SYSTEM CONTROL AND INTEGRATION OF STAND ALONE MICROFLUIDIC SYSTEMS

Nagendran, Preethy

January 2000

No description available.

MICROFLUIDIC SYSTEM

SANDWICH IMMUNOASSAY

DESIGN OF A DUAL WORKING ELECTRODE POTENTIOSTAT FOR REMOTE BIOSENSORS

VEPADHARMALINGAM, MURALIMANOHAR

January 2000

No description available.

potentiostat

sandwich immunoassay

electrochemical detection

RAPID DETECTION OF PROSTATE SPECIFIC ANTIGEN (PSA) ON A POLYMER LAB-ON-A CHIP

THATI, SHILPA

06 October 2004

No description available.

Prostate Specific Antigen

Polymer lab-on-a-chip

Sandwich Immunoassay

Optimization and Ultimate Limitations for Immunoassay and Clinical Diagnostics

January 2015

abstract: Biological fluids, in particular blood plasma, provide a vital source of information on the state of human health. While specific detection of biomarker species can aid in disease diagnostics, the complexity of plasma makes analysis challenging. Despite the challenge of complex sample analysis, biomarker quantification has become a primary interest in biomedical analysis. Due to the extremely specific interaction between antibody and analyte, immunoassays are attractive for the analysis of these samples and have gained popularity since their initial introduction several decades ago. Current limitations to diagnostics through blood testing include long incubation times, interference from non-specific binding, and the requirement for specialized instrumentation and personnel. Optimizing the features of immunoassay for diagnostic testing and biomarker quantification would enable early and accurate detection of disease and afford rapid intervention, potentially improving patient outcomes. Improving the limit of quantitation for immunoassay has been the primary goal of many diverse experimental platforms. While the ability to accurately quantify low abundance species in a complex biological sample is of the utmost importance in diagnostic testing, models illustrating experimental limitations have relied on mathematical fittings, which cannot be directly related to finite analytical limits or fundamental relationships. By creating models based on the law of mass action, it is demonstrated that fundamental limitations are imposed by molecular shot noise, creating a finite statistical limitation to quantitative abilities. Regardless of sample volume, 131 molecules are necessary for quantitation to take place with acceptable levels of uncertainty. Understanding the fundamental limitations of the technique can aid in the design of immunoassay platforms, and assess progress toward the development of optimal diagnostic testing. A sandwich-type immunoassay was developed and tested on three separate human protein targets: myoglobin, heart-type fatty acid binding protein, and cardiac troponin I, achieving superior limits of quantitation approaching ultimate limitations. Furthermore, this approach is compatible with upstream sample separation methods, enabling the isolation of target molecules from a complex biological sample. Isolation of target species prior to analysis allows for the multiplex detection of biomarker panels in a microscale device, making the full optimization of immunoassay techniques possible for clinical diagnostics. / Dissertation/Thesis / Doctoral Dissertation Chemistry 2015

Analytical chemistry

Biochemistry

assay optimization

microbead immunoassay

microscale separation

quantitation limit

sandwich immunoassay