Global ETD Search

91	Electrochemical and ion transport characterisation of a nanoporous carbon derived from SiC Zuleta, Marcelo January 2005 (has links) <p>In this doctoral project, a relatively new form of carbon material, with unique narrow pore size distribution around 7 Å and with uniform structure, has been electrochemically characterised using the single particle microelectrode technique. The carbon has been used as electrode material for supercapacitors. This type of capacitors is used as high power energy buffers in hybrid vehicles and for stationary power backup. The principle for the microelectrode technique consists of connecting a carbon particle with a carbon fibre by means of a micromanipulator. The single particle and carbon fibre together form a microelectrode. Combination of this technique with electroanalytical methods such as cyclic voltammetry and potential step measurements allows for the survey of electrochemical phenomena and for the determination of ion transport parameters inside the nanopores.</p><p>A mathematical model based on Fick’s second law, for diffusion of ions inside the nanopores at non steady state, was used for the determination of effective diffusion coefficients (Deff). The coefficients were calculated from an asymptotic solution of Fick’s equation, applied for a thin layer adjacent to the external surface of the carbon particles and valid for the current response in a short time region. Another asymptotic solution was obtained, using spherical geometry and valid for the current response in a long time region.</p><p>In this doctoral work, the carbon particles have been exposed to potential cycling, which mimics that of large electrodes during operation of a double layer capacitor. The potential-current response, E-I, for the nanoporous carbon, shows a pure capacitive behaviour between –0.5 V and 0.1 V vs. the Hg\|HgO reference electrode. The detection of the faradaic processes beyond these potentials was possible by lowering of the voltammometric sweep rate. The electrochemical processes occurring at positive and at negative potential were investigated separately.</p><p>Cyclic voltammometric measurements showed that the chemisorption of hydroxyl groups, occurring between 0.1 and 0.3 V, leads to a mild oxidation of the carbon structure, resulting in surface groups containing an oxygen atom at a specific carbon site (e.g., phenolic or quinine type). These oxygen-containing surface groups caused an increase of the specific capacitance, which remained constant throughout a number of voltammometric cycles. The Deff decreased on the other hand with the number of cycles. The Deff decreases also with the positive potential. The evaluation of Deff indicates adsorption of hydroxyl groups and an increase of the effective tortuosity of the pore system.</p><p>The oxidation of the carbon particles, between 0 and 0.5 V, leads to more extensive oxidation and to surface groups containing two oxygen atoms at a single carbon site, followed by formation of carbonate ions. The oxygen-containing surface groups and carbonate ions formed at these potentials do not contribute to the specific capacitance and drastically retard or obstruct the ion transport inside the nanopores.</p><p>At negative potentials the carbon particles show a dominantly capacitive behaviour. The faradaic processes taking place below –0.5 V vs. Hg\|HgO reference electrode are generation and adsorption of hydrogen. These processes do not perturb significantly the electrochemical and ion transport properties of the nanoporous carbon particles. It was found that hydrogen generation occurs at –0.5 V vs. Hg\|HgO and that two hydrogen oxidation processes take place at positive potentials. The results indicate that the weakly adsorbed hydrogen undergoes oxidation between 0 and 0.1 V and that the strongly adsorbed hydrogen is oxidised at more positive potentials.</p><p>The single particle technique was adapted for the determination of diffusion coefficients of an organic electrolyte. The different size of the anions and cations caused different transport characteristics at negative and positive potentials. Slow cycling was found important for ion penetration inside the nanopores and for the evaluation of the effective diffusion coefficients.</p><p>The effective diffusion coefficients for the nanoporous carbon using aqueous 6M KOH and 0.1M TEABF4 in acetonitrile were estimated to 1.4 (±0.8).10-9 cm2 s-1 and 1.3 (±0.4) 10-8 cm2 s-1, respectively.</p> Chemical engineering Cottrell equation radial diffusion chronoamperometry potential step measurements microelectrode technique nanoporous carbon Kemiteknik Chemical engineering Kemiteknik
