| 1. |
- Molinero-Fernandez, Águeda, et al.
(author)
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Demonstrating the Analytical Potential of a Wearable Microneedle-Based Device for Intradermal CO2 Detection
- 2024
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In: ACS Sensors. - : American Chemical Society (ACS). - 2379-3694. ; 9:1, s. 361-370
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Journal article (peer-reviewed)abstract
- Monitoring of carbon dioxide (CO2) 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 CO2 measurements needed in clinical setups. Although noninvasive alternatives have been proposed to assess CO2, 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 CO2. Accordingly, we have developed a microneedle (MN)-based sensor array, labeled as CO2–MN, comprising a combination of potentiometric pH- and carbonate (CO32–)-selective electrodes together with the reference electrode. The CO2–MN is built on an epidermal patch that allows it to reach the stratum corneum of the skin, measuring pH and CO32– concentrations directly into the interstitial fluid (ISF). The levels for the pH–CO32– tandem are then used to estimate the PCO2 in the ISF. Assessing the response of each individual MN, we found adequate response time (t95 < 5s), sensitivity (50.4 and −24.6 mV dec–1 for pH and CO32–, respectively), and stability (1.6 mV h–1 for pH and 2.1 mV h–1 for CO32–). We validated the intradermal measurements of CO2 at the ex vivo level, using pieces of rat skin, and then, with in vivo assays in anesthetized rats, showing the suitability of the CO2–MN wearable device for on-body measurements. A good correlation between ISF and blood CO2 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 CO2 as well as other clinically relevant gases.
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| 2. |
- Molinero Fernandez, Agueda, et al.
(author)
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In Vivo Transdermal Multi-Ion Monitoring with a Potentiometric Microneedle-Based Sensor Patch
- 2023
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In: ACS Sensors. - : American Chemical Society (ACS). - 2379-3694. ; 8:1, s. 158-166
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Journal article (peer-reviewed)abstract
- Microneedle sensor technology offers exciting opportunities for decentralized clinical analyses. A novel issue puts forward herein is to demonstrate the uniqueness of membrane-based microneedles to accomplish real-time, on-body monitoring of multiple ions simultaneously. The use of multi-ion detection is clinically relevant since it is expected to provide a more complete and reliable assessment of the clinical status of a subject concerning electrolyte disorders and others. We present a microneedle system for transdermal multiplexed tracing of pH, Na+, K+, Ca2+, Li+, and Cl-. The device consists of an array of seven solid microneedles externally modified to provide six indicator electrodes, each selective for a different ion, and a common reference electrode, all integrated into a wearable patch read in a potentiometric mode. We show in vitro measurements at the expected clinical levels, resulting in a fast response time, excellent reversibility and repeatability, and adequate selectivity. Close-to-Nernstian sensitivity, sufficient stability and resiliency to skin penetration guarantee the sensor's success in transdermal measurements, which we demonstrate through ex vivo (with pieces of rat skin) and in vivo (on-body measurements in rats) tests. Accuracy is evaluated by comparison with gold standard techniques to characterize collected dermal fluid, blood, and serum. In the past, interstitial fluid (ISF) analysis has been challenging due to difficult sample collection and analysis. For ions, this has resulted in extrapolations from blood concentrations (invasive tests) rather than pure measurements in ISF. The developed microneedle patch is a relevant analytical tool to address this information gap.
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| 3. |
- Moreno-Guzman, Maria, et al.
(author)
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Bi-enzymatic biosensor for on-site, fast and reliable electrochemical detection of relevant D-amino acids in bacterial samples
- 2017
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In: Sensors and actuators. B, Chemical. - : Elsevier BV. - 0925-4005 .- 1873-3077. ; 242, s. 95-101
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Journal article (peer-reviewed)abstract
- In this work, a bi-enzymatic biosensor allowed the total content of D-amino acids (DAAs) determination in highly relevant matrices involving bacteria. The strategy is based on the unique coimmobilization of D-amino acid oxidase (DAAO) and horseradish peroxidase (HRP) enzymes onto a multi-walled carbon nanotubes (MWCNTs) and gold nanoparticles (AuNPs) modified screen-printed electrode (SPCE). The greater amount of AuNPs deposited and hence the greater loading of both enzymes was observed when they were deposited after the activation of the carboxylated MWCNTs with EDC/Sulfo-NHS chemistry. These platforms provided a fast (300s) and selective quantification of DAAs with excellent precision (RSD < 5%) and accuracy (Recoveries 100-104%) in bacterial samples. Collectively, the electrochemical bi-enzymatic biosensor become an universal, fast, sensitive and easy-to-use approach to determine total content of DAAs in complex matrices.
