A whole-cell biosensor for monitoring pesticide pollution

McGinty, Pauric John

January 1996

No description available.

628.55

<em>N</em>-Acyltyramines as Substrates for Tyrosinase: Enzymatic Lag and Dopamine Precursor

Shafer, Jacob A

31 March 2009

Tyrosinase is a widespread, highly studied and important enzyme involved in processes ranging from the browning of mushrooms to roles in mammalian cancer. The enzyme suffers from a noticeable lag phase while the enzyme generates all necessary cofactors from available substrates. There have not been significant studies of the effect on lag from moving through a family of substituted substrates. This thesis reports the results of one such study using a family of N-acyltyramines. The selection of N-acyltyramines was ideal because the substrates in this reaction may be related to synthesis of N-acyldopamines, which serve many important physiological functions. It was concluded that the product formed from N-acetyltyramine is 1-acetyl-2,3-dihydro-1H-indole-6,7-dione, a quinone.

Kinetics

Enzyme

Quinone

Mushroom

Oxygen electrode

American Studies

Arts and Humanities

Evaluation of antioxidant effect of an algae extract on skin: in vitro study / Utvärdering av antioxidanteffekt av ett algextrakt på huden: in vitro-studie

Al Mustafa, Oday

January 2023

Algae extracts are used as cosmetic products and used as additives in specific foods because of their antioxidant activity. Reactive oxygen species (ROS) such as hydrogen peroxide and superoxide radicals are toxic on the skin and can be scavenged by antioxidants, which are abundant in microalgae. Antioxidant substances protect the skin against external factors such as ultraviolet light (UV). Many creams that are concerned with treating the skin have antioxidant molecules. Researchers are performing many studies to achieve natural and non-chemical skin maintenance for the skin. Conducting in vivo studies to analyze the antioxidant potential of extracts on skin needs ethical permission to recruit a specific number of people. In this study, pig ear skin was used with the help of a skin-membrane-covered oxygen electrode (SCOE) to analyze the antioxidant effect of an extract from the microalgae Chlamydomonas reinhardtii. A study proved that this method was effective in measuring other antioxidants. Hydroquinone was used as a control to see if the system worked correctly. Hydroquinone showed that it could penetrate the skin and give antioxidant activity. When the algae extract was used, the same effect as for hydroquinone could not be detected. With a 2,2-diphenylpicrylhydrazyl (DPPH) assay, the algae extract was analyzed for its antioxidant capacity, and the assay revealed a positive antioxidant effect of the extract. The spectrophotometric measurement of the amount of bioactive antioxidant molecules in the extract in different solutions suggested that the one resuspended in ethanol presented a higher amount of carotenoids and chlorophylls than the extract resuspended in an aqueous buffer. Additional research will be needed to characterize the antioxidant potential of the extract from the microalgae Chlamydomonas reinhardtii.

Algae extract

antioxidant

DPPH

microalgae

ROS

skin covered oxygen electrode

skin

Medical and Health Sciences

Medicin och hälsovetenskap

Nouveaux matériaux d’anode et cellules architecturées pour électrolyseur à haute température / Innovative anode materials and architectured cells for high temperature steam electrolysis operation

Ogier, Tiphaine

10 December 2012

Afin d’améliorer les performances électrochimiques de cellules d’électrolyse de la vapeur d’eau à haute température (EVHT), de nouveaux matériaux d’électrode à oxygène de typeLn2NiO4+δ (Ln = La, Pr ou Nd), Pr4Ni3O10±δ et La0,6Sr0,4Fe0,8Co0,2O3-δ ont été étudiés. Ces composés ont été sélectionnés pour leurs propriétés de conduction mixte électronique et ionique. Après la caractérisation de leurs propriétés physico-chimiques, les matériaux ont été mis en forme au sein de demi-cellules symétriques, en intercalant une couche d’interface fine à base de cérine entre l’électrode et l’électrolyte de zircone yttriée. Cette architecture contribue à la diminution de la résistance de polarisation de l’électrode (RP <0,1 Ω.cm2 à 800°C) et de la surtension anodique. Un modèle électrochimique a été développé afin de décrire et d’analyser les courbes de polarisation expérimentales.L’électrode présentant les plus faibles surtensions, Pr2NiO4+δ, a été sélectionnée et caractérisée au sein de cellules complètes à cermet support. En fonctionnement EVHT à800°C, une densité de courant élevée a été obtenue, de l’ordre de i = -0,9 A.cm-2 pour une tension de cellule de 1,3V et un taux de conversion d’environ 60%. / In order to improve the electrochemical performances of cells for high temperature steam electrolysis (HTSE), innovative oxygen electrode materials have been studied. The compounds Ln2NiO4+δ (Ln = La, Pr or Nd), Pr4Ni3O10±δ and La0.6Sr0.4Fe0.8Co0.2O3-δ have been selected for their mixed electronic and ionic conductivity. First, their physical and chemical properties have been investigated. Then, the electrodes were shaped on symmetrical half cells,adding a thin ceria-based interlayer between the electrode and the yttria doped zirconia-based electrolyte. These architectured cells lead to low polarization resistances (RP< 0.1 Ω.cm2 at 800°C) as well as reduced anodic over potentials . An electrochemical model has been developed in order to describe and analyze the experimental polarization curves.The electrode with the lower overpotential, i.e. Pr2NiO4+δ, has been selected and characterized into complete cermet-supported cells. Under HTSE operation, at 800°C, a high current density was measured, close to i = -0.9 A.cm-2 for a cell voltage equals to 1.3 V, the conversion rate being about 60%.

