Publications by Maria Cuartero Botia
Peer reviewed
Articles
[1]
X. Xuan et al., "Demonstration of a Validated Direct Current Wearable Device for Monitoring Sweat Rate in Sports," Sensors, vol. 24, no. 22, 2024.
[2]
A. Molina Osorio, G. A. Crespo and M. Cuartero, "Evidence of transient potentials in ion-selective electrodes based on thin-layer ion-exchange membranes," Electrochimica Acta, vol. 484, 2024.
[3]
E. Kendir Cakmak et al., "How to develop a bio-based phosphorus mining strategy for eutrophic marine sediments: Unlocking native microbial processes for anaerobic phosphorus release," Chemosphere, vol. 358, 2024.
[4]
Q. Wang et al., "Intradermal Lactate Monitoring Based on a Microneedle Sensor Patch for Enhanced In Vivo Accuracy," ACS Sensors, vol. 9, no. 6, pp. 3115-3125, 2024.
[5]
A. Wiorek et al., "Reversible electrochemical pH modulation in thin-layer compartments using poly(aniline-co-o-aminophenol)," Sensors and actuators. B, Chemical, vol. 419, 2024.
[6]
Q. Wang et al., "Unveiling Potassium and Sodium Ion Dynamics in Living Plants with an In-Planta Potentiometric Microneedle Sensor," ACS Sensors, 2024.
[7]
F. Zhu et al., "Unveiling the impact of carbon sources on phosphorus release from sediment: Investigation of microbial interactions and metabolic pathways for anaerobic phosphorus recovery," Chemical Engineering Journal, vol. 500, 2024.
[8]
Y. Liu, G. A. Crespo and M. Cuartero, "Voltammetric Ion-Selective Electrodes in Thin-Layer Samples : Absolute Detection of Ions Using Ultrathin Membranes," Analytical Chemistry, vol. 96, no. 3, pp. 1147-1155, 2024.
[9]
X. Xuan et al., "A Wearable Biosensor for Sweat Lactate as a Proxy for Sport Performance Monitoring," Analysis & Sensing, vol. 3, no. 4, 2023.
[10]
M. Miras et al., "Analytical Tool for Quality Control of Irrigation Waters via a Potentiometric Electronic Tongue," Chemosensors, vol. 11, no. 7, 2023.
[11]
X. Xuan et al., "Fully Integrated Wearable Device for Continuous Sweat Lactate Monitoring in Sports," ACS Sensors, vol. 8, no. 6, pp. 2401-2409, 2023.
[12]
A. Wiorek et al., "Imaging of CO2 and Dissolved Inorganic Carbon via Electrochemical Acidification–Optode Tandem," ACS Sensors, vol. 8, no. 7, pp. 2843-2851, 2023.
[13]
A. Molinero Fernandez et al., "In Vivo Transdermal Multi-Ion Monitoring with a Potentiometric Microneedle-Based Sensor Patch," ACS Sensors, vol. 8, no. 1, pp. 158-166, 2023.
[14]
C. Chen et al., "Portable All-in-One Electrochemical Actuator-Sensor System for the Detection of Dissolved Inorganic Phosphorus in Seawater," Analytical Chemistry, vol. 95, no. 8, pp. 4180-4189, 2023.
[15]
A. Wiorek, M. Cuartero and G. A. Crespo, "Selective Deionization of Thin-Layer Samples Using Tandem Carbon Nanotubes-Polymeric Membranes," Analytical Chemistry, vol. 95, no. 42, pp. 15681-15689, 2023.
[16]
I. Robayo Molina, G. A. Crespo and M. Cuartero, "Usefulness of the Distribution of Relaxation Time Method in Electroanalytical Systems : The Case of Voltammetric Ion-Selective Electrodes," ACS Omega, 2023.
[17]
R. L. Gil, C. G. Amorim and M. Cuartero, "Addressing the Detection of Ammonium Ion in Environmental Water Samples via Tandem Potentiometry-Ion Chromatography," ACS Measurement Science Au, vol. 2, no. 3, pp. 199-207, 2022.
[18]
F. Steininger et al., "Imaging Sample Acidification Triggered by Electrochemically Activated Polyaniline," Analytical Chemistry, vol. 94, no. 40, pp. 13647-13651, 2022.
[19]
N. Colozza et al., "Insights into Tripodal Tris(pyrazolyl) Compounds as Ionophores for Potentiometric Ammonium Ion Sensing," ChemElectroChem, vol. 9, no. 18, 2022.
[20]
Q. Wang et al., "Intradermal Glycine Detection with a Wearable Microneedle Biosensor : The First In Vivo Assay," Analytical Chemistry, vol. 94, no. 34, pp. 11856-11864, 2022.
[21]
M. Cuartero et al., "Potentiometric Electronic Tongue for Quantitative Ion Analysis in Natural Mineral Waters," Sensors, vol. 22, no. 16, 2022.
