At this time, no commercially available biomedical instrument exists that provides optical sensitivity to a single molecule of interest. Single-molecule studies are only carried out in specialized research labs using costly and bulky setups based on various types of microscopy. In this context, the overall goals and long- term objectives of the research proposed here are two-fold: (i) Development of a new kind of sensor platform with single molecule sensitivity for biomedical characterization instruments, (ii)Use of these sensors to study individual biomolecules to gain better understanding of fundamental processes in molecular biology. Integrated optical waveguides based novel liquid-core optical waveguides were developed by two of the investigators under an NIBIB R21 grant. At present, these waveguides can be used to guide light through picoliter volumes on a semiconductor chip, and to detect fluorescencefrom tens of molecules without the need for a bulky, external microscope. This novel silicon-based approach is compatible withfurther microfluidic integration and represents a paradigm shift in the way optical signals from minute amounts of biological analytes can be detected. Building on this research, our specific aims for this application are: 1. Demonstration of single-molecule sensitivity: We will improve the optical waveguides and detection setup to improve the sensitivity from currently 40 to single molecules 2. Development of integrated electrical and optical nanopore waveguide sensor: Using synthetic nanopores as smart gates to the liquid-core optical waveguides, we will develop a novel sensor that enables simultaneous electrical and optical sensing of single biomolecules. 3. Study of individual ribosomes: As one representative biomolecule, we will demonstrate sensing of single fluorescently labeled ribosomes and use the integrated waveguides to study dynamic effects on a millisecond timescale with the ultimate goal of elucidating the dynamics of the RNA translation process. An instrument with single molecule level sensitivity based on integrated technology would be compact, inexpensive, and portable. It would have significant impact on biology, medicine, and public health. Widespread deployment of improved analytical instrumentation in clinical settings, doctor's offices, remote locations, and underdeveloped countries around the world would be possible. In addition, researchers at the forefront of molecular biology could focus on the experimental results instead of the measurement apparatus. As a result, new insight into fundamental life science with long-term effects on drug development, disease detection and treatment can be gained.

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Research Project (R01)
Project #
5R01EB006097-03
Application #
7342896
Study Section
Instrumentation and Systems Development Study Section (ISD)
Program Officer
Korte, Brenda
Project Start
2006-04-01
Project End
2010-01-31
Budget Start
2008-02-01
Budget End
2009-01-31
Support Year
3
Fiscal Year
2008
Total Cost
$386,923
Indirect Cost
Name
University of California Santa Cruz
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
125084723
City
Santa Cruz
State
CA
Country
United States
Zip Code
95064
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Holmes, Matthew R; Shang, Tao; Hawkins, Aaron R et al. (2010) Micropore and nanopore fabrication in hollow antiresonant reflecting optical waveguides. J Micro Nanolithogr MEMS MOEMS 9:23004
Holmes, Matthew; Keeley, Jared; Hurd, Katherine et al. (2010) Optimized piranha etching process for SU8-based MEMS and MOEMS construction. J Micromech Microeng 20:1-8

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