Abstract: Provided is a method for producing astaxanthin, comprising: (a) performing heterotrophic cultivation of astaxanthin-producing Haematococcus pluvialis; (b) performing heterotrophic cultivation of the Haematococcus pluvialis obtained in step (a) under conditions of high acetate concentration and high dissolved oxygen concentration, where the acetate concentration is at least 1800 mg/L and the dissolved oxygen concentration is at least 2.0 mg/L; and (c) collecting algae cells from step (b) and/or harvesting astaxanthin. Also provided is a base medium for culturing Haematococcus pluvialis, a propagation feed medium, and an induction feed medium.

Abstract: A method for producing astaxanthin, comprising: (a) acquiring vegetative cells of astaxanthin-producing Haematococcus pluvialis; (b) heterotrophically culturing the vegetative cells of astaxanthin-producing Haematococcus pluvialis in a nutrient-poor culture medium containing an organic carbon source and under a no-light condition, to obtain spore cells; and (c) harvesting the spore cells and/or astaxanthin, and optionally purifying the astaxanthin. Also provided is a culture medium used in the described method.

Abstract: The present application provides a reusable ultrasonic surgical instrument, comprising a cannula subassembly, a scalpel waveguide, a base and a clamping driving component, wherein the cannula subassembly comprises a pair of clamp forceps at a distal end, an external cannula and an internal cannula, and the external cannula and the internal cannula are both provided by being coaxial with the scalpel bar; two rotating shafts are provided at a proximal end of the clamp forceps, one of the two rotating shafts is rotatably connected with the external cannula, the other rotating shaft is rotatably connected with the internal cannula; the cannula subassembly can be dismounted from the base and the clamping driving component towards a distal end direction of the axis of the scalpel bar or be mounted on the base or the clamping driving component towards a proximal end direction of the axis of the scalpel bar; the external cannula is connected with the base by one or multiple first detachable structures; and the intern

Abstract: Methods for producing lipids from lignocellulosic biomass are provided. Sugars produced by pretreatment of lignocellulosic biomass are utilized by heterotrophic oleaginous fungi or yeast to increase their biomass and to produce lipids without prior detoxification of the pretreated biomass. After the fungi/yeast are cultured with the sugars, solid residues from the pretreated biomass are combined with the fungi/yeast under conditions which allow simultaneous 1) enzymatic degradation of cellulose and/or hemicellulose to produce sugars and 2) fermentation of the sugars for further increases in biomass and lipid production.

Abstract: Methods and systems for producing lipids which may be used as biofuel are provided. Sugars produced by pretreatment of lignocellulosic biomass are utilized by heterotrophic oleaginous fungi or yeast to increase their biomass and to produce lipids without prior detoxification of the pretreated biomass. After the fungi/yeast are cultured with the sugars, solid residues from the pretreated biomass are combined with the fungi/yeast under conditions which allow simultaneous 1) enzymatic degradation of cellulose and/or hemicellulose to produce sugars and 2) fermentation of the sugars for further increases in biomass and lipid production.

Abstract: Oleaginous yeast strains are used to hydrolyze biomass (e.g. wheat straw) that has been pretreated using dilute acid, in order to produce lipids. The lipids may be used as feedstock for producing biofuels.

Abstract: Oleaginous yeast strains are used to hydrolyze biomass (e.g. wheat straw) that has been pretreated using dilute acid, in order to produce lipids. The lipids may be used as feedstock for producing biofuels.

Abstract: Disclosed is a culture system for the production of algae biomass to obtain lipid, protein and carbohydrate. By integrating heterotrophic processes with a phototrophic process in parallel, this system provides year around production in colder climates. By integrating heterotrophic processes with a phototrophic process in series, this system creates a two-stage, separated mixed-trophic algal process that uses organic carbon and nutrients for the production of seed in the heterotrophic process, followed by release of cultured seed in large-scale phototrophic culture for cell biomass accumulation. Organic carbon source including waste materials can be used to feed the heterotrophic process. The production capacity ratio between the heterotrophic and the phototrophic processes can be adjusted according to season and according to the availability of related resources. The systems are used for producing and harvesting an algal biofuel feedstock as well as other potential high-value products.