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41	Patterned nanoarray sers substrates for pathogen detection Marotta, Nicole Ella 25 August 2010 (has links) The objectives of the work presented were to 1) fabricate reproducible nanorod array SERS substrates, 2) detection of bacteria using nanorod substrates, 3) detection of DNA hybridization using nanorod substrates and 4) critically evaluate the sensing method. Important findings from this work are as follows. A novel method for batch fabrication of substrates for surface enhanced Raman scattering (SERS) has been developed using a modified platen machined to fit in a commercial electron beam evaporator. The use of this holder enables simultaneous deposition of silver nanorod (AgNR) arrays onto six microscope slide substrates utilizing glancing angle deposition. In addition to multiple substrate fabrication, patterning of the AgNR substrates with 36 wells allows for physical isolation of low volume samples. The well-to-well, slide-to-slide, and batch-to-batch variability in both physical characteristics and SERS response of substrates prepared via this method was nominal. A critical issue in the continued development of AgNR substrates is their stability over time, and the potential impact on the SERS response. The thermal stability of the arrays was investigated and changes in surface morphology were evaluated using scanning electron microscopy and x-ray diffraction and correlated with changes in SERS enhancement. The findings suggest that the shelf-life of AgNR arrays is limited by migration of silver on the surface. Continued characterization of the AgNR arrays was carried out using fluorescent polystyrene microspheres of two different sizes. Theory suggests that enhancement between nanorods would be significantly greater than at the tops due to contributing electromagnetic fields from each nanostructure. In contrast to the theory, SERS response of microspheres confined to the tops of the AgNR array was significantly greater than that for beads located within the array. The location of the microspheres was established using optical fluorescence and scanning electron microscopy. The application of SERS to characterizing pathogens such as bacteria and viruses is an active area of investigation. AgNR array-based SERS substrates have enabled detection of pathogens present in biofluids. Specifically, several publications have focused on determining the spectral bands characteristic of bacteria from different species and cell lines. Studies were carried out on three strains of bacteria as well as the medium in which the bacteria were grown. The spectra of the bacteria and medium were surprisingly similar, so additional spectra were acquired for commonly used bacterial growth media. In many instances, these spectra were similar to published spectra purportedly characteristic of specific bacterial species. In addition to bacterial samples, nucleic acid hybridization assays were investigated. Oligonucleotide pairs specifically designed to detect respiratory syncytial virus (RSV) in nasal fluids were prepared and evaluated. SERS spectra acquired on oligos, alone or in combination, contain the known spectral signatures of the nucleosides that comprise the oligo. However, spectra acquired on an oligo with a 5'- or 3' thiol were distinctly different from that acquired on the identical oligo without a thiol pendant group suggesting some control over the orientation of the oligo on the nanorod surface. The signal enhancement in SERS depends markedly upon the location of the probe relative to the substrate surface. By systematic placement of nucleotide markers along the oligo chain, the point at which the nucleotide disappears from the spectrum was identified. The overall findings for AgNR SERS substrates suggest that the applicability of SERS for detecting nucleic acid hybridization is limited. The strong distance dependence coupled with the lack of substrate stability at temperatures required for annealing oligos during hybridization suggest that AgNRs are not the platform to use for hybridization assays. Silver nanostructure Surface enhanced Raman scattering Silver nanorod array Surface enhanced Raman spectroscopy Oblique angle deposition Glancing angle deposition SERS substrate Raman effect Raman spectroscopy
