Development of biosensors based on Odorant Binding Proteins

Tuccori, Elena

January 2014

This PhD project aimed to investigate the possibility of using Odorant Binding Proteins (OBPs) as sensing layers of chemical sensors, for the detection of organic compounds in both vapour and liquid phases. OBPs are small soluble proteins present in high concentrations in the olfactory system of vertebrates and insects. OBPs are attractive in the biosensor field since they can bind odorants and pheromones in a reversible way. They are resistant to high temperatures and protease activity and they can be easily expressed in large amounts. OBPs belonging to different species of mammals and insects were utilised for developing biosensors relied on different transduction mechanisms. Recombinant OBPs were grafted on the gold electrode of transducers by using Self-assembled monolayers (SAMs) of alkanethiols. The efficiency of the immobilisation method was proved by using electrochemical techniques. Quartz crystal microbalances (QCMs), screen-printed electrodes (SPEs) and interdigitated electrodes (IDEs) were employed for developing three types of OBP-based biosensors. I. QCMs functionalised with OBPs were tested against pheromones (i.e. bombykol and bombykal) and volatile compounds found in foodstuffs (i.e. pyrazine derivatives and geosmin) in vapour phase. The QCM based biosensors showed a good degree of selectivity and a detection limit of the order of parts per billion, in air. II. In liquid phase, impedimetric biosensors based on SPEs also showed a good selectivity and sensitivity being able to detect analyte concentrations of the order of 10-9 M. III. OBPs immobilised on the gold electrodes of IDEs were instead tested against S-(+) carvone vapour, proving that the binding activity of the proteins was preserved in vapour phase and can be quantified as variation of capacitance. The developed OBP biosensors showed good selectivity, sensitivity and stability over time in both liquid and vapour phase. The responses of the sensors were reversible, allowing to the device to be used several times. Moreover, the biosensors were label-free, hence the interaction between OBPs and ligand was directly detected without using auxiliary probes/species. With these findings, we envisage the use of our biosensors in several applications, including monitoring of the quality of food along the transportation and storage, controlling of pests and useful insects in agriculture, or as analytical devices for studying the dynamics in binding processes.

572

Elektrochemické korozní charakteristiky Mg-Zn systémů připravených metodou práškové metalurgie / Electrochemical corrosion characteristics of Mg-Zn systems prepared by powder metallurgy

Kotek, Jakub

January 2018

The diploma thesis deals with evaluation of electrochemical corrosion characteristics of Mg-Zn systems prepared by powder metallurgy in SBF solution. The main aim of the thesis is to analyze the influence of chemical composition, achieved structure and parameters of the process of production of Mg-Zn systems on their electrochemical corrosion characteristics. The basic electrochemical properties of the prepared materials will be evaluated by electrochemical impedance spectroscopy. In order to clarify the mechanism of corrosion of materials, the immersion tests will be used, accompanied by metallographic observations.

Uhlíkové elektrody pro superkondenzátory / Carbon based electrodes for supercapacitors

Moncoľ, Maroš

January 2010

This master thesis deals with supercapacitors based on electrical double layer and proper carbon electrodes for this type of supercapacitors. In theoretical part of work is described theory of supercapacitors, energy storage principles and their properties. In the next part are described carbon materials, their properties and electrochemical methods of measurements that we used. In the experimental part is described preparation of electrodes, results and conclusion.

Optimalizace struktury kompozitních materiálů na bázi uhlíku / Optimalisation of coposite materials for civil engineering

Kazda, Tomáš

January 2011

This work is focused on optimalisation of coposite materials for civil engineering. In the theoretical part of the project is introduction of the composite materials and materials which are used for their production. There are also concerned their properties and possible application areas. In conclusion of theoretical part this project is a summary of the possible use of composite materials. The practical part compares the characteristics of the different types of composites made in terms of conductivity and the rate of corrosion.

Nanostrukturované povrchy pro elektrochemickou detekci / Nanostructured surfaces for electrochemical detection

Dzuro, Matej

January 2014

This work deals with the preparation of gold nanostructures for future usage in electrochemical sensors and biosensors, methods for their characterization and production. The emphasis is focused on the template-based electrodeposition method of gold and on study of the effect of manufacturing conditions on physical properties, mainly electrical and topological of nanostructures. Thesis is focused also on overall function and sensitivity of the gold nanostructured electrode.

