Provided herein scalable system and processes for cultivation and production of photo synthetic microorganisms.

Method for producing bioproducts from streams of organic material, comprising the following steps: (i) the physical-biological pre-treating of the organic stream with water and one or more mechanical steps; (ii) setting the pH value of the mixture between pH 5 and pH 9; iii) adding an inoculum of a natural anaerobic culture that releases organic compounds; iv) a first separation step which splits the mixture into a solid and a liquid fraction, after which an anaerobic fermentation processes the solid fraction, with formation of biogas and digestate; v) an aerobic treatment of the separated liquid fraction with biological conversion of the organic compounds to a protein-rich bioproduct; vi) a second separation step with separation of the formed protein-rich bioproduct; vii) recirculating the liquid phase; viii) drying the formed protein-rich bioproduct, such that in the end a dry, protein-rich bioproduct is obtained as well as the bioproducts biogas and digestate.

A method for conversion of food waste to biofuel can include a first fermentation in which food waste is converted C.sub.2-C.sub.4 short-chain carboxylic acids, and a second fermentation in which the C.sub.2-C.sub.4 short-chain carboxylic acid are elongated into C.sub.5-C.sub.8 medium-chain carboxylic acids. Medium-chain carboxylic acids can undergo hydrogenation-dehydration of the medium-chain carboxylic acids into C.sub.5-C.sub.8 linear olefins. The C.sub.5-C.sub.8 linear olefins are then oligomerized to a C.sub.10-C.sub.25 mixture comprising olefins, paraffin, cycloparaffins, and aromatics through dimerization; and saturated to C.sub.10-C.sub.25 mixture by hydrogenation to produce the biofuel.

The disclosure relates to a method of culturing and analyzing at least one cell in a microchamber configured to allow for optical inspection of the at least one cell, wherein liquid is extracted from the microchamber for analysis, characterized in that the analysis returns information about particles secreted from the at least one cell and that this information can be correlated to the individual cell and/or cell population. The disclosure further relates to a device for use in the method and a system and a computer program for performing one or more of the steps of the method.

A method of obtaining a compound may include adding a substrate to a medium in a reactor, and reacting the substrate in the reactor to form the compound. A first stream is separated from the reaction liquid through a first membrane. A second stream is separated from the reaction liquid through a second membrane. The first membrane is a filtration membrane and the second membrane is configured for liquid-gas or liquid-liquid extraction The first membrane and the second membrane are at least partially immersed in the medium and are moved relative to the reactor during the separation steps.

Described herein are genetically-engineered organisms comprising synthetic operons for the production of isoprenoids, carotenoids, and retinoids, optimized for use in a hydrocarbonoclastic organism, and methods for the synthesis and extraction of isoprenoids in a biofilm bioreactor comprising the genetically-engineered organisms.

Processes, systems, and associated control methodologies are disclosed that control the flow of biogas during the biogas cleanup process to create a more consistent flow of biogas through the digester, while also optimizing the output and efficiency of the overall renewable natural gas facility. In representative embodiments, a biogas buffer storage system may be used during the cleanup process to control the pressure and flow rate of biogas. The biogas buffer storage system may monitor and control the biogas flow rate to either bring down or increase the digester pressure, thereby maintaining a normalized biogas flow rate.

A fluid filtration system includes a fluid storage vessel such as a bioreactor, a filter housing including a filter element disposed therein, a pump coupled between the fluid storage vessel and the filter housing, and a flow diverter disposed between the pump and the filter housing. The pump is configured to move fluid from the fluid storage vessel through the filter element, and the flow diverter is configured for selectively directing fluid received from the pump to the first or second end of the filter housing. In a first mode of operation, the flow diverter directs flow through the filter housing in a first direction, while in a second mode of operation, the flow diverter directs flow through the filter housing in a second direction opposite the first direction.

A liquid filtration system comprising a syringe pump comprising a gas chamber and a movable plunger, wherein the gas chamber has an aperture at a first end and the plunger forms a seal within the internal walls of the chamber; a liquid chamber having two openings, the openings positioned at opposite ends of the chamber and the first opening connected to the aperture of the gas chamber; a bioreactor in fluidic communication with the second opening of the liquid chamber; a filter arranged to filter liquid passing between the bioreactor and the liquid chamber, the filter comprising a permeate outlet for removing filtered liquid; wherein, in use, the plunger may be moved in a reciprocating motion causing a corresponding movement of gas which drives liquid alternately between the liquid chamber and the bioreactor such that liquid passes through the filter and filtered liquid may be removed via the permeate outlet.

The embodiments of the disclosure provide a biological filtration system and a controlling method for the biological filtration system. The biological filtration system for filtering a solution in a bioreactor, comprises: a filter device having a top end and a bottom end, one of the top end and the bottom end being in fluid communication with the bioreactor for filtering the solution in the bioreactor; a liquid chamber in fluid communication with the other one of the top end and the bottom end for storing a solution in the filter device; a positive pressure pump, in fluid communication with the liquid chamber, for driving a solution to flow from the liquid chamber to the bioreactor; and a negative pressure pump, in fluid communication with the liquid chamber, for driving a solution to flow from the bioreactor to the liquid chamber.