42	Χρησιμοποίηση της μεθόδου SERS στην ελεγχόμενη αποδέσμευση μικρού μοριακού βάρους χημικών ενώσεων από πολυμερικές μήτρες Αναστασόπουλος, Ιωάννης 27 March 2012 (has links) Η χρήση των πολυμερών στον τομέα της ιατρικής βιομηχανίας κερδίζει ολοένα και μεγαλύτερο έδαφος τα τελευταία χρόνια έχοντας ήδη κάνει ισχυρή την παρουσία τους σε ένα ευρύ πεδίο κλάδων της βιοϊατρικής όπως στη μηχανική ιστών, στην εμφύτευση ιατρικών συσκευών και τεχνητών οργάνων, στην προσθετική και την οφθαλμολογία, στην οδοντιατρική και την αποκατάσταση οστών, στη χημειοθεραπεία και σε ποικιλία άλλων ιατρικών εφαρμογών. Με τη χρήση πολυμερικών συστημάτων μεταφοράς δραστικών ουσιών καθίσταται ικανή η ελεγχόμενη αργή αποδέσμευση φαρμάκων στο σώμα καθώς και η στοχευμένη απελευθέρωσή τους σε σημεία όπου υπάρχουν φλεγμονές ή όγκοι. Τοιουτοτρόπως, χημειοθεραπείες με χρήση βιοπολυμερών ως διαμεσολαβητές, προβάλλουν ως δυνητικές υποψήφιοι στην αντιμετώπιση του καρκίνου του εγκεφάλου με ενθαρρυντικά αποτελέσματα. Συγκρινόμενη με την τυπική συστημική χημειοθεραπεία, η ενδοογκική απελευθέρωση φαρμάκου με τη χρήση βιοπολυμερών θεωρητικώς παρουσιάζει αρκετά πλεονεκτήματα: τα βιοπολυμερή μπορούν να μεταφέρουν το φάρμακο απευθείας στον όγκο-στόχο αυξάνοντας τη συγκέντρωση τοπικά και παράλληλα μειώνοντας τη συστημική τοξικότητα· μπορούν έτσι να χρησιμοποιούνται στη θεραπεία ανοσοκατασταλμένων ασθενών που δεν μπορούν να υποβληθούν σε συστημική χημειοθεραπεία. Από τη στιγμή που είναι απαραίτητη η ποσοτικοποίηση των φαρμάκων για τον χαρακτηρισμό των συστημάτων αποδέσμευσης και για μελέτες φαρμακοκινητικής, θα πρέπει να επιλέγεται η καταλληλότερη μέθοδος ποσοτικοποίησης παρέχοντας υψηλή ευαισθησία και ακρίβεια, εξασφαλίζοντας μεγάλη ανιχνευτική ικανότητα ακόμη και για πολύ χαμηλές συγκεντρώσεις. Στην παρούσα εργασία δύο αναλυτικές τεχνικές, η απορρόφηση υπεριώδους-ορατού και η επιφανειακή ενίσχυση της σκέδασης Raman (Surface Enhanced Raman Scattering, SERS), χρησιμοποιήθηκαν για την ποσοτική εκτίμηση του αντινεοπλασματικού φαρμάκου Mitoxantrone και του αντιμυκητιακού παράγοντα Ambisome (Αμφοτερισίνη Β) που αποδεσμεύτηκαν από βιοσυμβατές πολυμερικές μήτρες συμπολυμερούς αιθυλενίου-οξικού βινυλεστέρα, συμπολυμερούς γλυκολικού-γαλακτικού οξέος και πολυπροπυλενίου. Το SERS είναι ένα νέο, εναλλακτικό, ταχύ και μη καταστροφικό εργαλείο που μπορεί να βρεί εφαρμογή και στην ποσοτική εκτίμηση ουσιών πάρα πολύ χαμηλών συγκεντρώσεων. Χάρις στην ενίσχυση που παρέχεται στο σήμα Raman από τα νανο-εκτραχυμένα υποστρώματα ευγενών μετάλλων ή τα νανο-συσσωματώματα κολλοειδών διαλυμάτων ευγενών μετάλλων, έχει αναφερθεί ακόμη και συλλογή φάσματος SERS από ένα μόνο μόριο. Συνεπώς, η εφαρμογή του SERS σε μελέτες ουσιών εξαιρετικά χαμηλών συγκεντρώσεων φαίνεται να είναι πολύ ενδιαφέρουσα. Κατασκευάστηκαν πολυμερικά υμένια με εγκλωβισμένες τις δραστικές ουσίες και η μελέτη αποδέσμευσης πραγματοποιήθηκε σε νερό. Ποσοτικές μετρήσεις με τη χρήση του SERS σε πολύ μικρές συγκεντρώσεις έδειξαν μεγαλύτερη ανιχνευτική ευαισθησία σε σχέση με αυτές που πραγματοποιήθηκαν με την απορρόφηση UV-Vis. Συμπερασματικά, το SERS δείχνει ικανό στον ποσοτικό προσδιορισμό ενεργών ουσιών που αποδεσμεύονται από βιοσυμβατά πολυμερικά συστήματα μεταφοράς δραστικών ουσιών σε πολύ μικρές συγκεντρώσεις. / The application of polymeric materials for medical purposes is growing very fast. Polymers have found applications in such diverse biomedical fields as tissue engineering, implantation of medical devices and artificial organs, prosthesis, ophthalmology, dentistry, bone repair, chemotherapy and many other medical fields. Polymer-based delivery