High-Speed Time-Difference Circuits

Li, Shuo

01 January 2013

This thesis presents time difference (TD) circuits that are important for measuring fluorescence lifetime, building LIDAR systems, and optimizing digital systems. The contribution of this thesis is to present a systematic organization of TD circuits and to present novel designs for digital-to-time conversion (DTC) and time-to-digital conversion (TDC). Four basic time difference circuits are presented: TD adder, arbiter, time-difference MUX, and time-difference memory. Specifications, symbols, and multiple circuit implementations are presented for each block. Then the basic blocks are combined to form two compound blocks: DTC and TDC. Novel designs are presented for both blocks along with detailed simulation results. The DTC was fabricated in TSMC’s 0.35um high-voltage process. A printed circuit board was designed to interface the DTC chip to a computer and test instruments. The DTC demonstrated 80ps resolution.

Digital-to-Time Converter

Time-to-Digital Converter

Fluorescence Lifetime Imaging

Biomedical

Electrical and Electronics

INVESTIGATING PROTEIN AGGREGATION IN NEURODEGENERATIVE DISEASES USING FLUORESCENCE LIFETIME IMAGING MICROSCOPY

Paula-Marie Ivey (20379645)

04 December 2024

<p dir="ltr">Alpha-synuclein protein aggregation, involving the recruitment of native monomeric protein by fibrillar seeds, has been proposed as the event that precipitates Parkinson’s disease pathology. However, the specific molecular processes underlying this aggregation are not fully understood, mirroring the limitations seen in understanding the etiology of other prion-like neurodegenerative diseases. There are proposed mechanisms connecting alpha-synuclein aggregation to endocytic processes involving the escape and retention of fibrillar seeds. Additionally, intracellular protein-membrane interactions may also play a role. However, effective methods to probe the evolution of aggregation states with sufficient sensitivity in the context of these cellular processes are lacking.</p><p dir="ltr">A time-gated fluorescence lifetime imaging microscope system was developed to monitor the evolution of seeded aggregation in primary neurons in the context of endocytic processes that have yet to be well explored. This aggregation monitoring was enabled by measuring self-quenching-induced fluorescence lifetime changes of alpha-synuclein-fluorophore fusion proteins, providing a sensitive aggregate detection method. Results from this work demonstrate that both escape and retention of fibrillar seeds from endocytic compartments are seeding pathways for aggregation. In addition, a novel imaging scheme was developed using fluorescence lifetime measurements of tethered Förster resonance energy transfer (FRET) reporters to probe membrane-induced alpha-synuclein aggregation. Using this method in neurons enabled deciphering of which intracellular membrane surfaces likely play a role in alpha-synuclein aggregation.</p><p dir="ltr">This work used fluorescence lifetime imaging to enable insights into the underlying mechanisms of alpha-synuclein aggregation in neurons. This has broader applications to other prion-like neurodegenerative diseases. These insights further our understanding of neurodegenerative disease etiology and can inform more effective treatments. Additionally, an approach to noise estimation that enables accurate extraction of fluorescence lifetime information in the presence of substantial detector noise is presented. This will enable longer-term multi-time-point fluorescence lifetime imaging of aggregation in neurons.</p>

fluorescence lifetime imaging (FLIM)

neurosciences

neurodegenarative disease

alpha-synuclein aggregation

Parkinson's disease

Untersuchung der Fluoreszenzlebensdauer von BODIPY-Farbstoffen in Polymerlösungen und Polymerschmelzen

