologies. Full article

This investigation explored the chemical constituents and biological activities of the steam-distilled oil of L. usitatissimum (SDOLU), employing sophisticated techniques including LC-HRMS, GC-MS, and GC-FID. The analysis identified a diverse array of 17 phenolic compounds, with linoleoyl chloride (64.05%) and linoleic acid (10.39%) as the major fatty acid components. The SDOLU demonstrated remarkable antioxidant capacity, effectively neutralizing free radicals in both DPPH^• (IC₅₀: 19.80 μg/mL) and ABTS^•+ (IC₅₀: 57.75 μg/mL) scavenging assays, alongside robust electron-donating activity in reducing ability tests. Moreover, the SDOLU showed significant inhibition of key enzymes implicated in metabolic and neurodegenerative disorders, including α-amylase (IC₅₀: 531.44 μg/mL), acetylcholinesterase (IC₅₀: 13.23 μg/mL), and carbonic anhydrase II (IC₅₀: 281.02 μg/mL). Collectively, these results highlight the SDOLU as a valuable natural source of multifunctional bioactivities with potential applications in combating oxidative stress and enzyme-related global diseases. Further studies are warranted to validate its therapeutic efficacy and expand its industrial utilization. Full article

Background: Huang Qin Decoction (HQD) is a well-established Traditional Chinese Medicine (TCM) formulation recognized for its application in the treatment of colorectal cancer (CRC). However, the precise therapeutic mechanisms remain inadequately defined. Methods: This study integrates metabolomics from a mouse model and network pharmacology to screen potential targets and bio-active ingredients of HQD. The pharmacological activity of HQD for CRC was evidenced via single-cell RNA sequencing (scRNA-seq), molecular docking, and molecular dynamics simulations. Atomic force microscopy (AFM) assays and cellular experimental validation were used to confirm the relative mechanisms. Results: The metabolite profile undergoes significant alterations, with metabolic reprogramming evident during the malignant progression of CRC liver metastasis. Network pharmacology analysis identified that HQD regulates several metabolic pathways, including arginine biosynthesis, alanine, aspartate, and glutamate metabolism, nitrogen metabolism, phenylalanine metabolism, and linoleic acid metabolism, by targeting key proteins such as aspartate aminotransferase (GOT1), cytochrome P450 1A2 (CYP1A2), and carbonic anhydrase 2 (CA2). ScRNA-seq analysis indicated that HQD may enhance the functionality of cytotoxic T cells, thereby reversing the immunosuppressive microenvironment. Virtual verification revealed a strong binding affinity between the identified hub targets and active constituents of HQD, a finding subsequently corroborated by AFM assays. Cellular experiments confirmed that naringenin treatment inhibits the proliferation, migration, and invasion of CRC cells by downregulating GOT1 expression and disrupting glutamine metabolism. Conclusions: Computational prediction and in vitro validation reveal the active ingredients, potential targets, and molecular mechanisms of HQD against CRC liver metastasis, thereby providing a scientific foundation for the application of TCM in CRC treatment. Full article

Background/Objectives: Human carbonic anhydrases (hCAs) are metalloenzymes involved in essential physiological processes, and their selective inhibition holds therapeutic potential across a wide range of disorders. However, the high degree of structural similarity among isoforms poses a significant challenge for the design of selective inhibitors. In this work, we present a machine learning (ML)-based platform for the isoform-specific prediction and profiling of small molecules targeting hCA I, II, IX, and XII. Methods: By integrating four molecular representations with four ML algorithms, we built 64 classification models, each extensively optimized and validated. The best-performing models for each isoform were applied in a virtual screening campaign for ~2 million compounds. Results: Following a multi-step refinement process, 12 candidates were identified, purchased, and experimentally tested. Several compounds showed potent inhibitory activity in the nanomolar to submicromolar range, with selectivity profiles across the isoforms. To gain mechanistic insights, SHAP-based feature importance analysis and molecular docking supported by molecular dynamics simulations were employed, highlighting the structural determinants of the predicted activity. Conclusions: This study demonstrates the effectiveness of integrating ML, cheminformatics, and experimental validation to accelerate the discovery of selective carbonic anhydrase inhibitors and provides a generalizable framework for activity profiling across enzyme isoforms. Full article

