Electrochemical Studies of The Interaction Between DNA and a Compound Having Anticancer Properties.

Pouliwe, Antibe

17 August 2011

Electrochemical method has been used to study the interaction between DNA and the compound N-(3',6'-dihydroxy-3-oxospiro[isobenzofuran-1(3H),9'-[9H]xanthen]-5-yl)-N'-(2-imidazoyl)urea having anticancer properties. A DNA modified nanometer-sized gold electrode was prepared by surface modification of a bare gold electrode using cysteamine. These electrodes have been characterized using electrochemical techniques and were used to study the interaction between DNA and the compound. Our results showed an increase in the adsorption peak current and a negative shift of E1/2 in the oxidation of ferrocyanide on cysteamine and DNA modified electrodes. For the interaction between the DNA and the compound having anticancer properties, a decrease in peak current of the oxidation of ferrocyanide was observed. The decrease in peak current is attributed to the shielding of the electroactive species by the compound intercalated to the DNA from reaching the electrode surface. Therefore, only few of the electroactive species are able to reach the electrode surface.

Modified gold electrode

Self assembly monolayer

Chemistry

Physical Sciences and Mathematics

Synthesis of Electroactive Molecules Based on Benzodioxins and Tetrathiafulvalenes

Dahlstedt, Emma

January 2003

This thesis deals with the synthesis of electroactiveorganic compounds. The synthesis of ethylenedioxy-benzodioxinstri-dioxin and tetra-dioxin are described. These molecules wereprepared with the aim of creating donor molecules for cationicradical salts. The symmetric analogs of tri-dioxin,methylenedioxy-derivative and ethylenedioxy-naphthalene werealso synthesized. Three different cation radical salts with 2:1stoichiometries were obtained from tri-dioxin, whiletetra-dioxin merely provided polycrystalline materials.Tri-dioxin and tetra-dioxin were also successful as operationalmatrixes in PALDI-TOF. Tetrathiafulvalenes with the2-dialkyl-amino-1,3-dithiolium-4-thiolate mesoion asbuilding-block was also synthesized. A series of doublyalkylthiol-substituted TTFs were prepared with the aim offorming self-assembly monolayers on gold surfaces in theapplication of organic thin film field-effect transistors.Film-formation for two TTFs were studied and they providedrelatively dense packed monolayers with a discrete distance ofthe TTF moiety from the gold surface. The mesoionic compound was also for the first time used inanumpolungreaction. The electrophile obtained in situ bytreatment of mesoion with sulfuryl chloride was reacted with avariety of electron-rich aromatic compounds. From the receivedproducts three new arylthio-substituted TTFs weresynthesized. <b>Keywords:</b>Synthesis, Benzodioxin, Tetrathiafulvalene,Mesoion, Organic Conductor, Cation Radical Salt, CyclicVoltammetry, Electrocrystallization, Self-Assembly Monolayer,SAM, Organic Field-Effect Transistor, OFET

Synthesis

Benzodioxin

Tetrathiafulvalene

Mesoion

Organic Conductor

Cation Radical Salt

Cyclic Voltammetry

Electrocrystallization

Self-Assembly Monolayer

SAM

Organic Field-Effect Transistor

OFET

Substituierte Oligo(ethylenglykol)-derivate zur Oberflächenmodifizierung

Gnauck, Mandy

22 July 2009

Die Immobilisierung von Oligo(ethylenglykol)-derivaten an Oberflächen von Metallen ist ein viel versprechender Ansatz, um unspezifische Adsorptionen von Proteinen, Bakterien und Zellen zu minimieren bzw. zu verhindern. Im Mittelpunkt der Arbeit stand die Entwicklung, Darstellung, Charakterisierung sowie Applikation maßgeschneiderter, self-assembly-fähiger Moleküle, die gezielt auf TiO2- und nicht auf SiO2-Oberflächen anbinden. Die resultierenden Monoschichten (SAMs) wiesen eine Biokompatibilität sowie Biofunktionalität auf. Dazu wurden neue bisher noch nicht beschriebene Moleküle entwickelt, die auf einer Kombination von funktionalisierten Oligo(ethylenglykol)-Einheiten mit Monoalkylphosphorsäure- und Alkylphosphonsäurederivaten basieren. Diese Verbindungen konnten durch die Anwendung der Self-Assembly-Technik erfolgreich aus wässriger Lösung auf TiO2-Substrate adsorbiert werden. Die hergestellten, ultradünnen monomolekularen Schichten wurden mit verschiedenen analytischen Methoden, wie Spektroskopische Ellipsometrie, winkelabhängiger XPS und SPR-Spektroskopie charakterisiert. Durch eine gezielte Anbindung an TiO2-Oberflächen und einer stabilen Ausbildung von SAMs konnten sowohl die unspezifische Proteinadsorption zurückgedrängt bzw. verhindert, als auch eine spezifische Anbindung von ausgewählten Proteinen realisiert werden. / The surface immobilization of oligo (ethylene glycol) on metals is a promising approach to minimize or prevent non-specific adsorption of proteins, bacteria and cells. The aim of this work was the design, preparation, characterization and application of tailor-made, self-assembly molecules, which are able to adsorbed selectively on TiO2 surfaces but not on SiO2. The resulting self-assembled monolayers (SAMs) had a biocompatibility and bio functionality. For this purpose new molecules have been developed, which are not described in the literature. These compounds are derivatives of monoalkyl phosphoric acids or alkyl phosphonic acids and contain a terminal functional oligo (ethylene glycol) unit. The compounds were assembled on the TiO2-surface by self-assembly technique from aqueous solution. The adsorbed layers were characterized by different analytical tools, like angle resolved XPS, spectroscopic ellipsometry and SPR-spectroscopy. The selective adsorption of SAMs on TiO2-surfaces and the formation of stable SAMs make it possible to prevent or minimize non specific protein adsorption and also to bind selected proteins via specific surface reactions.