Fröbe, Melanie

09 December 2016

Die vorliegende Arbeit befasst sich mit dem Fluoreszenzverhalten, speziell der Fluoreszenzlebensdauer, von BODIPY-Farbstoffen in Polymerlösungsmittelgemischen mit unterschiedlicher Polymerkonzentration sowie in Polymerfilmen bei unterschiedlichen Temperaturen. Dazu werden zunächst die Synthesen von vier verschiedenen BODIPY-Fluorophoren mit einem Phenylsubstituent in meso-Position aufgezeigt. Dahingehend wurde eine Synthesestrategie entwickelt, um eine einzelne Polypropylenkette an diese Farbstoffsysteme anzubinden. Dabei soll aufgezeigt werden, dass die Länge des Substituenten am Phenylsubstituenten am chromophoren Kern maßgeblich das Fluoreszenzverhalten der Sonde beeinflusst. BODIPY-Farbstoffe mit makromolekularen Substituenten zeigen im Vergleich zu Derivaten mit kürzeren Substituenten eine deutlich größere Fluoreszenzlebensdauer und eine nicht so stark ausgeprägte Temperaturabhängigkeit. Mehrere Zeitkomponenten der Fluoreszenzlebensdauer der Fluorophore in reinem Polypropylen bzw. deren Mehrkomponentensystemen (Polyethylenpropylen Copolymer oder Kraton) im Vergleich zu reinen Lösungsmitteln (Toluol oder Dodecen) deuten dabei auf lokale Heterogenitäten im Material hin. Außerdem wird der Einfluss der Viskosität auf die Fluoreszenzlebensdauer in Polymer/Lösungsmittelgemischen mit unterschiedlicher Polymerkonzentration untersucht und die Rolle des Wasserstoffbrückennetzwerkes zwischen den Polymer- und Lösungsmittelmolekülen diskutiert.

BODIPY

Fluoreszenzlebensdauer

Polymer

Polymerkonzentration

Polymerlösungen

Polymerschmelzen

BODIPY

fluorescence lifetime

polymer

polymer concentration

viscosity

temperature

polypropylene

polymer solutions

polymer melts

ddc:541

Polymere

Farbstoff

Viskosität

Temperatur

Fluoreszenz

Polypropylen

High-sensitivity spectral fluorescence lifetime imaging for resolving spectroscopically overlapping species

Crawford, Justin Lee

01 August 2009

The capability to resolve the contributions from spectroscopically overlapping fluorophores has enabled significant breakthroughs in cellular imaging. However, commercial microscopes for this purpose use analog light detection with least squares curve-fitting analysis and improvements in sensitivity are needed. To this end, a microscope has been constructed with high throughput and single-photon detection capability. The fluorescence is separated through use of a prism spectrometer or a series of dichroic mirrors into four spectral bands and detected using four single-photon avalanche diode (SPAD) detectors, which provide high-quantum efficiency in the red spectral region. The detectors are connected to a time-correlated single photon counting module to provide sub-nanosecond temporal resolution for distinguishing fluorophores with different fluorescence lifetimes. Maximum-likelihood (ML) methods have been developed for analyzing the temporally and spectrally resolved photon count data from the SPADs to find the contributions from different fluorescent species and from background. Commercially available SPADs exhibit a count-rate dependent time shift in the impulse response function, and hence the instrument incorporates custom modified SPADs with improved timing stability. Nevertheless, there is still some time shift, and hence the ML-analysis has been extended to include this as an adjustable parameter for each individual SPAD. Monte Carlo simulations have also been developed to enable studies of the number of photons needed to resolve specific fluorophores.

spectral fluorescence lifetime imaging

maximum likelihood

confocal microscopy

interference filters

single-photon avalanche detector

Biological and Chemical Physics

Optics

High-sensitivity spectral fluorescence lifetime imaging for resolving spectroscopically overlapping species

Crawford, Justin Lee

01 August 2009

The capability to resolve the contributions from spectroscopically overlapping fluorophores has enabled significant breakthroughs in cellular imaging. However, commercial microscopes for this purpose use analog light detection with least squares curve-fitting analysis and improvements in sensitivity are needed. To this end, a microscope has been constructed with high throughput and single-photon detection capability. The fluorescence is separated through use of a prism spectrometer or a series of dichroic mirrors into four spectral bands and detected using four single-photon avalanche diode (SPAD) detectors, which provide high-quantum efficiency in the red spectral region. The detectors are connected to a time-correlated single photon counting module to provide sub-nanosecond temporal resolution for distinguishing fluorophores with different fluorescence lifetimes. Maximum-likelihood (ML) methods have been developed for analyzing the temporally and spectrally resolved photon count data from the SPADs to find the contributions from different fluorescent species and from background. Commercially available SPADs exhibit a count-rate dependent time shift in the impulse response function, and hence the instrument incorporates custom modified SPADs with improved timing stability. Nevertheless, there is still some time shift, and hence the ML-analysis has been extended to include this as an adjustable parameter for each individual SPAD. Monte Carlo simulations have also been developed to enable studies of the number of photons needed to resolve specific fluorophores.

