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Nanophotonics with subwavelength apertures: theories and applications.Pang, Yuanjie 08 May 2012 (has links)
This dissertation presents subwavelength optics with focus on the theory and applications
of subwavelength apertures in a metal film. Two main issues regarding the
optics with subwavelength apertures are investigated. As the first issue, the extraordinary
optical transmission (EOT) through a single hole in a metallic waveguide is
presented. A total transmission through a single subwavelength aperture is theoretically
predicted for a perfect electric conductor regardless of the aperture size, without
relying on aperture arrays and surface corrugations as presented in previous works.
The waveguide EOT is then applied to boost the optical throughput of an apertured
near-field scanning optical microscope (NSOM) probe. Using a new structure for
the apertured NSOM probe which allows for waveguide EOT, the optical throughput
and the damage threshold are boosted by 100× and 40× as compared to a conventional
structure, and the experimental findings are backed-up by comprehensive
finite-difference time-domain (FDTD) simulations. Single fluorescent molecules are
scanned using the EOT apertured NSOM probe, and a spatial resolution of 62 nm is
achieved. As the second issue, subwavelength apertures are found useful for optical trapping.
A small dielectric particle can significantly change the optical transmission through
an aperture by dielectric loading, and subsequently, a large optical force is induced which favors trapping. A self-induced back-action (SIBA) optical trap is designed
using a circular nanohole in a gold film. Trapping of 50 nm polystyrene particle
is experimentally achieved, which is not possible using a conventional single beam
optical tweezers. The circular nanohole SIBA trap works beyond the perturbative
regime, as proven by FDTD simulations and a Maxwell stress tensor analysis. We
further improve the nanohole trapping using a double-nanohole, which is more sensitive
for small dielectric changes due to the intense local field enhancement between
its two sharp tips. A single 12 nm silica sphere is experimentally trapped using the
double-nanohole, as the smallest trapped dielectric particle reported. We also achieve
the trapping of a single protein – a bovine serum albumin (BSA) protein with a hydrodynamic
radius of 3.4 nm in the folded form. The trapped BSA is also unfolded
by the large optical force, as confirmed by experiments with changing optical power
and changing pH. The high signal-to-noise ratio of 33 in monitoring single protein
trapping and unfolding shows a tremendous potential for using the double-nanohole
as a sensor for protein binding events at a single molecule level. / Graduate
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Spectroelectrochemical analysis of the Li-ion battery solid electrolyte interphase using simulated Raman spectra / Analys av anodens gränsskikt i litiumjonbatterier med spektroelektrokemi och simulerade RamanspektraAndersson, Edvin January 2020 (has links)
Lithium Ion Batteries (LIBs) are important in today's society, powering cars and mobile devices. LIBs consist of a negative anode commonly made of graphite, and a positive cathode commonly made from transition metal oxides. Between these electrodes are separators and organic solvent based electrolyte. Due to the high potential of LIBs the electrolyte is reduced at the anode. The electrolyte reduction results in the formation of a layer called the Solid Electrolyte Interphase (SEI), which prohibits the further breakdown of the electrolyte. Despite being researched for over50 years, the composition formation of the SEI is still poorly understood. The aim of this project is to develop strategies for efficient identification and classification of various active and intermediate components in the SEI, to, in turn, gain an understanding of the reactions taking place, which will help find routes to stabilize and tailor the composition of the SEI layer for long-term stability and optimal battery performance. For a model gold/li-ion battery electrolyte system, Raman spectra will be obtained using Surface Enhanced Raman Spectroscopy (SERS) in a spectroelectrochemical application where the voltage of the working gold electrode is swept from high to low potentials. Spectra of common components of the SEI as well as similar compounds will be simulated using Density Functional Theory (DFT). The DFT data is also used to calculate the spontaneity of reactions speculated to form the SEI. The simulated data will be validated by comparing it to experimental spectra from pure substances. The spectroelectrochemical SERS results show a clear formation of Li-carbonate at the SERS substrate, as well as the decomposition of the electrolyte into other species, according to the simulated data. It is however shown that there are several issues when modelling spectra, that makes it harder to correlate the simulated spectra with the spectroelectrochemical spectra. These issues include limited knowledge of the structure of the compounds thought to form on the anode surface, and incorrect choices in simulational parameters. To solve these issues, more work is needed in these areas, and the spectroelectrochemical methods used in this thesis needs to be combined with other experimental methods to narrow down the amount of compounds to be modelled. More work is also needed to avoid impurities in the electrolyte. Impurities leads to a thick inorganic layer which prohibits the observation of species in the organic layer.