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| 4. |
- Wang, Qianyu, et al.
(author)
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Intradermal Glycine Detection with a Wearable Microneedle Biosensor : The First In Vivo Assay
- 2022
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In: Analytical Chemistry. - : American Chemical Society (ACS). - 0003-2700 .- 1520-6882. ; 94:34, s. 11856-11864
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Journal article (peer-reviewed)abstract
- Glycine (GLY) is gaining importance in medical diagnoses due to its relationship with multiple physiological functions. Today, GLY is exclusively analyzed using instrumentation centralized in clinical labs, and a tangible point-of-care tool that gathers real-time data from the patient for effective and fast evaluations is lacking. Relevant clinical advances are expected as soon as the rapid provision of both punctual and continuous measurements is possible. In that context, this work presents a microneedle (MN)-based biosensor for intradermal GLY detection in interstitial fluid (ISF). The MN tip is externally tailored to detect GLY levels through the hydrogen peroxide formed in its reaction with a quinoprotein-based GLY oxidase enzyme. The analytical performance of the MN biosensor indicates a fast response time (<7 s); acceptable reversibility, reproducibility, and stability; as well as a wide linear range of response (25-600 μM) that covers the physiological levels of GLY in ISF. The MN biosensor conveniently exhibits high selectivity for GLY over other compounds commonly found in ISF, and the response is not influenced by temperature, pH, or skin insertions. Validated intradermal measurements of GLY were obtained at the in vitro (with pieces of rat skin), ex vivo (on-body tests of euthanized rats) and in vivo (on-body tests of anesthetized rats) levels, demonstrating its ability to produce accurate physiological data. The developed GLY MN biosensor is skin-wearable and provides reliable, real-time intradermal GLY measurements in ISF by means of a minimally invasive approach.
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| 5. |
- Xuan, Xing, et al.
(author)
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Fully Integrated Wearable Device for Continuous Sweat Lactate Monitoring in Sports.
- 2023
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In: ACS Sensors. - : American Chemical Society (ACS). - 2379-3694. ; 8:6, s. 2401-2409
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Journal article (peer-reviewed)abstract
- The chemical digitalization of sweat using wearable sensing interfaces is an attractive alternative to traditional blood-based protocols in sports. Although sweat lactate has been claimed to be a relevant biomarker in sports, an analytically validated wearable system to prove that has not yet been developed. We present a fully integrated sweat lactate sensing system applicable to in situ perspiration analysis. The device can be conveniently worn in the skin to monitor real-time sweat lactate during sports, such as cycling and kayaking. The novelty of the system is threefold: advanced microfluidics design for sweat collection and analysis, an analytically validated lactate biosensor based on a rational design of an outer diffusion-limiting membrane, and an integrated circuit for signal processing with a custom smartphone application. The sensor covering the range expected for lactate in sweat (1-20 mM), with appropriate sensitivity (-12.5 ± 0.53 nA mM-1), shows an acceptable response time (<90 s), and the influence of changes in pH, temperature, and flow rate are neglectable. Also, the sensor is analytically suitable with regard to reversibility, resilience, and reproducibility. The sensing device is validated through a relatively high number of on-body tests performed with elite athletes cycling and kayaking in controlled environments. Correlation outcomes between sweat lactate and other physiological indicators typically accessible in sports laboratories (blood lactate, perceived exhaustion, heart rate, blood glucose, respiratory quotient) are also presented and discussed in relation to the sport performance monitoring capability of continuous sweat lactate.
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