spectral fluorescence lifetime imaging

maximum likelihood

confocal microscopy

interference filters

single-photon avalanche detector

Biological and Chemical Physics

Optics

Transient fluorescence spectroscopy and laser induced fluorescence lifetimes of terbium doped dipicolinic acid

Makoui, Anali

01 June 2007

We have investigated the use of deep UV laser induced fluorescence for the sensitive detection and spectroscopic lifetime studies of terbium doped dipicolinic acid (DPA-Tb) and used this to study the optical characteristics of DPA which is a chemical surrounding most bacterial spores. Background absorption spectra, fluorescence spectra, and Excitation Emission Matrix (EEM) spectra were made of the DPA-Tb complex, using both fixed 266 nm wavelength and tunable (220 nm -- 280 nm) UV laser excitations. Of importance, the fluorescence lifetimes of the four main fluorescence peaks (488 nm, 543 nm, 581 nm, and 618 nm) of the DPA-Tb complex have been measured for the first time to our knowledge. The lifetimes of all the fluorescing lines have been measured as a function of DPA-Tb concentration, solvent pH, and solvent composition, including that for the weakest fluorescing line of DPA-Tb at 618 nm. In addition, a new spectroscopic lifetime measurement technique, which we call "Transient Fluorescence Spectroscopy" was developed. In this technique, a weak, quasi-CW, amplitude modulated UV laser (8.5 kHz) was used to measure the lifetimes of the fluorescence lines, and yields insight into energy transfer and excitation lifetimes within the system. This technique is especially useful when a high power laser is not either available or not suitable. In the latter case, this would be when a high power pulsed deep-UV laser could produce bleaching or destruction of the biological specimen. In addition, this technique simulated the excitation and fluorescence emission of the DPA-Tb using a 4-level energy model, and solved the dynamic transient rate equations to predict the temporal behavior of the DPA-Tb emitted fluorescence. Excellent agreement between the experiments and the simulation were found. This technique has the potential to provide a more accurate value for the fluorescence lifetime values. In addition, with the use of asymmetric excitation waveforms, the dynamic transient rate equation analysis may allow for detailed studies of selected transfer mechanisms in a wide range of other spectroscopic applications including rare-earth solid-state lasing materials and biological samples.

Laser induced fluorescence spectroscopy

Fluorescence lifetime

Bacteria spore detection

Excitatin emission matrix spectra

American Studies

Arts and Humanities

Transfert d'énergie engendré par plasmon et imagerie de super-résolution en champ proche de milieux nano-structurés / Plasmon-mediated energy transfer and super-resolution imaging in the near field of nanostructured materials

