The Biopowerplant is a system that integrates the generation of carbon-neutral energy through the cultivation and conversion of microalgal biomass, with sewage sanitation and environmental carbon recovery, with the additional and secondary production of biofertilizer, biofuel, water for reuse. This system integrates a suboptimal anaerobic digestion subsystem focused on the generation of biogas, the processing of the resulting digestate through a microalgal consortium culture subsystem with biofilm induction and smooth decreasing gradient of light radiation, and the transformation of the generated microalgal biomass into syngas through a subsystem of evaporation, torrefaction, pyrolysis, gasification, and combustion in separate chambers. The syngas and methane from the biogas are subsequently used as fuel in an electric power generator capable of operating with mixed gases. The biogas generation process is enriched through the recirculation of the microalgal biomass supernatant, the residual heat from the syngas generation subsystem, and the heat transferred from the combustion gases of the electric generator. The residual sludge from the biogas generation subsystem is recirculated towards a longitudinal biopile subsystem, where it acts as an anaerobic medium compared to the aerobic medium that constitutes the concentrated microalgal biomass, and both streams are mixed to be transformed into the syngas generation subsystem. Input inflows for system operation are mainly sewage, and optionally seawater and/or leachate. The inflows must be bioaugmented with a microalgal consortium dosed automatically by a Compact in situ bioaugmentation system, preferably more than 3 kilometers before the inflow enters the system.

A cell-culture bioreactor operative to provide real-time reactor management in the fields of stir control, sparge control, and heat management responsively to wireless sensor feedback to optimize operating conditions to maximize cell-culture yield; and a bioreactor comprising: a vessel, having an open top; a headplate, configured to seal the vessel's open top; and a stirring device, comprising at least two independent stirring elements; wherein each of the stirring elements is configured to independently stir media accommodated within the vessel.

A bag assembly for use with a heat exchanger includes a flexible bag having of one or more sheets of polymeric material, the bag having a first end that bounds a first compartment and an opposing second end that bounds a second compartment, a support structure being disposed between the first compartment and the second compartment so that the first compartment is separated and isolated from the second compartment. A first inlet port, a first outlet port, and a first drain port are coupled with the flexible bag so as to communicate with the first compartment. A second inlet port, a second outlet port, and a second drain port are coupled with the flexible bag so as to communicate with the second compartment.

A test vessel includes one or more test locations configured to contain a medium suitable for culturing a live substance. A thermochromic material is thermally coupled to the one or more test locations. The thermochromic material is configured to exhibit a spectral shift in light emanating from the thermochromic material in response to an increase or decrease in energy conversion by the live substance that causes a change in temperature of the thermochromic material.

An integrated two-phase anaerobic dry fermentation reactor based on a biomimetic principle of rumen includes a reactor body; wherein the reactor body includes a dry fermentation chamber, a secondary fermentation chamber, and a liquid storage chamber. The dry fermentation chamber is arranged at an upper portion of the reactor body. The liquid storage chamber is arranged at a bottom of the reactor body. The secondary fermentation chamber is arranged between the dry fermentation chamber and the liquid storage chamber in the reactor body. The dry fermentation chamber is connected to the secondary fermentation chamber by a porous structure.

Disclosed is an in vitro exposure system that may radiate a uniform field having a constant wavefront to an experimental cell container and expose each cell container to a same electromagnetic field.

An apparatus is described which includes at least one reactor, at least one linear piston pump, the or each piston pump including a tube, a piston and an arm coupled to the piston, the or each piston pump arranged to inject feedstock to a respective reactor, a beam or plate coupled to the arm(s) of the piston pump(s) configured to linearly drive the piston(s) and a linear actuator for driving the beam or plate. The piston pump has a volume of at least 50 milliliters and an output port having a diameter of at least 5 mm.

What is described herein relates to a method for improving a cell culture comprising a) heating a cell culture process fluid using a single-use dense membrane hollow fiber module wherein said single-use dense membrane hollow fiber module comprises a plurality of dense membranes arranged as hollow fibers in a housing and/or b) wherein the cell culture has at least one cell culture chamber and at least the bottom or at least the top of said cell culture chamber is covered with an insulation.

This disclosure relates to a device for separating regenerative and/or adult stem cells from a fatty tissue taken from a biological structure. In one embodiment, the device includes a container for holding a substance mixture, the substance mixture including the fatty tissue and the regenerative and/or adult stem cells, and the container including at least two chambers separated from each other by at least one membrane. The device additionally includes a substance mixture feeding facility configured to introduce the substance mixture into the container, a rinsing agent feeding facility configured to introduce a fluid into the container, a stem cell removal facility configured to remove separated stem cells from the container, a rinsing agent removal facility configured to remove a substance mixture from the container that has been at least partially depleted of regenerative and/or adult stem cells, and a specifically permeable membrane.

Gas-utilizing microorganisms are stably cultured regardless of variations in a supply flow rate of a substrate gas. Gas-utilizing microorganisms 9 are cultured in a culture solution 2 in a culture tank 10. A substrate gas containing CO and H.sub.2 or the like is supplied to the culture tank 10 and is dissolved in the culture solution 2. When a supply flow rate of the substrate gas or predetermined constituents of the substrate gas to the culture tank 10 becomes a predetermined value or lower, a culture solution 2a is rapidly discharged from the culture tank 10.