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Wireless intracranial pressure sensors for the assessment of traumatic brain injury
Dissertation   Open access

Wireless intracranial pressure sensors for the assessment of traumatic brain injury

Xu Meng
Doctor of Philosophy (Ph.D.), Drexel University
May 2013
DOI:
https://doi.org/10.17918/etd-4195
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Meng_Xu_20132.94 MBDownloadView
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Abstract

Head--Wounds and injuries Brain--Wounds and injuries Biomedical Engineering
A significant cause of death and long term disability due to head injuries and pathological conditions is an elevation in the intracranial pressure (ICP). ICP measurements before and after the injury in a completely closed-head environment have significant research value, particularly during the acute post-injury period. With the current technology, a tethered fiber optic probe penetrates the brain, and therefore can only remain implanted for relatively short time periods. The goal of this research was to evaluate the dynamic performances of both AICP (previously designed) and digital ICP (DICP) (newly designed) devices in different traumatic brain injury (TBI) models: a swine model of closed-head rotational injury and a rat model of closed-head single and repetitive blast injury. The uniqueness of this work is accentuated by the first time in-vivo studies of dynamic ICP changes using custom-built ICP sensors implanted in two different TBI models. Following implant, baseline ICP readings were relatively stable prior to injury and closed-head rotation TBI induced a rapid and extreme ICP spike occurring directly upon injury. The acute elevation in ICP generally lasted for 40-60 minutes, followed by a gradual decline to a persistently maintained elevated level over several hours post-injury. The AICP devices were redesigned for the study of ICP variation in a rat model of single and repetitive blast induced TBI (bTBI) for seven days and the results revealed the ICP changes in a week under different blast overpressure (BOP) exposure conditions with respect to the peak pressure and the numbers of occurrences of BOP. In addition, a novel TBI in-vitro model was proposed to induce a BOP similar to that in the one measured in the animals head generated by shock tube for the study of immediate neuron response to BOP in a small Petri dish. This research highlights the utility of wireless ICP devices as a tool to diagnose and track long-term ICP changes following TBI in a range of severities and with diminished risk of infection. The simulation indicates an alternative method in the study of bTBI to establish biophysical mechanisms of acute neural cell injury.

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