Bouchet, Dorian

27 November 2017

Dans cette thèse, nous associons mesures expérimentales et modélisation des données pour étudier l'émission spontanée d'émetteurs fluorescents en environnement nano-structuré. Le mémoire est organisé en deux parties.Dans la première partie, nous étudions le transfert d'énergie entre émetteurs fluorescents en environnement plasmonique et sur des distances micrométriques. Pour commencer, nous caractérisons le transfert d'énergie entre deux ensembles d'émetteurs situés en champ proche d'une surface d'argent. Nous déterminons ainsi la dépendance en distance du taux de transfert d'énergie sur des distances micrométriques. Nous couplons ensuite une boite quantique et une bille fluorescente à un nano-fil d'argent et nous étudions le transfert d’énergie entre ces deux émetteurs, distants de plusieurs micromètres. Nous démontrons notamment le clignotement corrélé de ces deux émetteurs grâce à l'étude de la fonction de corrélation de leur intensité de fluorescence.Dans la seconde partie, nous sondons les variations spatiales de densité locale d'états électromagnétiques induites par des environnements nano-structurés grâce à différentes techniques de microscopie à super-résolution. A l'aide d'un microscope à balayage, nous réalisons tout d’abord une étude en trois dimensions de l’interaction de champ proche entre une bille fluorescente et différentes antennes en silicium. Nous introduisons ensuite une technique stochastique permettant de déterminer expérimentalement la position et le taux d'amortissement de molécules uniques photo-activées, avec une précision de localisation de l'ordre de 10 nm. Enfin, nous utilisons l'information de Fisher afin d'estimer les bornes inférieures de l'erreur type des estimations de positions et de taux d'amortissement réalisées dans le cadre de mesures sur molécules uniques. / In this thesis, we perform experimental measurements and data modelling to investigate spontaneous emission of fluorescent emitters in nanostructured environments. The manuscript is organised into two main parts.In the first part, we study micrometre-range energy transfer between fluorescent emitters in plasmonic environments. First of all, we characterise plasmon-mediated energy transfer between ensembles of fluorescent emitters located in the near field of a silver film. We thus determine the distance dependence of the energy transfer rate over micrometre distances. We then couple a single quantum dot and a fluorescent nanobead to a silver nanowire and we study evidences of the energy transfer between the two emitters, separated by several micrometres. We notably demonstrate a correlated blinking of the two emitters through the study of the correlation function of their fluorescence intensity.In the second part, we probe sub-wavelength spatial variations of the local density of electromagnetic states induced by nanostructured environments by means of different super-resolution microscopy techniques. To start with, we perform a three-dimensional study of the near-field interaction between a fluorescent nanobead and different silicon nanoantennas using a scanning-probe microscope. We then introduce a stochastic technique to experimentally determine the position and the fluorescence decay rate of single photo-activated molecules, with a localisation precision of the order of 10 nm. Finally, we use the Fisher information to estimate lower bounds on the standard errors on position and decay rate estimates performed in the context of single-molecule microscopy.

Plasmon de surface

Durée de vie de fluorescence

Champ proche

Antenne diélectrique

Molécule unique

Information de Fisher

Surface plasmon

Fluorescence lifetime

Near field

Dielectric antenna

Single molecule

Fisher information

530

Etude de la spore de Bacillus subtilis : caractérisation des structures impliquées dans sa résistance / Study of Bacillus subtilis spore's : characterication of stuctures implied in its resistance

