Your search keyword '"Jeremy Bonhomme"' showing total 4 results

1. Development of a Love-Wave Biosensor Based on an Analytical Model

Author

Frédéric Sarry, Jeremy Bonhomme, Mourad Oudich, Pedro Alberto Segura Chavez, Denis Beyssen, Omar Elmazria, Mohd Khairuddin Md Arshad, and Paul G. Charette

Subjects

Love wave, biosensor, viscosity, analytical model, acoustic ratio, ZnO, Biochemistry, QD415-436

Abstract

The present work deals with the development of a Love-wave biosensor for the diagnosis of the modification of cell viscosity. The relevant device performance such as insertion loss, attenuation, phase velocity, and sensitivity needs to be analysed as a function of the device structure and also regarding the effect of the liquid loading. In this study, we used an analytical model based on the equation of motions for a Love wave propagating in a three-layer structure. We show that the effect of the viscous coupling leads to insertion losses and a phase shift that impact the acoustic ratio. A comparison between experimental and theoretical results showed a good agreement between the behaviours as it was observed for the phase shift vs. the insertion loss with a limited difference in values (3.11/3.09—experimental/simulation for the sensitivity to the viscosity for different insertion losses) due to the assumptions made on the model used.

Published

2022

2. Nano-particle mass sensing using phononic pillars

Author

Jeremy, Bonhomme, primary, Mourad, Oudich, additional, Bahram, Djafari-Rouhani, additional, Frederic, Sarry, additional, Yann, Pennec, additional, Bernard, Bonello, additional, Denis, Beyssen, additional, and Charette, Paul G., additional

Published

2019

3. Phononic Crystal Made of Silicon Ridges on a Membrane for Liquid Sensing

Author

Abdellatif Gueddida, Victor Zhang, Laurent Carpentier, Jérémy Bonhomme, Bernard Bonello, Yan Pennec, and Bahram Djafari-Rouhani

Subjects

acoustic sensor, phononic crystal, defect mode, liquid viscosity, transmission curve, dispersion curve, Chemical technology, TP1-1185

Abstract

We propose the design of a phononic crystal to sense the acoustic properties of a liquid that is constituted by an array of silicon ridges on a membrane. In contrast to other concepts, the ridges are immersed in the liquid. The introduction of a suitable cavity in the periodic array gives rise to a confined defect mode with high localization in the cavity region and strong solid–liquid interaction, which make it sensitive to the acoustic properties of the liquid. By using a finite element method simulation, we theoretically study the transmission and cavity excitation of an incident flexural wave of the membrane. The observation of the vibrations of this mode can be achieved either outside the area of the phononic crystal or just above the cavity. We discuss the existence of the resonant modes, as well as its quality factor and sensitivity to liquid properties as a function of the geometrical parameters. The performance of the proposed sensor has then been tested to detect the variation in NaI concentration in a NaI–water mixture.

Published

2023

4. Love Wave Sensor with High Penetration Depth for Potential Application in Cell Monitoring

Author

Pedro A. Segura Chávez, Jérémy Bonhomme, Mohamed Lamine Fayçal Bellaredj, Lucile Olive, Denis Beyssen, Mourad Oudich, Paul G. Charette, and Frédéric Sarry

Subjects

love wave, viscosity, L-SAW, mechanical properties, cell monolayers, transmission line model (TLM), Biotechnology, TP248.13-248.65

Abstract

Love wave (L-SAW) sensors have been used to probe cell monolayers, but their application to detect changes beyond the focal adhesion points on cell monolayers, as viscosity changes on the cytoskeleton, has not been explored. In this work we present for the first time a Love wave sensor with tuned penetration depth and sensitivity to potentially detect mechanical changes beyond focal adhesion points of cell monolayers. We designed and fabricated a Love wave sensor operating at 30 MHz with sensitivity to detect viscous changes between 0.89 and 3.3 cP. The Love wave sensor was modeled using an acoustic transmission line model, whereas the response of interdigital transducers (IDTs) was modeled with the Campbell’s cross-field circuit model. Our design uses a substrate with a high electromechanical coupling coefficient (LiNbO3 36Y-X), and an 8-µm polymeric guiding layer (SU-8). The design aims to overcome the high insertion losses of viscous liquid environments, and the loss of sensitivity due to the low frequency. The fabricated sensor was tested in a fluidic chamber glued directly to the SU-8 guiding layer. Our experiments with liquids of viscosity similar to those expected in cell monolayers showed a measurable sensor response. In addition, experimentation with SaOs-2 cells within a culture medium showed measurable responses. These results can be of interest for the development of novel cell-based biosensors, and novel characterization tools for cell monolayers.

Published

2022