Desenvolvimento de superfícies nanoestruturadas capacitivas e eletroquimicamente ativas para aplicações em diagnóstico clínico /

Oliveira, Raphael Mazzine Barbosa.

January 2018

Orientador: Paulo Roberto Bueno / Coorientador: Flávio Cesar Bedatty Fernandes / Banca: Hideko Yamanaka / Banca: Marina Ribeiro Batistuti / Resumo: Desde a primeira descrição de biossensor reportada por Clark e Lyons em 1962, houve um extenso trabalho no desenvolvimento e aprimoramento de novas técnicas de biossensoriamento para detecção de biomarcadores com relevância médica. Destaca-se nesse processo o estudo de superfície de eletrodos, pois esse influencia diretamente em aspectos como; sensibilidade, estabilidade e qualidade do sinal. Portanto, este projeto consiste em avaliar comparativamente três superfícies de eletrodos baseadas em nanoestruturas contendo nanopartículas de azul da Prússia, funcionando com sonda redox do sistema, e materiais carbonáceos (como óxido de grafeno e nanotubos de carbono) para aplicação em biossensores. Foram avaliados aspectos como composição, características capacitivas redox e estabilidade de sinal. A técnica de análise utilizada é a espectroscopia de capacitância eletroquímica (ECE) que apresenta vantagens como não usar amplificadores de sinal (sondas redox) em solução, configuração esta, importante para métodos de diagnóstico point-of-care. Das superfícies analisadas, a composta por nanopartículas de azul da Prússia e óxido de grafeno (PBNP+GO) apresentou os melhores parâmetros de estabilidade e compatibilidade com os aspectos teóricos da técnica de ECE, sendo então selecionada para realização de testes de biossensoriamento que, através da funcionalização da superfície com anticorpos Anti-IL-6, detectaram seletivamente a presença do biomarcador IL-6. / Abstract: Since the first description of biosensor reported by Clark and Lyons in 1962, numerous works related to the development and enhancement of novel medical biosensing techniques have been published. In that context, it must be highlighted the study of electrode surfaces as it has direct influence in aspects like; sensitivity, stability and signal quality. Therefore, this project aims to evaluate three electrode surfaces based on nanostructures with Prussian blue nanoparticles, as redox probe, and carbonaceous materials (like graphene oxide and carbon nanotubes) and their application in biosensors. It was evaluated aspects like composition, redox capacitive characteristics and signal stability. The electrochemical capacitance spectroscopy technique (ECE) was used as it offers several advantages like no need of signal amplifiers (redox probes) in solution and, then, making this technique more adequate for point-of-care diagnosis. Among the analysed surfaces, the one composed by Prussian blue nanoparticles and graphene oxide (PBNP+GO) was identified as the best surface in terms of stability and compatibility to the theoretical aspects of ECE. Therefore, that structure was selected to further biosensing essays, by functionalizing the surface with Anti-IL-6 antibodies, that indicated the selective detection of the IL-6 biomarker. / Mestre

Biossensores.

Eletroquímica.

Grafeno.

Filmes finos.

Espectroscopia de impedancia.

Electrochemical Biosensor.

Capacitive Biosensor.

Graphene.

Energy-Efficient Capacitance-to-Digital Converters for Smart Sensor Applications

Alhoshany, Abdulaziz

12 1900

One of the key requirements in the design of wireless sensor nodes and miniature biomedical devices is energy efficiency. For a sensor node, which is a sensor and readout circuit, to survive on limited energy sources such as a battery or harvested energy, its energy consumption should be minimized. Capacitive sensors are candidates for use in energy-constrained applications, as they do not consume static power and can be used in a wide range of applications to measure different physical, chemical or biological quantities. However, the energy consumption is dominated by the capacitive interface circuit, i.e. the capacitance-to-digital converter (CDC). Several energy-efficient CDC architectures are introduced in this dissertation to meet the demand for high resolution and energy efficiency in smart capacitive sensors. First, we propose an energy-efficient CDC based on a differential successive-approximation data converter. The proposed differential CDC employs an energy-efficient operational transconductance amplifier (OTA) based on an inverter. A wide capacitance range with fine absolute resolution is implemented in the proposed coarse-fine DAC architecture which saves 89% of silicon area. The proposed CDC achieves an energy efficiency figure-of-merit (FOM) of 45.8fJ/step, which is the best reported energy efficiency to date. Second, we propose an energy efficient CDC for high-precision capacitive resolution by using oversampling and noise shaping. The proposed CDC achieves 150 aF absolute resolution and an energy efficiency FOM of 187fJ/conversion-step which outperforms state of the art high-precision differential CDCs. In the third and last part, we propose an in-vitro cancer diagnostic biosensor-CMOS platform for low-power, rapid detection, and low cost. The introduced platform is the first to demonstrate the ability to screen and quantify the spermidine/spermine N1 acetyltransferase (SSAT) enzyme which reveals the presence of early-stage cancer, on the surface of a capacitive biosensor. This platform, which is a biosensor combined with a highly energy-efficient digital CDC, is implemented and fabricated in a CMOS technology and can sense and convert the capacitance value from the biosensor to a digital word in an energy efficient way. The platform achieves an ultra-low power consumption: four orders of magnitude less than the state-of-the-art biosensor-CMOS platforms.