92	Uso de eletrodos de cobre e eletrodos modificados como sensores eletroquímicos / Use of copper and modified electrodes as electrochemical sensors Dantas, Luiza Maria Ferreira 28 November 2014 (has links) Este trabalho foi dividido em quatro etapas, além da introdução. A primeira parte consiste no estudo comparativo do comportamento eletroquímico de eletrodos de cobre em soluções tampão fosfato 0,10 mol L-1 com valores de pH 4,5 e 7,8, e em solução de NaOH com valores de pH 13,0 e 14,0. Mostrou-se que as espécies formadas eletroquimicamente sobre a superfície do eletrodo são dependentes do valor de pH e do potencial aplicado. Os resultados experimentais obtidos estão de acordo com aqueles reportados na literatura. A segunda parte da tese corresponde ao desenvolvimento de um sensor eletroquímico fabricado com microeletrodos de cobre para a determinação de peróxido de hidrogênio (H2O2) em amostras comerciais de antissépticos bucais e clareadores dentais. Nas condições experimentais otimizadas (solução tampão fosfato 0,10 mol L-1 (pH 7,0) e potencial de redução de -0,20 V), microeletrodos de cobre foram utilizados para a determinação de H2O2 sem a necessidade de etapas de extração, obtendo-se faixa linear de 0,015 a 6,4 mmol L-1 e limite de detecção de 2,8 µmol L-1. O método proposto mostrou-se reprodutível e a presença de interferentes na matriz da amostra analisada não alterou a resposta do sensor para H2O2. Na terceira parte, a reação de eletro-oxidação de glicerol em superfícies de cobre em soluções de NaOH foi investigada utilizando a microscopia eletroquímica de varredura (SECM) no modo de geração pelo substrato de cobre / coleta no microeletrodo de platina (tip) (SG/TC). Os experimentos com a SECM mostraram a dependência da corrente com a distância entre o gerador e a tip, assim como a dependência com a concentração da solução de NaOH. Além disso, a corrente monitorada no microeletrodo diminuiu significativamente após a adição de glicerol. A atividade eletrocatalítica de eletrodos de cobre, no que diz respeito à oxidação de glicerol em meio alcalino, permitiu o desenvolvimento de um sensor amperométrico para a determinação de glicerol em amostra de biodiesel, com um intervalo linear de 0,05 a 1,33 mmol L-1 e limite de detecção de 20 µmol L-1. A metodologia proposta foi aplicada para a determinação do analito em uma amostra de biodiesel de mamona. A quarta parte descreve a síntese, caracterização eletroquímica e utilização de nanotubos de carbono de paredes múltiplas (NCPM) decorados com nanopartículas de paládio (Pd) para a modificação da superfície de eletrodo de carbono vítreo (CV) para a oxidação de metanol, etanol e glicerol em solução de KOH 1,0 mol L-1. Os resultados mostraram que o NCPM/Pd é um bom catalisador para a eletro-oxidação de álcoois em meio alcalino e que maior atividade eletrocatalítica foi obtida para o glicerol. Em condições otimizadas, experimentos amperométricos foram realizados para o desenvolvimento do método analítico para a determinação de glicerol em biodiesel, obtendo-se um intervalo linear de 0,06 a 24 mmol L-1 e limite de detecção 30 µmol L-1. Amostras de biodiesel foram analisadas com sucesso por meio de curvas de adição de padrão utilizando o eletrodo CV/NCPM/Pd. / This thesis is divided into four parts, apart from a general introduction. Part 1 is concerned with a critical comparison of the electrochemical behaviour of copper electrodes, in 0.10 mol L-1 phosphate buffer solution (pH 4.5 and 7.8), and in NaOH solution (pH 13.0 and 14.0). The electrochemical study showed that the species formed on the surface depends on both pH and the applied potential. The experimental results are in good agreement with those reported in the literature. A second goal of the thesis was the development of an electrochemical sensor for hydrogen peroxide (H2O2) determination in commercial oral antiseptic and dental whitening samples using copper microelectrodes. With optimized experimental conditions (working potential applied = -0.20 V in 0.10 mol L-1 phosphate buffer solution pH= 7.0), copper microelectrodes can be used to detect H2O2 without any previous extraction steps, in the range of 0.015 to 6.4 mmol L-1 with a lower detection limit of 2.8 µmol L-1. In addition, the electrode exhibited an excellent reproducibility and long-term stability as well as negligible interference from sorbitol, ethanol, glycerin and saccharin. In the third part, the electrooxidation reaction of glycerol at copper surfaces in NaOH solutions was investigated using Scanning Electrochemical Microscopy (SECM) in a copper substrate