Protein-lipid interactions in raft-exhibiting membranes probed by combined AFM and FCS / Protein-Lipid Wechselwirkung in phasenseparierenden Membranen untersucht mit Rasterkraftmikroskopie und Fluoreszenzkorrelationsspektroskopie

Chiantia, Salvatore

18 July 2008

The cellular membrane is a complex biological entity, far from being an inert assembly of protein and lipids which separates cells from the surrounding environment. A multitude of biological processes, ranging from active transport of ions into and out of the cell, to the immune response, are regulated at the level of the plasma membrane. The understanding of their molecular basis is among the central goals of modern biological research. In order to dissect the complexity of actual cell membranes, which involves a very complex network of intermolecular interactions, a “divide and conquer” strategy proves very useful. To this end, researchers try to isolate molecules from complex biological contexts to understand their function in simple model systems under controlled conditions. A variety of model membranes have thus been developed in order to gain insight into membrane processes. This approach has resulted in a deeper knowledge on how lipids and proteins interact and how these interactions govern the function of cellular membranes. In the recent past in fact, a connection has been established between the lateral structure of the plasma membrane and its biological function. Furthermore, a large range of biophysical techniques have been used to characterize protein-lipid microdomains. For example, atomic force microscopy (AFM) is a powerful technique which allows a highly detailed topographical characterization of lipid domains in physiological conditions. While AFM imaging offers an extremely high spatial resolution, up to the nanometer scale, the limited image acquisition speed (minutes) can pose a severe drawback in adequately studying fast dynamic processes. On the other hand, fluorescence based imaging techniques are much faster (10-3-100 s), but certainly lack the high spatial resolution that AFM offers. FCS in particular can also provide information about dynamic processes, like diffusion of fluorescent membrane components. For these reasons, implementing a combination of the above mentioned techniques on the same sample (e.g. cell membrane models) would prove extremely beneficial in the complete dynamic and structural characterization of molecular interactions. . The work described in this thesis can be summarized in two main points: i) the development of a novel combined approach of atomic force microscopy (AFM), laser scanning imaging (LSM), and fluorescence correlation spectroscopy (FCS) and ii) the study of the effects of ceramide in the lateral organization of model plasma membranes. We described one of the first simultaneous applications of AFM and FCS on biologically relevant systems. More specifically, model membranes showing complex phase separation were investigated with a combined approach of AFM, confocal fluorescence imaging, force measurements and FCS, based on commercially available instruments. AFM conveys information about the structural and mechanical properties of the different lipid phases. Different membrane domains can be distinguished based on height difference, elastic properties and line tension as measured by the AFM tip. Simultaneous optical measurements offer the correlation of these data in real time with the partition behavior and diffusion of fluorescent lipids and proteins. We established a clear link between the local membrane viscosity, probed by FCS, and the lipid-lipid interactions involved in line tension, probed by AFM force measurements. An example of a significant drawback circumvented by the AFM-FCS approach involves the use of AFM micromanipulation to eliminate unwanted interactions between lipid particles — similar to intra-cellular vesicles found in vivo experiments — and the membrane, which usually result in distorted FCS autocorrelation curves. Finally, the combined application of AFM and FCS on membrane-anchored proteins reconstituted in lipid bilayers has been instrumental in clarifying inconsistencies that arose in work that focused solely on either AFM or fluorescence techniques. We have shown that, in the case of proteins diffusing in the plane of the membrane, AFM can unambiguously detect only a small immobile fraction. Furthermore, since AFM detection of proteins might be facilitated by high local membrane viscosity (e.g. in ordered lipid phases), the measurement of protein partition between disordered and ordered membrane domains might be biased toward the latter. In this case, the use of FCS as a complementary technique allows a more thorough investigation and deeper understanding of the system of interest. The second part of this thesis dealt with the study of complex lipid mixtures which are used to model the putative lipid/proteins domains in cells, called “rafts”. Firstly, we proved how the combined fluorescence imaging/AFM approach is useful in general for studying supported lipid membranes and the role of lipid domains in biological contexts. We investigated the effect of environmental stress on biological membranes and the protective effects of several substances. Our experimental approach was shown to be a new valuable method to visualize the dehydration damage and its effects on the lateral organization of lipid domains. Our results demonstrated that disaccharides like trehalose or sucrose are effective in protecting lipid membranes, not only on a macroscopic scale — preserving the overall integrity of the bilayer — but also on a microscopic scale, preventing the clustering of microdomains. These phenomena are interesting in the context of biological damage to living cells which need to be stored for long time, like organs to be transplanted or blood platelets. Finally, a large section of this thesis focused on the effects of a specific lipid called “ceramide” on the lateral organization of proteins and lipids in the plasma membrane. Ceramide is produced by cells in several situations, like bacterial infections or apoptosis. As consequence of ceramide production in vivo, the local concentration and the dynamic behavior of lipids and membrane receptors are supposed to exhibit strong variations. In order to understand the molecular mechanisms responsible for these effects, we applied a combination of AFM, FCS and fluorescence imaging on simple model membranes containing ceramide. We could show for the first time that, in presence of raft-like Lo/Ld phase separation, physiological quantities of ceramide induced the formation of a highly ordered gel phase, constituted of ceramide and sphingomyelin. The enzymatic production of ceramide was monitored both in supported and in free-standing bilayers. In the second case, ceramide production was connected to selective vesicle budding from the raft-like phase. Since short-chain analogues are often used in both medical applications and biochemical research to mimic the effect of long-chain ceramides, we investigated the effect of chain-length on ceramide-induced membrane reorganization. We could show that only long-chain ceramides (C18 and C16) form highly ordered domains. Interestingly, FCS measurements indicated that the physical properties of the Lo raft-like domains are hardly affected by the presence of ceramide domains. Furthermore, the increased thickness of the Ld phase — as measured by AFM — and its higher viscosity — as measured by FCS — strongly support the hypothesis of ceramide-induced cholesterol displacement from rafts. On the other hand, short-chain ceramides showed completely different biophysical properties that lead to a destabilization of the raft domains, possibly acting as surfactants between the different lipid phases. Our findings contribute to the explanation of in vivo experiments where short-chain ceramides inhibit cell signaling by disrupting the lipid order in the plasma membrane. We have so far demonstrated that ceramide plays a fundamental role in lipid-lipid interactions. In a physiological context, it is also known to produce dramatic effects in living cells. Since a majority of the processes in vivo are thought to be governed by the activity of proteins, it is highly likely that ceramide not only affects lipid organization but also modifies protein-protein and protein-lipid interactions to produce its effects. To test this hypothesis, we reconstituted several membrane proteins in lipid bilayers containing Ld, Lo, and ceramide-rich domains. We were able to show that some membrane proteins are sorted into ceramide-rich domains. More specifically, the raft-associated proteins we tested were enriched in the highly ordered ceramide-rich domains, while the Ld-associated components were excluded from them. Furthermore, the inclusion of any membrane component in ceramide-rich domains is directly connected to a dramatic reduction of its in-plane diffusion. In an in vivo context, such a reorganization of membrane receptors might be used by the cell to alter the signaling process, for example, by i) separating raft receptors from inhibitors with lower raft affinity, ii) bringing both raft-associated receptors and raft-associated signaling molecules into contact, or iii) stabilizing the interactions between a receptor and its ligand by decreasing their diffusion coefficients. In conclusion, this thesis describes a novel combination of AFM, LSM, and FCS for the investigation of the lateral organization of biological membranes. Our results show that this approach applied on model membranes of increasing complexity is an effective tool for understanding the molecular mechanisms behind the organization of biological membranes. This report opens up new possibilities for further investigation in living cell membranes using the same methodology we have described.

