Sub-micrometric reflectometry for localized label-free biosensing

Casquel, Rafael; Soler, Juan Antonio Lloret; Holgado, Miguel; López, Antonio Aznar; Lavín, Álvaro; Vicente, José Miguel Gómez de; Sanza, Francisco J.; Heras, María Fe Laguna; Bañuls, María‐José; Puchades, Rosa

doi:10.1364/oe.23.012544

Cited by 6 publications

(7 citation statements)

References 13 publications

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“…The optical tool used for analysis is based on a combination of two previously developed optical techniques, Beam Profile Reflectometry and Beam Profile Ellipsometry, used for the characterization of thin films in the semiconductor industry. The tool was adapted to characterize sub‐micrometric areas for localized label‐free biosensing, but the same principle can be used for determining the evolution of the refractive index of the wedge thin films prepared in the present work.…”

Section: Methodsmentioning

confidence: 99%

“…Subsequently, we present a morphological characterization of the deposited wedged‐shaped films, both at micro and nanoscales, and a micrometer‐resolved study of their optical properties. For this purpose we utilize a recently developed sub‐micrometric optical tool that, based on the principles of beam profile reflectometry and ellipsometry, utilizes a highly focalized laser to measure light reflectometry as a function of angle of incidence and polarization over small areas with a spot diameter smaller than 1 μm . Thanks to this specific instrument, micron size resolved refractive index and birefringence values have been obtained along the wedge zone.…”

Section: Introductionmentioning

confidence: 99%

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Micron‐scale wedge thin films prepared by plasma enhanced chemical vapor deposition

López-Santos

Álvarez

Palmero

et al. 2017

Plasma Processes & Polymers

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Wedge‐shaped materials are currently employed for optical analyses and sensing applications. In this paper, we present an easy to implement plasma enhanced chemical vapor deposition procedure to grow wedge‐shaped thin films with controlled slope at the scale of few hundred microns. The method relies on the use of few tenths micron height obstacles to alter the laminar flow of precursor gas during deposition and is applied for the fabrication of wedge‐shaped ZnO thin films. Local interference patterns, refractive index, and birefringence of the films have been measured with one micron resolution using a specially designed optical set‐up. Their micro‐ and nano‐structures have been characterized by means of scanning electron microscopy and theoretically reproduced by Monte Carlo calculations.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Micron‐scale wedge thin films prepared by plasma enhanced chemical vapor deposition

López-Santos

Álvarez

Palmero

et al. 2017

Plasma Processes & Polymers

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“…By adapting these techniques, we can reach even a lower spot size with a microscope objective of × 150, these are the so-called reflectometry and ellipsometry at profile level (RPL and EPL). These techniques allow characterizing the sensing surface with a sub-micrometric spot [55]. The system uses a laser source emitting at 637 nm with a high numerical aperture microscope objective (× 0.95).…”

Section: Optical Techniquesmentioning

confidence: 99%

“…The possibility of using a sub-micrometric spot allows localized label-free biosensing in small areas, such as submicrometric holes [20] or pillars. We used these techniques for biorecognizing anti-BSA over circular area of SU-8 over silicon functionalized with BSA with a limit of detection comparable with high resolution spectrometry [55]. The characterization of such small sensing areas can be interesting for increasing the integration of the sensing cell, or to measure variations of biofunctionalization or recognition on smaller areas.…”

Section: Optical Techniquesmentioning

confidence: 99%

Engineering vertically interrogated interferometric sensors for optical label-free biosensing

et al. 2020

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In this work, we review the technology of vertically interrogated optical biosensors from the point of view of engineering. Vertical sensors present several advantages in the fabrication processes and in the light coupling systems, compared with other interferometric sensors. Four different interrelated aspects of the design are identified and described: sensing cell design, optical techniques used in the interrogation, fabrication processes, fluidics, and biofunctionalization of the sensing surface. The designer of a vertical sensor should decide carefully which solution to adopt on each aspect to finally integrating all the components in a single platform. Complexity, cost, and reliability of this platform will be determined by the decisions taken on each of the design process. We focus in the research and experience acquired by our group during last years on the field of optical biosensors.

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“…Although this method only reveals differences in liquids with different RI, the availability of procedures relying on a microfluidic approach (i.e., handling minute amounts of liquid) may be of interest for certain niche applications (e.g., to monitor solute concentration in solutions or mixture of liquids) where the scarcity of samples is a bottleneck for a conventional RI detection [1]. Optofluidic RI sensors based on plasmonics [2][3][4][5][6], photonic crystals [7][8][9][10][11] or photonic crystals fibers [12] are primarily composed of periodic metallic or dielectric structures that can be used to confine and guide light. However, even if these sensing techniques enable detection of liquids with extremely small volumes, in practice, the rudimentary character of the currently available liquid delivery systems makes that still relatively large liquid volumes are required for detection.…”

Section: Introductionmentioning

confidence: 99%

Optofluidic liquid sensing on electromicrofluidic devices

Oliva-Ramirez

Wang

Rico

et al. 2020

Mater. Res. Express

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Electromicrofluidic (EMF) devices are used to handle and move tiny amounts of liquids by electrical actuation, including electrowetting-on-dielectric (EWOD) and dielectrophoresis (DEP). Monitoring the liquid characteristics in one of these devices requires suitable sensing transducers incorporated within the microfluidic structure. In the present work, we describe the incorporation of an optofluidic photonic transducer in an EMF device to monitor the refractive index of a liquid during its manipulation. The incorporated transducer consists of a responsive porous Bragg Microcavity (BM) deposited via physical vapor oblique angle deposition. Besides reporting the manufacturing procedure of the sensing-EMF device combining liquid handling and monitoring, the performance of the BM is verified by infiltrating several liquids dripped on its surface and comparing the responses with those of liquid droplets electrically moved from the delivery part of the chip to the BM location. This study proved that modified EMF devices can incorporate photonic structures to analyze very low liquid volumes (∼0.2 μL) during its handling.

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Sub-micrometric reflectometry for localized label-free biosensing

Cited by 6 publications

References 13 publications

Micron‐scale wedge thin films prepared by plasma enhanced chemical vapor deposition

Micron‐scale wedge thin films prepared by plasma enhanced chemical vapor deposition

Engineering vertically interrogated interferometric sensors for optical label-free biosensing

Optofluidic liquid sensing on electromicrofluidic devices

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