generation / platinum microelectrode (tip) collection mode (SG/TC). The results showed the dependence of the current measured at the tip with respect to the distance between generator and the tip, as well as on the concentration of the NaOH solution. Other studies led to the conclusion that the current measured at the tip decreased significantly after addition of glycerol in the solution. The electrocatalytic activity of copper electrodes for the oxidation of glycerol in alkaline medium allowed the development of an amperometric method to determine glycerol in biodiesel samples in the range 0.05 to 1.33 mmol L-1 with a detection limit of 20 µmol L-1. The determination of the analyte in a castor biodiesel sample employing a single copper microelectrode was carried out. The four part of this thesis shows results on the synthesis, electrochemical characterization and use of a glassy carbon (GC) electrode modified with multi-wall carbon nanotubes (MWCNT) decorated with palladium (Pd) for the electrochemical oxidation of methanol, ethanol and glycerol in 1.0 mol L-1 KOH solution. The results showed that MWCNT/Pd is a good electrocatalyst for methanol, ethanol and glycerol oxidation in alkaline medium, with highest activity toward glycerol oxidation. With optimized experimental conditions, an amperometric method was developed for the determination of glycerol in biodiesel samples, in the range of 0.06 to 24 mmol L-1 and detection limit of 30 µmol L-1. Biodiesel samples were successfully analyzed by the standard addition method using the GC/MWCNT/Pd film electrode. Carbon nanotube Copper microelectrode Electroanalytical methods Glicerol Glycerol Hydrogen peroxide Métodos eletroanalíticos Microeletrodos de cobre Nanotubos de carbono Paládio Palladium Peróxido de hidrogênio
93	Acid transport through gastric mucus : A study in vivo in rats and mice Phillipson, Mia January 2003 (has links) <p>The gastric mucosa is frequently exposed to endogenously secreted hydrochloric acid of high acidity. Gastric mucosal defense mechanisms are arranged at different levels of the gastric mucosa and must work in unison to maintain its integrity. </p><p>In this thesis, several mechanisms underlying gastric mucosal resistance to strong acid were investigated in anesthetized rats and mice. The main findings were as follows:</p><p>Only when acid secretion occurred did the pH gradient in the mucus gel withstand back-diffusion of luminal acid (100 mM or 155 mM HCl), and keep the juxtamucosal pH (pH<sub>jm</sub>) neutral. Thus, when no acid secretion occurred and the luminal pH was 0.8-1, the pH gradient was destroyed. </p><p>Bicarbonate ions, produced concomitant with hydrogen ions in the parietal cells during acid secretion and blood-borne to the surface epithelium, were carried transepithelially through a DIDS-sensitive transport. </p><p>Prostaglandin-dependent bicarbonate secretion seemed to be less important in maintaining a neutral pH<sub>jm</sub>. </p><p>Removal of the loosely adherent mucus layer did not influence the maintenance of the pH<sub>jm</sub>. Hence, only the firmly adherent mucus gel layer, approximately 80µm thick, seemed to be important for the pH<sub>jm</sub>. </p><p>Staining of the mucus gel with a pH-sensitive dye revealed that secreted acid penetrated the mucus gel from the crypt openings toward the gastric lumen only in restricted paths (channels). One crypt opening was attached to one channel, and the channel was irreversibly formed during acid secretion. </p><p>Gastric mucosal blood flow increased on application of strong luminal acid (155 mM HCl). This acid-induced hyperemia involved the inducible but not the neural isoform of nitric oxide synthase. These results suggest a novel role for iNOS in gastric mucosal protection and indicate that iNOS is constitutively expressed in the gastric mucosa. </p><p>It is concluded that a pH gradient in the gastric mucus gel can be maintained during ongoing acid secretion, since the acid penetrates the mucus only in restricted channels and bicarbonate is carried from the blood to the lumen via a DIDS-sensitive transporter.</p> Physiology Fysiologi Physiology Fysiologi
