SBIR-STTR Award

This Phase I Small Business Technology Transfer project aims to: (1) design, build and program a simple, dedicated instrument for Submitochondrial particle (SMP) performing tests, (2) develop software and protocols capable of flexibly addressing real world monitoring situations, (3) provide a limited number of demonstration units to potential customers for beta testing purposes, and (4) build toward a fully autonomous instrument (Phase II). SMP tests consist of a suite of robust biochemical toxicity bioassays that are simple and inexpensive to perform; require only basic laboratory equipment to conduct; and yield near-real time data (minutes). Bioenergetic processes critical to cell viability are measured by tracking the redox status of nicotinamide coenzymes by spectrophotometry, although other detection schemes (O2 dye coupling, fluorescence, use of lasers, etc.) are feasible. The technology has been proven to perform well in a variety of environmental and industrial situations as a surrogate for conventional whole-organism toxicity tests. Potential commercial applications are manifold and diverse, but acceptance has been slow for lack of a cheap (<$300), dedicated, yet flexible instrument that would minimize user training and could be incorporated into automated processes. Microcontroller devices are simple, inexpensive, programmable computing devices with data input/output capabilities linkable to detectors, controllers, and other devices.

This Small Business Technology Transfer (STTR) Phase II project will develop and optimize a novel bioassay tool for routine low-cost biomonitoring of water quality. Submitochondrial particle (SMP) toxicity bioassays, based on the in vitro responses to toxicants of the integrated enzyme functions in oxidative phosphorylation, are good predictors of conventional whole organism tests, yet can be completed in minutes. Phase I research proved the concept that SMP technology could be streamlined and semi-automated, enhancing their convenience and commercial potential. In Phase II, prototypes of two dedicated instruments will be developed to accommodate both the cuvette and 96-well microplate-based formats. Accessory liquid and cuvette handling tools will be developed to increase sample throughput. Features will be added to computer software developed in Phase I for running the tests, including support for other protocols; better error detection; statistical treatments and graphical presentation of data. SMP production methods and quality control procedures will be improved and standardized. The software and instrument prototypes will be tested at four independent laboratories to establish assay variability and to gain additional information on appropriate applications of the tests. If successful, this project will provide affordable tools that will allow for screening of water quality and wastewater discharges by industry and municipalities.