Long Term Corrosion of Reinforcing Strips in Mechanically Stabilized Earth Walls

Berke, Brandon Seth

16 March 2009

Mechanically stabilized earth (MSE) walls are a more advanced form of a retaining wall, often larger and able to hold back more backfill. This is achieved by reinforcing strips or meshes (most often galvanized steel) placed into the soil, which are held in place by friction. The strips mechanically stabilize the earth while undergoing tension. The wall is covered with concrete medallions that connect to the reinforcements. The medallions have only a secondary structural role in holding up the wall but provide cover that protects the soil from washing away. MSE walls are structures expected to have very long service lives (e.g. 100 years). Confirmation is needed that such durability can be achieved, especially to show that the progression of corrosion of the reinforcement is slow enough. Ten MSE walls around Florida were instrumented (electrical connections were made through the concrete covers to the buried elements) between 1996- 1998 and used to survey corrosion rates of galvanized strip or mesh soil reinforcements. Initial estimates of corrosion-related durability were obtained at that time, indicating a good prognosis for long term durability. The objective of the research in this thesis was to obtain additional indications of the durability of reinforcements in MSE walls in Florida so as to perform a more reliable projection of future performance. Corrosion behavior was measured at the same locations as the initial survey by electrochemical nondestructive tests and by destructive tests. The nondestructive testing consisted of half-cell potentials, polarization resistance measurements, and electrochemical impedance spectroscopy. Corrosion rates reported in this thesis are based upon polarization resistance measurements. The destructive testing consisted of soil extraction and hardware extraction. Hardware extraction enabled independent verification of estimates of electrochemical corrosion rate. Analysis of extracted soil verified that soil composition was within construction specifications. The data from the current survey were also used to further improve prediction of corrosion. The present series of evaluations confirm that the structures are performing as desired based upon the updated model projection of future corrosion.

Electrochemical Impedance

Buried Metal

Galvanized Steel

Polarization Resistance

Durability

American Studies

Arts and Humanities

Conducting Polymer Based Gel Electrolytes for pH Sensitivity

Kashyap, Aditya Jagannath

22 March 2019

The evaluation of concentration of ions and molecules with the help of biosensors have been regarded as an emerging technology. Bio and chemical sensors have a variety of applications in the field of medicine, military, environmental and food industries alike. With an estimated investment growth of over 4.31% in the development of pH sensors in the next five year, the objective of a developing a robust measurement system is all the more required. The scope of this research is to evaluate the ability of conducting polymer-based gel electrolytes for pH sensitivity, as a function of the transistor characteristics using an Extended Gate Field Effect Transistor or a conducting film in an electrochemical cell. Polymer gels were prepared by dissolving a suitable conducting polymer in an acidic media. The interaction of the gel with a buffer solution of known pH was collected as electric signals using a glassy carbon as an electrode. The electrochemical cell was further connected to the gate of a Metal-Oxide-Semiconductor Field Effect transistor (MOS-FET). The drain current was measured under two conditions; a) voltage across the gate (VGS) was kept constant, with varying voltage across the drain (VDS) and b) voltage across drain was fixed, while gate voltage changed. The drain current versus voltage of the transistor was plotted as a function of the ion interaction between the gel and the buffer. Different plots were recorded for different values of pH solutions. Final results were plotted to calculate the change in threshold voltage, for every change in pH of the observed solution. pH sensitivity of the gels was further tested through the Electrochemical Impedance Spectroscopy method, using a potentiostat and a three-electrode electrochemical cell. With a small excitation, the AC current flowing through the circuit at different frequencies were recorded and the plots discussed, to evaluate sensitivity to pH.

