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Analysis of institutional authors

Arranz A.AuthorRibagorda M.AuthorManso-Silván M.Author

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February 28, 2025
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Integrating voltammetry and substrate-enhanced luminescence for noninvasive glucose sensing

Publicated to:Biosensors and Bioelectronics: X. 23 - 2025-05-01 23(), DOI: 10.1016/j.biosx.2025.100591

Authors: López-Peña G; Pallarés Vilar A; Jaafar A; Simón-Fuente S; Arranz A; Ribagorda M; Manso-Silván M; Martín Rodríguez E

Affiliations

Universidad Autónoma de Madrid - Author
Universidad Autónoma de Madrid; Instituto Universitario de Ciencia de Materiales Nicolás Cabrera; Centro de Microanálisis de Materiales - Author
Universidad Autónoma de Madrid; Instituto Universitario de Ciencia de Materiales Nicolás Cabrera; Universidad Autónoma de Madrid; Instituto Ramón y Cajal de Investigación Sanitaria - Author
Universidad Autónoma de Madrid; Universidad Autónoma de Madrid - Author
Universidad Autónoma de Madrid; Universidad Complutense de Madrid - Author
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Abstract

This study presents a novel noninvasive and enzyme-free dual sensor based on porous silicon (PSi) for the detection of D-glucose through tear fluid analysis. The sensor incorporates NaGdF4:20% Yb3+, 2% Er3+ nanoparticles (YbEr-NPs) immobilized on a PSi substrate functionalized with a phenylboronic ester molecule. The YbEr-NPs enable luminescence-based sensing, exploiting the sensitivity of Er3+ ions to the OH vibrational groups present in D-glucose. Electrodes fabricated on a PSi substrate allow for voltammetric analysis, providing a second detection method. The voltammetric sensor achieved a limit of detection (LoD) of 20 mg/dL in the range of 20–200 mg/dL, which is suitable for detecting D-glucose concentrations in the tear fluid of diabetic patients. The luminescence-based sensor, utilizing the red-to-green emission ratio of YbEr-NPs, reached a LoD of 140 mg/dL in the range of 10–70 mg/dL, covering the hyperglycemic range. The interaction between the YbEr-NPs and the PSi substrate led to the appearance of new emission bands and increased intensity, attributed to surface defects acting as an additional excitation source. The 556 nm emission band showed a strong dependence on the D-glucose concentration, improving the LoD to 110 mg/dL. This provides a novel strategy for D-glucose detection based on the effect of the molecule on the interaction between the Rare-earth-doped nanoparticles and the PSi substrate. This triple-sensing approach offers a promising solution for noninvasive glucose monitoring, enabling detection in both the hypoglycemic and hyperglycemic ranges.

Keywords

GlucoseLuminescenceNanoparticlesRare earthsSensorSiliconVoltammetry

Quality index

Bibliometric impact. Analysis of the contribution and dissemination channel

The work has been published in the journal Biosensors and Bioelectronics: X due to its progression and the good impact it has achieved in recent years, according to the agency Scopus (SJR), it has become a reference in its field. In the year of publication of the work, 2025, it was in position , thus managing to position itself as a Q2 (Segundo Cuartil), in the category Biophysics.

Impact and social visibility

It is essential to present evidence supporting full alignment with institutional principles and guidelines on Open Science and the Conservation and Dissemination of Intellectual Heritage. A clear example of this is:

  • The work has been submitted to a journal whose editorial policy allows open Open Access publication.

Leadership analysis of institutional authors

There is a significant leadership presence as some of the institution’s authors appear as the first or last signer, detailed as follows: First Author (López-Peña G.) and Last Author (Martín Rodríguez E.).