Developing Multifunctional Surface Chemistry For Plasmonic Biosensing In Complex Media

Developing Multifunctional Surface Chemistry for Plasmonic Biosensing in Complex Media

Author : Fang Sun

Publisher :

Page : 168 pages

File Size : 40,27 MB

Release : 2016

Category : Biosensors

ISBN :

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Book Description

During the past decades, plasmonic sensors have been explored extensively due to their ultra-sensitivity and emerged as a new generation of analytical tools. Two of the most widely used and studied plasmonic sensors are surface enhanced Raman scattering (SERS) sensors and surface plasmon resonance (SPR) sensors, which are focused in this dissertation. SERS is a phenomenon which can significantly magnify the Raman signals of the molecules adsorbed on a nanostructured metal surface for up to millions of folds and have led to the detections of single molecules. SERS can also provide chemical fingerprints representing vibrational or rotational transitions specific to the molecular structure to identify the analyte. The SPR optical sensor can enable the direct observation of molecular interaction in real-time and offer the benefits of rapid, sensitive and label-free detection of chemical and biological species. Based on these advantages such as ultra-sensitivity and molecular specificity, both of the sensors have already been used for a variety of applications ranging from chemical and biological sensing, environmental monitoring to diagnostics. However, reliable biosensing in complex biological media based on these two advanced plasmonic sensors is still very challenging due to several reasons. For example, SERS is a near-field effect; the enhancement effect decreases exponentially with increasing distance from the surface. A bare SERS-active surface lacks selectivity; anything adsorbed onto the surface can be detected. In the complex media, the background noise from interfering species could mask the signals from target analytes. In addition, nonspecific adsorption from the complex media could impede the adsorption of target analytes to SERS-active substrate surfaces. Thus, a method which can amplify the detection signals over unwanted background is highly desirable and it is also essential to introduce nonfouling modifications to protect the SERS-active surface from nonspecific adsorption. For an SPR sensor, the specificity of the SPR sensor is totally dependent on the biomolecular recognition species employed while the sensitivity depends on the amount of nonspecific binding. Thereby, the surface chemistry which can not only effectively resist nonspecific protein adsorption but also provides abundant sites for the ligand immobilization is desired. In this dissertation, we discuss the design and selection of probe molecules on the SERS surface for specific detection and signal amplification of target analytes with small Raman activity or no activity such as fructose or hydrogen ion. In addition, to overcome the protein fouling problem, we introduce a zwitterionic nonfouling surface modification to the SERS sensor. We design and synthesize a zwitterionic short thiol, which contains a carboxybetaine head group resisting the protein adsorption effectively. The CBT possesses a small Raman activity generating negligible background noise even with high packing density. To future improve the nonfouling property of the modification, we also introduce the zwitterionic poly(carboxybetaine acrylamide) (pCBAA) polymer brush on the SERS surface via surface-initiated atom transfer radical polymerization (SI-ATRP). This modification enables the SERS detection of several therapeutic drugs directly in the human undiluted plasma. For the SPR sensor, we develop a facile and stable nonfouling coating method based on the zwitterionic hydrogel. The hydrogel coating demonstrate ultra-low fouling property from the undiluted blood serum and high antibody loading capacity due to the three-dimensional structure. At last, we also propose a new method to detect the anti-PEG antibody in blood sample based on the PEG coated SPR sensor. The surface chemistry is studied and optimized to achieve an extremely low limit of detection showing better sensitivity compared with traditional ELISA detection methods. By tailoring and tuning the surface chemistry, we explore and expand the applications of the plasmonic sensor in complex media. On the one hand, we introduce the attracting and probing molecules to enhance the detection signals. And on the other hand, we modify the zwitterionic nonfouling materials on the surface of sensors to decrease the background noise and interference. With the improved signal/noise ratio, the sensitivity of sensors can be dramatically increased.



Multifunctional Zwitterionic Surface Chemistry for Applications in Complex Media

Author : Norman D. Brault

Publisher :

Page : 135 pages

File Size : 18,74 MB

Release : 2014

Category :

ISBN :