94	Electrochemical and ion transport characterisation of a nanoporous carbon derived from SiC Zuleta, Marcelo January 2005 (has links) In this doctoral project, a relatively new form of carbon material, with unique narrow pore size distribution around 7 Å and with uniform structure, has been electrochemically characterised using the single particle microelectrode technique. The carbon has been used as electrode material for supercapacitors. This type of capacitors is used as high power energy buffers in hybrid vehicles and for stationary power backup. The principle for the microelectrode technique consists of connecting a carbon particle with a carbon fibre by means of a micromanipulator. The single particle and carbon fibre together form a microelectrode. Combination of this technique with electroanalytical methods such as cyclic voltammetry and potential step measurements allows for the survey of electrochemical phenomena and for the determination of ion transport parameters inside the nanopores. A mathematical model based on Fick’s second law, for diffusion of ions inside the nanopores at non steady state, was used for the determination of effective diffusion coefficients (Deff). The coefficients were calculated from an asymptotic solution of Fick’s equation, applied for a thin layer adjacent to the external surface of the carbon particles and valid for the current response in a short time region. Another asymptotic solution was obtained, using spherical geometry and valid for the current response in a long time region. In this doctoral work, the carbon particles have been exposed to potential cycling, which mimics that of large electrodes during operation of a double layer capacitor. The potential-current response, E-I, for the nanoporous carbon, shows a pure capacitive behaviour between –0.5 V and 0.1 V vs. the Hg\|HgO reference electrode. The detection of the faradaic processes beyond these potentials was possible by lowering of the voltammometric sweep rate. The electrochemical processes occurring at positive and at negative potential were investigated separately. Cyclic voltammometric measurements showed that the chemisorption of hydroxyl groups, occurring between 0.1 and 0.3 V, leads to a mild oxidation of the carbon structure, resulting in surface groups containing an oxygen atom at a specific carbon site (e.g., phenolic or quinine type). These oxygen-containing surface groups caused an increase of the specific capacitance, which remained constant throughout a number of voltammometric cycles. The Deff decreased on the other hand with the number of cycles. The Deff decreases also with the positive potential. The evaluation of Deff indicates adsorption of hydroxyl groups and an increase of the effective tortuosity of the pore system. The oxidation of the carbon particles, between 0 and 0.5 V, leads to more extensive oxidation and to surface groups containing two oxygen atoms at a single carbon site, followed by formation of carbonate ions. The oxygen-containing surface groups and carbonate ions formed at these potentials do not contribute to the specific capacitance and drastically retard or obstruct the ion transport inside the nanopores. At negative potentials the carbon particles show a dominantly capacitive behaviour. The faradaic processes taking place below –0.5 V vs. Hg\|HgO reference electrode are generation and adsorption of hydrogen. These processes do not perturb significantly the electrochemical and ion transport properties of the nanoporous carbon particles. It was found that hydrogen generation occurs at –0.5 V vs. Hg\|HgO and that two hydrogen oxidation processes take place at positive potentials. The results indicate that the weakly adsorbed hydrogen undergoes oxidation between 0 and 0.1 V and that the strongly adsorbed hydrogen is oxidised at more positive potentials. The single particle technique was adapted for the determination of diffusion coefficients of an organic electrolyte. The different size of the anions and cations caused different transport characteristics at negative and positive potentials. Slow cycling was found important for ion penetration inside the nanopores and for the evaluation of the effective diffusion coefficients. The effective diffusion coefficients for the nanoporous carbon using aqueous 6M KOH and 0.1M TEABF4 in acetonitrile were estimated to 1.4 (±0.8).10-9 cm2 s-1 and 1.3 (±0.4) 10-8 cm2 s-1, respectively. Chemical engineering Cottrell equation radial diffusion chronoamperometry potential step measurements microelectrode technique nanoporous carbon Kemiteknik Chemical engineering Kemiteknik
