<p>Hydrogels are widely used in biomedical interfaces, in which effective gas exchange (for example, O<sub>2</sub>, CO<sub>2</sub>) within a water-rich environment is essential. However, hydrogels show intrinsically limited air exchange efficiency, owing to the low solubility (<i>C</i>) and diffusivity (<i>D</i>) of non-polar gases in the polar water medium<sup><CitationRef CitationID="CR1">1</CitationRef></sup>. This limitation poses a substantial bottleneck in long-term applications, such as wearable health monitors<sup><CitationRef AdditionalCitationIDS="CR3 CR4 CR5 CR6" CitationID="CR2">2</CitationRef>–<CitationRef CitationID="CR7">7</CitationRef></sup> and tissue engineering<sup><CitationRef AdditionalCitationIDS="CR9 CR10 CR11" CitationID="CR8">8</CitationRef>–<CitationRef CitationID="CR12">12</CitationRef></sup>. Existing methods<sup><CitationRef AdditionalCitationIDS="CR14 CR15" CitationID="CR13">13</CitationRef>–<CitationRef CitationID="CR16">16</CitationRef></sup> to enhance air permeability suffer from poor robustness and/or an inherent trade-off between permeability and water content (for example, &lt;50 vol%). Here we introduce a viscoelastic phase separation<sup><CitationRef CitationID="CR17">17</CitationRef></sup> (VPS)-enabled strategy to create a non-collapsible, air-rich network in high-water-content hydrogels, achieving a record-high oxygen permeability of 185 barrer with 70 vol% water—a tenfold increase compared with pristine hydrogels. VPS, a ubiquitous phenomenon in soft matter, is used to drive hydrophobic, dry gas particles within a hydrophilic, wet medium into a thin, stable three-dimensional network. This approach allows the facile and scalable fabrication of air-permeable hydrogels across diverse chemistries and form factors. Physiological tests over a 10-day continuous wear condition confirmed their effectiveness in preventing fluid accumulation and maintaining skin health. This strategy paves the way for hydrogels in long-term biomedical applications in which efficient and sustained air exchange becomes critical.</p>

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Air-permeable hydrogels through viscoelastic phase separation of aerogels

  • Xiao-Yun Yan,
  • Shucong Li,
  • Won Jun Song,
  • Runze Li,
  • Aarosh Dahal,
  • Bastien F. G. Aymon,
  • Haodong Hu,
  • Deep K. Malu,
  • Gabriella E. Carreira,
  • Jingjing Wu,
  • Gengxi Lu,
  • Bolei Deng,
  • Jiayi Liu,
  • Siqin Yu,
  • Shu Wang,
  • Eric Lu,
  • Hyunhee Lee,
  • Hui Xu,
  • Anqi Chen,
  • Yuxing Yao,
  • James H. Zhang,
  • Chen Gong,
  • Yiyuan Sun,
  • Jeong-Yun Sun,
  • David A. Weitz,
  • Casey O’Brien,
  • Yuhang Hu,
  • Zachary P. Smith,
  • Aditya Kumar,
  • Xuanhe Zhao

摘要

Hydrogels are widely used in biomedical interfaces, in which effective gas exchange (for example, O2, CO2) within a water-rich environment is essential. However, hydrogels show intrinsically limited air exchange efficiency, owing to the low solubility (C) and diffusivity (D) of non-polar gases in the polar water medium1. This limitation poses a substantial bottleneck in long-term applications, such as wearable health monitors27 and tissue engineering812. Existing methods1316 to enhance air permeability suffer from poor robustness and/or an inherent trade-off between permeability and water content (for example, <50 vol%). Here we introduce a viscoelastic phase separation17 (VPS)-enabled strategy to create a non-collapsible, air-rich network in high-water-content hydrogels, achieving a record-high oxygen permeability of 185 barrer with 70 vol% water—a tenfold increase compared with pristine hydrogels. VPS, a ubiquitous phenomenon in soft matter, is used to drive hydrophobic, dry gas particles within a hydrophilic, wet medium into a thin, stable three-dimensional network. This approach allows the facile and scalable fabrication of air-permeable hydrogels across diverse chemistries and form factors. Physiological tests over a 10-day continuous wear condition confirmed their effectiveness in preventing fluid accumulation and maintaining skin health. This strategy paves the way for hydrogels in long-term biomedical applications in which efficient and sustained air exchange becomes critical.