Hybrid cavity-coupled plasmonic biosensors for low concentration, label-free and selective biomolecular detection

Vázquez‐Guardado, Abraham; Smith, A. Ezekiel; Wilson, Wade; Ortega, Jeanette; Perez, J. Manuel; Chanda, Debashis

doi:10.1364/oe.24.025785

Cited by 14 publications

(10 citation statements)

References 48 publications

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“…While the total concentration of IgG found in the adult plasma is about 7 mg/mL, IgG antibodies generated from different infections have significantly lower concentrations at the onset and exhibit unique chemical signatures . This underscores the need for an infection specific detection of IgG at low concentrations with high sensitivity. − Conventionally, antibody detection is done using the techniques like polymerase chain reaction (PCR), enzyme-linked immunosorbent assay (ELISA), or Western blot that are reliable, however, they are time-consuming processes, prone to contamination, and require high volumes of samples for definitive evaluation. − Alternatively, optical techniques for detection of biomolecules offer the benefits of faster sensing and can be done using a fraction of the sample quantity. − With label-free detection, the concerns of affecting antibody binding affinities and introducing undesired interactions or modifications is eliminated. This removes the restrictions that tag labels such as dyes give, where it can only see the binding at the very end or can potentially modify the sample outside of its’ natural state.…”

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confidence: 99%

Magnetoplasmons for Ultrasensitive Label-Free Biosensing

et al. 2021

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Early detection of immunoglobin G (IgG), a glycoprotein antibody produced in the serum due to various infections, is of paramount importance that will enable effective treatment, immunity assessment, and assist in monitoring outbreaks of contagious diseases. This work demonstrates the transverse magneto-optic Kerr effect (T-MOKE) based magnetoplasmons excited on a composite ferromagnetic/plasmonic grating as a highly sensitive, single wavelength, and target specific biosensing platform. The sharp T-MOKE sensitivity curve corresponding to reduced fwhm results in a two orders of magnitude enhancement in the resolving power compared to conventional propagating surface plasmon polariton (SPP), which is pivotal in identifying minute fluctuations in specific biomolecular concentrations. An order of magnitude improvement in antibody immunoglobin G (IgG) detection limit is observed compared to the SPP based sensing. A detection limit down to 10 ng/mL (66 pM) is achieved using the proposed T-MOKE technique. The results obtained provide compelling evidence of the significantly superior sensitivity and resolving power of the T-MOKE technique for the detection of Human IgG, and it is envisioned that this spectroscopy free, single wavelength measurement approach can be extended to detect biologically/chemically relevant molecules at lower concentrations for early biomedical diagnosis and therapy.

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Magnetoplasmons for Ultrasensitive Label-Free Biosensing

et al. 2021

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“…Interaction of incident light with three-dimensional (3D) metal–dielectric composite nanoarrays provides unique capabilities to manipulate light at nanoscale length. − Diverse types of 3D or quasi-3D plasmonic nanoarrays with tailored feature shapes, sizes, and configurations have been explored for a broad range of light-driven sensors and actuators such as imagers, biosensors, lasers, and antennas. − Traditionally, the construction of 3D plasmonic nanoarrays has largely relied on the use of nanolithography techniques by exploiting either electron-beam lithography (EBL), or focused ion-beam lithography (FIB), or interference lithography (IL), but their laborious, complex, and time-consuming nature impedes practical applications. − In addition, the nanolithography processes often require the use of thermal and chemical treatments, leading to additional increase of complexity and risk in protecting the substrate materials. Alternative strategies involve the use of micro/nanoscale 3D printing techniques such as nanoimprinting and modular microtransfer printing, allowing for deterministic integration of 3D plasmonic nanoarrays with a foreign receiver substrate, and thereby circumventing the incompatibility of the nanolithography conditions with substrate materials. − Nevertheless, the choice of receiver substrates remains limited by the required physical contact forces during printing steps, yielding an increased risk of potential damages to receiver substrates particularly composed of mechanically fragile materials and structures.…”

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Deterministic Nanoassembly of Quasi-Three-Dimensional Plasmonic Nanoarrays with Arbitrary Substrate Materials and Structures

et al. 2019

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Guided manipulation of light through periodic nanoarrays of three-dimensional (3D) metal–dielectric patterns provides remarkable opportunities to harness light in a way that cannot be obtained with conventional optics yet its practical implementation remains hindered by a lack of effective methodology. Here we report a novel 3D nanoassembly method that enables deterministic integration of quasi-3D plasmonic nanoarrays with a foreign substrate composed of arbitrary materials and structures. This method is versatile to arrange a variety of types of metal–dielectric composite nanoarrays in lateral and vertical configurations, providing a route to generate heterogeneous material compositions, complex device layouts, and tailored functionalities. Experimental, computational, and theoretical studies reveal the essential design features of this approach and, taken together with implementation of automated equipment, provide a technical guidance for large-scale manufacturability. Pilot assembly of specifically engineered quasi-3D plasmonic nanoarrays with a model hybrid pixel detector for deterministic enhancement of the detection performances demonstrates the utility of this method.

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“…In this work, we demonstrate a cavity-coupled plasmonic biosensor integrated with a microfluidic blood plasma separator − to detect the DENV biomarker directly from blood as schematically shown in Figure a. The cavity coupling improves the quality factor Q (bandwidth, Δλ) of the LSP resonance while large area parallel nanoimprinting-based patterning ensures deterministic resonance replication (λ R ). , In order to make it target specific, the plasmonic biosensor is functionalized with a high-affinity single stranded DNA (ssDNA) aptamer against the nonstructural NS1 protein from DENV2 serotype, Figure b.…”

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“…The plasmonic sensor used in this work is formed by hybridizing the LSP resonance (LSPR) with an asymmetric Fabry–Perot cavity resonator. ,, The plasmonic nanostructure, unlike conventional one metallic element, is composed of two complementary elements, hole/disk, of period/diameter of 560/200 nm and separated by 350 nm relief depth. The pattern is thermally embossed on UV curable epoxy SU-8 and coated with 30 nm of gold, see Figure a (inset).…”

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DNA-Modified Plasmonic Sensor for the Direct Detection of Virus Biomarkers from the Blood

et al. 2021

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The rapid spread of viral infections demands early detection strategies to minimize proliferation of the disease. Here, we demonstrate a plasmonic biosensor to detect Dengue virus, which was chosen as a model, via its nonstructural protein NS1 biomarker. The sensor is functionalized with a synthetic single-stranded DNA oligonucleotide and provides high affinity toward NS1 protein present in the virus genome. We demonstrate the detection of NS1 protein at a concentration of 0.1−10 μg/mL in bovine blood using an on-chip microfluidic plasma separator integrated with the plasmonic sensor which covers the clinical threshold of 0.6 μg/mL of high risk of developing Dengue hemorrhagic fever. The conceptual and practical demonstration shows the translation feasibility of these microfluidic optical biosensors for early detection of a wide range of viral infections, providing a rapid clinical diagnosis of infectious diseases directly from minimally processed biological samples at point of care locations.

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Hybrid cavity-coupled plasmonic biosensors for low concentration, label-free and selective biomolecular detection

Cited by 14 publications

References 48 publications

Magnetoplasmons for Ultrasensitive Label-Free Biosensing

Magnetoplasmons for Ultrasensitive Label-Free Biosensing

Deterministic Nanoassembly of Quasi-Three-Dimensional Plasmonic Nanoarrays with Arbitrary Substrate Materials and Structures

DNA-Modified Plasmonic Sensor for the Direct Detection of Virus Biomarkers from the Blood

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