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The realization of personalized medicine relies on the discovery of clinically relevant biomarkers as well as on the development of corresponding assays. Due to the complexity of human blood plasma and serum, the most common sources for biomarker analysis, current attempts to integrate existing biosensing assays with analyte detection has resulted in two major shortcomings: high rates of false-positives, from non-specific binding, and a lack of assay sensitivity, due to low ligand loading. Taken together, these two factors indicate that a high signal-to-noise ratio (S/N) is vital for achieving sensitive biomarker-based diagnostics. Furthermore, a single material that can (1) exhibit non-fouling properties from undiluted human blood, (2) present abundant and easily functionalizable chemical groups for ligand attachment, and (3) possesses high immobilization capacities, would offer the most promising approach to achieving this goal. Such idealities were addressed using zwitterionic poly(carboxybetaine) (pCB) surface chemistry. First, an important parameter was realized for identifying surface coatings suitable for real-world applications involving undiluted complex media. It was found that ultra low fouling properties using a thin film is possible if it is densely packed. While such prevention of non-specific adsorption is important, the detection of biomarkers also hinges on the ability to immobilize biologically active ligands all while maintaining the original ultra low fouling background noise of the surface coating. Hence, the dual-functionality of pCB, which provides both protein resistance and ligand functionalization, was then applied to protein arrays. Here, uniform spot morphology as well as excellent non-fouling properties following antibody immobilization was achieved. This enabled improvements in the sensitivity for multiplexed detection of target analytes directly from undiluted human plasma. As even the best non-fouling background combined with the highest affinity ligand would still have a limited S/N ratio due to the 2-dimensional (2-D) structure of polymer films, two efforts to improve the "signal" component were also investigated. The first method led to the development of a hierarchical architecture consisting of a thin and highly dense first layer and a loose but controlled second layer, for low fouling and high ligand loading, respectively. The second approach for improving biomarker assay performance involved taking advantage of new biosensor devices. Such novel sensor designs exhibit decreasing surface dimensions with unique geometries and enhanced theoretical sensitivities. Due to these distinct characteristics, the development of a dual-functional "graft-to" surface coating was necessary. Here, the conjugation of the adhesive molecule DOPA with pCB enabled the successful attachment to a biosensor surface while also demonstrating ultra low fouling and functionalization properties. This "graft-to" technology can be readily extended to other device platforms. Finally, while normal immobilization conditions for pCB allow for the attachment of acidic and neutrally charged ligands, two strategies for expanding the range of ligands, to include basic proteins (i.e. with high isoelectric points), which can be coupled to an ultra low fouling zwitterionic background were also investigated. It was found that the use of reversible citraconic anhydride protection enabled the coupling of the highly basic protein lysozyme to the pCB surface. The second strategy, involving a novel zwitterionic ultra low fouling material, led to an initial characterization which indicated promising results. In summary, this work represents a multifunctional zwitterionic surface chemistry readily suitable for applications in undiluted complex media.



Handbook of Surface Plasmon Resonance

Author : Richard B. M. Schasfoort

Publisher : Royal Society of Chemistry

Page : 426 pages

File Size : 38,64 MB

Release : 2008

Category : Science

ISBN : 0854042679

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Book Description

Surface plasmon resonance (SPR) plays a dominant role in real-time interaction sensing of biomolecular binding events. This book focuses on a total system description including optics, fluidics and sensor surfaces. It covers all commercial SPR systems in the market. It is the first of its kind and fills a gap in the technical literature as no other handbook on SPR is currently available. The final chapter discussed new trends and a vision is given for future developments and needs of the SPR market. This excellent handbook provides comprehensive information with easy to use, stand-alone chapte.



Plasmonic Biosensors

Author : A.B. Dahlin

Publisher : IOS Press

Page : 316 pages

File Size : 34,11 MB

Release : 2012-01-11

Category : Medical

ISBN : 1607509660

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Book Description

In this book Andreas Dahlin has written a comprehensive and thorough review of plasmonic biosensors that operate by refractometric detection. After an introductory chapter on biosensors, in which he sets out the concepts of biosensing in its application to such areas as proteomics, medical diagnostics and environmental control, he undertakes an integrated coverage of surface chemistry, surface physics and optics, specifically related to the requirements of design of a plasmonic biosensor. Sections on nanoparticle plasmons and surface plasmons follow, leading to a review of SPR technology for biosensing. The optical properties of nanoholes in metal films and other more complicated plasmonic nanostructures are also briefly discussed. Later chapters discuss experimental plasmon spectroscopy and spectral analysis while the final sections discuss topics such as sensor response and the extent to which quantitative measurements can be made. The book introduces a few relatively controversial opinions on some open questions, such as how best to define sensor performance and the practical use of highly miniaturized sensors. Each of the chapters is extensively referenced and contains appropriate illustrations. The book contains a wealth of information that will be highly beneficial to both existing and new users of refractometric sensing techniques in life science research. It will be a valuable resource for post-graduate research students, academic researchers and those working in industry.



Localized Surface Plasmon Resonance Based Nanobiosensors

Author : Yi-Tao Long

Publisher : Springer Science & Business Media

Page : 123 pages

File Size : 16,9 MB

Release : 2014-04-10

Category : Science

ISBN : 3642547958

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Book Description

This book introduces the fundamentals and applications of the localized surface plasmon resonance (LSPR) property of noble metallic nanoparticles, with an emphasis on the biosensing applications of plasmonic nanoparticles, especially in living cell imaging and photothermal therapy. It provides an overview of the different operating principles of plasmonic sensors, particularly the single-nanoparticle-based detections, and a series of creative biosensors based on the modulation of different parameters of nanoparticles (particle size, shape, composition and surrounding medium) for label-free detection. The interparticle coupling effect, plasmon resonance energy transfer, electron transfer on plasmonics surface are also covered in this book. This book is intended for graduate students and researchers working in the interdisciplinary field combining chemistry, biology, material science and nanophotonics. Yi-Tao Long is a Professor at the School of Chemistry and Molecular Engineering, East China University of Science and Technology, China.



