High-density stretchable microelectrode arrays: an integrated technology platform for neural and muscular surface interfacing

Guo, Liang

04 April 2011

Numerous applications in neuroscience research and neural prosthetics, such as retinal prostheses, spinal-cord surface stimulation for prosthetics, electrocorticogram (ECoG) recording for epilepsy detection, etc., involve electrical interaction with soft excitable tissues using a surface stimulation and/or recording approach. These applications require an interface that is able to set up electrical communications with a high throughput between electronics and the excitable tissue and that can dynamically conform to the shape of the soft tissue. Being a compliant and biocompatible material with mechanical impedance close to that of soft tissues, polydimethylsiloxane (PDMS) offers excellent potential as the substrate material for such neural interfaces. However, fabrication of electrical functionalities on PDMS has long been very challenging. This thesis work has successfully overcome many challenges associated with PDMS-based microfabrication and achieved an integrated technology platform for PDMS-based stretchable microelectrode arrays (sMEAs). This platform features a set of technological advances: (1) we have fabricated uniform current density profile microelectrodes as small as 10 microns in diameter; (2) we have patterned high-resolution (feature as small as 10 microns), high-density (pitch as small as 20 microns) thin-film gold interconnects on PDMS substrate; (3) we have developed a multilayer wiring interconnect technology within the PDMS substrate to further boost the achievable integration density of such sMEA; and (4) we have invented a bonding technology---via-bonding---to facilitate high-resolution, high-density integration of the sMEA with integrated circuits (ICs) to form a compact implant. Taken together, this platform provides a high-resolution, high-density integrated system solution for neural and muscular surface interfacing. sMEAs of example designs are evaluated through in vitro and in vivo experimentations on their biocompatibility, surface conformability, and surface recording/stimulation capabilities, with a focus on epimysial (i.e. on the surface of muscle) applications. Finally, as an example medical application, we investigate a prosthesis for unilateral vocal cord paralysis (UVCP) based on simultaneous multichannel epimysial recording and stimulation.

Neural interfaces

Neural prosthetics

Stretchable microelectrode arrays

Microfabrication

Polydimethylsiloxane (PDMS)

High density

Epimysial recording and stimulation

Myoelectric prosthesis

Polydimethylsiloxane

Microfabrication

Microelectrodes

Biocompatibility

Optimization of 3-d neural culture and extracellular electrophysiology for studying injury-induced morphological and functional changes

Vernekar, Varadraj Nagesh

06 April 2010

This work characterized an in vitro 3-D neural co-culture model electrophysiologically via multi electrode arrays (MEAs), and morphologically via immunocytochemistry. Since MEA surface insulation SU-8 2000 can be used in neural micro- and multi- electrode arrays, this investigation first developed techniques to make SU-8 2000 cytocompatible. The in vitro 3-D neural co-culture model was then used to study viability and electrophysiological responses to physical injury as well as drugs known to affect network signaling. 1) SU-8 2000 cytotoxicity to neuronal cultures was linked to both poor adhesive properties and toxic components, such as solvents and photo acid generator elements. Surface treatments of oxygen plasma or parylene coating following optimal combinations of heat and isopropanol sonication showed improvement in SU-8 2000 cytocompatibility. 2) The 3-D neural networks within the 3-D co-cultures maintained considerable process outgrowth and complex 3-D structure. The cultures were viable up to three weeks in vitro with functional synaptic connections and spontaneous electrophysiological activity that was responsive to chemical modulation. This electrophysiological activity was modulated by synaptic inhibition. 3) Injury experiments demonstrated that both shear and compression loading significantly increased acute membrane permeability of cells in a strain rate dependent manner. Cell death correlated with higher membrane permeability, and shear resulted in more death than compression in these 3-D cultures. While techniques were developed for making a major micro-fabrication material cytocompatible, engineering the 3-D neural co-culture resulted in a more physiologically-representative neural tissue platform, allowing an increased understanding of structure-function relationships. Overall, this research established and characterized a neural culture system for the mechanistic study of cell growth, cell-cell and cell-matrix interactions, as well as the responses to chemical or mechanical perturbations. This is the first investigation of the network-level electrophysiological activity of 3-D dissociated cultures. This system can be used to model various pathological states in vitro, testing various reparative drugs; cell-, and tissue-engineering based strategies; as well as for pre-animal and pre-clinical testing of neural implants.

