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The main objective of this research is to design, fabricate, characterize, and test the silicon based vertical electrode Nanogap biosensor which will be used to detect and identify target proteins in aqueous solution.
The main objective of this research is to design, fabricate, characterize, and test the silicon based vertical electrode Nanogap biosensor which will be used to detect and identify target proteins in aqueous solution.
The aim of this research work is to design, fabricate, characterize, and test nanogap-electrode based device for biochemical detection and DNA immobilization and hybridization detection. However, the focus of this research is to investigate electrically and chemically the effect of different materials and gap sizes on the nanogap electrodes design.
The aim of this research is to design, fabricate and characterize an array of planar nanogap capacitive sensor based on Poly-SiO2 structure by using size expansion technique.
Pressing performance demands require next-generation biosensors to detect target chemical and biological molecules with higher sensitivity, shorter response times, and lower detection limit. Micro- and nanoscale devices are attractive for a wide range of biosensor applications since at small scale, in addition to being more compact, the device may exhibit improved performance. The benefits include minimization of tissue damage for implantable devices, improved spatial resolution and sensitivity, as well as increased surface charge to mass ratio, which is important for the performance of our novel technology for nucleic acid detection described below. Borrowing from the processing technologies used in the semiconductor industry, we implemented micromachining techniques to fabricate devices at both the micro- and nanoscale. In this dissertation, we present our work on the fabrication and characterization of two next-generation biosensors. The first device we fabricated is a sequence-specific nucleic acid sensor based on the blockage of a nanopore. Current methods for nucleic acid detection generally rely on polymerase chain reaction (PCR) and fluorescent labeling, however, these methods render the devices slow, expensive, complex, and bulky. In order to address these limitations, a new sensor was fabricated from a single glass wafer, consisting of a glass nanopore in a thin glass membrane. For nanopore sensing, low frequency noise is critical since it limits the discrimination of signal change based on target analyte movement from the fluctuation of noise. To further our understanding of nanopores, we observed how different pore geometries affect noise characteristics, and then compared this newly developed glass nanopore to conventional Si-based nanopores. Based on the analysis, low-noise glass nanopores, suitable for sequence-specific nucleic acid detection, were fabricated. By scaling down the pore diameter to the nano-regime, 1 aM detection of 16S rRNA from Escherichia coli was demonstrated even in the presence of a million-fold background of RNA from Pseudomona putida. This new platform for the PCR-free, optics-free, label-free sequence-specific nucleic acid detection shows the potential to detect pathogens in body fluids, food, or water. In addition, we developed a new method to transfer enzyme to a microelectrode array on an implantable microprobe, which enables fabrication of better performing microprobes for the sensing of multiple neurochemicals in vivo. Monitoring the release of neurotransmitters in real-time offers valuable information necessary to understand neurological disorders and abnormal behaviors. We employed polydimethylsiloxane (PDMS) stamping to transfer enzyme onto microelectrode array microprobes. A model enzyme, glucose oxidase (GOx), was stamped onto the surface of disk electrodes to test the feasibility of PDMS stamping for biosensor fabrication. The model sensor showed a good combination of performance (29 A/mM cm2 sensitivity and 4 M detection limit) proving that PDMS stamping offers a simple and cost-effective enzyme deposition method for construction of electroenzymatic sensors. The next step was to add an alignment function to PDMS stamping to create microprobes with dual sensing (glucose and choline) capabilities for in vivo applications. Two different enzymes, GOx and choline oxidase (ChOx), were selectively transferred onto specific sites in a 4 microelectrode array by PDMS stamping with alignment using a microscope and a custom-built stage. The dual sensor showed improved consistency and performance including sensitivity to choline and to glucose (286 and 117 A/mM cm2, respectively) as well as low detection limits (3 and 1 M, respectively). This work demonstrated the ability to immobilize specific enzymes on selected microelectrodes in an array to give a high performance microprobe for simultaneous sensing of two analytes for neuroscience application.
This handbook is an interdisciplinary and comprehensive reference covering all aspects of cell biosensors. It is divided into four main sections which are led and organized by numerous international experts. The scope of coverage includes: Fundamentals and genetics for biosensor applications Transducers, Materials and Systems Markets, innovation and education Application of biosensors in business Biosensor research is an exciting hybrid world where biologists, chemists, physicists, engineers and computer engineers come together. This handbook will serve as an invaluable living resource for all researchers in academia and industry working with cell biosensors.
This book highlights selected articles from the electrical engineering track, with a focus on the latest trends in electrical and electronic engineering toward embracing Industry 4.0, as part of the Malaysian Technical Universities Conference on Engineering and Technology—MUCET 2019. The event brings together researchers and professionals in the fields of engineering, research, and technology, and provides a platform for future collaborations and exchanges.
Discusses different modelling techniques in microfluidics (FEM and CFD). Every reader will have an easy start to model any kind of microfluidic device. Presents the necessary fabrication technologies and examples of the latest microfluidic devices and systems. Microfluidics is a very new research area in microelectro-mechanical systems (MEMS). This book introduces the theory and practice of microfluidic technology. The content is designed to be of value to engineers with different backgrounds working in the area of microsystem technology. The book includes the necessary fabrication technologies and examples of the latest microfluidic devices and systems that have been realised by a worldwide community of researchers. It covers all aspects of microfluidic theory and describes the breath-taking developments in this field.
In this monograph, the graphene-based field-effect transistor (FET) biosensors are shown to be an emerging sensing platform. Divided into two parts the first set of chapters are devoted to basic knowledge of graphene, graphene FET and its biosensing. In the second part of this book the applications of graphene FET biosensors combined with various biotechnologies are presented. As well as discussing the existing technologies the authors also introduce their own ideas and concepts. Finally the remaining problems in graphene FET biosensors are discussed, along with proposed solutions and prospects for future applications. This monograph allows readers to grasp the basic knowledge and future direction of graphene-based FET biosensors.