(352d) Polymer-Based Sensors to Monitor Indoor Air Quality and Ocular Response | AIChE

(352d) Polymer-Based Sensors to Monitor Indoor Air Quality and Ocular Response

Authors 

Boudouris, B. - Presenter, Purdue University
Sensing elements continue to play a crucial role in myriad human health efforts, and devices based on functional polymers offer a means by which to usher in the next generation of advanced sensors. Here, we describe to distinct efforts with respect to this design archetype. In the first of these efforts, we combine a tailored blend of poly(ethylene oxide) (PEO) and polyethyleneimine (PEI) with microelectromechanical system (MEMS) resonant mass sensors to yield low-cost, low-power consumption carbon dioxide sensors. In this materials system, the PEI serves as an effective sorbent for carbon dioxide uptake while the PEO moiety aids in guiding the structure of the polymer blend. By controlling the polymer formulation and the processing procedure used to deposit these materials from solution, we control the micro- and nanoscale structure of the final polymer thin films. This control over the local structure allows for sensors that are highly specific to carbon dioxide relative to multiple potential interferent gases (e.g., carbon monoxide and ethanol). Moreover, the PEO-PEI sensors show clear response signals across a broad range of carbon dioxide concentrations (i.e., from 100 ppm to 10,000 ppm), and this is true in air-only background environments and in cases where a residual background of carbon dioxide is present and across a range of relative humidity values. Thus, these sensors can be utilized as proxies for room occupancy in buildings, which is becoming of increasing importance given the global pandemic and the need to minimize energy usage in the built environment.

In the second effort, we demonstrate the design of all-printed stretchable corneal sensor built on commercially-available disposable soft contact lenses that can intimately and non-invasively interface with the corneal surface of human eyes. This is critical as electroretinogram (ERG) examinations serve as routine clinical procedures in ophthalmology for the diagnosis and management of many ocular diseases. However, the rigid form factor of current corneal sensors produces a mismatch with the soft, curvilinear, and exceptionally-sensitive human cornea, which typically requires the use of topical anesthesia and a speculum for pain management and safety. On the other hand, our poly(3,4-ethylenedioxythiophene)-based (PEDOT-based) corneal sensor is integrated with soft contact lenses via an electrochemical anchoring mechanism in a seamless manner that ensures its mechanical and chemical reliability. Thus, the resulting device enables the high-fidelity recording of full-field ERG signals in human eyes without the need of topical anesthesia or a speculum. The device, superior to clinical standards in terms of signal quality and comfortability, is expected to address unmet clinical needs in the field of ocular electrodiagnosis. Moreover, we modified the general design of the sensor such that a new iteration serves as a means by which to measure interocular pressure. We did this because continuous monitoring of intraocular pressure remains a challenge in glaucoma care, especially during sleep. Specifically, we introduced an intrinsically soft and stretchable ocular tonometer built on a commercial overnight-wearable soft contact lens. The resulting ocular tonometer, or contact lens sensor, fits seamlessly across different corneal curvatures and thicknesses in human eyes and is capable of wirelessly capturing absolute intraocular pressure levels without iterative calibrations. We validated the biocompatibility, wireless sensing capability, on-eye safety, and 24-hour monitoring reliability of the contact lens sensor in human corneal cells in vitro, pig eyes ex vivo, and rabbit and dog eyes in vivo, respectively. We also showed the continuous monitoring of ambulatory intraocular pressure in human eyes under normal and ocular hypertension conditions to confirm the measurement accuracy, within-subject repeatability, and user comfort of the contact lens sensor beyond current state-of-the-art wearable ocular tonometers. We envision that the new contact lens sensor become the gold standard in managing glaucoma and ocular hypertension, especially as telehealth treatments continue to rise. In this way, we aim to have this talk describe two key areas where polymeric materials can improve sensors that will allow for enhanced human health.

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