Calibration of Etched Fiber Bragg Grating Sensor Arrays for Measurement of Molecular Surface Adsorption

Mudachathi, Renilkumar; Shivananju, Bannur Nanjunda; Prashanth, Gurusiddappa R.; Asokan, S.; Varma, Manoj M.

doi:10.1109/jlt.2013.2266658

Cited by 12 publications

(7 citation statements)

References 40 publications

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“…[ 161–163 ] FBGs are modified by chemically etching the clad region using hydrofluoric(HF) acid for highly sensitive monitoring of the LbL adsorption process. [ 164,165 ] By functionalizing the etched‐FBG with (PAH/PAA), pH induced environment was studied to find out the charge dependence of the weak polyelectrolytes. [ 166 ] These findings show good correlation with earlier reports by Rubner et al [ 167,168 ]…”

Section: Techniques To Probe Transportmentioning

confidence: 99%

Simplifying Molecular Transport in Polyelectrolyte Multilayer Thin Films

Pahal

Boranna

Prashanth

et al. 2021

Macro Chemistry & Physics

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The matrix properties of polyelectrolyte multilayer thin films (PEM) are critical in making them a viable candidate for various biomedical applications. The location and ability of molecules to diffuse through the PEM architecture determines their encapsulation and release capabilities in a given matrix for various biomedical applications. The main aim of this review article is to provide a complete understanding of molecular transport on the surface as well as across the bulk of the PEM matrix. Different physiochemical strategies to promote or suppress the diffusivity of various molecules inside the PEM are mentioned in brief. A set of guiding principles is uncovered for getting a complete picture of loading and release of molecules across the PEM structure, which can play a key role in designing a desirable PEM assembly and have important implications for designing multicomponent, targeted and controlled drug‐delivery vehicles. Understanding the molecular diffusivity in PEM stack at the nano and micro scales will help to design superior host materials for biomedical engineering applications.

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Section: Techniques To Probe Transportmentioning

confidence: 99%

Simplifying Molecular Transport in Polyelectrolyte Multilayer Thin Films

Pahal

Boranna

Prashanth

et al. 2021

Macro Chemistry & Physics

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“…A Fiber Bragg Grating (FBG) sensor was fabricated using the phase mask technique on single-mode fiber (SM1500). [46][47][48][49] Chemical etching was performed using Hydrogen Fluoride (HF) (40% concentration) to fabricate the EFBG sensors. [44] The calibration details of the EFBG sensor have been discussed in the previous work.…”

Section: Instrumentsmentioning

confidence: 99%

Fast‐Dip Layer‐by‐Layer Self‐Assembly of Polyelectrolytes as a Low‐Cost Biosensing Platform

Boranna

Vishwaraj

Pahal

et al. 2022

Macro Chemistry & Physics

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Polyelectrolyte multilayer (PEM) films fabricated using Layer-by-Layer (LbL) self-assembly are most versatile for numerous surface tailoring applications. Physicochemical customization of PEM at a nanometer scale is possible by choice of incorporated materials, assembly parameters, and assembly techniques. Conventional dip (CDip) (10-15 min dip time) coating dominates the PEM fabrication due to its simple, geometry-independent, and economical coating capabilities. Deposition of the PEM in CDip-LbL happens in two phases, that is, the initial adsorption phase followed by rearrangement of the complementary polyelectrolyte chains. By shortening the prolonged rearrangement phase, thicker stratified PEM films can form with a reduced dipping time (1 min), called Fast Dip (FDip). This reduction in the dipping time is studied in situ using Etched Fiber Bragg Grating-based sensors. To define the practical utility of the FDip deposited PEM, bio-molecular loading studies are performed using biotin and Bovine Serum Albumin (BSA). FDip-LbL is as effective as CDip-LbL self-assembly and also better than spin-LbL. Thus, the FDip deposition prompts a scalable LbL self-assembly process for quick fabrication of the biosensing platforms.

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“…Graphene‐based optical sensors can be theoretically studied by numerical models and simulations such as the finite element method (COMSOL), the finite‐difference time‐domain (FDTD) method, and spectral element method (SEM) . These models can be efficiently used for the numerical analysis of graphene optical sensors with excellent accuracy and efficiency.…”

Section: Numerical Model and Simulation Of Graphene Optical Sensorsmentioning

confidence: 99%

“…The most important advantages in optical sensing are lowering the limit of detection (LOD) and increasing the specificity of label‐free sensing . Accordingly, optical sensors have been explored for various sensing applications in recent decades, such as chemicals, bio‐sensing, pH, humidity, gas, light, temperature and more, using various nanomaterials . The most striking features of graphene‐based optical biochemical sensors are ultra‐high sensitivity and ultrafast speed, thereby posing great potential to replace some of the current electrical and optical sensors used for biochemical sensing applications.…”

Section: Introductionmentioning

confidence: 99%

The Roadmap of Graphene‐Based Optical Biochemical Sensors

Shivananju

Liu

et al. 2016

Adv Funct Materials

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Graphene is a novel two‐dimensional material composed of a one‐atom‐thick planar sheet of sp2‐bonded carbon atoms perfectly arranged in a honeycomb lattice that has exceptional photonic and electronic properties. We believe that the true potential of graphene lies in optical sensors, especially for biochemical sensing in the diagnostics and health care sector. Graphene has extraordinary properties, such as a one‐atom thickness, extremely high surface‐to‐volume ratio, large surface area, ability to quench fluorescence, excellent biocompatibility, broadband light absorption, ultrafast response time, high mechanical strength, outstanding robustness, and flexibility. The working principle is based on whenever the biomolecules come into contact with graphene, the Fermi level shifts to either p‐type or n‐type, changing the opto‐electronic properties. The most important factors in graphene‐based optical sensing are lowering the limit of detection and increasing the specificity of label‐free biochemical sensing. This article comprehensively and critically reviews emerging graphene optical biochemical sensors. We first elaborate on their opto‐electronic properties, fabrication, numerical modeling and simulation, and then review various sensing applications, such as single‐cell detection, neural imaging and optogenetics, colorimetric multifunctional sensors, cancer diagnosis, protein and DNA sensing, and gas sensing. Finally, the roadmap of current and future trends in graphene‐based optical biochemical sensors is discussed.

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Calibration of Etched Fiber Bragg Grating Sensor Arrays for Measurement of Molecular Surface Adsorption

Cited by 12 publications

References 40 publications

Simplifying Molecular Transport in Polyelectrolyte Multilayer Thin Films

Simplifying Molecular Transport in Polyelectrolyte Multilayer Thin Films

Fast‐Dip Layer‐by‐Layer Self‐Assembly of Polyelectrolytes as a Low‐Cost Biosensing Platform

The Roadmap of Graphene‐Based Optical Biochemical Sensors

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