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On the longevity and inherent hermeticity of silicon-ICs: evaluation of bare-die and PDMS-coated ICs after accelerated aging and implantation studies

Author

Listed:
  • Kambiz Nanbakhsh

    (Delft University of Technology)

  • Ahmad Shah Idil

    (University College London
    Imperial College London
    Care Research and Technology Centre
    Mint Neurotechnologies Ltd)

  • Callum Lamont

    (University College London)

  • Csaba Dücső

    (HUN-REN)

  • Ömer Can Akgun

    (Delft University of Technology
    Nikhef - Dutch National Institute for Subatomic Physics)

  • Domonkos Horváth

    (HUN-REN
    Faculty of Information Technology and Bionics)

  • Kinga Tóth

    (HUN-REN
    Faculty of Information Technology and Bionics)

  • Domokos Meszéna

    (HUN-REN
    Faculty of Information Technology and Bionics)

  • István Ulbert

    (HUN-REN
    Faculty of Information Technology and Bionics)

  • Federico Mazza

    (Imperial College London)

  • Timothy G. Constandinou

    (Imperial College London
    Care Research and Technology Centre
    Mint Neurotechnologies Ltd)

  • Wouter Serdijn

    (Delft University of Technology
    Erasmus Medical Center)

  • Anne Vanhoestenberghe

    (University College London
    King’s College London)

  • Nick Donaldson

    (University College London)

  • Vasiliki Giagka

    (Delft University of Technology
    Fraunhofer Institute for Reliability and Microintegration IZM)

Abstract

Silicon integrated circuits (ICs) are central to the next-generation miniature active neural implants, whether packaged in soft polymers for flexible bioelectronics or implanted as bare die for neural probes. These emerging applications bring the IC closer to the corrosive body environment, raising reliability concerns, particularly for chronic use. Here, we evaluate the inherent hermeticity of bare die ICs, and examine the potential of polydimethylsiloxane (PDMS), a moisture-permeable elastomer, as a standalone encapsulation material. For this aim, the electrical and material performance of ICs sourced from two foundries was evaluated through one-year accelerated in vitro and in vivo studies. ICs featured custom-designed test structures and were partially PDMS coated, creating two regions on each chip, uncoated “bare die” and “PDMS-coated”. During the accelerated in vitro study, ICs were electrically biased and periodically monitored. Results revealed stable electrical performance, indicating the unaffected operation of ICs even when directly exposed to physiological fluids. Despite this, material analysis revealed IC degradation in the bare regions. PDMS-coated regions, however, revealed limited degradation, making PDMS a suitable IC encapsulant for years-long implantation. Based on the new insights, guidelines are proposed that may enhance the longevity of implantable ICs, broadening their applications in the biomedical field.

Suggested Citation

  • Kambiz Nanbakhsh & Ahmad Shah Idil & Callum Lamont & Csaba Dücső & Ömer Can Akgun & Domonkos Horváth & Kinga Tóth & Domokos Meszéna & István Ulbert & Federico Mazza & Timothy G. Constandinou & Wouter , 2025. "On the longevity and inherent hermeticity of silicon-ICs: evaluation of bare-die and PDMS-coated ICs after accelerated aging and implantation studies," Nature Communications, Nature, vol. 16(1), pages 1-17, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-024-55298-4
    DOI: 10.1038/s41467-024-55298-4
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    1. Yeon Sik Choi & Yuan-Yu Hsueh & Jahyun Koo & Quansan Yang & Raudel Avila & Buwei Hu & Zhaoqian Xie & Geumbee Lee & Zheng Ning & Claire Liu & Yameng Xu & Young Joong Lee & Weikang Zhao & Jun Fang & Yuj, 2020. "Stretchable, dynamic covalent polymers for soft, long-lived bioresorbable electronic stimulators designed to facilitate neuromuscular regeneration," Nature Communications, Nature, vol. 11(1), pages 1-14, December.
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