Neural

3-D cultures

Electrophysiology

Three dimensional

MEA

Multi electrode arrays

SU-8

Injury

Microfabrication

Electrophysiology

Nerve tissue Electric properties

Neural networks (Neurobiology)

Microelectrodes

Immunocytochemistry

Generation of micro/nano metallic nanostructures using self-assembled monolayers as template and electrochemistry

She, Zhe

January 2012

This thesis studies a scheme to fabricate small-scaled metal structures by electrochemical metal deposition and lift off. The key point is the use of self-assembled monolayers (SAMs) to control both interfacial charge transfer in electrodeposition and adhesion of the deposit to the substrate. Patterned SAMs exhibiting blocking and non-blocking areas are applied as templates in electrochemical deposition of Cu or Au. Thiol SAMs on Au substrates are used, namely alkane thiols and thiols combining an aliphatic chain with a biphenyl or biphenyl analogous pyridine-phenyl moieties. The patterning of SAMs is realised with microcontact printing (μCP) and electron beam lithography. Electrochemical deposition based on defects in the SAMs is optimised towards generating small nanostructures and depending on the system single or stepped potential procedures are applied. Generated metal structures are transferred to an insulator by lift off. Au microstructures (~10 μm) have been made with microcontact printing and transferred onto epoxy glue, which can potentially be used as microelectrodes in electroanalytical chemistry. Sub-100 nm Cu features and sub-40 nm Au features have been created with electron beam lithography respectively. Lift off process has successfully transferred Cu nanostructures onto epoxy glue with high precision. In contrast to the deposition mediated by defects, Cu deposition mediated by discharging Pd²⁺ coordinated to a pyridine terminated SAM directly through the SAM molecules has been explored as a new approach. This new approach has potential to decrease the size of the metal structure further and the preliminary results show possibility of sub-10 nm features. SAMs prepared with a newly synthesised molecule, 3-(4'-(methylthio)-[1,1'-biphenyl]-4-yl)propane-1-thiol, are characterised by STM, XPS and NEXAFS. The metal structures are investigated by SEM, AFM and STM.

620.5

Techniky přípravy elektrod s nanostrukturovaným povrchem a jejich charakterizace / Preparation Techniques and Characterization of Electrodes with Nanostructured Surface

Hrdý, Radim

January 2013

Nowadays, nanostructures fixed on solid substrates and colloidal nanoparticles permeate through all areas of human life, in area of sensors and detection as well. This dissertation thesis deals with the fabrication of nanostructures on the surface of planar electrodes via self-ordered nanoporous template of aluminum trioxide. The nanofabrication, as one of many possible techniques, is used to increase the active surface area of electrodes by creating unique surface types with specific properties. These electrodes are very perspective in the applications, such as biomolecules electrochemical detection and measurement. The transformation of aluminum layer into non-conductive nanoporous template in the process of anodic oxidation is a fundamental technique employed to obtain the array of nanostructures in this thesis. The fabrication of high quality nanoporous membranes with narrow pore size distribution on various types of metallic multilayers is one of the key experimental parts in this work. Several problems associated with the production of the thin-film systems, including the dissolving the barrier oxide layer, are discussed and solved. Another part of this work deals with the use of nanoporous membrane as a template for the production of metallic nanostructures via electrochemical metal ions deposition directly into the pores. The obtained nanostructures as nanowires, nanorods or nanodots are characterized by the scanning electron microscopy and energy-dispersive or wavelength X-ray spectroscopy. The electrode surface, modified by gold nanostructures suitable for the detection of biomolecules, has been chosen for the electrochemical measurements, due to the gold biocompatibility. The nanostructured electrodes were characterized by electrochemical impedance spectroscopy and cyclic voltammetry. The effect of nanostructured surface geometrical parameters, including the size of the electrochemically active area, on the results of electrochemical measurements has been observed and compared to flat gold electrodes. Two model biomolecules, namely guanine and glutathione, have been chosen for the study of potential application of these nanostructures in biosensors.

