Electrochemical studies of coatings and thin films

Kang, Jiho.

January 2006

Thesis (Ph. D.)--Ohio State University, 2006. / Available online via OhioLINK's ETD Center; full text release delayed at author's request until 2007 Jan 27

Probing the biocompatibility of biomedical interfaces using the Quartz Crystal Microbalance with Dissipation

Cromhout, Mary

January 2011

The biomedical application of nanotechnology has come into the spotlight, with the promise of ‘personalised’ therapeutics that couple early diagnosis with targeted therapeutic activity. Due to the rapid growth of the biomedical applications of nanoparticles, along with the lack of understanding concerning their interactions with biomolecules, there is a pressing need for the development of standard methods directed at investigating the effect of introducing these unique particles into the human body. The central aim of this research is to establish a platform directed at assessing the biological fate of pioneering therapeutic particulate agents, such as metallophthalocyanines (MPcs) and multi-walled carbon nanotubes (FMWCNTs). In particular, we proposed, that Quartz Crystal Microbalance with Dissipation (QCM-D) technology may be employed to assess the composition of blood protein corona deposited on the therapeutic surface, and subsequently assess the biocompatibility of such particles. The proposed method of protein detection utilises the nanogram sensitivity of QCM-D technology to monitor highly specific antibody-antigen interactions. In particular those interactions which occur when probe antibodies are used to detect adsorbed blood proteins deposited on target particle-modified sensor surfaces. Protein detection analysis was directed toward identification of surface bound human serum albumin, complement factor C3c, and human plasma fibrinogen. Preliminary analysis of generic biomedical surfaces indicated human serum albumin demonstrates a higher binding affinity towards positively charged surfaces (i.e. cysteamine self-assembled monolayer), followed by hydrophobic surfaces. Detection of complement C3c, corresponded with literature, where lower levels were detected on negatively charged surfaces (i.e. mercapto undecanoic acid self-assembled monolayer), and higher levels of more hydrophobic surfaces (i.e. 11-amino undecane thiol self-assembled monolayer). Human plasma fibrinogen was observed to favour hydrophilic over hydrophobic self-assembled monolayer surfaces, which was in accordance with literature. Application of the proposed protein detection method for biocompatibility analysis of target therapeutic molecules, namely metallophthalocyanines and acid functionalised multi-walled carbon nanotubes, demonstrated a dependence on modified-surface film characteristics, such as surface charge and topography with regards to human serum albumin and human plasma fibrinogen analysis representing new insights into their potential biomolecular interactions The highest levels of detected human serum albumin and complement C3c were detected on the GePcSmix-modified surfaces. AlPcSmix-modified surfaces analysis suggested the highest levels of human plasma fibrinogen. Two methods of acid functionalisation were employed, using both nitric and sulphuric acid, and pure nitric acid. A general increase in detected human serum albumin, corresponding with an increase in functionalisation time, was observed. Complement C3c detection suggested an increase in deposited complement C3c, with increasing functionalisation time, when assessing nitric acid functionalised multi-walled carbon nanotubes, and a decrease, with increasing functionalisation time, when assessing nitric and sulphuric acid functionalised multi-walled carbon nanotubes. Analysis of human plasma fibrinogen was inconclusive, as were cytotoxicity experiments utilising MCF-7 cells in the presence of metallophthalocyanine complexes, raising simultaneously important considerations for their application and study. In the first such detailed examination of its kind it was concluded that the proposed method of protein detection, using QCM-D, allows for the rudimentary but rapid means of analysis of select protein corona deposited on particulate biomedical surfaces.

