A fluorescence study of nonionic surfactants

Fraser, Douglas

January 1989

No description available.

541

Fluorescence probe techniques

Design, synthesis and evaluation of fluorescent sensors for the detection of saccharide and reactive oxygen species

Sun, Xiaolong

January 2015

Reactive oxygen species (ROS) and reactive nitrogen species (RNS), saccharide (i.e. monosaccharide, disaccharide and polysaccharide), are continuously generated, transformed and consumed in the living systems. As a consequence of their significant value towards human health in aerobic life, it is very important and has drawn much attention in the chemical and biological sensing of the species. It is our long-standing interest in the recognition of monosaccharide (e.g. glucose) through exploration of various boronate-based fluorescence probes, thus, based on the previous work, we started on the design, synthesis and evaluation of novel fluorescent chemosensors for breakthrough discoveries in the detection of saccharide and ROS selectively and specifically, which are made up of different receptors and diverse singaling fluorophores, e.g. anthracene, coumarin, fluorescein, naphthalimine. Firstly, “integrated” and “insulated” boronate-based fluorescent probes (2-naphthylboronic acid and N-Methyl-o-(aminomethyl)phenylboronic acid) have been evaluated for the detection of hydrogen peroxide in the presence of saccharides (i.e. D-fructose). In the presence of D-fructose the initial fluorescence intensity of the “insulated” system is much higher and produces a blue visible fluorescence. Based on the experimental observation above in the boronate-based systems (i.e. B-N bond protection), a new water-soluble boronate-based fluorescent probe was designed and evaluated for the detection of peroxynitrite (much stronger oxidant) in the presence of D-fructose. The enhanced fluorescence of probe when bound with D-fructose was switched off in the presence of peroxynitrite. While, other reactive oxygen/nitrogen species led to only slight fluorescence decreases due to protection by the internal N-B interaction. The interaction of probe with D-fructose not only strengthens the fluorescence signal, but also protects the boronic acid to oxidation by other ROS/RNS. Therefore, under conditions generating various ROS/RNS, the boronate-based sugar complex preferentially reacts with peroxynitrite (ONOO−). The sensor displays good “on-off” response towards peroxynitrite both in RAW 264.7 cells and HeLa cells. A new ICT (internal charge transfer) sensing system was developed for the detection of hydrogen peroxide and peroxynitrite. The probe displayed an enhanced fluorescence change when bound with D-fructose due to the prolonged N-B distance. The fluorescence intensity of the probe dropped down both in the detection of H2O2 and ONOO− which was attributed to the oxidation of arylboronic acid even though in the presence of D-fructose. Using the self-assembly of aromatic boronic acids with Alizarin Red S (ARS), we developed a new chemo/biosensor for the selective detection of peroxynitrite. Phenylboronic acid, benzoboroxole and 2-(N, N-dimethylaminomethyl) phenylboronic acid were employed to bind with ARS to form the complex probes. In particular the ARS-NBA system with a high binding affinity can preferably react with peroxynitrite over hydrogen peroxide and hypochlorite due to the protection of the boron via the solvent-insertion B-N interaction. Our simple system produces a visible naked-eye colorimetric change and on-off fluorescence response towards peroxynitrite. By coupling a chemical reaction that leads to an indicator displacement, we have developed a new sensing strategy, referred to herein as RIA (Reaction-based Indicator displacement Assay). Next, we developed a novel class of simple materials for sensing monosaccharides by the functionalization of graphene oxide (GO) with boronate-based fluorescence probes. The composite materials were characterized by atomic force microscopy, Raman spectroscopy, and UV-vis/fluorescence spectroscopy. The strong fluorescence of the fluorescence probes is quenched in the presence of GO through fluorescence resonance energy transfer (FRET). The BA@GO composite sensors formed provide a useful platform for fluorogenic detection of monosaccharides based on the strong affinity between the boronic acid receptor and monosaccharides. The BA@GO composite sensor displayed a “turn-on” fluorescence response with a good linear relationship towards fructose over a range of other saccharides. Next, new water-soluble copper (II) complex fluorescence probes were developed and evaluated for the detection of nitric oxide and nitroxyl in a physiological condition. A significant fluorescence “off-on” response displayed by using the copper (II) complex for the detection of NO and HNO (Na2N2O3 as a donor). Under pathological conditions generating various ROS/RNS, the copper (II) complex fluorescent probe preferentially reacts with NO/HNO over other reactive oxygen species. The dual-analyte recognitions of the simple, sensitive probe were further applied in living cell for the exogenous NO/HNO. In the following work, we synthesised a phosphorous-based compound for the detection of HNO which derived from Angeli’s salt in a biological condition. Significantly, it displayed a high sensitivity and selectivity toward HNO over other various ROS species, especially NO since they have a similar chemical property. The underlying mechanism was attributed to the cleavage of C-O bond induced by Staudinger Ligation.