INVESTIGATIONS OF THE INTERACTIONS BETWEEN K+ AND Tl+ IN CHIRONOMUS RIPARIUS LARVAE

Belowitz, Ryan F.

10 1900

<p>Tl⁺ is thought to be toxic to cells due to ionic mimicry of K⁺. The aims of this study were two-fold. First, to identify whether K⁺ and Tl⁺ were interacting in isolated guts, whole animals and tissues in <em>Chironomus riparius, </em>and second, to determine the strategies of Tl⁺ tolerance. <em>C. riparius. </em>were very tolerant towards Tl⁺with a 48-hr LC₅₀ of 723 μmol l^-1. The Scanning Ion-selective Technique (SIET) allowed us to identify the caecae, AMG and PMG as the major K⁺-transporting regions of isolated guts. Evidence for an interaction was based on the finding that Tl⁺ was transported in the same directions at these segments (and others), and that 50 μmol l^-1Tl⁺ decreased K⁺ flux at the AMG and PMG. In addition, exposure to Tl⁺ prior to flux measurements had significant effects on net K⁺ transport by the gut. Measurements of Tl⁺ and K⁺ concentrations in the whole animal, gut and hemolymph by Atomic Absorption Spectroscopy (AAS) indicated that Tl⁺ uptake was saturable in the whole animal and gut, and non-saturable in the hemolymph. Together with the SIET measurements, the AAS data suggests that high levels of Tl⁺ can perturb K⁺ transport and homeostasis. The absorption of Tl⁺ from the gut to hemolymph, measured by SIET, was confirmed by hemolymph measurements of Tl⁺ using AAS. This indicated that Tl⁺ gains access to the hemolymph and that sensitive tissues (such as the nervous system) are thus exposed. However, survival of <em>C. riparius</em> at these concentrations implies efficient mechanisms for detoxification of Tl⁺. This tolerance may involve sequestration in the gut, metal-binding proteins and increased secretion by the anal papillae and MTs. In addition, loss of K⁺ from the muscle may prevent hypokalemia in the hemolymph and gut.</p> / Master of Science (MSc)

Thallium

Potassium

Chironomus riparius

Tl2+-selective microelectrodes

Tl tolerance

ion transport

SIET

Biology

Other Physiology

Toxicology

Biology

Studying the altered reactivity of electrochemical systems in room temperature ionic liquids

Ernst, Sven

January 2013

The work presented in this thesis examines the electrochemical behaviour of a number of species, both surface-bound and in the solution phase, in various room-temperature ionic liquids (RTILs), in order to identify systems which show altered reactivities in room-temperature ionic liquids, compared to that in conventional, molecular, aprotic solvents. The fundamentals of electrochemistry are outlined and an introduction to room-temperature ionic liquids is given, after which the results of six original investigations are presented, as follows; The electrochemical response of surface-bound anthraquinonyl films was investigated as a function of RTIL cation size. The reduction of oxygen to superoxide in the [C₂mim][NTf₂] RTIL was studied at different carbon electrodes. The mechanisms of electrodeposition and stripping of Zn(II) onto bulk zinc deposits, on glassy carbon electrodes, in the [C₄mPyrr][NTf₂] RTIL were investigated. A novel and successful method for the fabrication of zinc microdisk electrodes was developed and the electrochemical behaviour of these electrodes was investigated. The mechanisms for the electrochemical reductions of some bromo- and nitrobenzenes at platinum microelectrodes were determined in the [C₄mPyrr][NTf₂] ionic liquid, in order to identify systems which displayed changed reactivities in RTILs compared to those in molecular aprotic solvents. The altered reactivity of 1-bromo-4-nitrobenzene in the [C₄mPyrr][NTf₂] ionic liquid was utilised via electrochemical reduction at zinc microelectrodes in order to form arylzinc compounds. The work presented in this thesis shows that the oft-taken view that the reactivity of a given species in an ionic liquid will mimic that in conventional aprotic solvents is not always the case. Reactivities can be markedly different between RTILs and aprotic solvents and can also be highly dependent on the specific ionic liquid employed.

