Search Results (1,907)

Diclofenac (DCF), a widely consumed non-steroidal anti-inflammatory drug, presents significant environmental challenges due to its persistence and toxicity in aquatic ecosystems. This study investigates the pH-dependent ozonation of DCF in aqueous media, focusing on degradation kinetics, transformation pathways, and effects on key water quality indicators. Ozonation experiments were conducted across a broad pH range (2.0–13.0), using a multi-scale analytical approach combining UV/Vis spectroscopy, colorimetry, turbidity, and aromaticity measurements. The results show that pH strongly influences DCF degradation efficiency: acidic conditions favor selective reactions with molecular ozone, while an alkaline pH enhances non-selective oxidation via hydroxyl radicals. Spectroscopic analyses revealed the progressive breakdown of aromatic structures, the transient formation of quinonoid and phenolic intermediates, and eventual mineralization to inorganic by-products such as nitrate. Low-pH conditions also induced turbidity due to precipitation of neutral DCF species. These findings underline the importance of pH control in optimizing ozonation performance and minimizing toxic by-products. Furthermore, this study proposes ozonation as a viable pre-treatment step within Nature-Based Solutions (NBSs), potentially improving the performance of downstream biological systems such as constructed wetlands. The results contribute to the development of integrated and sustainable water treatment strategies for pharmaceutical contaminant removal and water reuse. Full article

Monomer-to-excimer transition has become a valuable technique in fluorescence imaging because of its ability to enhance imaging contrast. However, from a practical perspective, the accuracy of excimer formation at target sites warrants further exploration. Enzyme-triggered peptide self-assembly provides a promising solution to this limitation. As a proof-of-concept, in this study, we developed a furin-triggered peptide self-assembling fluorescent probe RF-Cou by coupling a coumarin dye 7-(diethylamino)-2-oxo-2H-chromene-3-carboxylic acid (Cou) with a furin-responsive peptide scaffold for precision live-cell imaging. Upon entering furin-overexpressing 4T1 tumor cells, RF-Cou underwent enzymatic cleavage, releasing an amphiphilic peptide motif and self-assembling into nanoparticles largely concentrated in the Golgi apparatus to confine the diffusion of Cou. During this process, the Cou excimers were formed and induced a red shift in the fluorescence emission, validating the feasibility of RF-Cou in efficient excimer imaging of furin-overexpressing tumor cells. We expect that our findings will highlight the potential of stimuli-responsive small molecular peptide probes to advance excimer-based imaging platforms, particularly for enzyme-specific cell imaging and therapeutic monitoring. Full article

Background/Objectives: Long-acting injections (LAIs) are innovative drug delivery systems that improve patient compliance by maintaining therapeutic drug levels over extended periods. Micro- and nanosuspensions are commonly used in LAIs to enhance bioavailability, but their thermodynamic instability poses challenges, including particle aggregation and growth. This study aimed to evaluate the impact of two helping processes—vehicle thermal treatment and high-shear homogenization—on the stability and manufacturing efficiency of aripiprazole monohydrate (AM) suspensions. Methods: AM suspensions containing sodium carboxymethyl cellulose (CMCNa), mannitol and disodium phosphate in water for injections (WFIs) were prepared using a combination of thermal treatment of the vehicle solution, high-shear homogenization and bead milling. Four manufacturing variants were tested to assess the influence of these processes on particle size distribution (PSD), viscosity and stability during a 3-month accelerated stability study. Molecular weight changes in CMCNa from thermal treatment were analyzed using size exclusion chromatography with multiangle scattering (SEC-MALS), and PSD was measured using laser diffraction. Results: Thermal treatment of the vehicle solution had minimal impact on CMCNa molecular weight, preserving its functionality. High-shear homogenization during bead milling significantly reduced particle aggregation, resulting in improved PSD and reduced viscosity. Synergistic effects of the two helping processes used in one manufacturing process were observed, which led to superior stability and minimal changes in PSD and viscosity during storage. Batches without the helping processes exhibited increased particle size and viscosity over time, indicating reduced suspension stability. Conclusions: Incorporating vehicle thermal treatment and high-shear homogenization during bead milling enhances the stability and manufacturing efficiency of AM suspensions. These findings underscore the importance of optimizing laboratory-scale processes to ensure the quality and safety of pharmaceutical suspensions. Full article