Biomedical materials

Nanostructured materials

Biomedical engineering

Quartz crystal microbalances

Blood proteins

Nanoparticles

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

Interfacial Study of Copper Electrodeposition with the Electrochemical Quartz Crystal Microbalance (EQCM)

Ojeda Mota, Oscar Ulises

05 1900

The electrochemical quartz crystal microbalance (EQCM) has been proven an effective mean of monitoring up to nano-scale mass changes related to electrode potential variations at its surface. The principles of operation are based on the converse piezoelectric response of quartz crystals to mass variations on the crystal surface. In this work, principles and operations of the EQCM and piezo-electrodes are discussed. A conductive oxide, ruthenium oxide (RuO2) is a promising material to be used as a diffusion barrier for metal interconnects. Characterization of copper underpotential deposition (UPD) on ruthenium and RuO2 electrodes by means of electrochemical methods and other spectroscopic methods is presented. Copper electrodeposition in platinum and ruthenium substrates is investigated at pH values higher than zero. In pH=5 solutions, the rise in local pH caused by the reduction of oxygen leads to the formation of a precipitate, characterized as posnjakite or basic copper sulfate by means of X-ray electron spectroscopy and X-ray diffraction. The mechanism of formation is studied by means of the EQCM, presenting this technique as a powerful in-situ sensing device.

Quartz crystal microbalances.

Copper.

Electroplating.

ruthenium

EQCM

patina

copper plating

Development of a QCM-D based biosensor for detection of waterborne E. coli O157:H7

Poitras, Charles.

January 2008

No description available.

Quartz crystal microbalances.

Monomolecular films.

Escherichia coli O157:H7.

Biosensors -- Design and construction.

Waterborne infection.

Procedural optimization of the quartz crystal microbalance for rapid detection of Escherichia coli O157:H7

Lim, Yimei Angelina

January 2007

[Truncated abstract] The applications of biosensors are rapidly expanding with the increased emphasis placed on the use of technology in the evaluation of food safety and also in military use. The United States food industry carried out 144.3 million microbiological tests in 1999 (Alocilja and Radke, 2003). These numbers are expected to rise with the recently implemented regulatory measures for food safety in the United States. In fact, similar trends in food safety are occurring on a global scale. Furthermore, with the recognition and establishment of Microbial Forensics as a new field of forensics, the interest in biosensor development for the detection of microbes will thrive. Moreover, the recent spate of biocrimes, notably the anthrax scares, has called for newer and improved techniques for the sensitive, rapid and reproducible detection of microbes. Biosensors have the capability to fill this role as an efficient device for microbial detection. There is a wide range of biosensors available for different purposes. In addition, their versatility allows for their overlap in many fields. The quartz crystal microbalance (QCM) is a biosensor that is cost-efficient, sensitive, field-deployable with the ability to perform automated, real-time assays within minutes. The QCM is a mass sensitive device that works on the principle where a change in mass deposited on the crystal is inversely proportional to the change in the resonant frequency of the crystal. Therefore, frequency decreases with increasing mass deposited. The QCM has been used in several studies as a biosensor for the detection of a number of viral and bacterial species. ... High antibody incubation concentration required a shorter antibody incubation duration. Conversely, low antibody incubation concentration required a longer antibody incubation duration. Furthermore, regardless of antibody incubation concentration, a distinct pattern in the rate of antibody binding with time was observed. One hour antigen incubation at ambient room temperature (22.5oC) was sufficient for the efficient binding of the antigens to the immobilized antibody layer. Extension of antigen binding time to 15 hours produced inconsequential differences in readings. The binding efficiency of the quartz crystals after a storage period of 2 to 4 weeks at ambient room temperature (22.5oC) fared better than the crystals that were refrigerated at 4oC. Results showed that 0.2M glycine hydrochloride is a poor reagent for the removal of the antigen layer on the quartz crystals for repeated assay use. The 16-mercaptohexadecanoic acid (MHDA) layer and adsorbed proteins on the quartz crystals can be removed by a mixture of sulphuric acid and hydrogen peroxide, known as a piranha process. This allows the crystals to be repeatedly recoated and reused. Overall, this research provides new insights into the preparation process of the quartz crystals for the specific detection of E. coli O157:H7. Conclusive results have been obtained for several tested parameters and suggestions have been raised for further studies in the optimization of the QCM for the E. coli O157:H7 detection process. With improved knowledge and recognition in the capability of the QCM as a biosensor, the QCM may soon be used in conjunction with conventional techniques for the rapid detection of E. coli O157:H7.

Biosensors

Quartz crystal microbalances

Escherichia coli O157:H7

Microbiology -- Technique

Food contamination -- Prevention

Biosensor

Quartz crystal microbalance

Escherichia coli O157:H7