The Global Aquaculture Challenge recognizes Xylome for innovation in aquaculture
October 5, 2021 – Xylome won an international award for innovation in aquaculture. The 2nd Global Aquaculture Challenge recognized Xylome’s Yoil(TM)-NoFish technology as an innovative, inexpensive and sustainable process that will generate omega-3 fatty acids for use as aquaculture feed. The Yield Lab Asia Pacific Agtech Fund and Accelerator sponsored a global competition to identify the most promising technologies for sustainable aquaculture. Xylome’s innovation focuses on the production of high omega-3 fatty acids from fermentation byproducts using an engineered highly lipogenic yeast. Using Xylome’s technology, Aquafeed containing heat-treated yeast in combination with other ingredients could cost as little as $0.65 a pound compared to $0.95 a pound for traditional aquafeed. That price target is especially feasible when combined with a soy protein base. Details about Xylome’s participation in this competition can be found here.
Xylome describes sustainable technology for engineered oils from agricultural byproducts
September 10, 2020 – Each year, the roughly 200 industrial ethanol plants in the U.S. collectively produce about 30 million metric tons (m.t.) of low-value waste stream called stillage containing water-soluble organics and corn fiber residues. Disposing of stillage is problematic. However, Xylome, a small business based in Madison, WI, has developed a way to use the waste stream as a consistent, stable feedstock for conversion to valuable products. The company has genetically engineered a novel yeast to enable this transformation.
Find a brief description of the technology in the American Institute for Chemical Engineering (AIChE) August Issue – now on line
Xylome awarded foundational patent on engineered yeast for lipid production
May 26, 2020 – The U.S. Patent Office has recognized Xylome’s exclusive right to claims under US 10,662,448 for “Compositions and methods for producing lipids and other biomaterials from grain ethanol stillage and stillage derivatives”.
Lipogenic yeasts are modified to express, constitutively express, or overexpress numerous enzymes for lipid synthesis and substrate utilization. The yeasts in some cases are also modified to reduce or ablate activity of certain proteins. The methods include cultivating the yeast to convert low value soluble organic stillage byproducts into lipids suitable for biodiesel production and other higher value uses.
Xylome acquires Sarnaya to provide base for cosmetic applications
November 10, 2019 – Xylome has acquired Sarnaya Skincare to provide the base materials for its skin cream. Xylome will begin production of yeast oil (Yoil™) at its contract facilities in Menomonee Falls, Wisconsin by May, 2021.
DOE selects Xylome to make biodiesel and higher value products from stillage fiber
September 4, 2018 – The BioEnergy Technologies Office (BETO) within the Office of Energy Efficiency and Renewable Energy (EERE) informed Xylome that it’s application submitted in response to a Funding Opportunity Announcement (FOA) was selected for award negotiations. Xylome must match 20% of the total project costs, which total approximately $1.3 million. The objective of the project is to generate biodiesel and higher value products from stillage fiber. The broader impact and commercial potential of this project is to produce, the next generation of sustainable, renewable, clean burning, high energy density, transportation biofuels. The project includes commercial collaboration with two large industrial ethanol producers.
Xylome Corporation awarded U.S. Department of Agriculture Phase I SBIR grant
June 1, 2017 – The US Department of Agriculture (USDA) awarded Xylome Corporation $100,000 for a Phase I Small Business Innovative Research (SBIR) grant to develop a Novel process for omega-3 oil production from agricultural byproducts. The grant, which started on June 1, 2017, focuses on metabolic engineering a yeast to produce omega-3 fatty acids for aquaculture.
Xylome Corporation awarded an SBIR Advance Award from Wisconsin for commercial and business development
March 1, 2017 – The Wisconsin SBIR Advance program awarded Xylome $75,000 for commercial and business development activities within Wisconsin. This grant has enabled Xylome to attend two trade shows that brought in major customer leads. It has also supported customer research that led to a new prospective product line.
Xylome awarded NSF Phase II SBIR grant
Sept 20, 2016 – Xylome Corporation was awarded $750,000 to develop a “Novel bioprocess for lipid production from industrial byproducts”. The two-year grant for $750,000, which started on October 1, 2016, will run through September 30, 2018.
The purpose of this Phase II project is to produce economically the next generation of sustainable, renewable, clean burning, high energy density, transportation biofuels. The proposed technology once successfully developed will enable existing biofuel producers to reduce their costs while increasing the value and diversity of their byproducts. It will convert their industrial waste products into tailored fatty acids suitable for biodiesel.
August 26, 2016 – Capital Press • Matthew Weaver
Xylome’s development of native yeasts that use unconventional sugars has significant implications for farmers and the processing industries.
June 4, 2016 – Económico • Francisco Ferreira da Silva
Brazil’s on-line news Económico reported on Xylome’s development of native yeasts for fermenting agricultural byproducts.
June 3, 2016 – Business Insider • Molly Sequin
A novel yeast, Spathaspora passalidarum, readily converts sugars from agricultural residues into sustainable, renewable biofuels.
Xylome Corporation awarded National Science Foundation Phase I SBIR grant
July 1, 2015 – The National Science Foundation (NSF) awarded Xylome Corporation $150,000 for a Phase I Small Business Innovative Research (SBIR) grant to develop a Novel process for lipid production from industrial byproducts. The grant, which starts on July 1, 2015, will focus on metabolic engineering a yeast to produce fatty acids for biodiesel production.