Microbiological quality control in cosmetic and pharmaceutical products is crucial for consumer safety. Traditional culture-based detection methods, such as plating on selective media, are time-consuming and may lack sensitivity. Fluorescence In Situ Hybridisation (FISH), a molecular and culture-independent technique, enables rapid and precise microbial identification by targeting specific RNA or DNA sequences with fluorescent probes. In this study, a novel DNA-FISH probe was developed for the detection of Candida albicans in cosmetic formulations. The probe’s specificity was assessed in silico and experimentally using flow cytometry (flow-FISH) on C. albicans and non-target microorganisms, including Pichia kudriavzevii, commonly known as Candida krusei, Saccharomyces cerevisiae, Wickerhamomyces anomalus, Escherichia coli, and Staphylococcus aureus. The probe exhibited 98.9% hybridization efficiency with C. albicans, yielding a fluorescence intensity (FI) of 25,000 (a.u.), while non-target yeasts demonstrated minimal hybridization (4.7%, 2.3%, and 1.9% for C. krusei, S. cerevisiae, and W. anomalus, respectively) and bacteria showed negligible FI. Additionally, the probe’s applicability was evaluated in a tonic formulation, where C. albicans’ hybridization efficiency was slightly reduced to 88.4%, suggesting that formulation components may influence probe performance. Nevertheless, the probe maintained high specificity and efficiency without formamide, a toxic reagent commonly used in FISH. These findings highlight the potential of FISH probes for rapid, accurate, and safe microbial detection, offering a valuable tool for microbiological quality control in the cosmetics industry. Full article

Background/Objectives: Propranolol HCl (PPH), a nonselective beta-adrenergic receptor blocker, is employed as an anti-hypertensive, anti-anginal, anti-arrhythmic, and anti-migraine agent. Given its utility in chronic conditions, developing a sustained-release dosage form becomes imperative to optimize therapeutic outcomes while enhancing patient adherence and minimizing side effects. In this study, we employed a widely adopted matrix-based system to develop PPH sustained-release (PPH-SR) matrix tablets, ensuring the uniform dispersion of the drug within the polymeric matrix to regulate its release rate. Methods: Utilizing cellulose-based polymers, specifically HPMC K100M and ethyl cellulose (EC), as matrix formers, nine different formulations were prepared at varying drug-to-polymer ratios. We employed a wet granulation method, followed by compression of the dried granules, to fabricate round-shaped biconvex PPH-SR tablets. Results: Among these different formulations, formulation 2 (F2), comprising 40 mg PPH and 50 mg HPMC K100M (along with other excipients), showed excellent flowability, as evidenced by Carr’s index and angle of repose values of 12.50 and 28.50, respectively. Additionally, the mechanical properties of F2 tablets showed a hardness of 12.34 ± 0.91 KP, an average weight of 200.45 ± 1.87 mg, with a friability of 0.20%, and a content uniformity of 98.36%. Moreover, in vitro release characteristics of F2 tablets demonstrated a sustained-release behavior, with 94.3 ± 10.2% drug release over 24 h. A comparative analysis with marketed tablets yielded similarity and dissimilarity factors of 64 and 8, respectively. Furthermore, the release profile of F2 exhibited a high degree of linearity with the Korsmeyer–Peppas model (R² of 0.977), showcasing its reliability and predictability. Conclusions: In essence, this in-house developed PPH sustained-release formulation can improve patient adherence, reduce side effects, and improve therapeutic outcomes. These results align with our objective of enhancing the therapeutic efficacy of PPH and affirm the broader relevance of innovative formulation strategies in addressing the challenges of chronic disease management. Full article