AFM

FCS

membrane

lipid

rafts

AFM

FCS

Membranen

lipid

rafts

ddc:530

rvk:UH 6320

Electron multiplying CCD – based detection in Fluorescence Correlation Spectroscopy and measurements in living zebrafish embryos / Elektronenvervielfachungs-CCD-basierte Detektion in der Fluoreszenz-Korrelations-Spektroskopie und Messungen in lebenden Zebrafisch-Embryonen

Burkhardt, Markus

07 October 2010

Fluorescence correlation spectroscopy (FCS) is an ultra-sensitive optical technique to investigate the dynamic properties of ensembles of single fluorescent molecules in solution. It is in particular suited for measurements in biological samples. High sensitivity is obtained by employing confocal microscopy setups with diffraction limited small detection volumes, and by using single-photon sensitive detectors, for example avalanche photo diodes (APD). However, fluorescence signal is hence typically collected from a single focus position in the sample only, and several measurements at different positions have to be performed successively. To overcome the time-consuming successive FCS measurements, we introduce electron multiplying CCD (EMCCD) camera-based spatially resolved detection for FCS. With this new detection method, multiplexed FCS measurements become feasible. Towards this goal, we perform FCS measurements with two focal volumes. As an application, we demonstrate spatial cross-correlation measurements between the two detection volumes, which allow to measure calibration-free diffusion coefficients and direction-sensitive processes like molecular flow in microfluidic channels. FCS is furthermore applied to living zebrafish embryos, to investigate the concentration gradient of the morphogen fibroblast growth factor 8 (Fgf8). It is shown by one-focus APD-based and two-focus EMCCD-based FCS, that Fgf8 propagates largely by random diffusion through the extracellular space in developing tissue. The stable concentration gradient is shown to arise from the equilibrium between a local morphogen production and the sink function of the receiving cells by receptor-mediated removal from the extracellular space. The study shows the applicability of FCS to whole model organisms. Especially in such dynamically changing systems in vivo, the perspective of fast parallel FCS measurements is of great importance. In this work, we exemplify parallel, spatially resolved FCS by utilizing an EMCCD camera. The approach, however, can be easily adapted to any other class of two-dimensional array detector. Novel generations of array detectors might become available in the near future, so that multiplexed spatial FCS could then emerge as a standard extension to classical one-focus FCS. / Fluoreszenz-Korrelations-Spektroskopie (FCS) ist eine hochempfindliche optische Methode, um die dynamischen Eigenschaften eines Ensembles von einzelnen, fluoreszierenden Molekülen in Lösung zu erforschen. Sie ist insbesondere geeignet für Messungen in biologischen Proben. Die hohe Empfindlichkeit wird erreicht durch Verwendung konfokaler Mikroskop-Aufbauten mit beugungsbegrenztem Detektionsvolumen, und durch Messung der Fluoreszenz mit Einzelphotonen-empfindlichen Detektoren, zum Beispiel Avalanche-Photodioden (APD). Dadurch wird das Fluoreszenzsignal allerdings nur von einer einzelnen Fokusposition in der Probe eingesammelt, und mehrfache Messungen an verschiedenen Positionen in der Probe müssen nacheinander durchgeführt werden. Um die zeitaufwendigen, aufeinanderfolgenden FCS-Einzelmessungen zu überwinden, entwickeln wir in dieser Arbeit Elektronenvervielfachungs-CCD (EMCCD) Kamera-basierte räumlich aufgelöste Detektion für FCS. Mit dieser neuartigen Detektionsmethode werden Multiplex-FCS Messungen möglich. Darauf abzielend führen wir FCS Messungen mit zwei Detektionsvolumina durch. Als Anwendung nutzen wir die räumliche Kreuzkorrelation zwischen dem Signal beider Fokalvolumina. Sie ermöglicht die kalibrationsfreie Bestimmung von Diffusionskoeffizienten und die Messung von gerichteter Bewegung, wie zum Beispiel laminarem Fluss in mikrostrukturierten Kanälen. FCS wird darüber hinaus angewendet auf Messungen in lebenden Zebrafischembryonen, um den Konzentrationsgradienten des Morphogens Fibroblasten-Wachstumsfaktor 8 (Fgf8) zu untersuchen. Mit Hilfe von APD-basierter ein-Fokus FCS und EMCCD-basierter zwei-Fokus FCS zeigen wir, dass Fgf8 hauptsächlich frei diffffundiert im extrazellulären Raum des sich entwickelnden Embryos. Der stabile Konzentrationsgradient entsteht durch ein Gleichgewicht von lokaler Morphogenproduktion und globalem Morphogenabbau durch Rezeptor vermittelte Entfernung aus dem extrazellulären Raum. Die Studie zeigt die Anwendbarkeit von FCS in ganzen Modell-Organismen. Gerade in diesen sich dynamisch ändernden Systemen in vivo ist die Perspektive schneller, paralleler FCS-Messungen von großer Bedeutung. In dieser Arbeit wird räumlich aufgelöste FCS am Beispiel einer EMCCD Kamera durchgeführt. Die Herangehensweise ist jedoch einfach übertragbar auf jede andere Art von zwei-dimensionalem Flächendetektor. Neuartige Flächendetektoren könnten in naher Zukunft verfügbar sein. Dann könnte räumlich aufgelöste Multiplex-FCS eine standardisierte Erweiterung zur klassischen ein-Fokus FCS werden.