547

Boronic acid, ROS, Fluorescence probe

Fluorescent probes of conformational signal relay in membrane environments

Lister, Francis George Alexander

January 2015

G-Protein Coupled Receptors (GPCRs) are a class of membrane-bound receptor proteins capable of relaying a biological signal across a cell membrane through a solely conformational change in their transmembrane domain. Previous work has shown that helical foldamers composed of achiral monomeric units can be used in an analogous manner to relay stereochemical information on the nano-scale through the conformational control of screw-sense preference. While this work has produced some highly successful examples of signal relay, mimicking the function of GPCRs, its reliance on screw-sense responsive NMR probes has restricted further development into membrane environments. This thesis describes the successful development of a pyrene based screw-sense responsive fluorescence probe and its subsequent use in the development of a series of membrane-based GPCR mimics. This thesis has also details the preliminary steps towards the development of light-responsive controllers of screw-sense preference for nano-scale signal relay devices.

572

Agreagační chování polysacharidů ve vodných roztocích / Aggregation Behaviour of Polysaccharides in Aqueous Solutions

Mravec, Filip

January 2008

Tato práce je zaměřena na agregační chování nativního a hydrofobně modifikovaného hyaluronanu, v různých molekulových hmotnostech a stupních substituce, ve vodném prostředí. Pro studium bylo vybráno šest fluorescenčních sond s různými vlastnostmi (Pyren; Nilská červeň; Perylen; Akridinová oranž; 6-(p-Toluidino)-2-nafthalenesulfonová kyselina; PRODAN). a výsledky získané pomocí těchto sond byly porovnány s jednoduchým anionaktivním tenzidem (Dodecylsíran sodný). U všech použité sond byly testovány jejich spektrální vlastnosti v závislosti na polaritě okolí a/nebo na koncentraci. Pro stanovení vlastností nepolárního jádra hyaluronového agregátu byly vybrány dvě sondy (Pyren, Nilská červeň). U domén byly sledovány polarita a viskozita vnitřního prostředí a jejich závislost na iontové síle a teplotě. Pro modifikované hyaluronany bylo stanoveno, že jejich kritická agregační koncentrace klesá s rostoucí molekulovou hmotností a stupněm substituce. Pro vlastní doménu platí, že její kompaktnost roste s rostoucí iontovou silou, ale klesá s rostoucí teplotou.

Charakterizace nově vyvinutých fluorescenčních sond v buněčných systémech / Characterization of newly developed fluorescence probes in cellular systems

Kadlecová, Julie

January 2021

Nanoparticles (NP) are currently a progressive area of scientific research. The possibility of synthesizing them according to the required parameters opens up possibilities for their wide use also in biomedicine. One example is a nanoparticle that can detect cellular processes, such as pH. We already know that the pH of healthy and cancer cells differs by the opposite gradient on the intracellular and extracellular side of the membrane. In this context, this work deals with the study of fluorescent silicon nanoparticles (SiNP) tested on a human keratinocyte cell line from a healthy donor (HaCaT) and from skin cancer donor (A431). Once found that even the highest concentrations of SiNP used are not cytotoxic, they can be further studied by fluorescence, confocal and super-resolution microscopy. In order to assess the pH detection properties of these SiNPs, a method for measuring intracellular pH with a fluorescent raciometric probe SNARF-1 using fluorescence spectroscopy and flow cytometry was introduced. Since the pH values of the intracellular environment are closely related to cellular metabolism, the metabolism of A431 and HaCaT cells was characterized and compared. To do this, methods for measuring analog glucose consumption (2-NBDG) and another new method for measuring real-time metabolism...

Chlorophyll Fluorescence Probe of Ultraviolet-B Photoinhibition of Primary Photoreactions in Intact Leaves

Nowak, Robert S.