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Využití vibrační spektroskopie pro studium pigmentu violaceinu / Application of vibrational spectroscopy in the study of violacein pigmentVáňová, Hana January 2015 (has links)
This thesis deals with the study of microbial pigment violacein in the real sample of lyophilized microorganisms. The sample was investigated by using methods of vibrational spectroscopy with focusing on the applicability of surface enhanced and resonance micro-Raman spectroscopy. For this purpose several different systems for enhancing Raman intensity together with the set of excitation lasers emitting in the visible light region were used. The conclusion of this thesis are the recommendations connected with the appropriateness of using each amplifying systems and excitation wavelengths for the successful identification of violacein pigment in the sample. Powered by TCPDF (www.tcpdf.org)
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Properties of Nanoscale Biomaterials for Cancer Detection and Other ApplicationsGeist, Brian Lee 10 June 2009 (has links)
The first thermal cycling experiments of ionic self-assembled multilayer (ISAM) films have been reported examining their survivability through repeated thermal cycles from -20° C to 120° C in ambient atmospheric conditions. The films were constructed from alternating layers of Nile Blue A and gold nanoparticles which provided a strong absorbance in the optical wavelength range. No degradation of the optical characteristics of the ISAM films was observed [1]. Techniques for measuring the capacitance and resistivity of various ISAM films have also been developed allowing for a more complete electrical characterization of ISAM films. Capacitance measurements enabled a calculation of the dielectric function and breakdown field strength of the ISAM films. The capacitance measurement technique was verified by measuring the dielectric function of a spin-coated thin film PMMA, which has a well characterized dielectric function [2]. Surface-enhanced Raman spectroscopy (SERS) has been studied as a possible detection method for malignant melanoma revealing spectral differences in blood sera from healthy horses and horses with malignant melanoma. A SERS microscope system was constructed with the capability of resolving the Raman signal from biologically important molecules such as beta-carotene and blood sera. The resulting Raman signals from sera collected from horses with malignant melanoma were found to have additional peaks not found in the Raman signals obtained from sera collected from healthy horses. A systematic analysis of the combination of absorbance and fluorescence signals of blood sera collected from populations of healthy dogs and dogs with cancer has resulted in a rapid and cost-effective method for monitoring protein concentrations that could possibly be used as part of a cancer screening process. This method was developed using the absorbance and fluorescence signals from known serum proteins, the combinations of which were used to match the absorbance and fluorescence signals of blood sera allowing for an accurate determination of protein concentrations in blood sera [3]. Finally, a novel method for measuring the melting point of DNA in solution using capacitance measurements is presented. This method allows for the determination of the melting temperature as well as the melting entropy and melting enthalpy of DNA strands. Two different short strands of DNA, 5'-CAAAATAGACGCTTACGCAACGAAAAC-3' along with its complement and 5'-GGAAGAGACGGAGGA-3' along with its complement were used to validate the technique as the characteristics of these strands could be modeled using theoretical methods. This experimental technique allows for the precise determination of the melting characteristics of DNA strands and can be used to evaluate the usefulness of theoretical models in calculating the melting point for particular strands of DNA. Additionally, a micro-fluidic device has been proposed that will allow for a rapid and cost-effective determination of the melting characteristics of DNA [4]. / Ph. D.
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Sustainable Nanomaterials Combined with Raman Spectroscopy-based Techniques to Advance Environmental SensingRahman, Asifur 22 February 2023 (has links)
The propagation of contaminants in the environment continues to threaten public health and safety. Conventional analytical techniques for environmental detection require centralized facilities and intensive resources for operation. An effective implementation of a wide network of field deployable point-of-use (POU) sensors can potentially enable real-time monitoring of water quality parameters and inform decision making on public health outbreaks. The use of nanotechnology and field-deployable analytical tools can potentially advance the development of POU sensors for future field application.