FCS

EMCCD

Fgf8

zebrafish embryos

FCS

EMCCD

Fgf8

Zebrafisch-Embryonen

ddc:530

rvk:UH 5870

rvk:WC 2600

Analyse de la dynamique du facteur de transcription HSF1 "Heat Shock Factor 1" par microscopie de fluorescence / Analysis of Heat Shock Factor dynamics using fluorescence microscopy

Herbomel, Gaëtan

19 October 2012

La majorité des études sur la dynamique des facteurs de transcription en cellules vivantes s'accordent sur une dynamique rapide. Il existe cependant quelques exceptions, comme la dynamique du facteur de transcription HSF « Heat Shock Factor », sur les chromosomes polyténiques de drosophile. Notre projet a consisté à étudier la dynamique d'HSF1 dans des cellules humaines. L'exposition des cellules à un stress tel qu'un choc thermique induit une réponse ubiquitaire et transitoire, dont la fonction est de protéger les cellules contre les effets délétères du stress. Au cours d'un choc thermique, plusieurs phénomènes se produisent : i) un arrêt global de la transcription excepté pour certains gènes tels que ceux codant pour les protéines de choc thermique (HSPs), dont l'expression est sous le contrôle du facteur de transcription HSF1. ii) une activation d'HSF1 qui se relocalise de façon rapide et transitoire sur les corps nucléaires de stress (nSBs), où il induit la transcription des séquences satellite III. Les nSBs forment un site d'activité naturellement amplifié et visible en microscopie. Nous avons utilisé deux techniques complémentaires pour étudier la dynamique d'HSF1 en cellules vivantes : le recouvrement de fluorescence après photoblanchiment (FRAP) et la spectroscopie à corrélation de fluorescence multi-confocale (mFCS), qui permet l'analyse FCS en plusieurs points simultanément. En cellules HeLa, la protéine HSF1-eGFP présente une dynamique rapide qui est significativement ralentie suite à un choc thermique. En mFCS, nous avons obtenu des constantes de diffusion de 14 µm²/s avant choc thermique et de 10 µm²/s après choc thermique. En FRAP, le temps de demi-recouvrement est de 0,2 s avant choc thermique, 2,6 s après choc thermique dans le nucléoplasme et 65 s sur les corps nucléaires de stress. Le ralentissement de la dynamique d'HSF1 s'explique par deux phénomènes : i) la formation de complexes de haut poids moléculaire, ii) une augmentation des interactions avec la chromatine. Pour mieux caractériser le changement de dynamique d'HSF1 après choc thermique, plusieurs mutants ont été analysés. Le domaine de trimérisation est indispensable pour le changement de dynamique après choc thermique, alors que le domaine de liaison à l'ADN et le domaine de transactivation n'ont que peu d'effet sur le changement de dynamique. Il ne peut donc pas être expliqué uniquement par les interactions directes à la chromatine du domaine de liaison à l'ADN, ni même par les liaisons indirectes du domaine de transactivation via d'autres protéines. La protéine HSF1 pourrait interagir de façon aspécifique avec la chromatine lors de la recherche de site de liaison, ou d'autres protéines via d'autres domaines pourraient entrainer des interactions indirectes avec la chromatine. / The majority of studies made on transcription factors dynamics on living cells agree with a fast dynamics process. However, there is some exceptions such as the dynamics of the transcription factor HSF “Heat Shock Factor” on drosophila polytenic chromosome. My project is to study HSF1 dynamics in human living cells. Cells exposure to a stress such as heat shock induces a transient and