95	Acid transport through gastric mucus : A study in vivo in rats and mice Phillipson, Mia January 2003 (has links) The gastric mucosa is frequently exposed to endogenously secreted hydrochloric acid of high acidity. Gastric mucosal defense mechanisms are arranged at different levels of the gastric mucosa and must work in unison to maintain its integrity. In this thesis, several mechanisms underlying gastric mucosal resistance to strong acid were investigated in anesthetized rats and mice. The main findings were as follows: Only when acid secretion occurred did the pH gradient in the mucus gel withstand back-diffusion of luminal acid (100 mM or 155 mM HCl), and keep the juxtamucosal pH (pHjm) neutral. Thus, when no acid secretion occurred and the luminal pH was 0.8-1, the pH gradient was destroyed. Bicarbonate ions, produced concomitant with hydrogen ions in the parietal cells during acid secretion and blood-borne to the surface epithelium, were carried transepithelially through a DIDS-sensitive transport. Prostaglandin-dependent bicarbonate secretion seemed to be less important in maintaining a neutral pHjm. Removal of the loosely adherent mucus layer did not influence the maintenance of the pHjm. Hence, only the firmly adherent mucus gel layer, approximately 80µm thick, seemed to be important for the pHjm. Staining of the mucus gel with a pH-sensitive dye revealed that secreted acid penetrated the mucus gel from the crypt openings toward the gastric lumen only in restricted paths (channels). One crypt opening was attached to one channel, and the channel was irreversibly formed during acid secretion. Gastric mucosal blood flow increased on application of strong luminal acid (155 mM HCl). This acid-induced hyperemia involved the inducible but not the neural isoform of nitric oxide synthase. These results suggest a novel role for iNOS in gastric mucosal protection and indicate that iNOS is constitutively expressed in the gastric mucosa. It is concluded that a pH gradient in the gastric mucus gel can be maintained during ongoing acid secretion, since the acid penetrates the mucus only in restricted channels and bicarbonate is carried from the blood to the lumen via a DIDS-sensitive transporter. Physiology Fysiologi Physiology Fysiologi
96	Uso de eletrodos de cobre e eletrodos modificados como sensores eletroquímicos / Use of copper and modified electrodes as electrochemical sensors Luiza Maria Ferreira Dantas 28 November 2014 (has links) Este trabalho foi dividido em quatro etapas, além da introdução. A primeira parte consiste no estudo comparativo do comportamento eletroquímico de eletrodos de cobre em soluções tampão fosfato 0,10 mol L-1 com valores de pH 4,5 e 7,8, e em solução de NaOH com valores de pH 13,0 e 14,0. Mostrou-se que as espécies formadas eletroquimicamente sobre a superfície do eletrodo são dependentes do valor de pH e do potencial aplicado. Os resultados experimentais obtidos estão de acordo com aqueles reportados na literatura. A segunda parte da tese corresponde ao desenvolvimento de um sensor eletroquímico fabricado com microeletrodos de cobre para a determinação de peróxido de hidrogênio (H2O2) em amostras comerciais de antissépticos bucais e clareadores dentais. Nas condições experimentais otimizadas (solução tampão fosfato 0,10 mol L-1 (pH 7,0) e potencial de redução de -0,20 V), microeletrodos de cobre foram utilizados para a determinação de H2O2 sem a necessidade de etapas de extração, obtendo-se faixa linear de 0,015 a 6,4 mmol L-1 e limite de detecção de 2,8 µmol L-1. O método proposto mostrou-se reprodutível e a presença de interferentes na matriz da amostra analisada não alterou a resposta do sensor para H2O2. Na terceira parte, a reação de eletro-oxidação de glicerol em superfícies de cobre em soluções de NaOH foi investigada utilizando a microscopia eletroquímica de varredura (SECM) no modo de geração pelo substrato de cobre / coleta no microeletrodo de platina (tip) (SG/TC). Os experimentos com a SECM mostraram a dependência da corrente com a distância entre o gerador e a tip, assim como a dependência com a concentração da solução de NaOH. Além disso, a corrente monitorada no microeletrodo diminuiu significativamente após a adição de glicerol. A atividade eletrocatalítica de eletrodos de cobre, no que diz respeito à oxidação de glicerol em meio alcalino, permitiu o desenvolvimento de um sensor amperométrico para a determinação de glicerol em amostra de biodiesel, com um intervalo linear de 0,05 a 1,33 mmol L-1 e limite de detecção de 20 µmol L-1. A metodologia proposta foi aplicada para a determinação do analito em uma amostra de biodiesel de mamona. A quarta parte descreve a síntese, caracterização eletroquímica e utilização de nanotubos de carbono de paredes múltiplas (NCPM) decorados com nanopartículas de paládio (Pd) para a modificação da superfície de eletrodo de carbono vítreo (CV) para a oxidação de metanol, etanol e glicerol em solução de KOH 1,0 mol L-1. Os resultados mostraram que o NCPM/Pd é um bom catalisador para a eletro-oxidação de álcoois em meio alcalino e que maior atividade eletrocatalítica foi obtida para o glicerol. Em