541

Desenvolvimento de novos sensores eletroquímicos descartáveis para fins analíticos / Development of new disposable electrochemical sensors for analytical purposes

Souza, Ana Paula Ruas de

16 October 2015

O presente trabalho trata do desenvolvimento de sensores eletroquímicos que possuam características descartáveis e ao uso destes dispositivos para a determinação de diferentes analitos em amostras biológicas, farmacêuticas e de interesse ambiental. O desenvolvimento e a aplicação dos sensores foram divididos em seis capítulos. O primeiro capítulo corresponde a fabricação de conjuntos de microeletrodos em suporte de CD-RW e placa fenolite utilizando impressão com tinta toner. Os conjuntos de microeletrodos foram fabricados por meio da deposição de duas máscaras de toner em um substrato de cobre ou ouro. Os eletrodos fabricados neste capítulo foram caracterizados e aplicados nos capítulos subsequentes. Os resultados da aplicação do conjunto de microeletrodos de cobre (DCRM) foram descritos no segundo capítulo. Os dispositivos foram aplicados para a determinação de peróxido de hidrogênio em amostras de antisséptico bucal e clareadores dentais. As determinações foram realizadas em solução de tampão fosfato (pH 7.0) por meio da técnica de amperometria (E = -0,2 V). Estes sensores foram também aplicados para determinação de ácido acetilsalítico (AAS) em amostras farmacêuticas em solução de hidróxido de sódio 0,1 mol L-1 por amperometria (E = 0,6 V). A determinação de nitrato em amostra de água de rio foi realizada por amperometria (E = -0,45V) em solução de sulfato de sódio 0,1 mol L-1 (pH = 2,0). Os resultados obtidos com o sensor demonstraram o sucesso das aplicações. As principais vantagens deste dispositivo dizem respeito à simplicidade de fabricação, baixo custo do equipamento e rapidez das análises. A caracterização eletroquímica do sensor e a determinação de ciclopirox olamina em solução de tampão BR 0,1 mol L-1 (pH = 5,0) utilizando o conjunto de microeletrodos de ouro (CD-RW) foi apresentada no terceiro capítulo. Os resultados obtidos mostraram que é possível realizar a determinação desta espécie de interesse em soluções oftalmológicas. O desenvolvimento, a caracterização e aplicação de um novo conjunto de microeletrodos de ouro fabricados a partir da redução eletroquímica da 5-bromo-1,10-fenantrolina em solução de dimetilformalmida (DMF) foi investidada no quarto capítulo. A superfície foi bloqueada com um filme isolante de 1,10-fenantrolina e o sensor foi caracterizado como um conjunto de microeletrodos de ouro. O sensor foi aplicado para a determinação de peróxido de hidrogênio, nas condições descritas anteriormente a fim de avaliar a aplicabilidade deste dispositivo. Os resultados obtidos foram promissores. A utilização de um eletrodo de microbanda impresso na configuração \"back-to-back\" foi descrita no quinto capítulo. A configuração faz uso da impressão de um novo eletrodo nas costas de um eletrodo impresso \"tradicional\", aumentando com isso a sensibilidade do sensor. O eletrodo impresso na configuração \"back-to-back\" foi utilizado para a determinação de íons Pb(II) em amostras de água potável por meio da técnica de voltametria de redissolução anódica por onda quadrada e os resultados obtidos foram concordantes com os encontrados utilizando espectrometria de emissão atômica por plasma acoplado. Os eletrodos de microbanda impressos na configuração \"back-to-back\" modificados com nanotubos de carbono para a determinação de capsaicina e dopamina e com ftalocianina de cobalto (II) para determinação de hidrazina foram investigados no sexto capítulo. Os