ubiquitous response that function's to protect cells against the deleterious effect of stress. During the course of a heat shock, several phenomenons take place: i) a global arrest of transcription, with the exception of some genes, such as those coding for the heat shock proteins (hsp), which expression is under the control of HSF1. ii) Activation of HSF1 that relocalize in a fast and transient way to nuclear stress bodies (nSBs), where it induces satellite III transcription. nSBs act as a natural amplification gene array, visible on microscopy. We have used two complementary techniques to look at HSF1 dynamics in living cells: Fluorescence recovery after photobleaching (FRAP) and multiconfocal fluorescence correlation spectroscopy (mFCS) that allow FCS analysis at several position simultaneously. On HeLa cells, HSF1-eGFP protein has a fast dynamics which is significantly slowed down following heat shock. On mFCS, we obtained a diffusion constant of 14 µm²/s before heat shock, and 10 µm²/s after heat shock. On FRAP, the half recovery time is 0.2 s before heat shock, 2.6 s after heat shock in the nucleoplasm and 65 s in nuclear stress bodies. HSF1 dynamics slowing down may be explain by two phenomenons: i) formation of high molecular mass complexes, ii) rise of interaction of HSF1 with chromatin. To better characterize changes in HSF1 dynamics after heat shock, several mutants have been analyzed. The trimerization domain of HSF1 is essential for dynamics changes after heat shock, while DNA binding domain (DBD) and transactivation domain (TAD) have only little effects on dynamics changes. These changes cannot only be explained by direct interaction of DNA binding domain with chromatin, neither by indirect interaction of the transactivation domain with other protein partners. HSF1 could be able to interact non-specifically with chromatin during the search for specific binding sites. Also other proteins via other domains might induce indirect binding to chromatin.

HSF1

Dynamique

FRAP

FCS

Microscopie de fluorescence

HSF1

Dynamics

FRAP

FCS

Fluorescence microscopy

570

Inverzní FCS ve výzkumu koloidních systémů / Inverse FCS in colloidal systems research

Richterová, Veronika

January 2018

This diploma thesis is focused on the study of inverse fluorescence correlation spectroscopy, especially with the regard for the usage of different fluorescent probes and different sized analysed particles. At first, the proper concentration of fluorescent probes was determined. In this concentration is the probe considered as a medium surrounding the analysed particles. Based on this concentration, which was determined as 400 M, several sets of samples were prepared. This samples contained different concentration of polystyrene particles of 100 and 500 nm diameter and multilamellar liposomes. Then, the FCS curves of samples with different fluorescent probes were measured. Fluorescein, rhodamine 6G and Atto 488 were used as fluorescent probes. As a result from experiments, it was found, that particles with 100 nm diameter cannot be analysed with none of the fluorescent probes. Inverse FCS method can be applied to systems, that contains particles with 500 nm diameter and fluorescein. Systems with rhodamine 6G have the same behaviour as typical FCS measurement. It is caused by dimerization of this probe and it cannot be used for 500 nm particles. Liposome samples can be established with iFCS method, but the results are biased by random distribution of liposomes size.