[22]
A. Wiorek, M. Cuartero and G. A. Crespo, "Selective Ion Capturing via Carbon Nanotubes Charging," Analytical Chemistry, vol. 94, no. 21, pp. 7455-7459, 2022.
[23]
Y. Liu, G. A. Crespo and M. Cuartero, "Spectroelectrochemistry with Ultrathin lon-Selective Membranes : Three Distinct Ranges for Analytical Sensing," Analytical Chemistry, vol. 94, no. 25, pp. 9140-9148, 2022.
[24]
K. Xu et al., "Ultrathin ion-selective membranes for trace detection of lead, copper and silver ions," Electrochimica Acta, vol. 427, 2022.
[25]
K. Van Hoovels et al., "Can Wearable Sweat Lactate Sensors Contribute to Sports Physiology?," ACS Sensors, vol. 6, no. 10, pp. 3496-3508, 2021.
[26]
T. Fuoco et al., "Capturing the Real-Time Hydrolytic Degradation of a Library of Biomedical Polymers by Combining Traditional Assessment and Electrochemical Sensors," Biomacromolecules, vol. 22, no. 2, pp. 949-960, 2021.
[27]
Q. Wang et al., "Electrochemical biosensor for glycine detection in biological fluids," Biosensors & bioelectronics, vol. 182, 2021.
[28]
[29]
M. Cuartero, "Electrochemical sensors for in-situ measurement of ions in seawater," Sensors and actuators. B, Chemical, vol. 334, 2021.
[30]
X. Xuan et al., "Lactate Biosensing for Reliable On-Body Sweat Analysis," ACS Sensors, vol. 6, no. 7, pp. 2763-2771, 2021.
[31]
J. J. Garcia-Guzman et al., "Microneedle based electrochemical (Bio)Sensing : Towards decentralized and continuous health status monitoring," TrAC. Trends in analytical chemistry, vol. 135, 2021.
[32]
A. Molina Osorio et al., "Modelling electrochemical modulation of ion release in thin-layer samples," JOURNAL OF ELECTROANALYTICAL CHEMISTRY, vol. 903, pp. 115851, 2021.
[33]
M. Aref et al., "Potentiometric pH Nanosensor for Intracellular Measurements : Real-Time and Continuous Assessment of Local Gradients," Analytical Chemistry, vol. 93, no. 47, pp. 15744-15751, 2021.
[34]
A. Wiorek et al., "Reagentless Acid–Base Titration for Alkalinity Detection in Seawater," Analytical Chemistry, vol. 93, no. 42, pp. 14130-14137, 2021.
[35]
Y. Liu, G. A. Crespo and M. Cuartero, "Semi-empirical treatment of ionophore-assisted ion-transfers in ultrathin membranes coupled to a redox conducting polymer," Electrochimica Acta, vol. 388, pp. 138634, 2021.
[36]
J. J. Garcia-Guzman et al., "Toward In Vivo Transdermal pH Sensing with a Validated Microneedle Membrane Electrode," ACS Sensors, vol. 6, no. 3, pp. 1129-1137, 2021.
[37]
A. Casanova et al., "A sustainable amperometric biosensor for the analysis of ascorbic, benzoic, gallic and kojic acids through catechol detection. Innovation and signal processing," The Analyst, vol. 145, no. 10, pp. 3645-3655, 2020.
[38]
S. Sandin et al., "Deactivation and selectivity for electrochemical ozone production at Ni- and Sb-doped SnO2 / Ti electrodes," Electrochimica Acta, vol. 335, 2020.
[39]
A. Wiorek et al., "Epidermal Patch with Glucose Biosensor : pH and Temperature Correction toward More Accurate Sweat Analysis during Sport Practice," Analytical Chemistry, vol. 92, no. 14, pp. 10153-10161, 2020.
[40]
W. Ning et al., "Magnetizing lead-free halide double perovskites," Science Advances, vol. 6, no. 45, 2020.
[41]
Y. Guo et al., "Molybdenum and boron synergistically boosting efficient electrochemical nitrogen fixation," Nano Energy, vol. 78, 2020.
[42]
B. Endrodi et al., "Selective electrochemical hydrogen evolution on cerium oxide protected catalyst surfaces," Electrochimica Acta, vol. 341, 2020.
[43]
Y. Liu et al., "Spectroelectrochemical Evidence of Interconnected Charge and Ion Transfer in Ultrathin Membranes Modulated by a Redox Conducting Polymer," Analytical Chemistry, vol. 92, no. 20, pp. 14085-14093, 2020.
[44]
K. Xu, M. Cuartero and G. A. Crespo, "Subnanomolar detection of ions using thin voltammetric membranes with reduced Exchange capacity," Sensors and actuators. B, Chemical, vol. 321, 2020.
[45]
Y. Liu et al., "Thin-Layer Potentiometry for Creatinine Detection in Undiluted Human Urine Using Ion-Exchange Membranes as Barriers for Charged Interferences," Analytical Chemistry, vol. 92, no. 4, pp. 3315-3323, 2020.