Many kinds of silicones are a wide family of hybrid inorganic–organic polymers which have valuable physical and chemical properties and find plenty of practical applications, not only industrial, but also numerous medical and pharmaceutical ones, mainly due to their good thermal and chemical stability, hydrophobicity, low surface tension, biocompatibility, and bio-durability. The important biomedical applications of silicones include drains, shunts, and catheters, used for medical treatment and short-term implants; inserts and implants to replace various body parts; treatment, assembly, and coating of various medical devices; breast and aesthetic implants; specialty contact lenses; and components of cosmetics, drugs, and drug delivery systems. The most important achievements concerning the biomedical and pharmaceutical applications of silicones, their copolymers and blends, and also silanes and low-molecular-weight siloxanes have been summarized and updated. The main physiological properties of organosilicon compounds and silicones, and the methods of antimicrobial protection of silicone implants, have also been described and discussed. The toxicity of silicones, the negative effects of breast implants, and the environmental effects of silicone-containing personal care and cosmetic products have been reported and analyzed. Important examples of the 3D printing of silicone elastomers for biomedical applications have been presented as well. Full article

The pharmaceutical industry faces mounting pressure to reduce its environmental impact while maintaining innovation in drug development. Artificial intelligence (AI) has emerged as a transformative tool across healthcare and drug discovery, yet its potential to drive sustainability by improving molecular design remains underexplored. This review critically examines the applications of AI in molecular design that can support in advancing greener pharmaceutical practices across the entire drug life cycle—from design and synthesis to waste management and solvent optimisation. We explore how AI-driven models are being used to personalise dosing, reduce pharmaceutical waste, and design biodegradable drugs with enhanced environmental compatibility. Significant advances have also been made in the predictive modelling of pharmacokinetics, drug–polymer interactions, and polymer biodegradability. AI’s role in the synthesis of active pharmaceutical compounds, including catalysts, enzymes, solvents, and synthesis pathways, is also examined. We highlight recent breakthroughs in protein engineering, biocatalyst stability, and heterogeneous catalyst screening using generative and language models. This review also explores opportunities and limitations in the field. Despite progress, several limitations constrain impact. Many AI models are trained on small or inconsistent datasets or rely on computationally intensive inputs that limit scalability. Moreover, a lack of standardised performance metrics and life cycle assessments prevents the robust evaluation of AI’s true environmental benefits. In particular, the environmental impact of AI-driven molecules and synthesis pathways remains poorly quantified due to limited data on emissions, waste, and energy usage at the compound level. Finally, a summary of challenges and future directions in the field is provided. Full article

Background and Aims: Colorectal cancer (CRC) remains the third most common cancer worldwide and a leading cause of cancer-related death. Chemoprevention through widely used pharmaceutical agents has garnered increasing interest due to its potential cost-effectiveness and accessibility. This review summarizes current evidence from observational studies, randomized controlled trials, and meta-analyses on the association between commonly prescribed medications and CRC incidence and survival, with particular emphasis on low-dose aspirin and oral anticoagulants (OACs). Scope: Aspirin is the most extensively studied agent, with substantial evidence supporting its protective effect on CRC-specific survival, particularly in long-term users, those with COX-2 overexpression, or PIK3CA mutations. OACs have recently gained attention due to their association with increased gastrointestinal bleeding, which may facilitate earlier CRC detection. While emerging evidence suggests a possible survival benefit through this mechanism, data remain heterogeneous and affected by methodological challenges such as lead-time bias. Metformin is associated with improved CRC outcomes, primarily in patients with type 2 diabetes, though its direct anti-tumor potential remains under investigation. Corticosteroids, statins, and beta-blockers have both limited and inconclusive evidence. Finally, recent studies on vitamin D, calcium, and folic acid suggest inconsistent associations, often confounded by lifestyle factors or underlying comorbidities. Conclusions: While promising, chemoprevention strategies require further validation in well-designed, mechanistically informed studies that account for confounding variables, treatment duration, and tumor biology. Personalized prevention—guided by genetic, molecular, and clinical risk factors—represents a promising path forward. Full article