systems enable controlled slow release of drugs into the body and also they make possible targeting of drugs into sites of inflammation or tumors. Thus, biopolymer-mediated chemotherapy has shown promising results in the treatment of brain tumors. When compared to conventional systemic chemotherapy, intratumoral biopolymer-mediated drug delivery has several theoretical advantages: Biopolymers can deliver drugs into the tumor bed, thus maximizing local concentration while minimizing systemic toxicity. They may therefore be employed in the treatment of immunodepressed patients etc. Since drugs need to be quantified for drug delivery system characterization, intracellular distribution studies, free or vehicular, and for pharmacokinetic assays, the most suitable quantification method must be chosen. It should have a high sensitivity, specificity and reproducibility and should be capable of measuring at very low concentration range, as well. In the present study, two analytical techniques are utilized to quantitatively evaluate the antineoplastic drug Mitoxantrone and the antifungal agent Ambisome (Amphotericin b) released from active agents-loaded biocompatible polymer matrices poly(propylene), poly(ethylene-co-vinyl acetate), poly(lactic-co-glycolic acid); the UV-Vis absorption and the Surface Enhance Raman Scattering (SERS). SERS is a new, versatile, fast and non destructive tool for the estimation of extremely small amounts of substances. Due to the enhancement provided to the Raman signal by the nano-rough noble-metal substrates or the nano-structured colloidal clusters of noble metals, even single molecule detection has been reported. Therefore, applying SERS to extremely low concentration measurements proves to be challenging. Drug loaded polymer specimens were prepared and the in vitro drug release was determined in water. Fast SERS quantitative measurements showed enhanced sensitivity compared to the UV-Vis absorption; SERS may enable low concentration quantitative assessment of controlled release of drugs from biopolymer-based delivery systems. Σκέδαση Raman 615.1 Surface enhanced raman Scattering Silver colloid Raman scattering
43	Exploring some aspects of cancer cell biology with plasmonic nanoparticles Austin, Lauren Anne 07 January 2016 (has links) Plasmonic nanoparticles, specifically gold and silver nanoparticles, exhibit unique optical, physical, and chemical properties that are exploited in many biomedical applications. Due to their nanometer size, facile surface functionalization and enhanced optical performance, gold and silver nanoparticles can be used to investigate cellular biology. The work herein highlights a new methodology that has exploited these remarkable properties in order to probe various aspect of cancer cell biology, such as cell cycle progression, drug delivery, and cell death. Cell death mechanisms due to localized gold and silver nanoparticle exposure were also elucidated in this work. Chapter 1 introduces the reader to the synthesis and functionalization of gold and silver nanoparticles as well as reviews their implementation in biodiagnostic and therapeutic applications to provide a foundation for Chapters 3 and 4, where their use in spectroscopic and cytotoxic studies are presented. Chapter 2 provides the reader with detailed explanations of experimental protocols for nanoparticle synthesis and functionalization, in vitro cellular biology experiments, and live-cell Raman spectroscopy experiments that were utilized throughout Chapters 3 and 4. Chapter 3 presents the use of nuclear-targeted gold nanoparticles in conjunction with a Raman microscope modified to contain a live-cell imaging chamber to probe cancer cell cycle progression (Chapter 3.1), examine drug efficacy (Chapter 3.2), monitor drug delivery (Chapter 3.3), and detect apoptotic molecular events in real-time (Chapter 3.4). In Chapter 4, the intracellular effects of gold and silver nanoparticles are explored through live-cell Rayleigh imaging, cell cycle analysis and DNA damage (Chapter 4.1), as well as through the elucidation of cytotoxic cell death mechanisms after nanoparticle exposure (Chapter 4.2) and live cell imaging of silver nanoparticle treated cancer cell communities (Chapter 4.3). Plasmonic nanoparticles Surface enhanced Raman scattering Gold nanoparticle Silver nanoparticle Rayleigh scattering Apoptosis
