SBIR-STTR Award

Fast, Quantitative Analysis of Trichloroethylene (Tce) in Water
Award last edited on: 1/7/2020

Sponsored Program
SBIR
Awarding Agency
NIH : NIEHS
Total Award Amount
$649,017
Award Phase
2
Solicitation Topic Code
-----

Principal Investigator
Mark Peterman

Company Information

OndaVia Inc (AKA: Labrador Research LLC)

26102 Eden Landing Road #1
Hayward, CA 94545
   (510) 576-0476
   info@ondavia.com
   www.ondavia.com
Location: Single
Congr. District: 15
County: Alameda

Phase I

Contract Number: 1R43ES026513-01
Start Date: 9/30/2015    Completed: 9/29/2016
Phase I year
2015
Phase I Amount
$149,017
?Groundwater contamination by chlorinated compounds is a significant risk to public health. Chlorine-containing compounds-ranging from pesticides to industrial solvents-are slow to degrade through natural pathways. Their wide-ranging presence is notable; for example, the industrial solvent trichloroethylene (TCE) has been detected at over fourteen-hundred DOD installations, twenty-three DOE installations, and thousands of commercial and residential sites nationwide, including 60% of Superfund sites. Although various remediation techniques are under study, all sites would benefit from rapid, ppb-level monitoring. These compounds are widely present at minute, low-part-per-billion (ppb) concentrations. At the same time, our water sources are threatened by numerous other pollutants with regulatory limits at ppb-levels. Currently available laboratory-based tools that ca measure these very low concentrations are expensive, complex, and cumbersome instruments. They do not enable the types of rapid, frequent, economical and broad-based testing needed to adequately monitor the nation's water sources. Next-generation capabilities to test water samples at sub-ppb for a wide-variety of compounds in fewer than five minutes would vastly improve the capabilities of water monitors and researchers. This ability will in turn allow water suppliers to increase monitoring frequency and to implement remediation steps, and will allow researchers to focus on obtaining more data and a better understanding of the health effects of chronic exposure. OndaVia intends to develop the advanced technology that is needed. For the multi-phase SBIR project envisioned here, OndaVia proposes to develop, prototype, validate, and commercialize a rapid- analysis instrument designed to measure compounds in aqueous solution using surface-enhanced Raman spectroscopy (SERS). This instrument relies upon OndaVia's proven and proprietary SERS detection technology that is both sensitive and quantitative, resulting in an easy-to-use, rapid-analysis instrument with few-parts-per-billion sensitivity. Specific Phase I Aims are focused on proving the feasibility of 1) detecting TCE at 5-ppb using our unique detector, and 2) determining a quantitative calibration curve for TCE over 0- to 100-ppb. Phase I success will set the stage for follow-on Phase II work focused on fully demonstrating/validating the capabilities of our prototype system with the goal of achieving 5-ppb detection levels in field samples in preparation for "Phase III" commercial development with private- sector investors/industry partners.

Public Health Relevance Statement:


Public Health Relevance:
Clean water is necessary for a healthy society, yet we are faced with constant new concerns about pollution in our water sources-including ever-increasing threats from trace pollutants such as chlorinated solvents that are widely present in our water supplies. Unfortunately, our water managers, research scientists and government agencies do not have available the types of low- cost/high-performance analytical tools they need to adequately study and monitor water pollutants at relevant parts-per-billion (ppb) levels. OndaVia's goal for this SBIR Phase I project is to prove the feasibility of developing/commercializing the rapid, easy-to-use, economical instrument that is needed to measure accurately water contamination at ppb levels to boost our country's ability to monitor and protect our surface, ground, waste, and drinking water sources.

NIH Spending Category:
Bioengineering

Project Terms:
Amines; analytical tool; aqueous; base; Calibration; Carcinogens; Chemicals; Chlorine; Chronic; Color; commercialization; Complex; cost; Country; Coupling; Data; design; Detection; detector; Development; Devices; drinking water; Engineering; experience; Frequencies (time pattern); Goals; Government Agencies; Health; Human; improved; industry partner; innovation; instrument; instrumentation; Laboratories; Lead; Legal patent; Malignant neoplasm of liver; Measurement; Measures; Monitor; nanoparticle; National Institute of Environmental Health Sciences; next generation; Non-Hodgkin's Lymphoma; novel; Pathway interactions; Performance; Pesticides; Phase; pollutant; Pollution; Preparation; Private Sector; Process; prototype; public health medicine (field); public health relevance; pyridine; Raman Spectrum Analysis; Reaction; Real-Time Systems; remediation; Renal carcinoma; Reporting; Research; research and development; Research Personnel; residence; response; Risk; Sampling; Scanning; Scientist; Signal Transduction; Site; Small Business Innovation Research Grant; Societies; Solutions; Solvents; Source; Staging; success; superfund site; Surface; System; Systems Analysis; Techniques; Technology; Testing; Time; tool; Trichloroethylene; Vision; wasting; Water; Water Pollutants; Water Pollution; water sampling/testing; Water Supply; Work

