Electroactive Poly(amidoamine) Organic Polymers (EPOP)

Jeffrey LaBelle (Inventor)

Research output: Patent

Abstract

The market for point of care test strips demands high quality tests and low production costs without sacrificing sensitivity and specificity. Highly-ordered nanomaterials are being investigated as a viable approach for meeting these demands. Highly-ordered nanomaterials are ideal as they are inexpensive to manufacture and have been shown to produce a remarkable increase in the sensitivity and specificity of electrochemical testing. Unfortunately, current fabrication techniques make it difficult to produce uniform or easily controlled nanostructures. Researchers at Arizona State University have developed novel electroactive organic polymer compositions that can be screen printed for biosensing applications, energy storage and alternative energy sources. Alternatively, these compositions may be good candidates for electron mediators or replacements for redox probes used in blood glucose sensors. These compositions self-assemble into uniform nanostructures with remarkable electrochemical activity. Moreover, these materials are relatively low cost and yield a high quantity of product. These compositions should be amenable to mass manufacturing using known scale-up methods. These low cost, self-assembling compositions provide unique and valuable characteristics for biosensing and energy applications. Potential Applications Electrochemical detection Biomarker detection Electron Mediators or replacements for redox probes in blood glucose sensors Energy applications Energy storage Alternative energy applications Benefits and Advantages Relatively long shelf life when stored in lighted conditions Low manufacturing costs Water based chemistry Green chemistry manufacturing Able to be screen printed for higher-volume productions at further reduced cost High production yields Hydrophilic - ideal for biological samples The compositions should be safe for applications in vivo Dowload Original PDF For more information about the inventor(s) and their research, please see Dr. La Belle's laboratory webpage
Original languageEnglish (US)
StatePublished - Feb 20 2014

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Organic polymers
Chemical analysis
Glucose sensors
Costs
Nanostructured materials
Energy storage
Blood Glucose
Nanostructures
Electrons
Biomarkers
Poly(amidoamine)
Fabrication
Water
Testing

Cite this

Electroactive Poly(amidoamine) Organic Polymers (EPOP). / LaBelle, Jeffrey (Inventor).

Research output: Patent

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abstract = "The market for point of care test strips demands high quality tests and low production costs without sacrificing sensitivity and specificity. Highly-ordered nanomaterials are being investigated as a viable approach for meeting these demands. Highly-ordered nanomaterials are ideal as they are inexpensive to manufacture and have been shown to produce a remarkable increase in the sensitivity and specificity of electrochemical testing. Unfortunately, current fabrication techniques make it difficult to produce uniform or easily controlled nanostructures. Researchers at Arizona State University have developed novel electroactive organic polymer compositions that can be screen printed for biosensing applications, energy storage and alternative energy sources. Alternatively, these compositions may be good candidates for electron mediators or replacements for redox probes used in blood glucose sensors. These compositions self-assemble into uniform nanostructures with remarkable electrochemical activity. Moreover, these materials are relatively low cost and yield a high quantity of product. These compositions should be amenable to mass manufacturing using known scale-up methods. These low cost, self-assembling compositions provide unique and valuable characteristics for biosensing and energy applications. Potential Applications Electrochemical detection Biomarker detection Electron Mediators or replacements for redox probes in blood glucose sensors Energy applications Energy storage Alternative energy applications Benefits and Advantages Relatively long shelf life when stored in lighted conditions Low manufacturing costs Water based chemistry Green chemistry manufacturing Able to be screen printed for higher-volume productions at further reduced cost High production yields Hydrophilic - ideal for biological samples The compositions should be safe for applications in vivo Dowload Original PDF For more information about the inventor(s) and their research, please see Dr. La Belle's laboratory webpage",
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