44	Development of a multiplexing biosensor platform using SERS particle immunoassay technology Kumarswami, Neelam January 2014 (has links) The purpose of this study is to demonstrate the ability of surface enhanced Raman scattering (SERS) active particles to enable multiplexed immunoassays in a lateral flow format for point of care (POC) testing. The SERS particles used for this study are chemically active glass coated gold particles, containing tracer molecules which in principle can be chosen to provide Raman Spectra with unique features allowing multiple tracers to be simultaneously measured and distinguished without interference between each other. Lateral flow immunoassay technology is the important part of this study and can be conveniently packaged for the use of other than highly skilled technicians outside of the laboratory. A well-known (single channel - simplex) device for the pregnancy test is a typical example of the lateral flow assay. Similar formats have been/are being developed by others for a range of POC applications – but most diagnostic applications require simultaneous determination of a range of biomarkers and multiplexed assays are difficult to achieve without significant interference between the individual assays. This is where SERS particles may provide some advantages over existing techniques. Cardiac markers are the growing market for point of care technology therefore biomarkers of cardiac injury (Troponin, myoglobin and CRP) have been chosen as a model. The object of the study is to establish the proof of concept multiplexing assay using these chosen biomarkers. Thus, initially all different particles were characterised in single and mixture form. Also development of conjugate chemistry between antibodies for each analyte that have been purchased from commercial sources and SERS particles were analysed using different conditions like buffer, pH and antibody loading concentration to get the optimum intensity. The selected SERS particles and their conjugates were tested for size, aggregation and immune quality using a range of techniques: ultraviolet-visible (UV/Vis) absorption spectroscopy, dynamic light scattering (DLS) and lateral flow assay. These characterisations methodologies gave the understanding of optimum conditions of the each conjugates and individual’s behaviour in mixture conditions as well. After the characterisation all conjugates were tested singularly on the lateral flow assay using buffers and serum. The results of this single analyte immunoassay explained the individual’s bioactivity on the lateral flow strip. Further in study, multiplex assay have been demonstrated in serum. These outcomes have described each candidate characteristic in a mixture form on the lateral flow strip. In order to get the optimum Raman intensity from multiplex assay, the detection and capture antibodies loading concentrations were tuned in the assay. Later on different combinations (high, medium and low concentrations) of all three analytes were analysed and has found some interferences in multiplex assay. To investigate these issues various aspect were considered. First of all, different possibilities of non-specific interactions between the co-analytes and antibodies were tested. In addition, steric hindrance and optical interference investigations were performed via several assays and analysis using Scanning electron microscopy. The outcomes have confirmed related optical interferences. Therefore other assay (wound biomarkers) established to eliminate the interferences. In summary, the works reported here have built and test the equipment and necessary reagents for individual assays before moving on the more complicated task. In addition, the entire study has given a deep knowledge of multiplex assay on a single test line including the investigation of the issues for selected cardiac biomarkers and their applications in the future. 535.8