[46]
C. Pérez Ràfols et al., "Why Not Glycine Electrochemical Biosensors?," Sensors, vol. 20, no. 14, 2020.
[47]
M. Cuartero et al., "Why ammonium detection is particularly challenging but insightful with ionophore-based potentiometric sensors - an overview of the progress in the last 20 years," The Analyst, vol. 145, no. 9, pp. 3188-3210, 2020.
[48]
R. Cánovas et al., "Cytotoxicity Study of Ionophore-Based Membranes : Toward On Body and in Vivo Ion Sensing," ACS Sensors, vol. 4, no. 9, pp. 2524-2535, 2019.
[49]
Q. Meng et al., "Efficient BiVO4 Photoanodes by Postsynthetic Treatment : Remarkable Improvements in Photoelectrochemical Performance from Facile Borate Modification," Angewandte Chemie International Edition, vol. 58, no. 52, pp. 19027-19033, 2019.
[50]
M. Cuartero et al., "Ferrocene self assembled monolayer as a redox mediator for triggering ion transfer across nanometer-sized membranes," Electrochimica Acta, vol. 315, pp. 84-93, 2019.
[51]
K. Xu, M. Cuartero and G. A. Crespo, "Lowering the limit of detection of ion-selective membranes backside contacted with a film of poly(3-octylthiophene)," Sensors and actuators. B, Chemical, vol. 297, 2019.
[52]
R. Cánovas, M. Cuartero and G. A. Crespo, "Modern creatinine (Bio)sensing : Challenges of point-of-care platforms," Biosensors & bioelectronics, vol. 130, pp. 110-124, 2019.
[53]
A. Wiorek et al., "Polyaniline Films as Electrochemical-Proton Pump for Acidification of Thin Layer Samples," Analytical Chemistry, vol. 91, no. 23, pp. 14951-14959, 2019.
[54]
B. Endrodi et al., "Selective Hydrogen Evolution on Manganese Oxide Coated Electrodes : New Cathodes for Sodium Chlorate Production," ACS Sustainable Chemistry and Engineering, vol. 7, no. 14, pp. 12170-12178, 2019.
[55]
M. Parrilla et al., "Wearable All-Solid-State Potentiometric Microneedle Patch for Intradermal Potassium Detection," Analytical Chemistry, vol. 91, no. 2, pp. 1578-1586, 2019.
[56]
M. Parrilla et al., "Wearable Potentiometric Ion Patch for On-Body Electrolyte Monitoring in Sweat : Toward a Validation Strategy to Ensure Physiological Relevance," Analytical Chemistry, vol. 91, no. 13, pp. 8644-8651, 2019.
[57]
M. Cuartero, M. Parrilla and G. A. Crespo, "Wearable Potentiometric Sensors for Medical Applications," Sensors, vol. 19, no. 2, 2019.
[58]
M. Parrilla, M. Cuartero and G. A. Crespo, "Wearable potentiometric ion sensors," TrAC. Trends in analytical chemistry, vol. 110, pp. 303-320, 2019.
[59]
M. Cuartero and G. A. Crespo, "All-solid-state potentiometric sensors : A new wave for in situ aquatic research," Current Opinion in Electrochemistry, vol. 10, pp. 98-106, 2018.
[60]
S. Jansod et al., "Colorimetric Readout for Potentiometric Sensors with Closed Bipolar Electrodes," Analytical Chemistry, vol. 90, no. 11, pp. 6376-6379, 2018.
[61]
M. Cuartero et al., "In Situ Detection of Macronutrients and Chloride in Seawater by Submersible Electrochemical Sensors," Analytical Chemistry, vol. 90, no. 7, pp. 4702-4710, 2018.
[62]
S. Sateanchok et al., "In-Line Seawater Phosphate Detection with Ion-Exchange Membrane Reagent Delivery," ACS Sensors, vol. 3, no. 11, pp. 2455-2462, 2018.
[63]
M. Cuartero and G. A. Crespo, "Using Potentiometric Electrodes Based on Nonselective Polymeric Membranes as Potential Universal Detectors for Ion Chromatography : Investigating an Original Research Problem from an Inquiry-Based-Learning Perspective," Journal of Chemical Education, vol. 95, no. 12, pp. 2172-2181, 2018.
Non-peer reviewed
Articles
[64]
X. Xuan et al., "A Wearable Biosensor for Sweat Lactate as a Proxy for Sport Performance Monitoring," Analysis & Sensing, vol. 3, no. 4, 2023.
Other
[65]
[66]
A. Wiorek, M. Cuartero and G. A. Crespo, "Selective Deionization of Thin-Layer Samples using the Tandem Carbon Nanotubes – Polymeric Membranes," (Manuscript).
[67]
Y. Liu, G. A. Crespo and M. Cuartero, "Voltammetric Ion-Selective Electrodes in Thin-Layer Samples : The Case for Absolute Potassium Detection Using Ultrathin Membranes," (Manuscript).
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2024-12-05 01:06:12