Design and optimization of a hybrid graphene-metallic metasurfaces terahertz biosensor for high-precision detection of reproductive hormones, integrating locally weighted linear regression analysis and 2-bit encoding capabilities

Jacob Wekalao (), Hussein A. Elsayed, Ahmed M. El-Sherbeeny, Mostafa R. Abukhadra and Ahmed Mehaney
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Jacob Wekalao: University of Science and Technology of China
Hussein A. Elsayed: Beni-Suef University
Ahmed M. El-Sherbeeny: King Saud University
Mostafa R. Abukhadra: Beni-Suef University
Ahmed Mehaney: Beni-Suef University

The European Physical Journal B: Condensed Matter and Complex Systems, 2025, vol. 98, issue 5, 1-22

Abstract: Abstract The detection and monitoring of reproductive hormones play a crucial role in understanding reproductive health, fertility treatments, and endocrine disorders. Traditional hormone detection methods, such as immunoassays and chromatography, while accurate, often require complex sample preparation, specialized laboratory settings, and considerable time for analysis. This has created a pressing need for rapid, sensitive, and cost-effective detection methods that can be implemented in point-of-care settings. Meanwhile, we have introduced in the present communication a novel terahertz (THz) biosensor design that integrates graphene, copper, and silver in engineered metasurfaces resonators for high-precision reproductive hormone detection. The proposed structure leverages graphene's tunable properties alongside plasmonic enhancement from copper and silver, achieving a remarkable sensitivity of 1000 GHz/RIU in the 1.335–1.343 refractive index range. Moreover, the sensor demonstrates excellent performance metrics, including a quality factor of 11.315 and a figure of merit of 5.618 RIU–1. In addition, the sensor's capabilities were validated through electromagnetic simulations and locally weighted linear regression analysis, achieving a perfect prediction accuracy with an R2 value of 100% across multiple parametric variations. Furthermore, the design functions as a 2-bit encoder, producing distinct transmittance patterns for different binary states. Finally, the sensor's remarkable performance, combined with its practical fabrication feasibility using conventional techniques, presents a promising solution for point-of-care reproductive hormone detection and monitoring. Graphical abstract

Date: 2025
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DOI: 10.1140/epjb/s10051-025-00933-2

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