Loison, Pauline

10 October 2013

La spore bactérienne est une forme microbienne multicouche extrêmement résistante aux perturbations environnementales. Cette résistance est notamment liée à sa structure unique qui est particulièrement peu perméable et compacte. Ce travail de thèse a pour but d’identifier et de caractériser les structures sporales impliquées dans ces propriétés. Des méthodes d’investigations globales comme la RMN ou l’anisotropie de fluorescence ont permis de montrer que le cortex des spores de Bacillus subtilis est modifié par la température, pour des valeurs proches de celle de l’activation de la germination. Ceci aura pour conséquence de modifier l’accès à la membrane interne. Un outil d’étude à l’échelle de la spore, l’imagerie en temps de vie de fluorescence (FLIM) couplé à l’utilisation d’un rotor moléculaire, a également été mis au point. Cet outil a permis de mettre en évidence que la membrane interne de B. subtilis possède une très forte viscosité, environ deux fois plus importante que celle de la membrane d’une cellule végétative. Cette viscosité n’est modifiée par la température qu’au-delà de 65 °C, correspondant également à l’activation de la germination. Une perturbation connue pour modifier l’intégrité de la structure de la spore a également été étudiée : l’éthanol couplé à une température importante (65 ou 70°C). Ce traitement est responsable d’une perméabilisation et d’une inactivation des spores. L’éthanol conduit notamment à l’altération de la membrane interne, dont la viscosité et la perméabilité sont modifiées. Ces résultats apportent de nouvelles données pour la compréhension des mécanismes responsables de l’inactivation des spores. Ils permettent d’envisager des applications, pour lesquelles une maitrise des modifications structurales est nécessaire, comme la microencapsulation. / The bacterial spore is a multilayer microbial form which is extremely resistant to environmental perturbations. This resistance is especially due to its unique structure which is particularly compact and weakly permeable. This work aims to identify and characterize the spore structures involved in these properties. Overall investigation methods, such as NMR and fluorescence anisotropy, have shown that the cortex of Bacillus subtilis spores is modified by temperature for level similar to that of the activation of germination. This will result in changes to the access to the inner membrane. A tool at the spore’s scale, the fluorescence lifetime imaging microscopy (FLIM) in conjunction with the use of a molecular rotor, has been set up. This tool allowed demonstrating that inner membrane of B. subtilis has a very high viscosity, about two times greater than that of the membrane of a vegetative cell. This viscosity is changed by temperature near 65 °C, which corresponds to activation of germination. A stress known to modify the structural integrity of the spore has also been studied: ethanol combined with significant temperature (65 ou 70 °C). This treatment is responsible for inactivation of spores in parallel with their permeabilization. Ethanol especially leads to alteration of the inner membrane for which the viscosity and permeability are changed. These results provide new understanding of mechanisms implicated in spores’ destruction. They allow considering some new applications, for which it is necessary to control structural changing, for example microencapsulation.

Spores de Bacillus subtilis

Imagerie en temps de vie de fluorescence

Membrane interne

Cortex

Ethanol

Bacillus subtilis spores

Fluorescence lifetime imaging

Inner membrane

Cortex

Ethanol

660.6

579

Hodnocení doby života a změn konfokální mikroskopií / Realisation of method for fluorescence lifetime and spectral changes evaluation using advanced confocal microscopy techniques

Rúbal, Radek

January 2015

Content is focused on fluorescence lifetime imaging techniques. Fluorescence lifetime is computed from data acquired with using of Leica TCS SP8X confocal microscope sequential scanning. Algorithms and software for the computation, imaging and analysis of fluorescence lifetime is presented. Software is allowing both 2D and 3D imaging of fluorescence lifetime. Techniques are used for fluorescence lifetime imaging of mesenchymal cells and fibroblasts tainted with SPIO-Rhodamin complex.

Kolagenní struktury od buněčných kultur k šlaše / Collagen structures from cell culture to intact tendon

Hadraba, Daniel

January 2017

CHARLES UNIVERSITY and HASSELT UNIVERSITY / tUL Doctoral dissertation Collagen structures from cell culture to intact tendon ABSTRACT Author: Daniel Hadraba Promoters: Assoc. Prof. Karel Jelen | Charles University Prof. Marcel Ameloot | Hasselt University Co-promoters: Dr. Frantisek Lopot | Charles University Prof. Virginie Bito | Hasselt University Annotation Author: Ing. Mgr. Daniel Hadraba Doctoral thesis title: Collagen structures from cell culture to intact tendon Year: 2010 - 2017 Doctoral program: Doctor of Biomechanics at Charles University Doctor of Biomedical Science at Hasselt University / transnational University Limburg Departments: Dept. Anatomy and Biomechanics | Faculty of Physical Education and Sport | Charles University Dept. Biophysics | Hasselt University Promoters: Assoc. Prof. Karel Jelen | Dept. Anatomy and Biomechanics | Faculty of Physical Education and Sport | Charles University Prof. Marcel Ameloot | Hasselt University / transnational University Limburg Co-promoters: Dr. Frantisek Lopot | Dept. Anatomy and Biomechanics | Faculty of Physical Education and Sport | Charles University Prof. Virginie Bito | Hasselt University / transnational University Limburg Bibliography details: Pages 102 Figures 30 Tables 2 Equations 17 Keywords: tendon, collagen, crimps, orientation, aging,...