In this dissertation, we developed environmental sensing techniques that utilize nanocomposites made of low-cost, biocompatible, and sustainable nanomaterials combined with Raman spectroscopy. First, a technology pre-assessment was performed that included a comprehensive evaluation of cellulose-derived nanocomposites and nanobiotechnology enabled techniques for their sustainable long-term environmental application. Furthermore, to contribute to the better understanding of the potential environmental implications of nanomaterial production and application, life cycle assessment (LCA) was used to evaluate the environmental impacts of six iron precursors and seven iron oxide nanoparticle synthesis methods. Secondly, in the technology development step, gold (Au) and iron oxide (Fe3O4) nanoparticles were incorporated onto bacterial cellulose nanocrystals and nanoscale magnetite were synthesized. As proof-of-concept environmental applications, the Au@Fe3O4@BCNCs were applied for the magnetic separation and surface-enhanced Raman scattering (SERS) detection of malachite green isothiocyanate (MGITC), and nanoscale magnetite were applied for phosphate (PO43-) removal and recovery from synthetic urine matrices. Finally, in the technological application step, three environmental sensing applications are presented that use nanomaterial-based sensor platforms and/or Raman spectroscopic techniques. The first application involved using Lectin-modified BCNCs coupled SERS and machine learning for discrimination of bacterial strains. The second application presents a simple Raman-stable isotope labeling approach for the study of viral infection of bacteria. The third application involved use of SERS pH nanoprobes for measuring pH in droplets of complex matrices (e.g., DMEM cell culture media, human saliva). / Doctor of Philosophy / The current generation of analytical tools for environmental detection rely upon centralized facilities and intensive resources for operation. The combination of nanotechnology and field deployable analytical tools can aid in the development of point-of-use (POU) sensors for field monitoring of environmental contaminants. In this dissertation, we combined low-cost, biocompatible, and sustainable nanomaterials with Raman spectroscopy-based techniques to develop potentially field-deployable environmental sensing techniques. First, a technology pre-assessment was performed which involved a comprehensive evaluation of cellulose-derived nanocomposites and nanobiotechnology enabled techniques for their sustainable long-term environmental application. Furthermore, life cycle assessment (LCA) was used to evaluate the environmental impacts of iron oxide nanoparticle synthesis methods to better understand environmental impacts of nanoparticle production. Secondly, in the technology development step, we developed the nanocomposites: Au and Fe3O4 nanoparticles incorporated bacterial cellulose nanocrystals and nanoscale magnetite. As proof-of-concept environmental applications, the Au@Fe3O4@BCNCs were used for the detection of malachite green isothiocyanate (MGITC), and the nanoscale magnetite were used for phosphate (PO43-) removal and recovery from synthetic urine. Finally, in the technological application step, (1) selective detection of bacteria was performed using lectin-modified BCNCs as SERS biosensors coupled with SERS and machine learning. (2) Viral infection of bacteria was evaluated using Raman spectroscopy and Deuterium isotope labeling, and (3) pH in micro-droplets of DMEM cell culture media and human saliva were observed using SERS pH nanoprobes.
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Paper-Based Sensors for Contaminant Detection Using Surface Enhanced Raman SpectroscopyJain, Ishan 29 June 2015 (has links)
Surface enhanced Raman spectroscopy (SERS) is highly promising analytical technique for trace detection of analytes. It is particularly well suited for environmental analyses due to its high sensitivity, specificity, ease of operation and rapidity. The detection and characterization of environmental contaminants, using SERS is highly related to the uniformity, activity and reproducibility of the SERS substrate.
