Said brewing system is intended to be fitted to a bioreactor which can be used in particular in milk and cheese factories, fermented dough production units, breweries, wine-making units or even low-temperature fermentation units in an aerobic or anaerobic environment, in particular lacto-fermentation units for the purpose of preserving vegetables, wastewater treatment stations, fish farming ponds with or without temperature control. According to the invention, said brewing system comprises:—at least one flexible and sealed brewing chamber (2, 3),—means (4) for receiving a fluid referred to as the filling fluid,—means (5, 51, 70, 71) for transferring the filling fluid between the brewing chambers (2, 3), and means (4) for receiving the filling fluid as well as varying the volume of the filling fluid admitted into each brewing chamber.

A concentration device for concentrating a liquid containing a target object, the concentration device including: a container configured to store the liquid containing the target object; a filter in the container; and a position control portion configured to change a position of the filter in the container.

The present disclosure relates to a bioreactor assembly having a housing defining an interior chamber; a lid assembly removably coupled to the housing and enclosing the interior chamber; and a gimbal assembly disposable within the interior chamber. The gimbal assembly includes a cradle configured to hold an organ or organ scaffold and an arm assembly configured to move the cradle between a plurality of positions. The bioreactor assembly also includes an ultrasound imaging unit positioned to capture volumetric and/or spatial data of the organ or organ scaffold.

A culture system and a culture device each can minimize the burden on workers and can effectively prevent the effect of temperature changes on culture by performing manipulation of a multilayer culture vessel and the culture in sequence in the same space. The culture system comprises a housing with an internal space in which a multilayer culture vessel including a plurality of trays therein is placed, and a manipulator manipulating the multilayer culture vessel while the multilayer culture vessel is kept in a state placed within the internal space. The multilayer culture vessel is communicated with a liquid supply tube such that a fluid material can be introduced into the multilayer culture vessel from an outside of the housing via the liquid supply tube, or that a fluid can be discharged from the multilayer culture vessel to the outside of the housing via the liquid supply tube.

The invention includes methods, apparatus, and systems for the conversion of hydrogen together with carbon dioxide or carbon monoxide to methane using a population of microbes and a defined liquid medium. The microbial population maintains the amount of nutrients in the liquid medium within a relative range without requiring replenishment of the nutrients. Methods and apparatus for enriching the microbial population are also described.

Disclosed herein are platforms, systems, and methods including a cell culture system that includes a cell culture container comprising a cell culture, the cell culture receiving input cells, a cell imaging subsystem configured to acquire images of the cell culture, a computing subsystem configured to perform a cell culture process on the cell culture according to the images acquired by the cell imaging subsystem, and a cell editing subsystem configured to edit the cell culture to produce output cell products according to the cell culture process.

The invention relates to a sensor module (1) for multiparametric analysis of a medium (105) and to the uses thereof. The sensor module (1) according to the invention is characterised by a combination of photonic and non-photonic measurement principles with parameter-sensitive coatings (103) on a substrate (100). A plurality of properties of a medium (105) can be detected over wide parameter ranges, wherein the most suitable method can be used for the corresponding parameter, at least for example with regard to the accuracy, the long-term stability, the resolution, the reproducibility, the energy consumption, the manufacturing costs, the necessary space requirements.

A sensor positioning system for a bioprocess engineering unit, wherein a container is provided for receiving a biological medium which, when installed, extends in the axial direction from an upper container end to a lower container end, wherein a holder is provided for holding the container when installed, wherein a sensor is provided for fixing to the container. A positioning aid device for positioning the sensor to be fixed is provided on the container, the positioning aid device has a positioning aid that can be applied directly to or near the container on the holder, which can be brought into different vertical positions and/or circumferential positions relative to at least one reference point provided on the container and/or holder, and the positioning aid device has a technical storage medium or analog print medium with an allocation list.

A bioprocess device assembly includes at least a first bioreactor and a second bioreactor, and a transfer system for transferring a certain volume of a medium contained in the first bioreactor into the second bioreactor. A biomass sensor is associated to the first bioreactor. A control unit is configured for receiving measurement data from the biomass sensor and controlling the transfer system. An inoculation method makes use of such a device assembly wherein the biomass sensor measures at least one parameter of biomass contained in the first bioreactor; the biomass sensor sends measurement data to the control unit; and the control unit evaluates the measurement data and, based on an evaluation of the measurement data decides whether the viable cell density is sufficient for inoculation, determines a necessary inoculation volume, and controls the transfer system to transfer the determined inoculation volume from the first bioreactor into the second bioreactor.

Control of humidity in chemical reactors, and associated systems and methods, are generally described. In certain embodiments, the humidity within gas transport conduits and chambers can be controlled to inhibit unwanted condensation within gas transport pathways. By inhibiting condensation within gas transport pathways, clogging of such pathways can be limited (or eliminated) such that transport of gas can be more easily and controllably achieved. In addition, strategies for purging condensed liquid from chemical reactor systems are also described.