Browsing by Author "Cetin, A.E."

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Citation - WoS: 2
Citation - Scopus: 2
Handheld Optofluidic Platform Towards Binding Dynamics Applications in Field-Settings
(Elsevier B.V., 2023) Yaman, S.; Avci, M.B.; Kurul, F; Topkaya, S.N.; Cetin, A.E.
We have introduced a lensfree optofluidic platform that incorporates subwavelength nanohole arrays, a compact microfluidics system, and on-chip computational imaging to enable label-free identification of biomolecular interactions. Our platform weighs only 260 g and has dimensions of 16 cm × 10 cm × 11 cm. It utilizes a CMOS imager to capture plasmonic diffraction field images, offering a wide field-of-view of up to 11.5 mm² for refractive index sensing. To illuminate the plasmonic chip, we employ an LED source positioned close to the transmission resonance of the nanohole arrays. This LED source creates diffraction patterns on the imager. The platform ensures the targeted delivery of analytes to the ligand-coated sensing surface using microfluidics. By analyzing real-time variations within the diffraction field images, we could reveal the time-dependent binding dynamics of biomolecules. Our platform has demonstrated an experimentally obtained limit of detection (LOD) as low as 5 ng/mL for protein IgG. Furthermore, based on the real-time diffraction field images, we successfully determine the association and disassociation constants, which account for the binding and detachment between protein A/G and IgG. We have also developed a software that allows full control of the hardware settings of the portable platform, including the camera and pump system. This software also incorporates an image-processing algorithm to calculate the binding parameters for the analytes of interest. Providing high-quality sensing capabilities in a cost-effective infrastructure, we believe that our optofluidic biosensor platform offers significant advantages for surface plasmon resonance (SPR) applications for field-settings. © 2023 Elsevier B.V.
Portable Optofluidic Device for Dynamic Binding Analysis in Field-Settings
(SPIE, 2024) Kurul, F.; Avci, M.B.; Yaman, S.; Topkaya, S.N.; Cetin, A.E.
Compact and portable biosensing technologies play an important role in replacing traditional counterparts that require costly and heavy equipment, as well as complex infrastructure. The integration of these easy-to-use and cheap devices allows for the conducting of biosensing analyses in resource-limited settings. The study produced a portable optofluidic platform that is lightweight (260 g) and compact (16 cm×10 cm×11 cm). It combines subwavelength nanohole arrays, microfluidics technology, and on-chip computational imaging. It records plasmonic diffraction field images with a CMOS imager and an LED light, allowing for a large field of view for refractive index measurement. This LED source generates diffraction patterns on the imager. The microfluidic pump confirms accurate analyte delivery, allowing real-time analysis of diffraction field images to reveal time-dependent binding kinetics of biomolecules. It identifies biomolecular interactions without labelling, allowing for the detection and quantification of biomolecules. Our platform has an outstanding limit-of-detection (LOD) of 5ng/mL for label-free detection of protein IgG. We effectively determined the association and dissociation constants for protein A/G and IgG binding using real-time diffraction field images. The optofluidic biosensor platform is ideal for surface plasmon resonance (SPR) in field applications. It can monitor interactions in real-time, making it useful for studying the way various biological and chemical compounds bind in many areas. © 2024 SPIE.