In this thesis, SERS substrates were produced by gold nanoparticle formation on wax patterned chromatography paper. In situ reduction of hydrogen tetrachloroaurate (gold precursor) by trisodium citrate dihydrate (reducing agent) was used to produce gold nanoparticles within a paper matrix. These gold nanoparticle based SERS substrates were analyzed by FE-SEM, UV-Vis and Raman spectroscopy. This work discusses the SERS signal enhancements for Raman active MGITC dye for a series of substrates prepared by in situ reduction of gold salt and pre-produced gold nanoparticles. UV-Vis analysis was performed to understand the effect of different molar ratio (reducing agent to gold precursor) and reaction time on the size and shape of the localized surface plasmon resonance (LSPR) band that dictates the SERS enhancements. It was concluded that lower molar ratio (1:1 and 2:1) of citrate-to gold produced better SERS signal enhancements and broader LSPR band. Therefore, use of lower molar ratio (MR) was recommended for paper-based substrates using in situ-based reduction approach. / Master of Science
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Advanced methods for enhanced sensing in biomedical Raman spectroscopyBalagopal, Bavishna January 2014 (has links)
Raman spectroscopy is a powerful tool in the field of biomedicine for disease diagnosis owing to its potential to provide the molecular fingerprint of biological samples. However due to the inherent weak nature of the Raman process, there is a constant quest for enhancing the sensitivity of this technique for enhanced diagnostic efficiency. This thesis focuses on achieving this goal by integrating advanced methods with Raman spectroscopy. Firstly this thesis explores the applicability of a laser based fluorescence suppression technique – Wavelength Modulated Raman Spectroscopy (WMRS) - for suppressing the broad luminescence background which often obscure the Raman peaks. The WMRS technique was optimized for its applications in single cell studies and tissue studies for enhanced sensing without compromising the throughput. It has been demonstrated that the optimized parameter would help to chemically profile single cell within 6 s. A two fold enhancement in SNR of Raman bands was demonstrated when WMRS was implemented in fiber Raman based systems for tissue analysis. The suitability of WMRS on highly sensitive single molecule detection techniques such as Surface Enhanced Raman Spectroscopy (SERS) and Surface Enhanced Resonance Raman Spectroscopy (SERRS) was also explored. Further this optimized technique was successfully used to address an important biological problem in the field of immunology. This involved label-free identification of major immune cell subsets from human blood. Later part of this thesis explores a multimodal approach where Raman spectroscopy was combined with Optical Coherence Tomography (OCT) for enhanced diagnostic sensitivity (>10%). This approach was used to successfully discriminate between ex-vivo adenocarcinoma tissues and normal colon tissues. Finally this thesis explores the design and implementation of a specialized fiber Raman probe that is compatible with surgical environments. This probe was originally developed to be compatible with Magnetic Resonance Imaging (MRI) environment. It has the potential to be used for performing minimally invasive optical biopsy during interventional MRI procedures.
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The adsorption of thiophenol on gold - a spectroelectrochemical studyHolze, Rudolf 24 February 2016 (has links) (PDF)
The adsorbate formed by adsorption of thiophenol on a polycrystalline gold electrode and brought into contact with aqueous solutions of 1 M HClO4 and 0.1 M KClO4 has been studied using cyclic voltammetry and surface-enhanced Raman spectroscopy. A strong adsorption is deduced from observations made using cyclic voltammetry. From the SER spectra, interactions of thiophenol with the gold surface via a gold–sulfur bond with the aromatic ring pointing away from the surface is concluded for both electrolyte solutions. / Dieser Beitrag ist aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.
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Investigating the effects of chemotherapy and radiation therapy in a prostate cancer model system using SERS nanosensorsCamus, Victoria Louise January 2016 (has links)
Intracellular redox potential (IRP) is a measure of how oxidising or reducing the environment is within a cell. It is a function of numerous factors including redox couples, antioxidant enzymes and reactive oxygen species. Disruption of the tightly regulated redox status has been linked to the initiation and progression of cancer. However, there is very limited knowledge about the quantitative nature of the redox potential and pH gradients that exist in cancer tumour models. Multicellular tumour spheroids (MTS) are three-dimensional cell cultures that possess their own microenvironments, similar to those found in tumours. From the necrotic core to the outer proliferating layer there exist gradients of oxygen, lactate, pH and drug penetration. Tumours also have inadequate vasculature resulting in a state of hypoxia. Hypoxia is a key player in metabolic dysregulation but can also provide cells with resistance against cancer treatments, particularly chemotherapy and radiation therapy. The primary hypoxia regulators are HIFs (Hypoxia Inducible Factors) which under low O2 conditions bind a hypoxia response element, inhibiting oxidative phosphorylation and upregulating glycolysis which has two significant implications: the first is an increase in levels of NADPH/NADH, the main electron donors found in cells which impacts the redox state, whilst the second is a decrease in intracellular pH (pHi) because