A Novel Biosensing Interface Preparation Method for ElectroMagnetic Piezoelectric Acoustic Sensor

Sheng, Jack

06 April 2010

Preliminary work towards the development of novel biosensing interfaces for EMPAS (ElectroMagnetic Piezoelectric Acoustic Sensor) is presented in this manuscript. This method involves the use of unprecedented thiosulfonate-based linkers to construct robust and durable SAMs (Self-Assembling Monolayer) onto piezoelectric quartz crystals, which can chemoselectively immobilize thiol-containing biomolecules under aqueous conditions in a single, straightforward, reliable and coupling-free manner. Initial efforts are devoted to the construction of SAMs and the subsequent immobilization of thiol-containing biomolecules, and then characterization by CAMs (Contact Angle Measurement) and ARXPS (Angle-Resolved X-ray Photoelectron Spectroscopy). This method is then implemented into the construction of biosensing interfaces dedicated to the detection of avidin. With the incorporation of OEG (Oligo(Ethylene Glycol)) backbone and diluent in the method, 14-fold difference in signal response of EMPAS was observed between biotinylated and unfunctionalized SAMs.

biosensor

self-assembling monolayer

EMPAS

thiolsulfonate

0486

A Novel Biosensing Interface Preparation Method for ElectroMagnetic Piezoelectric Acoustic Sensor

Sheng, Jack

06 April 2010

Preliminary work towards the development of novel biosensing interfaces for EMPAS (ElectroMagnetic Piezoelectric Acoustic Sensor) is presented in this manuscript. This method involves the use of unprecedented thiosulfonate-based linkers to construct robust and durable SAMs (Self-Assembling Monolayer) onto piezoelectric quartz crystals, which can chemoselectively immobilize thiol-containing biomolecules under aqueous conditions in a single, straightforward, reliable and coupling-free manner. Initial efforts are devoted to the construction of SAMs and the subsequent immobilization of thiol-containing biomolecules, and then characterization by CAMs (Contact Angle Measurement) and ARXPS (Angle-Resolved X-ray Photoelectron Spectroscopy). This method is then implemented into the construction of biosensing interfaces dedicated to the detection of avidin. With the incorporation of OEG (Oligo(Ethylene Glycol)) backbone and diluent in the method, 14-fold difference in signal response of EMPAS was observed between biotinylated and unfunctionalized SAMs.

biosensor

self-assembling monolayer

EMPAS

thiolsulfonate

0486

Preparation of Heparin Surface for Quantification of Fibroblast Growth Factor-2 (FGF-2) Binding Using Surface Plasmon Resonance (SPR)

Kirtland, David Rand

17 June 2005

A mixed self assembling monolayer (mSAM) chip with attached heparin was developed to analyze heparin-protein interactions using a Reichert Inc, SR7000, surface plasmon resonance (SPR) instrument. The heparin was attached via streptavidin-biotin linkage where the streptavidin was covalently coupled to the mSAM and biotinylated heparin bound to it. These chips were then used to quantify the interactions of fibroblast growth factor-2 (FGF-2) with the surface bound heparin. Kinetic rate constants of association and disassociation were calculated. The association data of FGF-2 with heparin was fit to a single compartment, well-mixed model as the data did not exhibit mass transfer limitations. The results suggested that rebinding was prevalent and observed disassociation rates differed significantly in the presence of competing soluble heparin during disassociation. Our results indicate that the Reichert instrument and mSAM chips can be used to analyze heparin-protein interactions but that a careful protocol, outlined in this thesis, should be followed to obtain optimal data. / Master of Science

Mixed Self-Assembled Monolayer

Mixed Self Assembling Monolayer (mSAM)

Surface Plasmon Resonance (SPR)

Growth Factor

Biosensor

Heparin