Fluorescence fluctuation studies of biomolecular interactions in solutions, biomembranes and live cells

Chmyrov, Volodymyr

January 2016

Fluorescence spectroscopy and imaging have a very broad spectrum of applicationswithin the life sciences, in particular for detection and characterization ofbiomolecular dynamics and interactions in different environments. This thesis comprisesprojects that strive to further expand the information content extracted fromthe detected fluorescence, leading to sensitive readout parameters for studies ofbiomolecular dynamics and interactions. Two major strategies are presented toachieve this aim. The first strategy is based on the expansion of the availablereadout parameters beyond the "traditional" fluorescence parameters: intensity,wavelength, polarization and fluorescence lifetime. The additional parameters arebased on blinking properties of fluorescent labels. In particular on transitions betweensinglet and triplet states, and transitions between the trans- and cis-isomersof fluorophores. Two publications in the thesis are based on this strategy (paperI and IV). The second strategy is based on the utilization of fluorescence intensityfluctuations in order to detect the oligomerization mechanisms of fluorescentlylabeled peptides and proteins. This strategy combines the intensity fluctuationanalysis and the readout of distance dependent energy transfer between fluorescentmolecules together with the correlation analysis of fluorescence from two labeledproteins emitting at different wavelengths. Another two publications presented inthe thesis are based on the second comprehensive strategy (papers II and III).The work presented in this thesis shows that the blinking kinetics of fluorescentlabels contain significant information that can be exploited by a combination of fluctuationsanalysis with distance dependent excitation energy transfer between thefluorescent molecules, or by analysis of fluorescence covariance between moleculesthat emit at different wavelengths. These fluorescence-based methods have a significantpotential for molecular interaction studies in the biomedical field. / <p>QC 20160527</p>

FCS

FCCS

Isomerization

TRAST

NMR

FRET

biomombrane

fluidity

NANOPARTICLE BEHAVIOR IN BIOLOGICAL GELS AND BIOFLUIDS: THE IMPACT OF INTERACTIONS WITH CHARGED BIOGELS AND THE FORMATION OF PROTEIN CORONAS ON NANOPARTICLES

Zhang, Xiaolu

01 January 2015

With the rapid growth of nanotechnology, situations where nanomaterials will interact with biological systems will unquestionably grow. Therefore, it is increasingly understood that interactions between nanomaterials and biological environments will play an essential role in nanomedicine. Biological polymer networks, including mucus and the extracellular matrix, serve as a filter for the exchange of molecules and nanoparticles. Such polymer networks are complex and heterogeneous hydrogel environments that regulate transport processes through finely tuned particle-network interactions. In chapters 3 and 4, we investigate the role of electrostatics on the basic mechanisms governing the diffusion of charged molecules inside model polymer networks by using fluorescence correlation spectroscopy (FCS). In chapter 3, we show that particle transport of charged probe molecules in charged hydrogels is highly asymmetric and that the filtering capability of the gel is sensitive to the solution ionic strength. Brownian dynamics simulations are in quantitative agreement with our experimental result. In chapter 4, we focus on hyperbranched cationic dendrimer macromolecules (polyamidoamine, PAMAM) which differ from probes in size, charge density and chain flexibilities. Our results show PAMAM has strongly reduced mobility in like charge gels and greatly enhanced apparent diffusivity in oppositely charged gels. Further studies with salt suggest that the oppositely charged polymer network acts as a giant counterion enhancing the mobility of PAMAM by changing its conformation to a more compacted state. Due to their large surface areas, nanomaterials in biological fluids are modified by adsorption of biomolecules, mainly proteins, to form so called “protein coronas”. These coronas ultimately define the biological identity of the nanoparticles and dictate the interactions of cells with the protein-NP complex. We have studied the adsorption of human transferrin and bovine serum albumin on the surface of sulfonated polystyrene nanoparticle. In chapter 5, we show the formation of multi-layered protein coronas and compare to established adsorption models. In addition we followed for the first time the protein binding kinetics as a function of pH and salt. Through these studies, we aim to gain quantitative knowledge of the dynamic rearrangement of proteins on engineered nanomaterials.