01 May 1980

Damage to primary photosynthetic reactions caused by environmental stress can be assessed by measurement of chlorophyll fluorescence induction in intact leaves. This approach was applied in studies of ultraviolet-B photoinhibition of photosynthesis in Pisum sativum L. and Rumex patientia L. leaves. At ultraviolet-B dose rates insufficient to cause inhibition of net photosynthesis, changes in the magnitude of fluorescence transients did occur, which suggested direct effects on chloroplast pigments in Pisum and inhibition of photosynthetic electron transport between the photosystems in both species. Leaves of these two species subjected to a much higher dose rate had a significant reduction of net photosynthesis and changes in the magnitude of fluorescence transients that indicated partial loss of water-splitting capability and direct effects on chloroplast pigments. Ultraviolet radiation-induced changes of photosynthetic thylakoid membranes may be ultimately responsible for these disruptions of the primary photosynthetic reactions.

chlorophyll fluorescence probe

ultraviolet-b photoinhibition

primary photoreaction

intact leaves

Cell and Developmental Biology

Environmental Sciences

Plant Sciences

Molecularly imprinted chromogenic and fluorogenic receptors as optical sensor matrix

Wan, Wei

17 July 2015

Diese Dissertation befasste sich mit der Entwicklung von optischen Sensormaterialien für anionische Zielmoleküle durch die Kopplung der herausragenden Erkennungsfähigkeiten von molekular geprägten Polymere (molecularly imprinted polymers, MIPs) mit der Empfindlichkeit fluorometrischer Nachweisverfahren. In dieser Arbeit wurde dabei der direkte Einschritt-Nachweis für das Design der Sensormaterialien adaptiert. Hierbei wird eine Fluoreszenzsonde für die Signalübertragung kovalent in die Hohlräume der MIP-Matrix eingebaut. MIP-Sensormaterialien wurde in monolithischen, Dünnfilm- und Kern/Schale-Partikel-Formaten hergestellt. Die hergestellten Materialien wurden unter Verwendung unterschiedlicher Techniken charakterisiert. Die Performanz der Sensormaterialien wurde auch in Bezug auf die Sensitivität, Selektivität sowie Ansprechzeit bewertet. In dieser Arbeit wurden dabei Systeme untersucht, bei denen die Signalerzeugung sowohl auf dem „Einschalten“ als auch auf dem „Ausschalten“ der Fluoreszenz beruhte. Mit den hergestellten Materialien wurden dabei viele Ziele des Projekts erreicht. Sowohl die synthetisierten dünnen Filme als auch die Kern/Schale-Partikel zeigten eine hohe Selektivität für die geprägten Aminosäuren, auch in Bezug auf die Unterscheidung von Enantiomeren. Diese Sensormaterialien waren ebenfalls durch eine niedrige Nachweisgrenze bis 60 µM und eine schnelle Ansprechzeit von 20 Sekunden gekennzeichnet. Insbesondere die Kern/Schale-Partikel können mit verschiedenen Detektionstechniken gekoppelt werden und sind potentiell für die Entwicklung von miniaturisierten Messinstrumenten für die on-line-Detektion sowie Point-of-Care-Diagnostik (patientennahe Labordiagnostik) einsetzbar. / This dissertation derives from the DFG project aimed on preparing optical sensor material for anionic target through combing the outstanding recognition of Molecularly imprinted polymer (MIPs) and sensitive fluorescence technique. A single step direct sensing strategy is adopted to prepare the sensor material in this thesis. Here, a fluorescence probe is covalently embedded into the MIP cavity for signal transduction. MIP sensor material are prepared in forms of bulk, thin film and particles. The material is characterized using various techniques. The performance of the sensor materials is also assessed in terms of sensibility, selectivity as well response time. Both the switching on and off signaling methods are tested in this thesis. The prepared material achieves the goal of the project. Both the prepared thin film as well as core-shell particle show prominent selectivity even a strong enantioselective discrimination. These sensing materials also have low LOD to 60 µM and fast sensing response of 20 seconds. Especially the core-shell sensing particle can be coupled with various detection techniques and is potentially applicable for developing miniaturized sensing instrument for on-line detection as well as point of care diagnose.

molekular geprägten Polymere

Kern/Schale-Partikel

anionische Sensorik

Fluoreszenzsonde

Molecularly imprinted polymer

fluorescence probe

core-shell particle

anion sensor

30 Chemie

VG 6857

VK 8007

ddc:540