Researchers developed an advanced sensor platform that measures metabolites - key molecules involved in sustaining life through metabolism - inside the body in real time.
The study demonstrates that this RNAi approach shuts down vital fungal genes, thereby inhibiting pathogen growth - a groundbreaking step in the development of new antifungal therapies.
Scientists developed a new photopolymerisation reaction controlled antagonistically by two different colours of light. Specifically, one light beam promotes the formation of the polymeric material, while another beam halts the reaction.
New bacterial nanocellulose-covered stents integrate seamlessly with tissues, deliver drugs precisely, and promise safer treatments for airway and vascular diseases.
Researchers have created a magnetic tweezer system that could one day make it possible for doctors to do remote, non-invasive, highly precise medical procedures on their patients using a microrobot.
Automated glass-chamber system transfers graphene from copper to wafers using fluid cycles, enabling precise, hands-free chip production like a miniature assembly line.
Researchers integrated ferrocene (Fe-containing molecular sandwich) with carbon nanohoops to create a system releasing Fe2+ ions when activated by green light.
Scientists have for the first time filmed the real-time growth and contraction of Palladium nanoparticles, opening new avenues for utilising and recycling precious metal catalysts.
A novel method to improve the photoluminescent efficiency of metal clusters has been developed - which could potentially be used in applications such as bioimaging or display technologies.
Researchers have developed a technology that utilizes nanoscale wrinkles formed on transparent films to display or conceal color patterns, such as the Korean traditional Dancheong designs, by folding and unfolding the film.
