Explore how plants like neem and aloe act as eco-friendly nano-factories, synthesizing silver nanoparticles with potent antimicrobial, anticancer, and catalytic properties.
Discover the marine bacterium Loktanella rosea and its revolutionary lipopolysaccharide structure—a biochemical oddity with implications for medicine, industry, and our understanding of microbial adaptation.
Explore the hidden world of Pseudomonas syringae’s antimetabolite toxins—chemical weapons that disrupt plant metabolism, cause devastating diseases, and inspire innovative agricultural solutions.
Explore the dual roles of amino acids in health and disease: Discover how cancer's addiction to L-asparagine drives treatment innovation, and why β-hydroxyaspartic acid derivatives could revolutionize drug development.
Explore how copper(II) complexes with 1,10-phenanthroline, adenine, and thymine are synthesized, characterized, and harnessed to combat antibiotic-resistant bacteria.
Explore the groundbreaking design of ester insulin—a chemically convertible proinsulin surrogate that mimics natural folding mechanisms to streamline insulin synthesis. Discover its implications for diabetes treatment and drug development.
Discover how the single-celled alga Chlamydomonas prioritizes copper usage between photosynthesis and respiration, revealing nature’s blueprint for resource efficiency.
Explore the hidden world of lichens—fungi-algae partnerships that craft survival blueprints through intricate morphogenesis and bioactive compounds. Discover groundbreaking research on Cladia retipora and Dactylina arctica.
Explore the legacy of Alan D. Elbein, a trailblazer in glycobiology whose work on carbohydrate metabolism and glycoprotein synthesis laid the foundation for modern biomedicine.
Discover how cutting-edge imaging technologies reveal the hidden dance of protein thiol modifications in real time—and why these tiny chemical tweaks hold keys to aging, disease, and cellular survival.
Explore how Fourier Transformed AC Voltammetry (FTacV) revolutionizes our understanding of HypD's redox chemistry, unlocking insights into enzyme dynamics and biomedical applications.