of increased lactate production. Thus, redox state and intracellular pHi can be used as indicators of metabolic changes within 3D cultures and provide insight into cellular response to therapy. Surface-Enhanced Raman Spectroscopy (SERS) provides a real-time, high resolution method of measuring pHi and IRP in cell culture. It allows for quick and potentially portable analysis of MTS, providing a new platform for monitoring response to drugs and therapy in an unobtrusive manner. Redox and pH-active probes functionalised to Au nanoshells were readily taken up by prostate cancer cell lines and predominantly found to localise in the cytosol. These probes were characterised by density functional theory and spectroelectrochemistry, and their in vitro behaviour modelled by the chemical induction of oxidative and reductive stress. Next, targeting nanosensors to different zones of the MTS allowed for spatial quantification of redox state and pHi throughout the structure and the ability to map the effects of drug treatments on MTS redox biology. The magnitude of the potential gradient can be quantified as free energy (ΔG) and used as a measurement of MTS viability. Treatment of PC3 MTS with staurosporine, an apoptosis inducer, was accompanied by a decrease in free energy gradients over time, whereas treatment of MTS with cisplatin, a drug to which they are resistant, showed an increase in viability indicating a compensatory mechanism and hence resistance. Finally, using this technique the effects of ionising radiation on IRP and pHi in the tumour model was explored. Following exposure to a range of doses of x-ray radiation, as well as single and multi-fractionated regimes, IRP and pHi were measured and MTS viability assessed. Increased radiation dosage diminished the potential gradient across the MTS and decreased viability. Similarly, fractionation of a single large dose was found to enhance MTS death. This novel SERS approach therefore has the potential to not only be used as a mode of drug screening and tool for drug development, but also for pre-clinical characterisation of tumours enabling clinicians to optimise radiation regimes in a patient-specific manner.
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Spontaneous Raman spectroscopy : exploring applicability in drug discovery and the medical sciencesRabl, Thomas January 2018 (has links)
This thesis reports the investigation of spontaneous Raman Spectroscopy (RS) for its applicability in early drug discovery. A key focus has been to develop an understanding of the applicability of RS for the quantification and localisation of compound concentration inside mammalian cells. Further investigation into the use of Surface Enhanced Raman Spectroscopy (SERS) for research on Visceral Leishmaniasis (VL) and Leishmania donovani as well as investigating applicability for cancer research are decisive parts of this work. The key work described in this thesis is the investigation of whole cell concentration of compounds inside THP-1 and Madin Darby Canine Kidney (MDCK) cells. For true quantification the Cell Silent Region (CSR) is used to measure without interference from cellular background signal. The model compound is erlotinib, an anti-cancer drug with an alkyne group expressing a peak in the CSR. The developed RS system is calibrated using the current gold standard technique Ultra Performance Liquid Chromatography tandem Mass Spectrometry (UPLC-MS/MS). However, because of the single cell nature of the RS information on inter cell variability can be extracted. The RS measurements suggest that there is a large variation of concentration within single cell populations. The RS measurements can therefore give insight in single cell behaviour within a large cell population. Findings shows that washing cycles, before fixation, alter the intra-cellular concentrations significantly. This is hypothesised to be caused by the sudden change in concentration on the outside of the cell that applies an osmotic pressure, leading to loss of substance from inside the cell wall. Localisation of erlotinib is shown within THP-1 cells and points towards an accumulation inside the cell nucleus. Later, internalised Au nano-particles in the range of 30 nm to 80 nm have been investigated for their enhancement effects and localisation inside THP-1 cells. Au nano-particles are found to be internalised easily by differentiated THP-1 cells and accumulate in lysosomes. This allows for a high local enhancement of the spontaneous Raman signal. However, no advantage for the detection of lysosomally trapped compounds (chloroquine, chlorpromazine) was achieved. The detection of substances without a signal in the CSR was achieved without enhancement. Nonetheless, compounds with intrinsic peaks in the CSR could benefit from this enhancement. Lastly the RS system is explored for alternative uses in early drug discovery. This includes the detection of toxicity as well as the discrimination of cell types. Toxicity has been detected using optically trapped THP-1 cells and doxorubicin. Utilising Principal Component Analysis (PCA) combined with Linear Discriminant Analysis (LDA) on these measured spectra, allowed for a clear discrimination of toxically influenced from healthy cells. Differences mainly show up in DNA content caused by the mode of action of doxorubicin and caused by the trapping, which generates most of the signal within the nucleus of the cell. Discriminating cancerogenic (DU145) from healthy prostate cells (PNT2) has been achieved by probing fixed cells and evaluating the acquired Raman spectra with a PCA/LDA combination. The accuracy of separation of these cells when tested with a 10-fold cross-validation technique, is above 98 %, allowing a good discrimination.
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