Nanoparticle

FCS

diffusion

PAMAM

Protein corona

Biochemistry

Biophysics

I. Hydrophobic nanoporous silica particles for biomedical applications. II. Novel approaches to two-dimensional correlation spectroscopy

Brumaru, Claudiu Stelian

01 May 2013

Many highly effective drugs display serious side-effects. To limit them, one can contain the drug in tiny containers, which are subsequently delivered toward targets inside the body. The entrapment of drug molecules prevents them from coming in contact with and thus causing damage to normal cells. Inherently, it is difficult to reach 100% efficiency of drug trapping and release when employing physical caps to seal the vehicles. Instead, we propose drug trapping inside the nanopores of hydrophobic silica particles by "hydrophobic trapping". This phenomenon is associated with the repulsive "force field" generated inside nanometer-sized hydrophobic channels that completely prevents aqueous solutions from entering the channels. We demonstrate the excellent trapping efficiency using C18-modified silica particles with 10 nm pores and the anticancer drug doxorubicin. The major challenge in using hydrophobic particles in biological applications is their tendency to cluster in aqueous media. To overcome it, we use surfactants as solubilization means. We have developed protocols that effectively solubilize the outer surface of the particles while preventing surfactant micelles from entering nanopores. Consequently, particles become well-dispersible in aqueous solutions, with the pre-loaded drug safely contained inside nanopores. Nanomaterials exhibit heterogeneity on their surfaces that impact their functional applications. Although techniques such as atomic force microscopy are great tools for studying nanomaterials with their excellent spatial resolution, they cannot probe the inner surface of porous structures. We have established a method of single-molecule ratiometric imaging that is currently the only technique able to provide the nanopolarity of adsorption sites located on the pore surface. We analyze the polarity distribution of adsorptions events for the solvatochromic probe Nile Red at the C18/acetonitrile interface and discover at least two different populations of adsorption sites. One of them corresponds to the polarity of surface silanol groups while the other sites have a polarity consistent with the environment inside the C18 organic layer. We also discover an additional adsorption mode situated at a polarity higher than exposed silanol surface that could presumably be linked to a different ionization state of the silanol groups. We are developing a method for resolving spectra of complex samples using two-dimensional hetero-correlation spectroscopy by correlating the intensity fluctuations in optical spectra to those of completely separated peaks in analytical separations. We demonstrate this methodology for fluorescence spectra and electrophoregrams of mixtures anthracene-pyrene. All the individual vibronic features that overlap in mixtures are cleanly extracted in cross-sections of the two-dimensional asynchronous spectrum.

2D-FCS

Biomedical

Drug delivery

Nanoporous

Silica

Single-molecule

Chemistry

The Use of Family and Consumer Sciences County Extension Faculty to Provide Emergency Preparedness Education in the Western Region of the United States

Beck, Sara A.

01 May 2013

As the number of people affected by natural and man-made disasters increases, so does the need for emergency preparedness education. Previous research has indicated that education and training can have an impact on the resiliency of individuals, families, and communities. The use of Extension professionals in regional and county offices across each state is an effective means for education. In this study, family and consumer sciences (FCS) county Extension faculty in the Western Region of the United States were surveyed to determine the best practices used and perceptions of the importance and their ability to educate individuals, families, and communities on emergency preparedness. Many respondents agreed on effective strategies to recruit individuals to Extension programming. Overall, FCS county Extension faculty indicated that emergency preparedness being offered was important; however, they did not think they had adequate knowledge or ability to educate on many emergency preparedness topics.