Background/Objectives: The need for dual-targeted enzyme inhibitors is critical in addressing complex diseases like Alzheimer’s and glaucoma. Imidazothiadiazole and chalcone moieties are known for diverse bioactivities. This study aimed to develop novel imidazothiadiazole–chalcone hybrids as potential inhibitors of acetylcholinesterase (AChE), butyrylcholinesterase (BChE), and human carbonic anhydrase isoforms (hCAs), specifically hCA I and hCA II. Methods: Four hybrid molecules (8a–8d) were synthesized and structurally confirmed via ¹H NMR, ¹³C NMR, FT-IR, MS, and elemental analysis techniques. Their enzyme inhibitory activities were assessed using Ellman’s and Verpoorte’s methods. Molecular docking and 100 ns molecular dynamics (MD) simulations were conducted to examine binding interactions. Absorption, distribution, metabolism, excretion, and toxicity (ADMET) properties were predicted using the pkCSM platform. Results: All compounds showed strong enzyme inhibition: AChE (K_i: 3.86–11.35 nM), BChE (K_i: 1.01–1.78 nM), hCA I (K_i: 45.13–81.24 nM), and hCA II (K_i: 36.08–52.45 nM). Docking analyses confirmed favorable binding, particularly with active-site residues. MD simulations demonstrated stable interactions throughout 100 ns. Compound 8a exhibited the highest cholinesterase inhibition, while compounds 8d and 8c were the most potent against hCA I and hCA II, respectively. The ADMET results showed high absorption and acceptable safety, with mild mutagenicity or cardiotoxicity concerns in select compounds. Conclusions: These findings suggest that imidazothiadiazole–chalcone hybrids are promising multi-target enzyme inhibitors. Their potent activity, structural stability, and pharmacokinetic potential support their further development for therapeutic use in neurodegenerative and ocular diseases. Full article

Acetazolamide (AZA) is a validated carbonic anhydrase inhibitor (CAI) that has the potential for use in various therapeutic applications. Herein, we report a novel AZA-loaded biodegradable nanodelivery system that was proven to enhance the antibacterial efficacy of the drug against Gram-negative bacteria, such as Escherichia coli. Carbonic anhydrases (CA, EC 4.2.1.1) in E. coli play a crucial role in bacterial metabolism and CO₂/HCO₃⁻ balance; therefore, they represent a suitable target for antimicrobial strategies. The nanoparticles were obtained using a green synthetic protocol that allowed conjugation of a natural fatty acid to hyaluronic acid (HA) under solvent-free conditions. Full characterization of the micellar aggregates was performed (diameter of the micelles, zeta potential, and drug release study). In vitro studies demonstrated that AZA loaded in HA-based nanoparticles significantly inhibited E. coli growth at concentrations as low as 0.5 µg/mL, whereas higher concentrations of free AZA were required, as previously reported. Additionally, encapsulated AZA disrupted glucose consumption in E. coli, indicating its profound impact on bacterial metabolism. These findings suggest that the HA–palmitate nanoparticle not only enhances the delivery and efficacy of AZA but also offers a strategy to affect bacterial metabolism. Full article

Diuretics are a class of pharmacological agents that promote the renal excretion of water and electrolytes, increasing urine output and reducing fluid retention. They play a critical role in the management of edematous syndromes, irrespective of their etiology (cardiac, renal, or hepatic), as well as in the treatment of hypertension (HTA). The mechanism of action of diuretics can be classified as either renal, as seen with saluretic diuretics that inhibit sodium and water reabsorption at various segments of the nephron, or extrarenal, involving alterations in the glomerular filtration pressure or osmotic mechanisms. Based on their site of action and mechanism, diuretics are categorized into multiple classes, including loop diuretics, thiazide and thiazide-like diuretics, potassium-sparing diuretics, carbonic anhydrase inhibitors, and osmotic diuretics. These agents are frequently used in combination with other antihypertensive or heart failure medications to optimize therapeutic efficacy. By reducing the blood volume and peripheral vascular resistance, diuretics improve cardiac function, lower blood pressure, and enhance exercise tolerance. Additionally, they are employed in managing chronic kidney disease (CKD), electrolyte imbalances, and specific metabolic disorders. Given the potential for adverse effects such as electrolyte disturbances and renal dysfunction, diuretic therapy should be individualized, with the careful monitoring of the dosage, patient response, and comorbid conditions. Patient education on adherence, lifestyle modifications, and the recognition of side effects is essential for optimizing the therapeutic outcomes and minimizing the risks associated with diuretic therapy. Full article

Background/Objectives: α-carbonic anhydrase (α-TcCA) has emerged as a promising drug target in T. cruzi, the causative agent of Chagas disease in the Americas. Sulfonamides, known inhibitors of CAs, bind to the zinc ion on the enzyme’s active site. This study proposes the repositioning of sulfonamide-based drugs to identify new trypanocidal agents. Method: Ligand-based virtual screening and molecular docking analysis were performed on FDA-approved drugs targeting α-TcCA. These compounds were evaluated in vitro and ex vivo against the A1 and NINOA strains, followed by enzymatic assays. Results: Four sulfonylureas were selected: glimepiride (Glim), acetohexamide (Ace), gliclazide (Glic), and tolbutamide (Tol). Ace and Tol had half-maximal inhibitory concentration (IC₅₀) values similar or better than reference drugs against the NINOA strain in the epimastigote and trypomastigote stages, while Glic and Glim had the highest activity against the A1 strain (epimastigotes and amastigotes). Notably, Ace had the highest trypanocidal activity against all stages in NINOA, with IC₅₀ values of 6.5, 46.5, and 46 μM for epimastigotes, trypomastigotes, and amastigotes, respectively. Additionally, Ace inhibited α-TcCA with K_I = 5.6 μM, suggesting that its trypanocidal effect is associated to the enzyme inhibition. Conclusions: This study supports the repositioning of FDA-approved sulfonamide-based hypoglycaemic agents as trypanocidal compounds. Future studies should focus on structural modifications to improve selectivity. Integrating docking, parasitological, and enzymatic data is crucial for optimizing drug candidates for Chagas disease. Full article