Phase II

Contract Number: 2R44ES026513-02A1
Start Date: 9/30/2015    Completed: 8/31/2020
Phase II year
2018
Phase II Amount
$500,000
Summary: Groundwater contamination by chlorinated compounds is a significant risk to public health. Chlorine-containing compounds?ranging from pesticides to industrial solvents?are slow to degrade through natural pathways. Their wide-ranging presence is notable; for example, the industrial solvent trichloroethylene (TCE) has been detected at over fourteen-hundred DOD installations, twenty-three DOE installations, and thousands of commercial and residential sites nationwide, including 60% of Superfund sites. Although various remediation techniques are under study, all sites would benefit from rapid, ppb-level monitoring. These compounds are widely present at minute, low-part-per-billion (ppb) concentrations. At the same time, our water sources are threatened by numerous other pollutants with regulatory limits at ppb-levels. Currently available laboratory-based tools that can measure these very low concentrations are expensive, complex, and cumbersome instruments. They do not enable the types of rapid, frequent, economical and broad-based testing needed to adequately monitor the nation's water sources. Next-generation capabilities to test water samples at sub-ppb for a wide-variety of compounds in fewer than five minutes would vastly improve the capabilities of water monitors and researchers. This ability will in turn allow water suppliers to increase monitoring frequency and to implement remediation steps, and will allow researchers to focus on obtaining more data and a better understanding of the health effects of chronic exposure. OndaVia is developing the required advanced monitoring technology. For the multi-phase SBIR project envisioned here, OndaVia proposes to develop, prototype, validate, and commercialize a rapid-analysis instrument designed to measure compounds in aqueous solution using surface- enhanced Raman spectroscopy (SERS). This instrument relies upon OndaVia's proven and proprietary SERS detection technology that is both sensitive and quantitative, resulting in an easy-to- use, rapid-analysis instrument with few-parts-per-billion sensitivity. Specific Phase II Aims are focused on delivering a prototype TCE analysis kit capable of detecting TCE at 5-ppb in field samples. Phase II success will set the stage for follow-on ?Phase III? commercialization with our private-sector investors and industry partners.

Thesaurus Terms:
Affect; Aging; Alkalinity; Amines; Analytical Tool; Aqueous; Base; Calibration; Carcinogens; Characteristics; Chemicals; Chlorides; Chlorine; Chronic; Color; Colorimetry; Commercialization; Complex; Contaminated Water; Corrosion; Cost; Country; Data; Design; Detection; Development; Disinfection; Drinking Water; Early Identification; Environmental Pollution; Equipment; Feasibility Studies; Frequencies; Gases; Goals; Government Agencies; Ground Water; Health; Hour; Human; Hydrochloric Acid; Improved; Industrialization; Industry; Industry Partner; Instrument; Isomerism; Laboratories; Life; Malignant Neoplasm Of Liver; Mass Fragmentography; Measures; Methods; Methylene Chloride; Monitor; National Institute Of Environmental Health Sciences; Next Generation; Niacinamide; Non-Hodgkin's Lymphoma; Novel; Oils; Pathway Interactions; Perchlorates; Performance; Pesticides; Phase; Pollutant; Pollution; Private Sector; Process; Prototype; Public Health; Pyridine; Raman Spectrum Analysis; Reaction; Reagent; Remediation; Renal Carcinoma; Reporting; Research; Research Personnel; Residence; Response; Risk; Sales; Sampling; Scientist; Site; Small Business Innovation Research Grant; Societies; Solvents; Source; Success; Superfund Site; Surface; System; Techniques; Technology; Testing; Tetrachloroethylene; Time; Tool; Trichloroethanes; Trichloroethylene; Trihalomethanes; Wasting; Water; Water Pollutants; Water Sampling/Testing; Water Supply; Work;