condições otimizadas, experimentos amperométricos foram realizados para o desenvolvimento do método analítico para a determinação de glicerol em biodiesel, obtendo-se um intervalo linear de 0,06 a 24 mmol L-1 e limite de detecção 30 µmol L-1. Amostras de biodiesel foram analisadas com sucesso por meio de curvas de adição de padrão utilizando o eletrodo CV/NCPM/Pd. / This thesis is divided into four parts, apart from a general introduction. Part 1 is concerned with a critical comparison of the electrochemical behaviour of copper electrodes, in 0.10 mol L-1 phosphate buffer solution (pH 4.5 and 7.8), and in NaOH solution (pH 13.0 and 14.0). The electrochemical study showed that the species formed on the surface depends on both pH and the applied potential. The experimental results are in good agreement with those reported in the literature. A second goal of the thesis was the development of an electrochemical sensor for hydrogen peroxide (H2O2) determination in commercial oral antiseptic and dental whitening samples using copper microelectrodes. With optimized experimental conditions (working potential applied = -0.20 V in 0.10 mol L-1 phosphate buffer solution pH= 7.0), copper microelectrodes can be used to detect H2O2 without any previous extraction steps, in the range of 0.015 to 6.4 mmol L-1 with a lower detection limit of 2.8 µmol L-1. In addition, the electrode exhibited an excellent reproducibility and long-term stability as well as negligible interference from sorbitol, ethanol, glycerin and saccharin. In the third part, the electrooxidation reaction of glycerol at copper surfaces in NaOH solutions was investigated using Scanning Electrochemical Microscopy (SECM) in a copper substrate generation / platinum microelectrode (tip) collection mode (SG/TC). The results showed the dependence of the current measured at the tip with respect to the distance between generator and the tip, as well as on the concentration of the NaOH solution. Other studies led to the conclusion that the current measured at the tip decreased significantly after addition of glycerol in the solution. The electrocatalytic activity of copper electrodes for the oxidation of glycerol in alkaline medium allowed the development of an amperometric method to determine glycerol in biodiesel samples in the range 0.05 to 1.33 mmol L-1 with a detection limit of 20 µmol L-1. The determination of the analyte in a castor biodiesel sample employing a single copper microelectrode was carried out. The four part of this thesis shows results on the synthesis, electrochemical characterization and use of a glassy carbon (GC) electrode modified with multi-wall carbon nanotubes (MWCNT) decorated with palladium (Pd) for the electrochemical oxidation of methanol, ethanol and glycerol in 1.0 mol L-1 KOH solution. The results showed that MWCNT/Pd is a good electrocatalyst for methanol, ethanol and glycerol oxidation in alkaline medium, with highest activity toward glycerol oxidation. With optimized experimental conditions, an amperometric method was developed for the determination of glycerol in biodiesel samples, in the range of 0.06 to 24 mmol L-1 and detection limit of 30 µmol L-1. Biodiesel samples were successfully analyzed by the standard addition method using the GC/MWCNT/Pd film electrode. Glicerol Métodos eletroanalíticos Microeletrodos de cobre Nanotubos de carbono Paládio Peróxido de hidrogênio Carbon nanotube Copper microelectrode Electroanalytical methods Glycerol Hydrogen peroxide Palladium
97	Optimization of Cell Culture Procedures for Growing Neural Networks on Microelectrode Arrays Santa Maria, Cara L. 12 1900 (has links) This thesis describes the development of an optimized method for culturing dissociated, monolayer neuronal networks from murine frontal cortex and midbrain. It is presented as a guidebook for use by cell culture specialists and laboratory personnel who require updated and complete procedures for use with microelectrode array (MEA) recording technology. Specific cell culture protocols, contamination prevention and control, as well common problems encountered within the cell culture facility, are discussed. This volume offers value and utility to the rapidly expanding fields of MEA recording and neuronal cell culture. Due to increasing interest in determining the mechanisms underlying Parkinson's disease, the newly developed procedures for mesencephalon isolation and culture on MEAs are an important research contribution. Cell culture microelectrode array protocols midbrain frontal cortex neuronal networks Cell culture. Neural networks (Neurobiology) Microelectrodes. Mice -- Nervous system.