Amorphous solid dispersion (ASD) technology is popularly used for enhancing the solubility of poorly water-soluble drugs. Drug molecules in ASDs can be dispersed in the form of either amorphous (AASD) or molecular (MASD) forms. The boundary between AASDs and MASDs (A–M boundary) is defined as the drug concentration at which the existence of MASDs obviously influences the physicochemical properties of ASDs. In this work, fluorescence spectroscopy based on the aggregation-caused quenching (ACQ) phenomenon was used to determine the A–M boundary of curcumin (CUR) ASDs prepared via neat ball milling. The relationship between the fluorescence intensity and the loading of CUR in the sample is consistent with the Stern–Volmer equation. For the CUR ASDs with PVP, the samples with CUR loading below 10% show significantly increased fluorescence and have a higher solubility (~178 μg·mL⁻¹), suggesting the A–M boundary is around 10%. Similar A–M boundaries around 10% were also observed for CUR ASDs with PVPVA, Soluplus, HPMC, and HPMCAS. It is of great significance to define the A–M boundary of ASDs for guiding pharmaceutical ASD formulas by balancing drug loading, stability, and solubility. Full article

A new class of spiro[1,2,4]triazolo[1,5-c]quinazoline derivatives is presented as promising modulators of diacylglycerol kinase α (DGK-α), a target implicated in cancer, neurological disorders, and immune dysfunction. Through structure-based computational design using the CB-Dock2 platform with human DGK-α (PDB ID: 6IIE), 40 novel compounds were systematically evaluated along with established inhibitors (ritanserin, R59022, R59949, BMS502, and (5Z,2E)-CU-3) across five distinct binding pockets. Several compounds demonstrated binding profiles at the level of or surpassing the reference compounds. The physicochemical analysis revealed balanced drug-like properties with favorable molecular weights (252–412 g/mol) and appropriate three-dimensionality. The toxicological assessment indicated reassuring safety profiles with predicted LD₅₀ values of 1000–2000 mg/kg and minimal hepatotoxicity, carcinogenicity, and mutagenicity potential. Notably, compound 33 (adamantyl-substituted) emerged as exceptionally promising, exhibiting strong binding affinity, moderate solubility, and selective CYP inhibition patterns that minimize drug–drug interaction risks. Detailed molecular interaction mapping identified critical binding determinants, including strategic hydrogen bonding with TRP151, GLU166, and ARG126. The multidimensional evaluation identified compounds 13, 18, 33, and 40 as particularly promising candidates that balance potent target engagement with favorable pharmaceutical profiles, establishing this scaffold as a valuable platform for developing next-generation therapeutics targeting DGK-α -mediated signaling pathways. Full article

Biodegradable polyesters serve as matrices in pharmaceutical applications for the controlled release of therapeutic agents. These polymers are essential in the advancement of drug delivery systems (DDSs) that facilitate the gradual drug release over a predetermined duration. Therefore, this study introduces the novel use of a diethyl zinc/propyl gallate catalytic system to synthesize glycolide/ε-caprolactone copolymers (PGCL) for subsequent biomedical applications. A total of twenty-four biodegradable copolymeric matrices, characterized by a highly random microstructure and an average molecular weight (M_n) ranging from approximately 27 to 62 kDa, were synthesized and analyzed. The resulting copolymer samples underwent Neutral Red Uptake (NRU) and Umu tests, revealing no signs of cyto- or genotoxicity. Furthermore, a hemolysis assay was conducted on selected samples, indicating their suitability for intravenous administration. Finally, a release study of paclitaxel (PACL) from one of the synthesized matrices demonstrated a sustained and highly controlled drug release profile, following first-order kinetics and the Fickian diffusion mechanism. Full article

