Disclosed are a heating culture device used to provide an environment with a vertical temperature difference and a method of using the heating culture device. The heating culture device is provided for accommodating and heating a cell separation device which carries living cells having flagella and capable of moving autonomously and has a film for passing through the living cells and partitioning the cell separating device into upper and lower chambers. The heating culture device includes a carrying assembly, a chip carrier box, a case assembly and a control assembly. When a cover of the heating culture device is covered during operation, the control assembly can control driving state of an upper electric heating plate at the cover according to the temperature of a heat spreader set on the cover; and control a fan at the bottom according to the temperature at the bottom of the chip carrier box.

Systems and methods are disclosed for continuously optimizing the profile of an aqueous culture comprising microorganisms. The systems and methods comprise a controlled environment comprising a housing enclosing a lighting device and controlled temperature environment, and sensor modules for measuring culture and environment parameters. The sensor modules may be in communication with an automated computer control system to continuously optimize the microorganism culture profile.

An anaerobic digestion system is provided that includes a blend tank operable to control and perform pre-treatment of feedstock. An anaerobic digester is operable to digest the feedstock provided from the blend tank in a totally enclosed oxygen-free environment within a specific temperature range. A bio-mass tank processes liquid digestate from the anaerobic digester. One or more baffles are positioned in the digester, with the one or more baffles providing for plug flow through at least a portion of the digester to create baffled zones that are at least partially operable independently of adjacent baffled zones. A bio-mass tank processes liquid digestate from the anaerobic digester. An energy source is coupled to the anaerobic digester.

A system for receiving a disposable bag (44) has a receiving container (10) with a container interior for receiving the disposable bag (44) and a temperature-control hollow wall (20) that at least partially surrounds the container interior of the receiving container (10). A temperature-control unit controls the temperature of the container interior by will a temperature-control medium arranged in the temperature-control hollow wall (20) at a maximum pressure of about 1 bar.

A combined anaerobic digester system and gas-to-liquid system is disclosed. The anaerobic digester requires heat, and produces methane. The gas-to-liquid system produces heat, and converts methane to higher-value products, including methanol and formaldehyde. As such, the combination of the two systems results in significant savings in terms of capital and operating expenses. A process for producing bio-formaldehyde and bio-formalin from biogas is also disclosed.

A bioartificial liver device including a bioreaction chamber having a plurality of semi-permeable membranes and a plurality of filter spaces each confined by two adjacent semi-permeable membranes; a plurality of liver cell perfusion ports each communicating with one of the filter spaces for introducing the liver cells into the filter spaces, and a positive peristaltic pump. In the device, the semi-permeable membranes are disposed substantially horizontal with respect to the ground, and the positive peristaltic pump is adapted to drive the plasma flow from the bottom wall of the device to the top wall. The device of the invention improves the cell loading and the area for substance exchange between the blood and the liver cells.

The disclosure features a bioreactor for the growth of macroalgae and methods for using the bioreactor to maintain optimal nutrient levels for the organisms in an aquarium or aquaculture system. The devices and methods of the disclosure provide for the bioremediation of excess nutrients in order to maintain nutrient balance in an aquarium or aquaculture system that facilitates growth and/or health of one or more of the organisms that reside therein.

Methods and apparatus for culturing microorganisms are described, including culturing in mixotrophic culture conditions. A bioreactor array with multiple culture vessels with independently controllable inputs is used to culture similar cultures of microorganisms in which at least one parameter differs from other culture vessels in the bioreactor array.

The rapid thermal cycling of a material is targeted. A microfluidic heat exchanger with an internal porous medium is coupled to tanks containing cold fluid and hot fluid. Fluid flows alternately from the cold tank and the hot tank into the porous medium, cooling and heating samples contained in the microfluidic heat exchanger's sample wells. A valve may be coupled to the tanks and a pump, and switching the position of the valve may switch the source and direction of fluid flowing through the porous medium. A controller may control the switching of valve positions based on the temperature of the samples and determined temperature thresholds. A sample tray for containing samples to be thermally cycled may be used in conjunction with the thermal cycling system. A surface or internal electrical heater may aid in heating the samples, or may replace the necessity for the hot tank.

Manufacturing system and method for creating multiple tissue constructs from cells. System can include a thaw subsystem (if the cells are provided in a frozen state), an expansion subsystem, a concentration subsystem, and a tissue maturation subsystem. Each of these subsystems is modular and can be reconfigured, and the process can be repeated depending on the specific tissue process being implemented. Multiple tissue types can be combined in multiple bioreactors. The activities of multiple bioreactors can be coordinated and controlled in an automated manner by a supervisor controller. The supervisor controller can receive user input at the start of the process, and can manage the process henceforth, alerting the user if user actions are required.