Epilepsy is a neurological disorder characterized by repeated convulsions. Antiepileptic drugs (AEDs) are the main course of therapy for epilepsy. These medications are given according to each patient’s personal medical history and the types of seizures they suffer. They have been employed for decades to manage epilepsy, thus delivering relief from seizures through numerous mechanisms of action. Aside from their anticonvulsant attributes, current evidence suggests that certain AEDs may display potential inhibitory effects against cancer invasion and metastasis. This review explored the complicated interactions between the modes of action of AEDs and the pathways causing cancer, and the potential impact of AEDs on the invasion and metastasis of various forms of cancer, while addressing their associated side effects. For example, valproic acid inhibits histone deacetylase, causing hyperacetylation of genes, especially those regulating cell cycle, culminating in cell cycle arrest. Topiramate inhibits carbonic anhydrase, thus disrupting the acidic microenvironment needed for cancer cells to thrive. Lacosamide increases the slow inactivation of the voltage gated Na⁺ channel, thus inhibiting the growth, proliferation, and metastasis of many cancers. Although drug development is a complex task due to regulatory, intellectual property, and economic challenges, researchers are exploring drug repurposing tactics to overcome these challenges and to find new therapeutic alternatives for diseases like cancer. Thus, drug repurposing is considered among the most effective ways to develop drug candidates using novel properties and therapeutic characteristics, and this review also discusses these issues. Full article

Vascular endothelial growth factor receptor-2 (VEGFR-2), a tyrosine kinase receptor (TKR), plays a crucial role in angiogenesis and is overexpressed in most cancers. It is important for tumor angiogenesis, facilitating essential angiogenic cellular processes, such as promoting endothelial cell survival, proliferation, migration, and vascular permeability. Consequently, VEGFR-2 has become one of the main targets for anti-angiogenic therapy, with its inhibition serving as a crucial strategy for developing new drugs to mitigate angiogenesis-dependent cancers. Small-molecule drugs targeting VEGFR-2, approved by the USFDA, are exhibiting the development of drug resistance during chemotherapy, with cardiac-related side effects being consistently reported. In conclusion, it is important to develop novel strategies to enhance the efficacy of VEGFR-2 inhibitors and eliminate their adverse effects. Multifunctional drugs that target multiple pathways present a promising strategy, enhancing efficacy while minimizing side effects. Sulfonamide derivatives are extensively used in medicinal chemistry and modern drug discovery due to their variety of pharmacological activities. The present review focuses on novel compounds endowed with potential VEGFR-2 inhibition, four of which additionally present carbonic anhydrase inhibitory activity. Full article

Background—Aggressive solid tumors are commonly characterized by both basic intracellular pH and acidic extracellular pH, which increase cell survival and proliferation. As carbonic anhydrases IX/XII are involved in this pH regulation, their inhibition is an appealing approach in cancer therapy, avoiding cancer cell survival and proliferation. Substituted coumarins are selective non-classical CA IX and CA XII inhibitors. Methods—In this study, new 7-hydroxycoumarinamides were synthesized and assayed for CA inhibition and antiproliferative activity. Results—All of the coumarinamides showed human CA IX and CA XII selective inhibition over the off-target CA I and CA II isoforms. Coumarin acts as a suicide inhibitor because its heterocyclic ring can be hydrolyzed by CA esterase activity to give the corresponding 2-hydroxycinnamic acid derivative which blocks the entrance of the active site. The 2-hydroxycinnamic acid derivatives deriving from the most potent and selective coumarinamides were docked into CA IX and XII to better understand the activity and selectivity against the two CA isoforms. The most active coumarinamides also produced a decrease of A549 cell proliferation and were able to arrest cells at the G1/S checkpoint. Conclusions—These results may open new perspectives for developing coumarin-based CA IX/XII inhibitors. Full article

