The automated cell culture arrangement according to the invention comprises at least one closed cell culture module with at least one bioreactor. The closed cell culture module is a closed system, which means that within the closed cell culture module a closed sterile environment can be maintained. The automated cell culture arrangement according to the invention, further comprises at least one pump for pumping liquids within the closed cell culture module and at least one additional tool module, which is configured or configurable to act upon or to monitor the contents of a bioreactor and is movable relative to the at least one closed cell culture module or it is movable relative to one or several components of the at least one closed cell culture module.

A cell culture apparatus includes: an isolator in which a sterile space accommodating a cell incubator filled with a culture solution containing cells to be cultured is disposed; a sampling unit configured to sample the culture solution in the cell incubator; a delivery flow path through which an inside of the sterile space and an outside of the sterile space communicate with each other, the delivery flow path configured to limit a flow in the delivery flow path to a direction that is directed from the inside of the sterile space toward the outside of the sterile space; and a culture solution delivering section configured to deliver the sampled culture solution to the outside of the sterile space via the delivery flow path.

An improved cell culture monitoring system and method that detects cell growth and concentration in a dynamic environment of incubator/shaker. In order to reduce power consumption and make a wireless cell culture monitoring system practical, several methods of temperature compensation are used to replace a method of controlling the temperature of sensing module. Furthermore its power consumption can be significantly reduced by using an adaptive and synchronized light pulse detection technique.

An isolator system 1 includes: a main isolator 3 in which an aseptic state is maintained and which is for performing an aseptic operation; an incubator 4 in which the aseptic state is maintained and which is connected to the main isolator 3 and is for culturing cells and the like; decontamination means 35 for decontaminating the inside of the main isolator 3; and a decontamination station 9 that decontaminates the inside of the incubator 4. The isolator system 1 further includes a blocking member 30 for sealing a connection port 13 from the outside, the port being provided in the main isolator 3 and being for connection with the incubator 4. When the inside of the main isolator 3 is decontaminated, the connection port 13 is sealed from the outside with the blocking member 30. The isolator system that can efficiently decontaminate the main isolator and the subisolator connected to this main isolator can be provided.

A controlled environment enclosure comprises a robotic arm manipulation system used to protect and unprotect a fluid path and a swab within the controlled environment enclosure. The apparatus allows the fluid path to be protected against dangerous decontamination vapors and chemicals before the controlled environment enclosure is decontaminated. The apparatus allows the fluid path to be unprotected without the use of gloves or other means that degrade the integrity of the controlled environment enclosure when decontamination is completed. The apparatus and method allow for the protecting, unprotecting and decontaminating sequences to be automated. In some embodiments the fluid path comprises a fill needle that can removably and aseptically be sealed with a disposable monolithic injection moulded polymeric fill needle sheath. The apparatus and method further allow for the use of a swab disposed in a swab holder that is aseptically and removably sealable to a swab cap to protect the swab against decontamination vapors.

The insert shelf (1) is characterized in that it has at least one means (3) with which an incubation medium located in an incubation vessel placed on the insert shelf (1) can be set in motion during an incubation treatment or during an incubation process in an incubator (2). For this purpose, the at least one means (3) can be operated electrically and/or preferably moved mechanically.

A microscope for microscopic examination of a sample includes an illumination optics for illuminating the sample, an imaging optics for imaging the sample, a sample chamber for receiving the sample. The sample chamber has a door providing access into the sample chamber. The microscope further includes a first fan assembly arranged on a first side of the sample chamber for blowing atmosphere into the sample chamber or for draining atmosphere out of the sample chamber, through at least one first opening arranged on the first side in a first side wall of the sample chamber, and at least one second opening arranged on a second side in a second side wall of the sample chamber for allowing atmosphere from inside the sample chamber to exit the sample chamber or for allowing atmosphere from outside the sample chamber to enter the sample chamber.

The device permitting an early detection, without measurement of the fluorescence, of colonies resulting from the multiplication of micro-organisms present in a sample to be tested, includes a substantially flat and horizontal detection surface, on which at least one support for growing the micro-organisms in the form of colonies is arranged immobile. The support is of the type membrane or agar medium. There is a detection system, such as a linear scanner, mounted movable and flat for scanning the whole or part of the surface, including at least one CCD sensor associated with an optical system comprised of at least one lighting and at least one optical device, such as a lens. The CCD sensor has a resolution higher than or equal to 2400 dpi. The detection system images colonies having a diameter smaller than 50 [mu]m through a useful magnification higher than or equal to 60.

An intelligent microbial sample treatment system includes a workbench, and a sample treatment assembly, a culture medium treatment assembly, a streaking assembly and a culture medium storage assembly that are disposed on the workbench; the sample treatment assembly comprises a sample transfer device, a filling device, and a scanning device, a weight detection device, a filling location, a shaking device and waiting locations that are disposed in sequence; and the sample transfer device moves a sample cup among the scanning device, the weight detection device, the filling location, the shaking device and the waiting locations. The intelligent microbial sample treatment system disclosed by the present invention enables improvement of work efficiency and reduction of space occupation and has a reasonable structural layout and high work efficiency.

A cell culture apparatus including cell culture units U and a measurement part (5). The measurement part (5) is provided with an imaging part (51) and is disposed so as to be capable of moving up and down between a back panel part (21) of a casing (2) and a culture container accommodating shelf (32). When the measurement unit (5) reaches a measurement position of each cell culture unit U which is a measurement subject, the culture container accommodating shelf (32) slides toward the measurement unit (5) so that portions to be measured of culture containers U20, U30 in each cell culture unit U come in an imaging range of the imaging part (51).