45	Diatoms in Photonics and Plasmonics: Characteristics and Applications Alvarez, Christine January 2016 (has links) We have investigated some of the many photonic and plasmonic properties of the diatom Coscinodiscus wailesii. We start by showing that when diatom frustules are converted to high-index magnesium silicide while maintaining their structure, they exhibit a broad (1μm - 2μm) photonic bandgap that varies in wavelength according to the position and angle of the incident light on the frustule. We then demonstrate the use of the micro and nanostructured silica diatom frustule as a low-cost, easily prepared substrate for surface-enhanced Raman spectroscopy by coating the frustule in 25 nm of silver and a monolayer of thiophenol. Some potential applications of diatoms to water quality measurements are suggested, and steps are taken to image a diatom frustule and chloroplasts simultaneously in vivo using rhodamine 19 dye and fluorescence microscopy. We propose future experiments that could ascertain whether there is any biological effect of the light filtering properties of the diatom frustule, and put forth some suggestions as to how to influence the morphology and photonic properties of the frustule via chemical contaminants in the diatom seawater growth medium. Diatom Fluorescence microscopy Photonic crystal SERS Surface enhanced Raman Optical Sciences Coscinodiscus wailesii
46	A CHARACTERIZATION OF THE OXIDATION-REDUCTION CYCLE AND SURFACE MORPHOLOGY OF ELECTROCHEMICAL SURFACE ENHANCED RAMAN SCATTERING Tuschel, David Daniel, 1957- January 1986 (has links) No description available. Surface chemistry. Surface roughness. Raman effect, Surface enhanced. Oxidation-reduction reaction.
47	Φασματοσκοπικός έλεγχος αποδέσμευσης (νανο)ϋλικών ενσωματωμένων σε βιοπολυμερή Ανδρικάκη, Σόνια 04 February 2014 (has links) Η παρούσα διατριβή εξειδίκευσης αποτελεί το προοίμιο μιας μακρόπνοης εμπλοκής του εργαστηρίου υλοποίησής της στη μελέτη ενδεχόμενης μετανάστευσης ουσιών που χρησιμοποιούνται ως ενισχυτικά φραγής ή/και ως χημικοί αισθητήρες σε βιοπολυμερικές συσκευασίες τροφίμων και αποδέσμευσής τους σε προσομοιωτές τροφίμων. Στο πλαίσιο αυτό, η εργασία αυτή αποτελεί μια προσπάθεια ανάδειξης της μεθόδου επιφανειακής ενίσχυσης της σκέδασης Raman (Surafce Enhanced Raman Scattering) ως κατάλληλης για τον ποσοτικό προσδιορισμό μικρού μοριακού βάρους ενώσεων που ενδεχομένως αποδεσμεύονται σε υδατικά διαλύματα ή/και συγκεκριμένους προσομοιωτές τροφίμων. Η μελέτη εστιάστηκε στην ελεγχόμενη αποδέσμευση φαρμακευτικών ουσιών από μια βιοπολυμερική μήτρα κυρίως κατά το πρώιμο στάδιο της μελέτης και τις παραμέτρους που επηρεάζουν το φαινόμενο αυτό. Βασικός στόχος της μελέτης ήταν η κατά το δυνατό μείωση του ορίου ανίχνευσης με SERS της αποδεσμευόμενης ουσίας με την εμβάπτιση της βιοπολυμερικής μήτρας που την εμπεριέχει σε πρότυπα υδατικά διαλύματα. Πραγματοποιήθηκε μια διεξοδική μελέτη των υποστρωμάτων που χρησιμοποιούνται στο SERS και συγκεκριμένα του νανοκολλοειδούς αργύρου (Ag). Για τον σκοπό αυτό, πραγματοποιήθηκαν πειράματα τα οποία έδειξαν την εξάρτηση της έντασης SERS από τη συσσωμάτωση των υποστρωμάτων Ag συναρτήσει του χρόνου και του παράγοντα συσσωμάτωσης, NaCl. Η εφαρμογή του SERS σε μελέτες ουσιών εξαιρετικά χαμηλών συγκεντρώσεων αναδεικνύεται ως ένα πολύ ενδιαφέρον πεδίο έρευνας. Επίσης, ως πρότυπο πείραμα, παρουσιάζεται μεθοδολογία μελέτης με την τεχνική SERS της αποδέσμευσης του αντικαρκινικού φαρμάκου Μitoxantrone (ΜΤΧ) από εμπορικά ράμματα Maxon. Για το σκοπό αυτό, παρασκευάστηκαν πολυμερικά υμένια με εγκλωβισμένη τη δραστική ουσία και η μελέτη της αποδέσμευσης της σε νερό και PBS (phosphate buffered saline) πραγματοποιήθηκε με SERS και UV-Vis, αντίστοιχα. Η φασματοσκοπία UV-Vis χρησιμοποιήθηκε συμπληρωματικά. Στηριζόμενοι στη μεθοδολογία που αναπτύξαμε εξάγαμε ποσοτικά αποτελέσματα από τρία διαφορετικά εργαστηριακά δείγματα, τα οποία προήλθαν από ανάμιξη εμπορικών ραμμάτων Maxon με 1% κ.