resultados obtidos foram concordantes com aqueles descritos em outros trabalhos encontrados na literatura. / This work presents results on the fabrication of disposable electrochemical sensors and the use of such devices for the determination of different analytes in biological, pharmaceutical and environmental samples. The development and application of these sensors have been divided into six chapters. The first chapter describes the fabrication of a microelectrode ensemble (CD-RW) using ink toner. The sensor was fabricated by deposition of two toner pattern masks on copper and gold substrates. The electrodes fabricated according this procedure were characterized and applied in subsequent chapters. The second chapter describes the use of a disposable copper random microarrays (DCRM) for the amperometric determination of three analytes: hydrogen peroxide in real samples (oral antiseptic and dental whitening) at -0.2 V in phosphate buffer (pH 7.0) solution, acetylsalicylic acid (ASA) in pharmaceutical formulations at 0.6 V in 0.10 mol L-1 NaOH solution and nitrate in river samples at -0.45V in a 0.10 mol L-1 sodium sulfate solution (pH 2.0). The good results obtained with the DCRM demonstrated the successful application of this new sensor. The main advantages of the proposed manufacturing procedure are the simplicity, low cost of equipment and the high speed of production. The third chapter presents results on the use of a gold random microarray (GRM) for the determination of ciclopirox olamine in 0.10 mol L-1 Britton Robinson buffer solution (pH 5.0). Following the optimization of the experimental parameters, the proposed sensor presented excellent analytical properties for the amperometric detection of ciclopirox olamine at +0.85 V. The usefulness of the GRM sensor was confirmed by determining ciclopirox olamine in commercial products and the results obtained agreed well with those found by potentiometric titration and the labeled values. The fourth chapter describes the fabrication of a random assembly of microelectrodes (RAMs) by electrochemical reduction of 5-bromo-1,10- phenathroline in N,N-dimethylformamide (DMF), generating the 1,10-phenanthroline radical, which was covalently grafted on gold electrodes. After several potential cycles, the gold surface was partially blocked with an insulating film of 1,10-phenanthroline and the resulting modified electrode exhibited the characteristics of RAMs for the electrochemical reduction of the reversible probe 1,4-benzoquinone in DMF. This sensor was applied for hydrogen peroxide detection at -0.2 V in phosphate buffer (pH 7.0) solution. The fifth chapter reports on the use of screen-printed back-to-back microband electroanalytical sensors for quantification of lead(II) ions in drinking water samples in 0.01 mol L-1 HCl and the validation of the results by ICP-OES. The sixth chapter shows results on the use of back-to-back screen-printed microband electrodes modified with single-walled carbon nanotubes and cobalt phthalocyanine. The electroanalytical applications of this novel electrode configuration were exemplified towards the sensing of dopamine, capsaicin and hydrazine.

Back-to-back configuration

Chemical sensors

Configuração back-to-back

Conjunto de microeletrodos

Electroanalytical methods

Electrochemical modification

Eletrodos impressos

Métodos eletroanalíticos

Microband

Microbanda

Modificação eletroquímica

Random microelectrodes

Screen-printed electrode

Sensores químicos

Mesure de bioimpédance électrique par capteurs interdigités / Electrical Bioimpedance Measurement by Interdigital Sensors