Community Programs

Emergency Preparedness

Extension

FCS

Resilience

Education

Construction of a temperature controlled sample stage and the application on single molecule study liquid crystals

Chuang, Yu-Tzu

10 February 2006

In this dissertation, we construct a temperature controlled sample stage that is compatible with high numerical aperture objective optical microscope, and perform single molecule experiments under the system. Mixing dilute fluorophore (CdSe/ZnS quantum dot, DiI, Rhodamine B) into the liquid crystal matrix (5CB), we monitor the fluorescence dynamics of the individual fluorophore at various temperature. Different from the thermodynamic states of conventional materials, those specific class of materials which we called ¡§liquid crystals¡¨ are attracted for their existence of unique liquid crystal phase, which exhibits a solid-state like higher orientation ordering, and a liquid-state like liquidity. Probe individual fluorophore allows us to monitor the nanometer length scale local structural and dynamic heterogeneity in the solid, liquid crystal and liquid phases. The operating temperature of the platform covers more than 20 oC to 40 oC range with stability much better than 0.1 oC. Quantum dot in PMMA exhibits a clear on-off blinking behavior, and the single exponential fluorescence lifetime relaxation. While in the solid phase of the liquid crystal matrix, quantum dot exhibits similar behavior, which indicates the quantum dot is confined in the matrix. However, there exists slightly difference in decay lifetime. On the contrary, in the liquid crystalline phase as well as the liquid phase, quantum dot exhibits bi-exponential relaxation behavior. Besides a similar time scale relaxation dynamics, there exists additional fast decay behavior, which is from the feasible rotational rotation in the non-rigid matrix. In particular, the anisotropic decay dynamics in the liquid crystalline phase indicates the orientation preference of the liquid crystal molecules. Fluorescence Correlation Spectroscopy (FCS) provides the information of local dynamics of various time scales. FCS results exhibit an unclear transition that crossovers several decades in time scale, which indicates the highly heterogeneity of the liquid crystal. The results of DiI exhibits different rising time in the fluorescence lifetime measurement, which implies the forming of aggregation due to the limited solubility of the DiI molecules in the liquid crystal matrix. Results of Rhodamine B exhibit a clear rotational diffusion dynamics at ~ microsecond scale and the corresponding translational diffusion dynamics at ~ mini-second scale. Moreover, the transition time scale of translational diffusion exhibits a temperature dependence. At higher temperature, it shifts to a shorter time scale.

single molecular

FCS

fluorescence lifetime

DiI

Quantum dot

Rhodamine B

Single molecule investigating Rhodamine B dilute solution at confocal and TIR configurations

Wei, Yi-chung

18 January 2007

The motion of dye molecules in the solution is highly influenced by the Brownian motion caused by the stochastic collisions with the solvents, and it results the fluorescence intensity fluctuation. The thesis study the fluorescence intensity fluctuation of dilute dye molecule (Rhodamine B) in methanol solution ( - ), under confocal and total internal reflection (TIR) microscopy configurations. Five parameters are used to probe the fluorescence characteristics: (1) the difference between confocal and the TIR configurations. The configuration influences the laser focusing area and consequently the intensity distribution. The effective focusing area in confocal configuration is an ellipsoid shape, while that of TIR configuration is a disk shape around the interface with depth 100-200 nm. It results the TIR configuration less background and higher concentration capability. (2) concentration. We control the concentration from much less than one molecule to more than one molecule in the effective focusing area, and we observe the change of burst intensity distribution. (3) the focus position. By changing the focusing position, we study the effective focusing region changes. (4) excited intensity, and (5) fluorescence correlation spectroscopy (FCS). Our results indicate that TIR configuration exhibits lower background, and is suitable to higher concentration solution. In addition, when the dye concentration in the focusing area is much less than 1, the FCS amplitude is no longer follow 1/N, but rather be proportional to N, where N is the concentration.

Fluorescence

evanescent wave

Rhodamine B