β. MTX: (α) στην άμορφη φάση έπειτα από ταχεία ψύξη του τήγματος, (β) στην ημικρυσταλλική φάση με σχετικά χαμηλό ποσοστό κρυσταλλικότητας, που λάβαμε έπειτα από ανόπτηση της άμορφης φάσης για περιορισμένο χρόνο στη θερμοκρασία κρυστάλλωσης και (γ) σε μια επίσης ημικρυσταλλική φάση με αρκετά μεγάλο ποσοστό κρυστάλλωσης (όσης και τα εμπορικά ράμματα). Τα αποτελέσματα δείχνουν πως υπάρχει συσχέτιση μεταξύ κρυσταλλικότητας και αποδέσμευσης του φαρμάκου, με τα μικρότερα ποσά αποδέσμευσης στην περίπτωση του άμορφου δείγματος. Αυτό που παρατηρήθηκε στα πρώιμα στάδια της αποδέσμευσης από τις μετρήσεις SERS φαίνεται να επαληθεύεται από αντίστοιχα αποτελέσματα σε μεταγενέστερα στάδια αποδέσμευσης που λάβαμε με εφαρμογή της συμβατικής τεχνικής απορρόφησης ορατού – υπεριώδους (UV-Vis). Ωστόσο, οι ποσοτικές μετρήσεις με τη χρήση του SERS σε πολύ μικρές συγκεντρώσεις έδειξαν μεγαλύτερη ανιχνευτική ευαισθησία σε σχέση με αυτές που πραγματοποιήθηκαν με την απορρόφηση UV-Vis. Συμπερασματικά, το SERS δείχνει ικανό στον ποσοτικό προσδιορισμό ενεργών ουσιών που αποδεσμεύονται από βιοσυμβατά πολυμερικά συστήματα μεταφοράς δραστικών ουσιών σε πολύ μικρές συγκεντρώσεις. / This thesis of specialization is the precursor of a long-term involvement of the laboratory of Applied Molecular Spectroscopy of FORTH/ICE-HT in the implementation of the study of the migration of substances used as barrier and/or as chemical sensors in biopolymer based food packaging and their release into food simulants. In this context, this work attempts to highlight the method of surface enhanced Raman scattering (SERS) as appropriate for quantifying low molecular weight compounds that may be released in aqueous solutions and/or specific food simulants. The study focused on the controlled release of pharmaceuticals from a biopolymeric matrix mainly during the early stage of the study and the parameters affecting this phenomenon. The main objective of the study was to reduce SERS detection limit of the released substance by emerging the substance-incorporated biopolymeric matrix in standard aqueous solutions. In this context, we developed methods to maximize SERS enhancement and consequently reduce the limit of detection of an active substance, Mitoxantrone (MTX). This was achieved by a thorough study of the substrates used in SERS, namely nanocolloidal silver (Ag) suspensions. For this purpose, we contacted experiments which show the dependence of the SERS intensity on the aggregation of Ag substrates as a function of both time and the aggregating agent, NaCl. Also, as a standard experiment, present SERS methodology was applied in the study of the release of the anticancer drug Mitoxantrone (MTX) from commercially available sutures, Maxon. For this purpose, polymeric films prepared with the encapsulated active substance were immersed either in water or/and in PBS (phosphate buffered saline) and the release of MTX was probed by both SERS and UV-Vis. Based on the developed methodology we obtained quantitative results from three different laboratory samples produced by mixing commercial Maxon sutures with 1 wt% MTX: (a) an almost completely amorphous mixture produced by quenching from the melt, (b) a semi-crystalline one possessing low crystallinity that was produced by annealing the amorphous sample at the temperature close to the crystallization one and (c) a semi-crystalline one possessing high crystallinity similar to the commercial product. The results indicate a correlation between crystallinity and drug release rate; the more amorphous the sample is the less quantity of the drug is released. SERS was able to probe the active agent at the early state of release; UV-Vis has supported these results at a later state of the release process. In conclusion, SERS may enable low concentration quantitative assessment of controlled release of drugs from biopolymer-based delivery systems. Νανοϋλικά Συσκευασίες τροφίμων Βιοπολυμερή Αποδέσμευση 664.024 Nanomaterials Food packaging Biopolymers