Ibrahim, Mouhamad

07 December 2012

Ce travail de thèse traite de la caractérisation par spectroscopie d'impédance d'échantillons biologiques de très faibles dimensions. Les phénomènes de polarisation, classiques en spectroscopie d'impédance, créent une contrainte et augmentent l'erreur de mesure en basses fréquences. L'objectif principal de cette thèse est l'optimisation géométrique de la structure d'un capteur à électrodes interdigitées afin d'élargir la bande de fréquence utile. Le premier chapitre synthétise les données fondamentales relatives au comportement électrique des tissus biologiques ainsi que leurs propriétés électriques. Un état de l'art des techniques fondamentales de mesure d'impédance basées sur les électrodes micrométriques est aussi décrit. Le deuxième chapitre concerne une approche théorique pour l'optimisation du capteur. Cette optimisation sert à élargir la bande de fréquence utile de mesure. Elle consiste à choisir un rapport optimum de distance inter-électrodes sur largeur d'électrode. Une modélisation tridimensionnelle du système d'électrodes chargé par un milieu biologiquea été simulée sous ConventorWare©. Les résultats de cette simulation sont discutés. Le troisième chapitre traite de la conception et de la réalisation des biocapteurs. Les dispositifs technologiques développés sont décrits. La conception et la fabrication des composants sont présentées. Dans le dernier chapitre, une campagne de mesure sur des micro-volumes de fluides (solutions étalons, sang humain) est réalisée. Les mesures sont effectuées à l'aide de cinq micros capteurs à électrodes interdigitées. Les mesures réalisées sur des échantillons (solution étalons, sang humain) ainsi que la validation des dispositifs sont discutées. Les résultats obtenus sont comparés à des valeurs publiées dans la littérature et la théorie d'optimisation développée est validée et justifiée expérimentalement / The characterization by impedance spectroscopy of biological micro samples is one of the objectives of this thesis. The well known polarization phenomena at low frequency is a constraint that increases the measurement error. The main objective of this thesis is to optimize the geometric structure of an interdigitated electrode sensor in order to obtain confident experimental results in an extended useful frequency band without a significant influence of the polarization effect. The first chapter synthesizes fundamental data on the electrical behavior of biological tissues and their electrical properties. A state of the art techniques of the fundamental impedance measurement based on micrometric electrodes is also presented. The second chapter developps a theoretical approach for optimization of the biosensor. This optimization is used to expand the usable measurement. Indeed, it leads to determine the optimum distance between electrodes versus electrode width. A 3D modeling of the electrode system loaded by a biological medium was simulated using ConventorWare and the results are discussed. In the third chapter, the devices developed in this work are described. Design and manufacture of the biosensor components are described. In the last chapter, measurements on microvolumes of fluids (standard solutions, human blood) using five micros sensors with interdigitated electrodes are presented and discussed. Finally we compare these results to published values in the literature and the optimization theory is experimentally validated

Spectroscopie d'impédance électrique

Bioimpédance

Microélectrodes

Ingénierie biomédicale

Instrumentation électronique

Biocapteur

Polarisation électrique

Propriétés électriques

Electrical impedance spectroscopy

Bioimpedance

Microelectrodes

Biomedical engineering

Electronic instrumentation

Biosensor

Electrical polarization

Electrical properties

660.6

610.28

Desenvolvimento de novos sensores eletroquímicos descartáveis para fins analíticos / Development of new disposable electrochemical sensors for analytical purposes