capacitative sensor interface

CDC

energy-efficient

capacitive biosensor

figure of merit (FOM)

CMOS

Desenvolvimento de superfícies nanoestruturadas capacitivas e eletroquimicamente ativas para aplicações em diagnóstico clínico / Development of capacitive and electrochemical active nanostructured surfaces for application in clinical diagnostics

Oliveira, Raphael Mazzine Barbosa

21 August 2018

Submitted by RAPHAEL MAZZINE BARBOSA DE OLIVEIRA (mazzine.r@gmail.com) on 2018-08-31T12:54:04Z No. of bitstreams: 1 DISSERTACAO_RMAZZINE.pdf: 2481284 bytes, checksum: e17b453dc770c4f6b899c9c0a5de342a (MD5) / Approved for entry into archive by Ana Carolina Gonçalves Bet null (abet@iq.unesp.br) on 2018-09-05T12:38:02Z (GMT) No. of bitstreams: 1 oliveira_rmb_me_araiq_int.pdf: 2195098 bytes, checksum: 013fbe713d5edbed6ff4d629e660b906 (MD5) / Made available in DSpace on 2018-09-05T12:38:02Z (GMT). No. of bitstreams: 1 oliveira_rmb_me_araiq_int.pdf: 2195098 bytes, checksum: 013fbe713d5edbed6ff4d629e660b906 (MD5) Previous issue date: 2018-08-21 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Desde a primeira descrição de biossensor reportada por Clark e Lyons em 1962, houve um extenso trabalho no desenvolvimento e aprimoramento de novas técnicas de biossensoriamento para detecção de biomarcadores com relevância médica. Destaca-se nesse processo o estudo de superfície de eletrodos, pois esse influencia diretamente em aspectos como; sensibilidade, estabilidade e qualidade do sinal. Portanto, este projeto consiste em avaliar comparativamente três superfícies de eletrodos baseadas em nanoestruturas contendo nanopartículas de azul da Prússia, funcionando com sonda redox do sistema, e materiais carbonáceos (como óxido de grafeno e nanotubos de carbono) para aplicação em biossensores. Foram avaliados aspectos como composição, características capacitivas redox e estabilidade de sinal. A técnica de análise utilizada é a espectroscopia de capacitância eletroquímica (ECE) que apresenta vantagens como não usar amplificadores de sinal (sondas redox) em solução, configuração esta, importante para métodos de diagnóstico point-of-care. Das superfícies analisadas, a composta por nanopartículas de azul da Prússia e óxido de grafeno (PBNP+GO) apresentou os melhores parâmetros de estabilidade e compatibilidade com os aspectos teóricos da técnica de ECE, sendo então selecionada para realização de testes de biossensoriamento que, através da funcionalização da superfície com anticorpos Anti-IL-6, detectaram seletivamente a presença do biomarcador IL-6. / Since the first description of biosensor reported by Clark and Lyons in 1962, numerous works related to the development and enhancement of novel medical biosensing techniques have been published. In that context, it must be highlighted the study of electrode surfaces as it has direct influence in aspects like; sensitivity, stability and signal quality. Therefore, this project aims to evaluate three electrode surfaces based on nanostructures with Prussian blue nanoparticles, as redox probe, and carbonaceous materials (like graphene oxide and carbon nanotubes) and their application in biosensors. It was evaluated aspects like composition, redox capacitive characteristics and signal stability. The electrochemical capacitance spectroscopy technique (ECE) was used as it offers several advantages like no need of signal amplifiers (redox probes) in solution and, then, making this technique more adequate for point-of-care diagnosis. Among the analysed surfaces, the one composed by Prussian blue nanoparticles and graphene oxide (PBNP+GO) was identified as the best surface in terms of stability and compatibility to the theoretical aspects of ECE. Therefore, that structure was selected to further biosensing essays, by functionalizing the surface with Anti-IL-6 antibodies, that indicated the selective detection of the IL-6 biomarker. / 1583843

Biossensor eletroquímico

Biosensor Capacitivo

Grafeno

Azul da Prússia

Electrochemical Biosensor

Capacitive Biosensor

Graphene

Prussian Blue

Electrochemical Capacitance Spectroscopy