Surface Design: Applications in Bioscience and Nanotechnology

Author : Renate Förch

Publisher : John Wiley & Sons

Page : 532 pages

File Size : 17,52 MB

Release : 2009-08-06

Category : Science

ISBN : 3527628606

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Book Description

This carefully selected balance of tutorial-like review chapters and advanced research covers hot topics in the field of biointerfaces, biosensing, nanoparticles at interfaces, and functionalized quantum dots. It also includes chapters arising from non-published work with topics such as surface design and their applications, as well as new developments in analytical tools for materials science and life science. Based on the very close and complementary collaboration of three distinguished leading research groups, this book highlights recent advances in the field ranging from synthesis and fabrication of organic and polymeric materials, surface and interface science to advanced analytical methods. It thus addresses new concepts in micro- and nanofabrication, bio-nanotechnology, biosensors and the necessary compositional and structural analysis. Particular attention is paid throughout to complex hierarchical interface architectures and possible applications of the chemical and physical methodologies discussed, covering bio-diagnostics, novel biosensors and adhesion science. With its unique combination of expertise from chemistry, physics, biology, surface science and engineering, this is a valuable companion for students, practitioners and established experts.



Development of and Application of Plasmonic Nanomaterials for Mass Spectrometry Based Biosensing

Author : Roberto Carlos Gamez

Publisher :

Page : pages

File Size : 23,79 MB

Release : 2015

Category :

ISBN :

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Book Description

The use of nanomaterials for sensing and biological applications has recently gained interest owing to the unique physical, chemical and optical properties that arise when materials are reduced to the nanoscale. The unique optical properties exhibited by gold (Au) and silver (Ag) nanomaterials have made for versatile platforms in a wide range of applications including surface plasmon biosensing techniques and laser desorption/ionization mass spectrometry (LDI-MS). A primary driver for this work is the relative ease performing surface modifications to nanoparticles (NPs), which can be used to enhance the selectivity of ionization and/or facilitate analyte capture. The research presented here focuses on the development of AuNP and AgNP based biosensors for selective capture and ionization of low abundance compounds from complex mixtures and subsequent detection by LDI-MS and Matrix Assisted Laser Desorption Ionization- Mass Spectrometry (MALDI-MS). First, a 'strategy' for selective capture and ionization of specific compound classes based on chemical derivatization of gold nanorods (AuNRs) and infrared laser desorption ionization (IR-LDI) is described. LDI is performed at near infrared wavelengths (1064 nm) that overlap with the longitudinal surface plasmon resonance (LSPR) mode of AuNRs which allows absorbed energy from the laser to facilitate the desorption and ionization of the analyte. Capture of hydrophobic species using surfactant coated AuNRs and subsequent detection by IR-LDI-MS was also demonstrated in these experiments. Second, the fabrication of a label-free MS and optical detection based biosensor platform consisting of a phospholipid layer partially tethered to the surface of a gold nanorod for the detection of low abundance lipophilic analytes from complex mixtures is described. In these experiments, stable phospholipid capped AuNRs are produced by tethering some of the phospholipids to the surface of the AuNRs though a covalent, gold-thiol linkage. The effectiveness of the biosensor is demonstrated for the label-free detection of a membrane active lipophilic drug from aqueous solution and of a lipopeptide from fetal bovine serum. Lastly, porous AgNP embedded thin films were fabricated by the sol-gel method and utilized as matrix-free LDI-MS biosensors applicable to several chemical classes. In these experiments, UV laser irradiation (337 nm) of the AgNP facilitates desorption and ionization of a number of peptides, triglycerides, and phospholipids. Preferential ionization of sterols from vesicles composed of olefinic phosphosphatidylcholines is also demonstrated. The electronic version of this dissertation is accessible from http://hdl.handle.net/1969.1/152818



Handbook of Surface Plasmon Resonance

Author : Richard B. M. Schasfoort

Publisher : Royal Society of Chemistry

Page : 555 pages

File Size : 24,73 MB

Release : 2017-05-30

Category : Science

ISBN : 1782627308

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Book Description

Surface plasmon resonance (SPR) plays a dominant role in real-time interaction sensing of biomolecular binding events, this book provides a total system description including optics, fluidics and sensor surfaces for a wide researcher audience.





Nanoplasmonic Sensors

Author : Alexandre Dmitriev

Publisher : Springer Science & Business Media

Page : 394 pages

File Size : 49,48 MB

Release : 2012-07-31

Category : Science

ISBN : 1461439337

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Book Description

This book is a compendium of the finest research in nanoplasmonic sensing done around the world in the last decade. It describes basic theoretical considerations of nanoplasmons in the dielectric environment, gives examples of the multitude of applications of nanoplasmonics in biomedical and chemical sensing, and provides an overview of future trends in optical and non-optical nanoplasmonic sensing. Specifically, readers are guided through both the fundamentals and the latest research in the two major fields nanoplasmonic sensing is applied to – bio- and chemo-sensing – then given the state-of-the-art recipes used in nanoplasmonic sensing research.