npj Digital Medicine (Mar 2020)

Continuous, noninvasive wireless monitoring of flow of cerebrospinal fluid through shunts in patients with hydrocephalus

  • Siddharth R. Krishnan,
  • Hany M. Arafa,
  • Kyeongha Kwon,
  • Yujun Deng,
  • Chun-Ju Su,
  • Jonathan T. Reeder,
  • Juliet Freudman,
  • Izabela Stankiewicz,
  • Hsuan-Ming Chen,
  • Robert Loza,
  • Marcus Mims,
  • Mitchell Mims,
  • KunHyuck Lee,
  • Zachary Abecassis,
  • Aaron Banks,
  • Diana Ostojich,
  • Manish Patel,
  • Heling Wang,
  • Kaan Börekçi,
  • Joshua Rosenow,
  • Matthew Tate,
  • Yonggang Huang,
  • Tord Alden,
  • Matthew B. Potts,
  • Amit B. Ayer,
  • John A. Rogers

DOI
https://doi.org/10.1038/s41746-020-0239-1
Journal volume & issue
Vol. 3, no. 1
pp. 1 – 11

Abstract

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Abstract Hydrocephalus is a common disorder caused by the buildup of cerebrospinal fluid (CSF) in the brain. Treatment typically involves the surgical implantation of a pressure-regulated silicone tube assembly, known as a shunt. Unfortunately, shunts have extremely high failure rates and diagnosing shunt malfunction is challenging due to a combination of vague symptoms and a lack of a convenient means to monitor flow. Here, we introduce a wireless, wearable device that enables precise measurements of CSF flow, continuously or intermittently, in hospitals, laboratories or even in home settings. The technology exploits measurements of thermal transport through near-surface layers of skin to assess flow, with a soft, flexible, and skin-conformal device that can be constructed using commercially available components. Systematic benchtop studies and numerical simulations highlight all of the key considerations. Measurements on 7 patients establish high levels of functionality, with data that reveal time dependent changes in flow associated with positional and inertial effects on the body. Taken together, the results suggest a significant advance in monitoring capabilities for patients with shunted hydrocephalus, with potential for practical use across a range of settings and circumstances, and additional utility for research purposes in studies of CSF hydrodynamics.