The Caryophyllaceae family, commonly utilized in traditional medicine, exhibits various effects revealed by ethnopharmacological studies. Thus, the diuretic effect of the leaf and stem of three Gypsophila taxa endemic to Türkiye was evaluated for the first time by comparing their bio-metabolic profiles, antioxidant capacities, carbonic anhydrase inhibition, and infrared spectra. The leaf and stem of Gypsophila taxa were macerated in 50% ethanol and 50% water, bio-metabolic profiles were performed by a new validated ultra-performance liquid chromatographic (UPLC) method and spectrophotometric methods, the antioxidant capacity was determined by DPPH and ABTS assays, and the in vitro diuretic activity was evaluated by carbonic anhydrase inhibition. The results show that the G. simonii leaf exhibited the highest quantity of rutin and total polyphenols content (TPC). On the other hand, the G. germanicopolitana leaf showed the highest quantity of rosmarinic acid, and the G. eriocalyx leaf contained the maximum total flavonoids content (TFC). The antioxidant results indicated that G. eriocalyx has the highest capacity. The G. germanicopolitana leaf strongly inhibited the enzyme activity. The ATR-FTIR spectra showed that the general chemical composition in the leaf and stem parts was preserved after the extraction process. Band intensity changes may be due to the extraction process and the amount of substances. In conclusion, the species of Gypsophila taxa show considerable potential for utilization in the pharmaceutical area. Full article

Background: Acetazolamide is a carbonic anhydrase inhibitor that inhibits proximal sodium bicarbonate reabsorption, thus increasing urinary bicarbonate excretion. Despite its widespread distribution in the body and beneficial effects on alkaline diuresis, its efficacy and the optimal dosage and duration of acetazolamide in treating metabolic acidosis remain areas of uncertainty. This review aims to assess the effectiveness of acetazolamide in treating chloride depletion alkalosis, mainly induced by diuretics, through a systematic evaluation of clinical research data. Methods: A comprehensive search was conducted on PubMed and Embase. This review included randomized controlled trials, observational studies, and case reports. Data extraction included dose, route, frequency, indication, duration of therapy, patient demographics, and outcomes. Results: A comprehensive search strategy identified 107 studies, of which 7 met the inclusion criteria after full-text review. The reviewed studies encompassed two randomized clinical trials, one case–control study, and three case reports, collectively involving 111 patients with metabolic alkalosis. The studies revealed varied outcomes regarding the efficacy of acetazolamide in treating metabolic alkalosis induced by diuretics. While some trials demonstrated significant improvements in serum bicarbonate levels and acid–base balance, others found no statistically significant reduction in the duration of mechanical ventilation. Case reports highlighted the successful use of acetazolamide in diverse patient populations, including pediatric patients with heart disease and individuals with chronic obstructive pulmonary disease. Conclusions: Acetazolamide holds promise in addressing chloride depletion alkalosis. However, a targeted clinical trial investigating its effectiveness in diuretic-induced metabolic alkalosis must strengthen the existing knowledge base. Full article

The selective inhibition of key enzymes, such as carbonic anhydrases (CAs IX and XII), which are overexpressed in cancer tissues, has emerged as a promising strategy in cancer research. However, a multitarget approach is often preferred to achieve enhanced therapeutic outcomes. In this study, aryl sulfonamides were conjugated with a thiosemicarbazone moiety to enable dual functionality: the inhibition of CAs and the chelation of metal cations. Several structural factors were systematically modified, including the position of the sulfonamido group, the length of the linker, the nature of the aromatic residue, and the type of substituents. Tumor-associated CAs IX and XII inhibition was evaluated using the stopped-flow CO₂ hydrase assay, and the inhibition constants (K_i) were determined. The most promising compounds were further analyzed through molecular docking simulations. Metal chelation capabilities were evaluated using UV–Vis spectroscopy, while antiproliferative activities were measured using the sulforhodamine B (SBR) assay. Additionally, holotomographic 3D microscopy was employed to investigate the mechanisms of cell death. Sulfonamido-derived Schiff bases were synthesized through a three-step procedure that did not require column chromatography purification: (1) isothiocyanation of amino-sulfonamides, (2) nucleophilic addition of hydrazine, and (3) acid-promoted condensation with different aldehydes (benzaldehydes or pyridine-2-carboxaldehyde). The synthesized compounds exhibited inhibition of CAs in the low nanomolar to submicromolar range, with selectivity largely influenced by structural features. Notably, the m-sulfonamide derivative 5b, bearing a pyridin-2-yl residue, demonstrated potent and selective inhibition of CA IX (K_i = 4.9 nM) and XII (K_i = 5.6 nM). Additionally, it efficiently chelated Fe²⁺, Fe³⁺, and Cu²⁺ and showed promising antiproliferative activity (GI₅₀ 4.5–10 µM). Mechanistic studies revealed that apoptosis was involved in its mode of action. Therefore, the synergistic integration of sulfonamides and thiosemicarbazones represents an effective strategy for the development of multimodal anticancer agents. Full article