Characterizartion

Conducting Polymer Composite

EGFET

Electrochemical impedance Spectroscopy

Electrochemical Systems

Materials Science and Engineering

Polymer Chemistry

Microfluidic Electrical Impedance Spectroscopy

Foley, John J

01 September 2018

The goal of this study is to design and manufacture a microfluidic device capable of measuring changes in impedance valuesof microfluidic cell cultures. Tocharacterize this, an interdigitated array of electrodes was patterned over glass, where it was then bonded to a series of fluidic networks created in PDMS via soft lithography. The device measured ethanol impedance initially to show that values remain consistent over time. Impedance values of water and 1% wt. saltwater were compared to show that the device is able to detect changes in impedance, with up to a 60% reduction in electrical impedance in saltwater. Cells were introduced into the device, where changes in impedance were seen across multiple frequencies, indicating that the device is capable of detecting the presence of biologic elements within a system. Cell measurements were performed using NIH-3T3 fibroblasts.

Microfluidics

Electrochemical Impedance Spectroscopy

Device Design

Lithography

Biological Engineering

Biomechanics and Biotransport

Biomedical

Biomedical Devices and Instrumentation

Biotechnology

Study of green film-forming corrosion inhibitor based on mussel adhesive protein

Holmér, Camilla

January 2013

Today there are numerous methods to slow down a corrosion process of metallic materials. However, due to environmental effects and health risk issues, several traditional corrosion inhibitors have to be phased out. Hence, it is of great importance to develop new corrosion inhibitors that are “green”, safe, smart and multifunctional. In this essay, the focus is on mussel adhesive protein (MAP) and its possibility to reduce the rate of the corrosion process. The protein exhibit great adhesive strength and protective properties, allowing it to adhere to a multitude of different surfaces and is therefore of great interest of corrosion science. The protein Mefp-1, derived from the blue mussel´s foot, had been pre-adsorbed on the carbon steel surface and provided good corrosion inhibition in a basic chloride solution for a short exposure time. The protection was further improved with the assist of iron and ceria ions by formation of protein/ions complexes within the surface films and thus enhanced the corrosion protection for longer exposure time. Ceria nanoparticles were used in order to create a multi-layer composite film with an even higher corrosion protection. The results suggest a denser film compared to previous samples and a more uniform surface.

Mussel adhesive protein (MAP)

corrosion

corrosion protection

potentiodynamic polarization

Chemical Sciences

Kemi

Modelling and Experimental Investigation of the Dynamics in Polymer Electrolyte Fuel Cells

Wiezell, Katarina

January 2009

In polymer electrolyte fuel cells (PEFC) chemical energy, in for example hydrogen, is converted by an electrochemical process into electrical energy. The PEFC has a working temperature generally below 100 °C. Under these conditions water management and transport of oxygen to the cathode are the parameters limiting the performance of the PEFC. The purpose of this thesis was to better understand the complex processes in different parts of the PEFC. The rate-limiting processes in the cathode were studied using pure oxygen while varying oxygen pressure and humidity. Mass-transport limitations in the gas diffusion layer using oxygen diluted in nitrogen or helium was also studied. A large capacitive loop was seen at 1-10 Hz with 5-20 % oxygen. When nitrogen was changed to helium, which has a higher binary diffusion coefficient, the loop decreased and shifted to a higher frequency. Steady-state and electrochemical impedance spectroscopy (EIS) models have been developed that accounts for water transport in the membrane and the influence of water on the anode. Due to water drag, the membrane resistance changes with current density. This gives rise to a low frequency loop in the complex plane plot. The loop appeared at a frequency of around 0.1 Hz and varied with D/Lm2, where D is the water diffusion coefficient and Lm is the membrane thickness. The EIS model for the hydrogen electrode gave three to four semicircles in the complex plane plot when taking the influence of water concentration on the anode conductivity and kinetics into account. The high-frequency semicircle is attributed to the Volmer reaction, the medium-frequency semicircle to the pseudocapacitance resulting from the adsorbed hydrogen, and the low-frequency semicircles to variations in electrode performance with water concentration. These low-frequency semicircles appear in a frequency range overlapping with the low-frequency semicircles from the water transport in the membrane. The effects of current density and membrane thickness were studied experimentally. An expected shift in frequency, when varying the membrane thickness was seen. This shift confirms the theory that the low-frequency loop is connected to the water transport in the membrane. / <p>QC 20121011</p>

polymer electrolyte fuel cell

modelling

electrochemical impedance spectroscopy

water transport

membrane

Inorganic Chemistry

Oorganisk kemi