SBIR-STTR Award

Real-Time Biosensor for Measuring Hazardous Chemical Contaminants in Ground Water
Award last edited on: 9/15/2015

Sponsored Program
SBIR
Awarding Agency
NSF
Total Award Amount
$1,336,195
Award Phase
2
Solicitation Topic Code
-----

Principal Investigator
Brian Heinze

Company Information

OptiEnz Sensors LLC

320 E Vine Drive Suite 221
Fort Collins, CO 80524
   (970) 227-0921
   N/A
   www.optienzsensors.com
Location: Single
Congr. District: 02
County: Larimer

Phase I

Contract Number: ----------
Start Date: ----    Completed: ----
Phase I year
2013
Phase I Amount
$179,999
This Small Business Innovation Research (SBIR) Phase I project proposes to develop a cell-free optical enzymatic biosensor for monitoring trichloroethene (TCE) concentrations in water. The biosensing concept will be implemented in an optical fiber format, in which optical biosensor tips are linked to a small electro-optical unit. Chemical detection takes place on biosensor tips that are coated with enzymes and fluorescent chemicals. In preliminary experiments, sensors using whole cells containing the desired enzymes were shown to measure TCE concentrations. However, those whole-cell sensors had limitations with respect to their detection limits and manufacturability. Thus, the research objectives of this project are to develop a cell-free version of this biosensor by extracting the necessary multicomponent enzyme and incorporating the enzyme onto the biosensor tips. Attainment of these objectives will advance the TCE-sensing technology toward a robust and readily manufactured system for TCE monitoring with improved detection limits, increased accuracy, and reliability.

The broader impact/commercial potential of this project, if successful, will be to increase the efficiency of identifying, mapping, and remediating water sources contaminated with TCE. Water use has been growing at more than twice the population rate. Both water quantity and water quality are becoming dominant issues in many countries. The necessity of monitoring aqueous-phase TCE concentrations will continue for many generations due to its widespread occurrence in water sources, its toxicity, and its high stability. A significant need exists and will continue to rise worldwide for devices that can measure the concentration of TCE as well as other chlorinated organic chemicals in water, and that can do so rapidly, accurately, and inexpensively. Continuous in-situ data production in the field of environmental sensing will greatly increase efficiency in all processes that require a measurement of TCE concentration. This sensor will allow for continuous monitoring of possible contamination sources in the case of a contamination event. Also, it will afford facile depth and spatial profiling of TCE plumes in aquifers. This technology will replace the current chromatography-based measurement protocols, which are not readily adapted for in-situ, on-line, or in-the-field measurements, and cannot produce data continuously.

Phase II

Contract Number: ----------
Start Date: ----    Completed: ----
Phase II year
2015
(last award dollars: 2017)
Phase II Amount
$1,156,196

The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase II project is to increase the efficiency of identifying, mapping, and remediating water sources contaminated with chlorinated solvents. Chlorinated solvents are used in vast quantities as solvents and degreasing agents, and in the dry cleaning industry. The necessity of monitoring chlorinated solvents in water will continue for many generations due to their widespread occurrence in water sources around the world, their toxicity, and their high stability. A significant need exists and will grow for devices that can continuously measure the concentration of chlorinated organic chemicals in water, and that can do so accurately and inexpensively. Continuous in-situ data production in the field of environmental sensing will greatly increase efficiency in all processes that require a measurement of these chemicals, having a significant impact on the costs and timelines associated with remediation of contaminated sites. This sensor will allow for continuous monitoring of possible contamination sources in the case of a contamination event. Also, it will afford easy profiling of contamination plumes in aquifers. This technology will replace the current laboratory-based measurement protocols, which are not readily adapted for in-situ, on-line, or in-the-field measurements, and cannot produce data continuously.This SBIR Phase II project proposes to develop an optical enzymatic biosensor for continuous, quantitative monitoring of chlorinated solvent concentrations in water. Chlorinated solvent contamination of groundwater is a widespread ongoing issue around the world. The biosensing concept will be implemented in an optical fiber format, in which optical biosensor tips are linked to a small electro-optical unit. Analyte detection takes place on biosensor tips that are coated with enzymes and fluorescent chemicals. The scope of the research includes two parallel strategies for obtaining highly stable detection enzymes such that long lifetime sensors are achievable, development of a system to deliver required reagents to the sensing tip, development of signal processing algorithms to enable high accuracy measurements in variable environmental conditions and speciation of chlorinated compounds within mixtures, a manufacturing study for high throughput fabrication of the sensors, and field testing of the device at multiple contamination sites. Attainment of these objectives will advance the sensing technology to a robust and readily manufactured system for chlorinated solvent monitoring with low detection limits, high accuracy, and reliability.