Ana Paula Ruas de Souza

16 October 2015

O presente trabalho trata do desenvolvimento de sensores eletroquímicos que possuam características descartáveis e ao uso destes dispositivos para a determinação de diferentes analitos em amostras biológicas, farmacêuticas e de interesse ambiental. O desenvolvimento e a aplicação dos sensores foram divididos em seis capítulos. O primeiro capítulo corresponde a fabricação de conjuntos de microeletrodos em suporte de CD-RW e placa fenolite utilizando impressão com tinta toner. Os conjuntos de microeletrodos foram fabricados por meio da deposição de duas máscaras de toner em um substrato de cobre ou ouro. Os eletrodos fabricados neste capítulo foram caracterizados e aplicados nos capítulos subsequentes. Os resultados da aplicação do conjunto de microeletrodos de cobre (DCRM) foram descritos no segundo capítulo. Os dispositivos foram aplicados para a determinação de peróxido de hidrogênio em amostras de antisséptico bucal e clareadores dentais. As determinações foram realizadas em solução de tampão fosfato (pH 7.0) por meio da técnica de amperometria (E = -0,2 V). Estes sensores foram também aplicados para determinação de ácido acetilsalítico (AAS) em amostras farmacêuticas em solução de hidróxido de sódio 0,1 mol L-1 por amperometria (E = 0,6 V). A determinação de nitrato em amostra de água de rio foi realizada por amperometria (E = -0,45V) em solução de sulfato de sódio 0,1 mol L-1 (pH = 2,0). Os resultados obtidos com o sensor demonstraram o sucesso das aplicações. As principais vantagens deste dispositivo dizem respeito à simplicidade de fabricação, baixo custo do equipamento e rapidez das análises. A caracterização eletroquímica do sensor e a determinação de ciclopirox olamina em solução de tampão BR 0,1 mol L-1 (pH = 5,0) utilizando o conjunto de microeletrodos de ouro (CD-RW) foi apresentada no terceiro capítulo. Os resultados obtidos mostraram que é possível realizar a determinação desta espécie de interesse em soluções oftalmológicas. O desenvolvimento, a caracterização e aplicação de um novo conjunto de microeletrodos de ouro fabricados a partir da redução eletroquímica da 5-bromo-1,10-fenantrolina em solução de dimetilformalmida (DMF) foi investidada no quarto capítulo. A superfície foi bloqueada com um filme isolante de 1,10-fenantrolina e o sensor foi caracterizado como um conjunto de microeletrodos de ouro. O sensor foi aplicado para a determinação de peróxido de hidrogênio, nas condições descritas anteriormente a fim de avaliar a aplicabilidade deste dispositivo. Os resultados obtidos foram promissores. A utilização de um eletrodo de microbanda impresso na configuração \"back-to-back\" foi descrita no quinto capítulo. A configuração faz uso da impressão de um novo eletrodo nas costas de um eletrodo impresso \"tradicional\", aumentando com isso a sensibilidade do sensor. O eletrodo impresso na configuração \"back-to-back\" foi utilizado para a determinação de íons Pb(II) em amostras de água potável por meio da técnica de voltametria de redissolução anódica por onda quadrada e os resultados obtidos foram concordantes com os encontrados utilizando espectrometria de emissão atômica por plasma acoplado. Os eletrodos de microbanda impressos na configuração \"back-to-back\" modificados com nanotubos de carbono para a determinação de capsaicina e dopamina e com ftalocianina de cobalto (II) para determinação de hidrazina foram investigados no sexto capítulo. Os resultados obtidos foram concordantes com aqueles descritos em outros trabalhos encontrados na literatura. / This work presents results on the fabrication of disposable electrochemical sensors and the use of such devices for the determination of different analytes in biological, pharmaceutical and environmental samples. The development and application of these sensors have been divided into six chapters. The first chapter describes the fabrication of a microelectrode ensemble (CD-RW) using ink toner. The sensor was fabricated by deposition of two toner pattern masks on copper and gold substrates. The electrodes fabricated according this procedure were characterized and applied in subsequent chapters. The second chapter describes the use of a disposable copper random microarrays (DCRM) for the amperometric determination of three analytes: hydrogen peroxide in real samples (oral antiseptic and dental whitening) at -0.2 V in phosphate buffer (pH 7.0) solution, acetylsalicylic acid (ASA) in pharmaceutical formulations at 0.6 V in 0.10 mol L-1 NaOH solution and nitrate in river samples at -0.45V in a 0.10 mol L-1 sodium sulfate solution (pH 2.0). The good results obtained with the DCRM demonstrated the successful application of this new sensor. The main advantages of the proposed manufacturing procedure are the simplicity, low cost of equipment and the high speed of production. The third chapter presents results on the use of a gold random microarray (GRM) for the determination of ciclopirox olamine in 0.10 mol L-1 Britton Robinson buffer solution (pH 5.0). Following the optimization of the experimental parameters, the proposed sensor presented excellent analytical properties for the amperometric detection of ciclopirox olamine at +0.85 V. The usefulness of the GRM sensor was confirmed by determining ciclopirox olamine in commercial products and the results obtained agreed well with those found by potentiometric titration and the labeled values. The fourth chapter describes the fabrication of a random assembly of microelectrodes (RAMs) by electrochemical reduction of 5-bromo-1,10- phenathroline in N,N-dimethylformamide (DMF), generating the 1,10-phenanthroline radical, which was covalently grafted on gold electrodes. After several potential cycles, the gold surface was partially blocked with an insulating film of 1,10-phenanthroline and the resulting modified electrode exhibited the characteristics of RAMs for the electrochemical reduction of the reversible probe 1,4-benzoquinone in DMF. This sensor was applied for hydrogen peroxide detection at -0.2 V in phosphate buffer (pH 7.0) solution. The fifth chapter reports on the use of screen-printed back-to-back microband electroanalytical sensors for quantification of lead(II) ions in drinking water samples in 0.01 mol L-1 HCl and the validation of the results by ICP-OES. The sixth chapter shows results on the use of back-to-back screen-printed microband electrodes modified with single-walled carbon nanotubes and cobalt phthalocyanine. The electroanalytical applications of this novel electrode configuration were exemplified towards the sensing of dopamine, capsaicin and hydrazine.

