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Wireless, battery-free, fully implantable multimodal and multisite pacemakers for applications in small animal models

Author

Listed:
  • Philipp Gutruf

    (University of Arizona
    Northwestern University)

  • Rose T. Yin

    (The George Washington University)

  • K. Benjamin Lee

    (The George Washington University
    The George Washington University)

  • Jokubas Ausra

    (University of Arizona)

  • Jaclyn A. Brennan

    (The George Washington University)

  • Yun Qiao

    (The George Washington University)

  • Zhaoqian Xie

    (Dalian University of Technology
    Northwestern University)

  • Roberto Peralta

    (University of Arizona)

  • Olivia Talarico

    (University of Arizona)

  • Alejandro Murillo

    (The George Washington University)

  • Sheena W. Chen

    (The George Washington University)

  • John P. Leshock

    (Northwestern University)

  • Chad R. Haney

    (Northwestern University)

  • Emily A. Waters

    (Northwestern University)

  • Changxing Zhang

    (Tsinghua University)

  • Haiwen Luan

    (Northwestern University)

  • Yonggang Huang

    (Northwestern University)

  • Gregory Trachiotis

    (The George Washington University)

  • Igor R. Efimov

    (The George Washington University)

  • John A. Rogers

    (Northwestern University)

Abstract

Small animals support a wide range of pathological phenotypes and genotypes as versatile, affordable models for pathogenesis of cardiovascular diseases and for exploration of strategies in electrotherapy, gene therapy, and optogenetics. Pacing tools in such contexts are currently limited to tethered embodiments that constrain animal behaviors and experimental designs. Here, we introduce a highly miniaturized wireless energy-harvesting and digital communication electronics for thin, miniaturized pacing platforms weighing 110 mg with capabilities for subdermal implantation and tolerance to over 200,000 multiaxial cycles of strain without degradation in electrical or optical performance. Multimodal and multisite pacing in ex vivo and in vivo studies over many days demonstrate chronic stability and excellent biocompatibility. Optogenetic stimulation of cardiac cycles with in-animal control and induction of heart failure through chronic pacing serve as examples of modes of operation relevant to fundamental and applied cardiovascular research and biomedical technology.

Suggested Citation

  • Philipp Gutruf & Rose T. Yin & K. Benjamin Lee & Jokubas Ausra & Jaclyn A. Brennan & Yun Qiao & Zhaoqian Xie & Roberto Peralta & Olivia Talarico & Alejandro Murillo & Sheena W. Chen & John P. Leshock , 2019. "Wireless, battery-free, fully implantable multimodal and multisite pacemakers for applications in small animal models," Nature Communications, Nature, vol. 10(1), pages 1-10, December.
    • Handle: RePEc:nat:natcom:v:10:y:2019:i:1:d:10.1038_s41467-019-13637-w
    DOI: 10.1038/s41467-019-13637-w
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    Cited by:

    1. Alex Burton & Zhong Wang & Dan Song & Sam Tran & Jessica Hanna & Dhrubo Ahmad & Jakob Bakall & David Clausen & Jerry Anderson & Roberto Peralta & Kirtana Sandepudi & Alex Benedetto & Ethan Yang & Diya, 2023. "Fully implanted battery-free high power platform for chronic spinal and muscular functional electrical stimulation," Nature Communications, Nature, vol. 14(1), pages 1-17, December.
    2. Le Cai & Alex Burton & David A. Gonzales & Kevin Albert Kasper & Amirhossein Azami & Roberto Peralta & Megan Johnson & Jakob A. Bakall & Efren Barron Villalobos & Ethan C. Ross & John A. Szivek & Davi, 2021. "Osseosurface electronics—thin, wireless, battery-free and multimodal musculoskeletal biointerfaces," Nature Communications, Nature, vol. 12(1), pages 1-12, December.
    3. Kaicheng Deng & Yao Tang & Yan Xiao & Danni Zhong & Hua Zhang & Wen Fang & Liyin Shen & Zhaochuang Wang & Jiazhen Pan & Yuwen Lu & Changming Chen & Yun Gao & Qiao Jin & Lenan Zhuang & Hao Wan & Liujin, 2023. "A biodegradable, flexible photonic patch for in vivo phototherapy," Nature Communications, Nature, vol. 14(1), pages 1-15, December.

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