SBIR-STTR Award

Algae are rapidly growing in importance as an abundant and renewable source of many valuable components that are currently cultivated for applications in biofuels and other bioproducts, such as additives for food, nutrition supplements, pharmaceuticals, chemicals, etc. Growing algae is the largest cost in algal products today, and algae crop loss due to predators or other invasive microorganisms represent one of the major reasons for this cost. This necessitates development of cost-efficient and effective technologies to empower methodologies for algae crop protection, as well as to optimize algae research and cultivation processes for biofuels and other bioproducts applications. An innovative platform is proposed for automated high-throughput monitoring and characterization of microalgae during cultivation process for biofuel and other bioproducts production in-field or for laboratory research. Specifically, the proposed platform will be able to 1) monitor and characterize the cultivated microalgae population with resolution down to individual alga (including classification of different types of algae in case of a polyculture community); 2) automatically estimate in a label-free way the individual alga characteristics, such as shape, size, color and lipid content, empowering precise decision making to adjust cultivation process or to initiate harvesting; 3) empower crop protection methodologies by detecting invasive or predatory microorganisms and provide advanced warning to enable the corresponding risk-mitigation strategies. During Phase I, the following objectives will be accomplished: 1) develop an initial prototype version of the proposed platform adapted for monitoring and characterization of flowing dense samples (samples from microalgae cultivation process), 2) develop deep learning enabled image processing algorithms to characterize identified microalgae and detect contaminating micro-objects to empower crop protection methodologies, 3) determine feasibility of individual algae lipid content estimation via phase measurement, 4) perform proof of concept evaluation of the platform based on samples obtained from algae cultivated in the laboratory and in-field during two deployment campaigns at real-world algae production facilities.The proposed platform will have significant commercial applications for the intended market of algae-based biofuel and bioproducts commercial producers, research laboratories and government organizations. The market demand will be primarily driven by platform?s capabilities to empower crop protection methodologies and, therefore, significantly reducing crop loss. Furthermore, algae characterization capabilities of the platform will empower precise cultivation approaches that are envisioned to further improve the economics of algae cultivation and research. Furthermore, fundamental technology behind the proposed platform will also be applicable to secondary markets, such as identification of harmful algal blooms and other dangerous microorganisms in natural and artificial bodies of water. These capabilities will be valuable for ensuring health and safety of aquaculture operations and public health. Furthermore, low cost of the proposed fundamental technology and high performance characteristics in micro-object detection enable application of the proposed platform to drinking water monitoring and characterization market.

Algae are rapidly growing in importance as an abundant and renewable source of thousands of valuable components that are cultivated for applications in biofuels and other bioproducts, such as additives for food, nutrition supplements, pharmaceuticals, chemicals, etc. Growing algae is the largest cost in algal products today, and algae crop loss due to microscopic pests represents one of the major reasons for this cost. This necessitates development of cost-efficient and automated technologies to empower methodologies for algae crop protection, as well as to optimize algae research and cultivation processes for biofuels and other bioproducts applications. An innovative platform is developed for automated high-throughput monitoring and characterization of microalgae during cultivation process for biofuel and other bioproducts production in-field or for laboratory research. Specifically, the proposed platform will be able to 1) monitor and characterize the cultivated microalgae samples with resolution down to individual alga (including specific classification of algae, pests and other microobjects); 2) automatically estimate in a label-free way the individual alga characteristics, such as shape, size, color and lipid content, empowering precise decision making to adjust cultivation process or to initiate harvesting; 3) empower crop protection methodologies by early detection of microscopic pests and provide advanced warning to enable the corresponding risk-mitigation strategies. During Phase I, the following objectives were accomplished: 1) developed an initial prototype version of the proposed platform adapted for monitoring and characterization of dense microalgae samples, 2) developed deep learning enabled image processing algorithms to characterize identified microalgae and to detect pests and other micro-objects to empower crop protection methodologies, 3) developed a metric for individual algae lipid content estimation, 4) performed proof of concept evaluation of the platform in the laboratory and in-field during a deployment campaigns at a partner facility where algae were cultivated and monitored. During Phase II the final prototype will be integrated, optimized and developed to be robust and cost- effective. It will incorporate embedded computing to enable portability and long-term unattended operation. New modes of operation, DENSE and NORMAL, will be developed for the device. In DENSE mode the system will enable concentrated sample processing at high flowrate aiming to identify and quantify pests. This mode will be designed for long-term unattended deployments. For this mode, a new sensor will also be developed enabling estimation of biomass concentration. The NORMAL mode will be developed for laboratory operations and for processing of diluted samples with high accuracy. The focus of this mode will be on performing detailed analysis. Furthermore, an advanced lipids measurement algorithm will be developed to significantly complement existing algae analytics. Finally, the device will be integrated and evaluated in the laboratory and during several long-term in-field experimental campaigns at partner facilities. The proposed platform will have significant commercial applications for the intended market of algae-based biofuel and bioproducts commercial producers, research laboratories and government organizations. There also are several secondary markets for the underlying technology, including in aquaculture, public health, drinking water safety, microbial products, clinical research and pharma.