A combined algae bioreactor and heat-driven CO.sub.2 capture system for algae production is provided. The combined system includes a bioreactor with a parabolic trough collector (PTC) shaped structure, a PTC top surface with a spectrum-splitting coating, a thermal solar receiver, a liquid inlet, a liquid outlet, a CO.sub.2 feed pipeline, and gas release holes. The thermal solar receiver is arranged at the focal point of the bioreactor's PTC shape. The liquid inlet and the liquid outlet are arranged at two ends of a diagonal line of an opening of the bioreactor respectively. The CO.sub.2 feed pipeline is connected to the bottom end of the bioreactor. The gas release holes are arranged at the two ends of the opening of the bioreactor. A spectrum-splitting coating is applied on the bioreactor's PTC top surface, which promotes algae production.

A culture dish combination for embryo thawing and embryo transfer is provided. The culture dish combination includes a first culture dish and a second culture dish, the first culture dish includes a first dish cavity for thawing and laser-assisted hatching of frozen embryos, and an opening of the first dish cavity is upward. The second culture dish is detachably connected to the first culture dish, and the second culture dish includes a second dish cavity for balancing culture medium before the embryo transfer; the second culture dish further includes a third dish cavity surrounding the second dish cavity, and openings of the second dish cavity and the third dish cavity are upward. The culture dish combination solves problems of complex operations of thawing the frozen embryo, laser-assisted hatching and the embryo transfer, which increases the accuracy of the operation of embryo thawing and improves the stability of the incubator environment.

A system for capturing an image of a plated culture dish. The system includes an imaging device having a camera with a telecentric lens adapted to capture an image of the plated culture dish, a minor adapted to ensure that a label on the side of the plated culture dish is captured in an image of the plated culture dish that is captured by the imaging device. The system further includes at least one light system for illuminating the plated culture dish for image capture. The mirror is placed adjacent to the side of the plated culture dish on which the label is placed and at least a portion of the minor extends beneath a bottom portion of the plated culture dish at the side of the plated culture dish.

The invention provides a structured cell growth matrix or assembly comprising a one or more spacer layers and one or more cell immobilization layers. The invention further provides a bioreactor comprising said matrix or assembly.

A bioreactor (1; 2; 3) includes a receiving container (10) for receiving a disposable bag (44). A bottom surface (11) of the receiving container (10) is designed to support the disposable bag (44) in the receiving container (10). An outlet opening (5) is formed in the bottom surface (11) and tapers down with respect to the ground for receiving a drain port (45) of the disposable bag (44). The drain port is complementary to the outlet opening (5).

A bioreactor includes a base and a lid. The base includes two opposing curved or convoluted surfaces, two opposing flat surfaces, a window disposed on one of the flat surfaces, the window having a higher degree of transparency compared to other portions of the base, wherein images or videos of cells are captured through the window by non-invasive ISM device, and a rounded bottom. The lid is attachable to the base. The lid includes a shaft and a semipermeable membrane attached to the shaft, the semipermeable membrane being permeable to oxygen but impermeable to viruses and bacteria. The PAT-based online analysis directs the adaptive manipulations of bioreactor towards efficient, automated, and GMP-compliant clinical protocols of cell culture.

The invention relates to a method for producing reaction vessels from glass and to the glass reaction vessels obtainable by this method. The method comprises the following steps: 1. irradiating the surface of a first glass sheet by means of a laser beam of a wavelength for which the first glass sheet is permeable, 2. etching the first glass sheet to form recesses that extend over the complete thickness of the first glass sheet, and 3. connecting a second sheet with a surface of the first glass plate.

A system and method for growing and maintaining biological material including producing a protein associated with the tissue, selecting cells associated with the tissue, expanding the cells, creating at least one tissue bio-ink including the expanded cells, printing the at least one tissue bio-ink in at least one tissue growth medium mixture, growing the tissue from the printed at least one tissue bio-ink, and maintaining viability of the tissue.

A cell culture cartridge is provided comprising a plurality of zones geometrically configured to provide for symmetrical fluid flow with each of the plurality of zones to avoid dead areas in flow within each of the plurality of zones. In certain embodiments, at least eight inlets are provided, with an inlet positioned at each corner of the cell culture cartridge. In certain embodiments, a shared outlet is positioned on a top surface of the cell culture cartridge.

A cell treatment system includes an analysis unit to calculate the area or size of each of cell aggregates existing on the cell culture vessel based on an image; a display device to show the area or size of each of the cell aggregates on a display; a laser irradiator to emit laser toward the cell culture vessel so as to kill cells existing on the cell culture vessel; an input device to receive an operation input designating cells to be killed with irradiation of the laser or cells to survive without the irradiation of the laser among the cells existing on the cell culture vessel, or an operation input designating a position to be irradiated with the laser or a position not to be irradiated with the laser on the cell culture vessel; and a control unit to control a position irradiated with the laser.