The present application relates to a method for adaptive evolution of living cells by continuous culture of said living cells.

Disclosed is a bioreactor including a rotation device that rotates a reaction container while a reference direction is taken as an axial direction thereof, and an angle adjusting device coupled to the rotation device to adjust an angle defined by the reference direction, which is dependent on an arrangement posture of the rotation device, with respect to a ground surface, by changing the arrangement posture of the rotation device.

The present invention relates to a flexible bag, a perfusion filter and a fluid port. The fluid port comprises: —a first fluid connection (3; 3′); —a second fluid connection (5; 5′) being in fluid communication with the first fluid connection (3; 3′); —an intermediate fluid path (7: 7′) connecting the first fluid connection (3; 3′) with the second fluid connection (5; 5′); wherein said intermediate fluid path (7; 7′) at least a portion of which comprises a substantially right-angled bend (9; 9′); —a protection cap (11; 11′) protecting at least the bend (9; 9′) of the intermediate fluid part (7; 7′) from contact with other objects; and —a connection surface (13; 13′) configured for sealing to a film of an object to be supplied by said port, said connection surface will, when sealed to the film of the object, together with the film provide a fluid tight seal surrounding the first fluid connection (3; 3′).

An orbital shaker device (1) for biotechnological and/or biomedical applications comprises a frame (10), a platform (15) for receiving biotechnological and/or biomedical containers (50), eccentric couplings (13, 14) for allowing an orbital movement of the platform (15) relative to the frame (10), counterweight units (17, 18) for balancing the orbital movement, and at least one motor (19) for driving the eccentric couplings (13, 14). The device comprises two eccentric couplings (13, 14) arranged near respective opposite edges (27, 28) of the platform (15), while each counterweight unit (17, 18) is arranged approximately in the plane of the combined center of gravity of the platform (15) and the containers (50). Furthermore, both eccentric couplings (13, 14) are driven by the motor (19) or motors, either directly or indirectly. In this way, an optimal vibration compensation is achieved while allowing an imaging unit (40) to be mounted underneath the platform (15).

In one example in accordance with the present disclosure, a cell analysis system is described. The cell analysis system includes at least one cell analysis device. Each cell analysis device includes a channel to serially feed individual cells from a volume of cells into a lysing chamber. The cell analysis device also includes at least one feedback-controlled lysing element in the lysing chamber to agitate a cell. The cell analysis system also includes a controller to analyze the cell. The controller includes a lysate analyzer to analyze properties of the lysate and a rupture analyzer to analyze parameters of an agitation when a cell membrane ruptures.

The present invention relates to cell culture in bioreactors, such as flexible cellbag bioreactors. More closely the invention relates to a method and system for determining the cell density in a bioreactor culture and for controlling the perfusion rate of a suspension culture of cells in a bioreactor, comprising measuring the oxygen uptake of primary mononuclear cells in a non-static bioreactor.

The invention is an automated advanced tissue engineering system that comprises a housing in which one or more tissue engineering modules are accommodated together with a central microprocessor that controls functioning of the tissue engineering modules. In one embodiment, the tissue engineering module comprises a housing supporting one or more bioreactor chamber assemblies and a fluid reservoir operationally engageable with the housing. The bioreactor chamber assemblies may be selected depending on the end product option desired and may include, for example, a cell therapy bioreactor chamber, a single implant bioreactor chamber and a multiple (mosaic) implant bioreactor chamber.

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.

The present disclosure provides a biomimetic cell culture apparatus that mimics interactions among organs in a human body. The present disclosure includes a plurality of culture units for culturing cells, a conduit for connecting the plurality of culture units to each other to form a circulating path, a pump unit disposed on the conduit for forming a flow in culture medium such that the culture medium circulates through the plurality of culture units, and an agitating module for agitating the plurality of culture units.

An enzymatic processing plant for continuous flow-based enzymatic processing of organic molecules, comprises an enzymatic processing area, wherein the enzymatic processing area comprises a turbulence-generating pipe with a repeatedly changing centre-line and/or a repeatedly changing cross-section, for generating turbulence to mix a reaction mixture and prevent sedimentation of particles as the reaction mixture is flowing through the turbulence-generating pipe, and wherein the enzymatic processing plant and the enzymatic processing area are arranged such that the reaction mixture is subjected to turbulence within the enzymatic processing area for a reaction time of 15 minutes or more.