Self-Assembly-Monoschichten

Oligo(ethylenglykol)

Phosphonsäure

Oberflächenmodifikation

Proteinresistenz

self-assembly monolayer

oligo(ethylene glycol)

phosphonate

surface modification

protein resistance

ddc:620

rvk:VH 9707

Synthesis of Electroactive Molecules Based on Benzodioxins and Tetrathiafulvalenes

Dahlstedt, Emma

January 2003

<p>This thesis deals with the synthesis of electroactiveorganic compounds. The synthesis of ethylenedioxy-benzodioxinstri-dioxin and tetra-dioxin are described. These molecules wereprepared with the aim of creating donor molecules for cationicradical salts. The symmetric analogs of tri-dioxin,methylenedioxy-derivative and ethylenedioxy-naphthalene werealso synthesized. Three different cation radical salts with 2:1stoichiometries were obtained from tri-dioxin, whiletetra-dioxin merely provided polycrystalline materials.Tri-dioxin and tetra-dioxin were also successful as operationalmatrixes in PALDI-TOF.</p><p>Tetrathiafulvalenes with the2-dialkyl-amino-1,3-dithiolium-4-thiolate mesoion asbuilding-block was also synthesized. A series of doublyalkylthiol-substituted TTFs were prepared with the aim offorming self-assembly monolayers on gold surfaces in theapplication of organic thin film field-effect transistors.Film-formation for two TTFs were studied and they providedrelatively dense packed monolayers with a discrete distance ofthe TTF moiety from the gold surface.</p><p>The mesoionic compound was also for the first time used inan<i>umpolung</i>reaction. The electrophile obtained in situ bytreatment of mesoion with sulfuryl chloride was reacted with avariety of electron-rich aromatic compounds. From the receivedproducts three new arylthio-substituted TTFs weresynthesized.</p><p><b>Keywords:</b>Synthesis, Benzodioxin, Tetrathiafulvalene,Mesoion, Organic Conductor, Cation Radical Salt, CyclicVoltammetry, Electrocrystallization, Self-Assembly Monolayer,SAM, Organic Field-Effect Transistor, OFET</p>

Synthesis

Benzodioxin

Tetrathiafulvalene

Mesoion

Organic Conductor

Cation Radical Salt

Cyclic Voltammetry

Electrocrystallization

Self-Assembly Monolayer

SAM

Organic Field-Effect Transistor

OFET

Substituierte Oligo(ethylenglykol)-derivate zur Oberflächenmodifizierung

Gnauck, Mandy

07 July 2009

Die Immobilisierung von Oligo(ethylenglykol)-derivaten an Oberflächen von Metallen ist ein viel versprechender Ansatz, um unspezifische Adsorptionen von Proteinen, Bakterien und Zellen zu minimieren bzw. zu verhindern. Im Mittelpunkt der Arbeit stand die Entwicklung, Darstellung, Charakterisierung sowie Applikation maßgeschneiderter, self-assembly-fähiger Moleküle, die gezielt auf TiO2- und nicht auf SiO2-Oberflächen anbinden. Die resultierenden Monoschichten (SAMs) wiesen eine Biokompatibilität sowie Biofunktionalität auf. Dazu wurden neue bisher noch nicht beschriebene Moleküle entwickelt, die auf einer Kombination von funktionalisierten Oligo(ethylenglykol)-Einheiten mit Monoalkylphosphorsäure- und Alkylphosphonsäurederivaten basieren. Diese Verbindungen konnten durch die Anwendung der Self-Assembly-Technik erfolgreich aus wässriger Lösung auf TiO2-Substrate adsorbiert werden. Die hergestellten, ultradünnen monomolekularen Schichten wurden mit verschiedenen analytischen Methoden, wie Spektroskopische Ellipsometrie, winkelabhängiger XPS und SPR-Spektroskopie charakterisiert. Durch eine gezielte Anbindung an TiO2-Oberflächen und einer stabilen Ausbildung von SAMs konnten sowohl die unspezifische Proteinadsorption zurückgedrängt bzw. verhindert, als auch eine spezifische Anbindung von ausgewählten Proteinen realisiert werden. / The surface immobilization of oligo (ethylene glycol) on metals is a promising approach to minimize or prevent non-specific adsorption of proteins, bacteria and cells. The aim of this work was the design, preparation, characterization and application of tailor-made, self-assembly molecules, which are able to adsorbed selectively on TiO2 surfaces but not on SiO2. The resulting self-assembled monolayers (SAMs) had a biocompatibility and bio functionality. For this purpose new molecules have been developed, which are not described in the literature. These compounds are derivatives of monoalkyl phosphoric acids or alkyl phosphonic acids and contain a terminal functional oligo (ethylene glycol) unit. The compounds were assembled on the TiO2-surface by self-assembly technique from aqueous solution. The adsorbed layers were characterized by different analytical tools, like angle resolved XPS, spectroscopic ellipsometry and SPR-spectroscopy. The selective adsorption of SAMs on TiO2-surfaces and the formation of stable SAMs make it possible to prevent or minimize non specific protein adsorption and also to bind selected proteins via specific surface reactions.

info:eu-repo/classification/ddc/620

ddc:620