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Design and Optimization of SiON Ring Resonator-Based Biosensors for Aflatoxin M1 Detection.

Guider R, Gandolfi D, Chalyan T, Pasquardini L, Samusenko A, Pucker G, Pederzolli C, Pavesi L - Sensors (Basel) (2015)

Bottom Line: Sensitivities and limit of detection (LOD) were also measured using glucose-water solutions and compared with expected results from simulations.We were able to detect the binding of aflatoxin for concentrations as low as 12.5 nm.The results open up the path for designing cost-effective biosensors for a fast and reliable sensitive analysis of AFM1 in milk.

View Article: PubMed Central - PubMed

Affiliation: Nanoscience Laboratory, Department of Physics, University of Trento, Via Sommarive 14, Povo (TN) 38123, Italy. romain.guider@unitn.it.

ABSTRACT
In this article, we designed and studied silicon oxynitride (SiON) microring-based photonic structures for biosensing applications. We designed waveguides, directional couplers, and racetrack resonators in order to measure refractive index changes smaller than 10-6 refractive index units (RIU). We tested various samples with different SiON refractive indexes as well as the waveguide dimensions for selecting the sensor with the best performance. Propagation losses and bending losses have been measured on test structures, along with a complete characterization of the resonator's performances. Sensitivities and limit of detection (LOD) were also measured using glucose-water solutions and compared with expected results from simulations. Finally, we functionalized the resonator and performed sensing experiments with Aflatoxin M1 (AFM1). We were able to detect the binding of aflatoxin for concentrations as low as 12.5 nm. The results open up the path for designing cost-effective biosensors for a fast and reliable sensitive analysis of AFM1 in milk.

No MeSH data available.


(Left) Extinction ratio analysis for the L2 sample; (Right) Quality factor analysis for the L2 sample.
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sensors-15-17300-f006: (Left) Extinction ratio analysis for the L2 sample; (Right) Quality factor analysis for the L2 sample.

Mentions: According to our simulations, we analyzed the quality factor of the ring resonators for both L2 and L5 wafers for the waveguide width of 1000 nm. We measured resonators covered with an oxide cladding and with different coupling lengths in order to find the critical coupling regime and thus the intrinsic quality factor of the resonator. Results are presented in Figure 6 for the L2 wafer and in Figure 7 for the L5 wafer.


Design and Optimization of SiON Ring Resonator-Based Biosensors for Aflatoxin M1 Detection.

Guider R, Gandolfi D, Chalyan T, Pasquardini L, Samusenko A, Pucker G, Pederzolli C, Pavesi L - Sensors (Basel) (2015)

(Left) Extinction ratio analysis for the L2 sample; (Right) Quality factor analysis for the L2 sample.
© Copyright Policy
Related In: Results  -  Collection

License
Show All Figures
getmorefigures.php?uid=PMC4541935&req=5

sensors-15-17300-f006: (Left) Extinction ratio analysis for the L2 sample; (Right) Quality factor analysis for the L2 sample.
Mentions: According to our simulations, we analyzed the quality factor of the ring resonators for both L2 and L5 wafers for the waveguide width of 1000 nm. We measured resonators covered with an oxide cladding and with different coupling lengths in order to find the critical coupling regime and thus the intrinsic quality factor of the resonator. Results are presented in Figure 6 for the L2 wafer and in Figure 7 for the L5 wafer.

Bottom Line: Sensitivities and limit of detection (LOD) were also measured using glucose-water solutions and compared with expected results from simulations.We were able to detect the binding of aflatoxin for concentrations as low as 12.5 nm.The results open up the path for designing cost-effective biosensors for a fast and reliable sensitive analysis of AFM1 in milk.

View Article: PubMed Central - PubMed

Affiliation: Nanoscience Laboratory, Department of Physics, University of Trento, Via Sommarive 14, Povo (TN) 38123, Italy. romain.guider@unitn.it.

ABSTRACT
In this article, we designed and studied silicon oxynitride (SiON) microring-based photonic structures for biosensing applications. We designed waveguides, directional couplers, and racetrack resonators in order to measure refractive index changes smaller than 10-6 refractive index units (RIU). We tested various samples with different SiON refractive indexes as well as the waveguide dimensions for selecting the sensor with the best performance. Propagation losses and bending losses have been measured on test structures, along with a complete characterization of the resonator's performances. Sensitivities and limit of detection (LOD) were also measured using glucose-water solutions and compared with expected results from simulations. Finally, we functionalized the resonator and performed sensing experiments with Aflatoxin M1 (AFM1). We were able to detect the binding of aflatoxin for concentrations as low as 12.5 nm. The results open up the path for designing cost-effective biosensors for a fast and reliable sensitive analysis of AFM1 in milk.

No MeSH data available.