Production d’hydrogène

Electrode à oxygène

Matériaux d’anode

Oxydes nickelates

Hydrogen production

Oxygen electrode

High temperature steam electrolysis

Anode materials

Nickelates oxides

621.312 429

Synthèse et caractérisations électrochimiques de nouveaux matériaux pour anodes d'électrolyseurs à haute température / Synthesis and electrochemical characterizations of new materials for high temperature electrolyser anodes

Chauveau, Florent

15 December 2009

L’électrolyse de la vapeur d’eau à haute température (EHT) est une voie permettant de produire de l’hydrogène d’une grande pureté et avec un fort rendement, ceci sans émission de CO2. Un des verrous actuels de cette technologie est la forte surtension associée à la réaction d’oxydation des ions O2- qui se déroule à l’électrode à oxygène (anode). L’objectif de ce travail était de concevoir de nouveaux matériaux d’anode possédant des propriétés de conductivité mixte (i.e. électronique et ionique), dans le but d’obtenir des surfaces de réaction plus importantes afin de diminuer cette surtension. A cet effet, une étude comparative a été réalisée sur huit oxydes (ferrites et nickelates de terres rares). Après synthèse et mise en forme, ces matériaux ont fait l’objet de caractérisations physico-chimiques puis électrochimiques en demi-cellules symétriques sous atmosphère unique afin de déterminer ceux présentant les meilleures propriétés sous courant nul et sous polarisation anodique. Quatre composés de structure dérivée de type K2NiF4 ont ainsi été sélectionnés pour être caractérisés de façon plus approfondie en cellules complètes à électrolyte support en conditions EHT (750 - 850°C). Il a ainsi été possible d’obtenir, pour une tension de cellule de 1,3 V une densité de courant de 0,9 A/cm² à 850°C, soit près de deux fois plus qu’avec une cellule identique comportant comme matériau d’anode un composite commercial optimisé à base de LaMnO3 substitué au strontium. / High temperature steam electrolysis (HTSE) is a way to produce hydrogen with a high purity, with noteworthy efficiency and without CO2 emission. Nowadays, a blocking point concerning this technology is the high overvoltage related to the oxidation of the O2- ions occurring at the oxygen electrode (anode). The aim of this work was to design new anode materials with mixed conducting properties (i.e. electronic and ionic), in order to obtain larger reaction areas and to lessen this overvoltage. In this aim, eight compounds (ferrites and rare earth nickelates) were investigated. After synthesis and shaping, these compounds were characterized using physical, chemical and electrochemical analyses in symmetrical half cells, under single atmosphere, in order to determine which ones have the best properties under zero current and under anodic polarization. Four compounds of structure derived from K2NiF4-type were then selected to be more accurately characterized in complete electrolyte supported cells, under HTSE conditions (750 - 850°C). It was then possible to obtain, for a 1.3 V cell voltage, a current density of 0.9 A/cm² at 850°C, which is nearly two times larger than the one obtained with a same cell including a commercial composite material based on strontium substituted LaMnO3 as anode.

Production d’hydrogène

Matériaux d’anode

Electrode à oxygène

Oxydes nickelates

Hydrogen production

Anode material

Electrochemical impedance spectroscopy

Oxygen electrode

Nickelate oxides