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Demonstrating the Analytical Potential of a Wearable Microneedle-Based Device for Intradermal CO<sub>2</sub> Detection

Águeda Molinero‐Fernández, Qianyu Wang, Xing Xuan, Åsa Konradsson‐Geuken, Gastón A. Crespo, María Cuartero

2024ACS Sensors17 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Monitoring of carbon dioxide (CO 2 ) body levels is crucial under several clinical conditions (e.g., human intensive care and acid–base disorders). To date, painful and risky arterial blood punctures have been performed to obtain discrete CO 2 measurements needed in clinical setups. Although noninvasive alternatives have been proposed to assess CO 2, these are currently limited to benchtop devices, requiring trained personnel, being tedious, and providing punctual information, among other disadvantages. To the best of our knowledge, the literature and market lack a wearable device for real-time, on-body monitoring of CO 2 . Accordingly, we have developed a microneedle (MN)-based sensor array, labeled as CO 2 –MN, comprising a combination of potentiometric pH- and carbonate (CO 3 2– )-selective electrodes together with the reference electrode. The CO 2 –MN is built on an epidermal patch that allows it to reach the stratum corneum of the skin, measuring pH and CO 3 2– concentrations directly into the interstitial fluid (ISF). The levels for the pH–CO 3 2– tandem are then used to estimate the P CO 2 in the ISF. Assessing the response of each individual MN, we found adequate response time ( t 95 < 5s), sensitivity (50.4 and −24.6 mV dec –1 for pH and CO 3 2–, respectively), and stability (1.6 mV h –1 for pH and 2.1 mV h –1 for CO 3 2– ). We validated the intradermal measurements of CO 2 at the ex vivo level, using pieces of rat skin, and then, with in vivo assays in anesthetized rats, showing the suitability of the CO 2 –MN wearable device for on-body measurements. A good correlation between ISF and blood CO 2 concentrations was observed, demonstrating the high potential of the developed MN sensing technology as an alternative to blood-based analysis in the near future. Moreover, these results open new horizons in the noninvasive, real-time monitoring of CO 2 as well as other clinically relevant gases.

Topics & Concepts

Stratum corneumPotentiometric titrationBiomedical engineeringContinuous monitoringIn vivoHuman skinpCO2Wearable computerCarbon dioxideMaterials scienceElectrodeChemistryMedicineComputer scienceAnesthesiaPathologyEmbedded systemPhysical chemistryOrganic chemistryOperations managementGeneticsEconomicsBiotechnologyBiologyAnalytical Chemistry and SensorsMechanical and Optical ResonatorsAdvanced Chemical Sensor Technologies