[
  {
    "id": "FCZ4WC4V",
    "type": "article-journal",
    "abstract": "Overcoming the mechanical disparities between implantable neural electrodes and biological tissue is crucial in mitigating immune responses, reducing shear motion, and ensuring durable functionality. Emerging hydrogel-based neural interfaces, with their volumetric capacitance, customizable conductivity, and tissue-mimicking mechanical properties, offer a more efficient, less detrimental, and chronically stable alternative to their rigid counterparts. Here, we provide an overview of the exceptional advantages of hydrogels for the development of next-generation neural interfaces and highlight recent advancements that are transforming the field.",
    "container-title": "Communications Materials",
    "DOI": "10.1038/s43246-024-00541-0",
    "ISSN": "2662-4443",
    "issue": "1",
    "journalAbbreviation": "Commun Mater",
    "language": "en",
    "license": "2024 The Author(s)",
    "page": "1-9",
    "source": "www.nature.com",
    "title": "Hydrogels for next generation neural interfaces",
    "URL": "https://www.nature.com/articles/s43246-024-00541-0",
    "volume": "5",
    "author": [
      {
        "family": "Cheng",
        "given": "Simin"
      },
      {
        "family": "Zhu",
        "given": "Ruiqi"
      },
      {
        "family": "Xu",
        "given": "Xiaomin"
      }
    ],
    "accessed": {
      "date-parts": [
        [
          "2024",
          11,
          22
        ]
      ]
    },
    "issued": {
      "date-parts": [
        [
          "2024",
          6,
          12
        ]
      ]
    }
  }
]