The presently disclosed subject matter provides a cell culture evaluation system including a measurement unit, a first storage unit, a second storage unit, an evaluation unit and an output unit, wherein: the measurement unit includes a sensor that acquires evaluation target data about motion or a state of a culture tool; the first storage unit stores the evaluation target data; the second storage unit stores reference data; the evaluation unit compares the evaluation target data with the reference data so as to evaluate an execution state of a cell culture process; and the output unit outputs an evaluation result created by the evaluation unit.

A system and method for a reactor-based biomass processing comprising: detecting a biomass input, comprising: detecting the biomass type, detecting the biomass quality, comprising detecting the biomass composition including the biomass moisture content, and detecting the biomass quantity; determining an optimized end-product, wherein the end-product is at least partially based on: a selected production target, the biomass input, and on local conditions; and producing the end-product, comprising: monitoring reaction conditions, configuring the reactor for the output production, based at least partially on biomass input, wherein configuring the reactor includes adjusting an oxygen flow rate into the reactor, and implementing a biomass decomposition.

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.

The present invention relates to a process for depositing at least a culture of microorganisms to an elongated element, preferably a yarn, comprising the steps of: providing at least a first feeding device comprising at least a first outlet; supplying at least one elongated element to said at least first feeding device; feeding to said first outlet at least a first culture comprising at least one microorganism; dispensing said first culture from said at least first outlet; contacting at least part of said elongated element with said first culture of microorganisms, to provide at least a part of said elongated element with an amount of said first culture of microorganisms.

A fabrication support apparatus of a layered cell sheet in which a plurality of cell sheets are layered on one another includes circuitry. The circuitry is configured to acquire optical information that is information regarding optical properties of the layered cell sheet; to calculate a thickness distribution of the layered cell sheet based on the acquired optical information; to determine a layering position of a cell sheet to be newly layered on the layered cell sheet based on the calculated thickness distribution; and to output information of the determined layering position.

Disposable, pre-sterilized, and pre-calibrated, pre-validated sensor components are provided. The sensor components interact with a sensor system having disposable fluid conduit or bioreactor bag and a reusable sensor assembly. The components can include an optical bench or inset optical component or module designed to be integrated within the disposable fluid conduit or bioreactor bag, which provides an optical light path through the conduit or bag. The sensors systems are designed to store sensor-specific information, such as calibration and production information, in a non-volatile memory chip on the disposable fluid conduit or bag and on the reusable sensor assembly. Methods for calibrating the sensor and for determining a target property of an unknown fluid are also disclosed. The devices, systems and methods relating to the sensor are suitable for and can be outfitted for turbidity sensing.

The present invention relates to the use of online biomass capacitance monitoring in cultures as a way to control the growth of cells through the use of a temperature control loop. In certain embodiments, a biomass capacitance probe is used to measure the cell density, and a predetermined growth curve is used to adjust the temperature in the culture.

The present disclosure provides a system, including methods and apparatus, for culturing, monitoring, and/or analyzing organoids. In an exemplary method of organoid culture, the method may comprise disposing a scaffold in a receptacle having an open side. A sealing member may be bonded to the open side of the receptacle to create a chamber. An organoid may be formed in the chamber using the scaffold. Fluid and/or at least one substance may be introduced into the chamber from an overlying reservoir for contact with the organoid.

Systems and methods for automated cell culturing are disclosed. In some embodiments, one or more cell culture vessels are fluidly connected with one or more multiport valves and one or more fluid pumps. The fluid pumps may pump various fluids into and out of the cell culture vessels as necessary to support cell growth, routed by the one or more multiport valves. In some embodiments, one or more components may be removable from other components so that some components may be prepared and sterilized independently prior to usage.

Reader and plate methods, operations, and systems for observing a biological sample are shown and described. In one embodiment, a device for observing biological growth, when present, on a growth plate, includes an imaging device and a variable positioning nest. The nest may include a first sunken frame to receive a first growth plate, and an offset second sunken frame to receive a distinct second growth plate in an operating position offset about the first operating position.