48	Investigating the use of protein-targeted pegylated gold nanoparticle probes in the surface-enhanced Raman spectroscopy of cells Shaw, Conor 02 January 2015 (has links) Currently, it is very challenging to accurately monitor the response of patients to radiation therapy over the course of treatment. The initial response to ionizing radiation occurs in the cells at a molecular level, and effects of the response are not typically noticeable on short time scales. Surface-enhanced Raman Spectroscopy, or SERS, has proven to be a useful technique in the analysis of tissues and cells at a molecular level. Specifically, the use of targeted SERS probes allows for the detection of specific proteins on the cell membrane. The work presented here looks to assess the feasibility of using targeted SERS probes and two-dimensional SERS microscopy to measure the response of tumour cells to ionizing radiation, by identifying changes in the distribution of membrane proteins following exposure to clinically relevant doses of ionizing radiation (≤ 60Gy). Two different types of targeted SERS probes were investigated, based on the work of Grubisha et al. ([1]; Type I) and Qian et al. ([2]; Type II), both containing a gold nanoparticle core. In a simplified cellular experiment, biotin on the surface of biotinylated OVCAR5 cells was targeted with streptavidin-SERS probes, and the Type-II SERS probes showed the most promising results. However, SERS maps still provided less characteristic spectral signal than expected, and challenges remain in the development of a reproducible cellular imaging technique. Despite difficulties in cellular imaging, the functionality of the Type-II SERS probes was verified separately, using gold slides with a biotin monolayer in place of cells. Following verification, the SERS intensities provided by differently sized clusters of the SERS probes were characterized. To begin, both SERS maps and scanning electron microscope (SEM) images of gold slides were acquired after incubation with Type-II SERS probes for multiple times (1hr, 2hr, 3hr, 12hr). Data analysis of the SEM images provided a measure of the physical distribution of the SERS probes on the surface of the slide, while analysis of the SERS maps provided information about the spectral distribution of the probes. By relating the information provided by the SEM images and SERS maps, a simple polynomial relationship between SERS intensity and the number of clustered SERS probes providing the enhancement was determined, providing a framework for quantifiable SERS imaging. Finally, an independent experiment was devised to ensure that exposure to clinically relevant doses of ionizing radiation would affect the ability of the targeted protein to bind to SERS probes, thus leading to measurable differences in SERS maps of irradiated and unirradiated cells. A series of experiments utilizing the enzyme-linked immunosorbant assay (ELISA) was performed to test the effect of ionizing radiation-induced damage on the ability of streptavidin to bind to biotin, and the results confirmed that a noticeable reduction in binding could be detected at doses as low as 10 Gy. The results of this work demonstrate that following the development of a suitable cell/SERS probe incubation technique, Type-II SERS probes would be appropriate for use in quantifiable SERS imaging. Also, it is suggested that a measurable change in protein function will be present when comparing SERS maps of control cells to those of cells irradiated to clinically relevant doses. / Graduate Surface-enhanced Raman spectroscopy SERS Nanoparticles Ionizing Radiation-induced damage Cancer Tumour cells SERS enhancement