Ganoderma leucocontextum, a newly identified species from the Tibetan Plateau, has been mainly studied for its polysaccharides and triterpenoids, with no prior reports on fungal immunomodulatory proteins (FIPs). This study explores the biological activity of FIP-gle2, cloned from G. leucocontextum and expressed in Pichia pastoris. The effects and mechanisms of recombinant FIP-gle2 (rFIP-gle2) on cell activity and melanin synthesis in mouse melanoma B16-F10 cells were investigated in vitro. The results showed that the FIP-gle2 gene, with an open reading frame (ORF) of 333 bp, encodes a 111-amino acid polypeptide with a molecular weight of 12.60 kDa and an isoelectric point of 4.48. We achieved a yield of 184.18 mg/L of rFIP-gle2. In vitro functional experiments showed that rFIP-gle2 significantly inhibited the proliferation of B16-F10 melanoma cells and induced apoptosis in a dose-dependent manner, particularly at concentrations above 1 μg/mL. At 3 μg/mL, rFIP-gle2 effectively inhibited tyrosinase activity and reduced melanin content, downregulating microphthalmia-associated transcription factor (MITF), tyrosinase (TYR), and tyrosinase-related proteins (TRP-1 and TRP-2). Furthermore, RNA-seq analysis indicated that differentially expressed genes in treated cells were enriched in the mitogen-activated protein kinase (MAPK) signaling pathway, with Western blotting confirming enhanced phosphorylation of JNK, ERK, and p38 proteins. Thus, P. pastoris is an effective host for rFIP-gle2 production, which shows potential for applications in pharmaceuticals, cosmeceuticals, and food fields. Full article

Peptides are molecules composed of two or more amino acids linked by peptide bonds, and they play essential biological roles. In recent decades, peptides have become pivotal bioactive ingredients in pharmaceuticals and cosmetics due to their unique features. Originally developed for therapeutic purposes, peptides have gained popularity in the cosmetic field, providing solutions for anti-aging, whitening, moisturizing, and skin repair. Moreover, innovations such as artificial intelligence-assisted peptide design, efficient delivery systems, and the integration of multifunctional ingredients have significantly contributed to the industry’s rapid evolution. This review explores the historical milestones of peptides in medicine and cosmetics, delves into cutting-edge synthesis technologies, and dissects the molecular mechanisms behind their cosmetic properties. Research in medicinal peptides has promoted the development of cosmetic peptides. Despite their potential, challenges such as stability, bioavailability, and cost-effective production remain barriers to widespread adoption. Future studies should focus on enhancing peptide stability, developing synergistic formulations, and conducting large-scale clinical trials to validate long-term efficacy. With continuous innovation, peptides are poised to redefine the cosmetic industry, bridging the gap between pharmaceuticals and skincare for safer and more effective solutions. Full article

Alzheimer’s disease (AD) is the most common neurodegenerative disease which has a rather complex pathophysiology. During its course, several neurotransmitter neuronal systems get affected such as acetylcholinergic, glutamatergic, gamma-aminobutyric acid (GABA)ergic systems, etc. Such complex physiology requires a sophisticated approach to pharmaceutical management. Therefore, multi-target drugs seem to be an appealing solution. In the present study, we designed and synthesized a hybrid molecule—N-sinapoylamide of memantine, whose parent molecules memantine (MEM) and sinapic acid have been shown in vivo to impact glutamatergic, acetylcholinergic, and GABA-ergic systems, respectively. In silico comparative testing of these molecules was performed, their patterns of interaction with the target enzymes or molecular complexes were analyzed, and some of the mechanisms of action were proposed. Consequently, in vivo testing was performed on a scopolamine mice model of AD and the results overly confirm part of the in silico findings. Therefore, the hybrid molecule (N-Sinapoyl-memantine) seems to be a potent candidate for further evaluation in the management of AD. Full article