98	Application of Cultured Neuronal Networks for Use as Biological Sensors in Water Toxicology and Lipid Signaling. Dian, Emese Emöke 08 1900 (has links) This dissertation research explored the capabilities of neuronal networks grown on substrate integrated microelectrode arrays in vitro to be applied to toxicological research and lipid signaling. Chapter 1 details the effects of chlorine on neuronal network spontaneous electrical activity and pharmacological sensitivity. This study demonstrates that neuronal networks can maintain baseline spontaneous activity, and respond normally to pharmacological manipulations in the present of three times the chlorine present in drinking water. The findings suggest that neuronal networks may be used as biological sensors to monitor the quality of water and the presence of novel toxicants that cannot be detected by conventional sensors. Chapter 2 details the neuromodulatory effects of N-acylethanolamides (NAEs) on the spontaneous electrical activity of neuronal networks. NAEs are a group of lipids that can mimic the effects of marijuana and can be derived from a variety of plant sources including soy lecithin. The most prominent NAEs in soy lecithin, palmitoylethanolamide (PEA) and linoleoylethanolamide (LEA), were tested individually and were found to significantly inhibit neuronal spiking and bursting activity. These effects were potentiated by a mixture of NAEs as found in a HPLC enriched fraction from soy lecithin. Cannabinoid receptor-1 (CB1-R) antagonists and other cannabinoid pathway modulators indicated that the CB1-R was not directly involved in the effects of NAEs, but that enzymatic degradation and cellular uptake were more likely targets. The results demonstrate that neuronal networks may also be a viable platform for the elucidation of biochemical pathways and drug mechanisms of action. Water quality. Water quality biological assessment. Water -- Pollution -- Toxicology. Neural circuitry. Lipids. neuronal networks microelectrode array pharmacology
99	Mikroelektrodová pole pro bioelektroniku / Microelectrode arrays for mioelectronic Bráblíková, Aneta January 2019 (has links) Organic electronic biosensors are developed as suitable devices that can transform electrochemical processes within the cell membrane into an electronic signal and enable to measure electrical activity of excitable cells and tissues both in vitro and in vivo and thus represent valuable alternative to current cell monitoring methods. In this work we focus on the fabrication of electrophysiological sensors based on organic semiconductors printed by the material printing method. Microelectrode arrays (MEAs) are active components of the device, which can monitore cellular activity and above that stimulating cells with electrical pulses. The proposed platform should be used for cytotoxicity of potential drugs especially on cardiac cells (cardiomyocytes). The experimental part focus on specific production processes of platforms, which were prepared in the laboraty with emphasis on biocompatibility and conductivity of device.
100	Optimization of microelectrode sensor sensitivity for real-time monitoring important physiological parameters of human renal epithelial cell Yuan, Fan 07 May 2020 (has links) In order to calculate specific impedance of cell-covered electrodes in a Equation of morphological parameters of cell per se, an ECIS model of Human Renal Epithelial Cell are created by analysis partial differential equations describing three intrinsic pathways of electrical currents in the system. Based on this cell model, this research explores how some adjustable dimensional parameters of electrode-configuration impact sensor sensitivity by changing the overall impedance contribution of electrical double layer. Namely, it includes electrode planner area, spacing between working and counter electrode and geometry of electrode, scanning frequency. Qualitative studies on how sensor sensitivity rely on configurational parameters are conducted with these parameters involved. Moreover, theoretical analysis of sensitivity by using equivalent circuit model is also carried out. As results of COMSOL simulations, special double layer electrode configurations and selectively planted cell monolayer arrangement are proposed regardless of fabrication difficulties. Accordingly, some possible strategies to make these arrangements come true are also illustrated. Finally, superior possible COMSOL simulation model is suggested and discussed for future optimization works. / 2021-05-07T00:00:00Z Bioengineering COMSOL simulation Finite element analysis Human renal epithelial cell Microelectrode sensor Real-time monitoring Sensor sensitivity

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