49	Absorção Óptica Aumentada de Elipsóides Metálicos Cobertos com uma Camada Orgânica na Região do Infravermelho / Surface Enhanced Infrared Absorption of Light by Metalic Elipsoids Covered with an Organic Layer. Muniz, Eduardo Perini 24 January 2003 (has links) Foi estudada a absorção da luz por partículas metálicas esferoidais, filmes metálicos finos e filmes metálicos finos cobertos com uma camada de material orgânico nas regiões espectrais do visível e do infravermelho. A dependência das características dos picos de absorção de luz por partículas metálicas para com a forma e o tipo de material foi analisada. Modelos para o estudo de filmes metálicos finos foram deduzidos, a aproximação por rede de dipolos foi escolhida e resultados obtidos com o uso desta teoria foram comparados com resultados experimentais e com resultados teóricos encontrados na literatura. Um modelo para o estudo de filmes metálicos cobertos com uma camada de material orgânico foi proposto e sua consistência e utilidade foram testadas. Computações foram efetuadas usando o programa Maple. / The absorption of light in the visible and infrared spectral regions by spheroidal metal particles, thin metallic films and thin metallic films covered with organic layers was studied. The dependence of the intensity and frequency of the peaks of absorption of light by metal particles with the shape and the kind of metal was studied. Models for the study of thin metallic films were deduced, the net dipole approximation is chosen and results obtained with it are compared with experimental results and with results obtained with a Maxwell-Garnett type theory. A model for the study of metallic films covered with organic layers was proposed and tested for consistency and utility. Computations were carried out using Maple.
50	Systems redox biology analysis of cancer Johnston, Hannah Elizabeth January 2018 (has links) The Warburg effect describes the survival advantage of cancer cells in that they can proliferate under low oxygen/hypoxic conditions via a less efficient pathway known as glycolysis. It has not yet been documented at which point, in an oxygen gradient, phenotypic changes occur. Measuring the intracellular redox potential (IRP) and its impact on cellular dynamics would provide greater insight into how disruption of redox homeostasis caused by changes in oxygen concentration leads to aberrant cell signalling and diseases such as cancer. Current techniques in measuring IRP include redox-sensitive fluorescent proteins such as roGFP which is glutathione-specific. Measuring the concentration of one redox couple is, however, not an accurate representation of IRP as it does not necessarily inform about the state of other redox couples. Furthermore, fluorescent biosensors can suffer from photobleaching and may interact with other oxidants. The IRP was measured, in this work, using our newly developed novel-class of surface enhanced Raman scattering nanoparticles which can quantitatively measure the redox potential of cells in vitro. A 'homemade' device was created to keep the cells under fixed pO2 whilst obtaining measurements. The IRP was correlated with the transcriptomic and downstream metabolic profiles of MCF7 breast cancer cells, under perturbed pO2, using 1H NMR spectroscopy (NMR), mass spectrometry (MS) and RNA-sequencing. Discriminatory metabolites were all associated with energy and glucose metabolism. Discriminatory microRNAs were all affiliated with the hallmarks of cancer; the regulation of some is controlled by transcription factors containing redox-sensitive motifs in their DNA binding domains. Multivariate analysis techniques were used to analyse the different data streams in a holistic way that allows the correlation of redox potential, metabolism and transcription.

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