# iPPSIS: implanted Passive Pressure Sensor Interrogated with (ultra)-Sound

> **NIH NIH R01** · EMORY UNIVERSITY · 2024 · $495,977

## Abstract

ABSTRACT
More than 1.3 million new patients are diagnosed each year with neurological conditions that may result in ele-
vated intracranial pressure (ICP). In these patients, the limited ability to make accurate, stable pressure meas-
urements with wireless, MRI compatible devices contributes to poor clinical outcomes. It is hypothesized that a
novel ultrasound-based wireless transduction approach combined with an implanted pressure-sensitive target
has the potential to nearly eliminate drift, improving patient management. Long recognized as an unaddressed
clinical need, implanted pressure sensors that measure intracranial pressure have been proposed since the
1950’s. Unfortunately, nearly all neuro sensors rely on the same underlying technology: a thin membrane that
can deflect directly adjacent to a sealed air chamber or vacuum. Due to the size scales involved and the material
constraints with traditional radio-frequency approaches, all of these devices experience drift as air or water vapor
diffuse across the thin membrane and/or induce stress in packaging materials. This fundamentally limits the
usefulness of these devices. As an example, the gold standard implanted pressure sensor for neurosurgeons,
the Codman Microsensor ICP Transducer is wired, MRI conditional, and has an average drift of 1 mm Hg over
1 week. While recent innovations have led to the development of fiber optic-based sensors and even dissolvable
sensors, these devices still rely on the same fundamental approach, and do not address the need for long-term
stable sensors. This proposal seeks to advance a new approach to clinical testing: using ultrasound to transduce
information from an implanted microsystems target.
Our novel approach combines: 1) a novel MRI compatible pressure sensor “target” filled with liquids and air that
move in response to pressure, and 2) an ultrasound-based platform that can image the movement of this air and
liquid, thereby enabling a quantitative measurement of pressure. In the target, a thin membrane adjacent to a
liquid-filled chamber deflects in response to pressure. This deflection causes a connected serpentine channel to
fill with liquid. Since air is easily visualized in the device with ultrasound due to the high acoustic impedance
mismatch, and since the air movement is proportional to pressure, this combined system creates an easy to read
quantitative pressure measurement. Therefore, this project aims to accomplish the following:
Aim 1: Development and long-term in vitro testing of membrane-based pressure micro-sensor ultrasound target.
Aim 2: Develop ultrasound-based readout of passive implanted pressure sensor.
Aim 3: Validate in vivo implant procedure and sensor integrity in acute and multi-week porcine models.
When complete, a new class of ultra-stable, testable, long-term ICP pressure sensors will be available to quan-
titatively monitor patients at risk of elevated intracranial pressure. This will spare patients from inconclusive im-
a...

## Key facts

- **NIH application ID:** 10859025
- **Project number:** 1R01EB035582-01
- **Recipient organization:** EMORY UNIVERSITY
- **Principal Investigator:** Brooks D Lindsey
- **Activity code:** R01 (R01, R21, SBIR, etc.)
- **Funding institute:** NIH
- **Fiscal year:** 2024
- **Award amount:** $495,977
- **Award type:** 1
- **Project period:** 2024-06-15 → 2028-03-31

## Primary source

NIH RePORTER: https://reporter.nih.gov/project-details/10859025

## Citation

> US National Institutes of Health, RePORTER application 10859025, iPPSIS: implanted Passive Pressure Sensor Interrogated with (ultra)-Sound (1R01EB035582-01). Retrieved via AI Analytics 2026-05-24 from https://api.ai-analytics.org/grant/nih/10859025. Licensed CC0.

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