Miniaturized Passive Hydrogel Check Valve for Hydrocephalus Treatment

Author

Schwerdt, Helen N. ; Bristol, Ruth E. ; Junseok Chae

Author_Institution

Dept. of Electr. Eng., Arizona State Univ., Tempe, AZ, USA

Volume

61

Issue

3

fYear

2014

fDate

41699

Firstpage

814

Lastpage

820

Abstract

Improvements in cerebrospinal fluid (CSF) draining techniques for treatment of hydrocephalus are urgently sought after to substitute for current CSF shunts that are plagued by high failure rates. The passive check valve aims to restore near natural CSF draining operations while mitigating possible failure mechanisms caused by finite leakage or low resilience that frequently constrain practical implementation of miniaturized valves. A simple hydrogel diaphragm structures core passive valve operations and enforce valve sealing properties to substantially lower reverse flow leakage. Experimental measurements demonstrate realization of targeted cracking pressures (P_T ≈ 20-110 mmH₂O) and operation at -800 <; ΔP <; 600 mmH₂O without observable degradation or leakage.

Keywords

biomechanics; brain; cracks; diaphragms; fracture; hydrogels; medical disorders; neurophysiology; patient treatment; cerebrospinal fluid draining techniques; core passive valve operations; current CSF shunts; enforce valve sealing properties; failure mechanisms; high failure rates; hydrocephalus treatment; low reverse flow leakage; miniaturized passive hydrogel check valve; miniaturized valves; natural CSF draining operations; simple hydrogel diaphragm structures; targeted cracking pressure realization; Biomembranes; Fluids; Iterative closest point algorithm; Silicon; Substrates; Valves; Check valve; hydrogel; implantable microsystem; intracranial pressure (ICP) regulation; passive valve;

fLanguage

English

Journal_Title

Biomedical Engineering, IEEE Transactions on

Publisher

ieee

ISSN

0018-9294

Type

jour

DOI

10.1109/TBME.2013.2290291

Filename

6661354