Configuração back-to-back

Conjunto de microeletrodos

Eletrodos impressos

Métodos eletroanalíticos

Microbanda

Modificação eletroquímica

Sensores químicos

Back-to-back configuration

Chemical sensors

Electroanalytical methods

Electrochemical modification

Microband

Random microelectrodes

Screen-printed electrode

Micromachined three-dimensional electrode arrays for in-vitro and in-vivo electrogenic cellular networks

Rajaraman, Swaminathan

06 April 2009

This dissertation presents an investigation of micromachined three-dimensional microelectrode arrays (3-D MEAs) targeted toward in-vitro and in-vivo biomedical applications. Current 3-D MEAs are predominantly silicon-based, fabricated in a planar fashion, and are assembled to achieve a true 3-D form: a technique that cannot be extended to micro-manufacturing. The integrated 3-D MEAs developed in this work are polymer-based and thus offer potential for large-scale, high volume manufacturing. Two different techniques are developed for microfabrication of these MEAs - laser micromachining of a conformally deposited polymer on a non-planar surface to create 3-D molds for metal electrodeposition; and metal transfer micromolding, where functional metal layers are transferred from one polymer to another during the process of micromolding thus eliminating the need for complex and non-repeatable 3-D lithography processes. In-vitro and in-vivo 3-D MEAs are microfabricated using these techniques and are packaged utilizing Printed Circuit Boards (PCB) or other low-cost manufacturing techniques. To demonstrate in-vitro applications, growth of 3-D co-cultures of neurons/astrocytes and tissue-slice electrophysiology with brain tissue of rat pups were implemented. To demonstrate in-vivo application, measurements of nerve conduction were implemented. Microelectrode impedance models, noise models and various process models were evaluated. The results confirmed biocompatibility of the polymers involved, acceptable impedance range and noise of the microelectrodes, and potential to improve upon an archaic clinical diagnostic application utilizing these 3-D MEAs.

Metal transfer micromolding

MEMS

Micromachining

Biocompatible MEMS

In-vitro tissue slice electrophysiology

Neurotechnology

Microelectrode impedance

Biomedical

Laser micromachining

In-vivo nerve tracking

Microelectrodes

Biosensors

Polymers in medicine