molecular docking – Page 3

Synergistic potential and apoptosis induction of Bunium persicum essential oil and its pure components, cuminaldehyde and γ-terpinene, in combination with fluconazole on Candida albicans isolates: in vitro and in silico evaluation

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Researchers tested a spice-derived essential oil called Bunium persicum and two of its active compounds to see if they could work better with the antifungal drug fluconazole against drug-resistant yeast infections. They found that one component called cuminaldehyde was particularly effective and worked synergistically with fluconazole, meaning the combination was more powerful than either treatment alone. These natural compounds could potentially help treat fungal infections that no longer respond to standard medications, offering a promising approach using plant-based remedies alongside conventional drugs.

The Molecular Mechanism of Polysaccharides from Polygonatum cyrtonema Hua in Improving Hyperuricemia by Regulating Key Targets of Uric Acid Metabolism in Mice

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This research demonstrates that a traditional Chinese medicinal plant called Polygonatum cyrtonema contains beneficial polysaccharides that can help lower high uric acid levels in the blood, which is a major cause of gout and kidney disease. The study found that these polysaccharides work by reducing the enzyme that produces uric acid and helping the kidneys excrete more of it, while also reducing inflammation. Importantly, this natural treatment protected kidney tissue better than the standard pharmaceutical drug allopurinol, suggesting it could be a safer long-term option for managing high uric acid levels.

Cinchona-based liquid formulation exhibits antifungal activity through Tryptophan starvation and disruption of mitochondrial respiration in Rhizoctonia Solani

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Researchers found that an extract from Cinchona bark, containing the compound quinine, effectively kills rice-damaging fungus Rhizoctonia solani through two mechanisms: starving the fungus of the amino acid tryptophan and disrupting its energy-producing mitochondria. This natural plant-based treatment could serve as an eco-friendly alternative to synthetic fungicides, reducing crop losses from fungal diseases while avoiding the environmental damage and resistance problems associated with chemical pesticides.

Electrospun Membranes Loaded with Melanin Derived from Pecan Nutshell (Carya illinoinensis) Residues for Skin-Care Applications

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Researchers developed new skincare membranes by combining pecan shell waste with advanced fiber technology. These membranes harness melanin from the shells to create materials with strong antioxidant and antibacterial properties that could protect skin from aging and infections. The innovation demonstrates how agricultural waste can be transformed into valuable cosmetic products that are both effective and environmentally friendly.

Transcriptomics Insights into Targeting CK2 Complex in Cryptococcus neoformans: Implications for Large-Scale Antifungal Virtual Screening

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Scientists studied how a fungus called Cryptococcus neoformans causes serious brain infections and found that disabling a specific protein complex (CK2) could be an effective treatment strategy. Using computer analysis of genetic data, they identified three existing drugs—amphotericin B, idarubicin, and candicidin—that could potentially target and kill this dangerous fungus. This research provides a foundation for developing better treatments for cryptococcal meningitis, a life-threatening infection that kills hundreds of thousands of people annually, especially those with weakened immune systems.

Drug repurposing to fight resistant fungal species: Recent developments as novel therapeutic strategies

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Fungal infections are becoming increasingly difficult to treat due to growing drug resistance, affecting millions of people worldwide each year. This research collection explores creative solutions by repurposing existing medications and developing new combination therapies that work better together against resistant fungal species. Studies show promising results combining common antibiotics like minocycline with antifungal drugs, and natural compounds from traditional medicine show potential for treating hard-to-treat infections like Candida and Aspergillus.

Synergistic potential and apoptosis induction of Bunium persicum essential oil and its pure components, cuminaldehyde and γ-terpinene, in combination with fluconazole on Candida albicans isolates: in vitro and in silico evaluation

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Researchers studied how Bunium persicum essential oil and two of its active components work together with the antifungal drug fluconazole to fight resistant Candida yeast infections. They found that cuminaldehyde, one of the oil’s main components, was particularly effective when combined with fluconazole and could trigger yeast cell death. These natural compounds could offer a promising new approach to treating fungal infections that have become resistant to standard medications.

Cinchona-based liquid formulation exhibits antifungal activity through Tryptophan starvation and disruption of mitochondrial respiration in Rhizoctonia Solani

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Scientists tested a plant-based extract from Cinchona bark as a natural fungicide against a serious fungus that damages rice crops. The active ingredient, quinine, works by two methods: it blocks the fungus from getting the amino acid tryptophan it needs to survive, and it damages the fungus’s energy-producing structures. When researchers added tryptophan back to the treated fungus, it recovered, confirming this is how the treatment works. This natural fungicide could offer farmers an eco-friendly alternative to chemical pesticides.

An Efficient Microwave Synthesis of 3-Acyl-5-bromoindole Derivatives for Controlling Monilinia fructicola and Botrytis cinerea

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Scientists developed new chemical compounds called indole derivatives that can kill harmful fungi that destroy fruit crops like stone fruits and grapes. These compounds were made using microwave heating, which is faster and more efficient than traditional methods. Testing showed that some of these new compounds were even better at fighting these fungal diseases than current commercial fungicides, offering promise for protecting crops in agriculture.

In vitro and in vivo efficacy of the antimycobacterial molecule SQ109 against the human pathogenic fungus, Cryptococcus neoformans

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Researchers discovered that SQ109, an antimycobacterial drug, can effectively kill Cryptococcus fungi that cause serious brain infections in people with weakened immune systems. Unlike current treatments, cryptococcal cells don’t easily develop resistance to SQ109, and it works even better when combined with fluconazole. In mouse studies, SQ109 successfully treated cryptococcal infections, suggesting it could be a valuable new treatment option for patients worldwide, especially in resource-limited regions.

Research Keyword: molecular docking