麻豆淫院

Hydrogels are soft, water-rich polymeric materials that can swell or shrink in response to environmental stimuli. This ability to change shape makes them valuable in miniaturized devices for flexible electronics, microrobotics, intelligent surfaces, and biomedical applications such as drug delivery. For example, hydrogel pores can be engineered to trap and release tiny drug particles on demand.

However, most current hydrogel pores use circular designs, which limit control over shape change and lead to unpredictable, slow actuation. They often close unevenly and recover poorly, reducing their precision and reliability.

To address these challenges, a research team led by Professor Hyunsik Yoon from the Department of Chemical and Biomedical Engineering at Seoul National University of Science and Technology in Korea, introduced a new origami-inspired folding strategy for reversible actuation of hydrogel pores.

"Unlike conventional circular pores, which result in randomized folding, our design involves a facet-driven folding strategy, integrating origami-inspired hinge-and-facet architectures into polygonal hydrogel pores, to enable programmable and predictable actuation,

The team also included Dr. Ji Hoon Kim and Professor Wo Bo Lee from Seoul National University. Their study was in the journal Matter.

The proposed strategy uses polygonal pores with fixed boundaries and predetermined hinges for controlled pore closure and restoration. Upon swelling, the facets of the polygonal pores bulge inward toward the center of the pore along specific directions guided by the predetermined hinges at the vertices, ultimately closing the pore. When the hydrogel shrinks, the facets are restored along the same paths, achieving predictable restoration.

Additionally, the extent of pore closure can be controlled by changing the polygonal shape and fine-tuning the geometric properties. Importantly, the polygonal pores retain 90% of their original shape after repeated swelling-shrinking cycles, demonstrating excellent reliability.

The researchers applied this strategy to achieve pH-triggered release of microparticles, where the pores release microparticles in a staged manner, based on the pH of the environment. "This pH responsive mechanism is highly useful for drug delivery applications, where drug release is staged and targeted to specific regions marked by pH fluctuations," says Prof. Lee.

The researchers also explored information encryption using these pores by creating a mixed matrix of square and circular hydrogel pores, containing fluorescent particles. The difference in closing behavior between the two shapes allowed them to hide or reveal patterns, enabling one-time-use encryption.

"Our strategy can be integrated into drug delivery systems for achieving high spatial and temporal precision, improving therapeutic outcomes while minimizing side effects," states Dr. Kim. "Moreover, this design opens new opportunities for advanced lab-on-a-chip systems, next-generation soft robotic components, and diagnostic assays."