Abstract: In a method for producing a compound of at least two polymer substrates, two polymer substrates each having a connecting surface are provided. At least one of the polymer substrates is coated with a self-assembling polypeptide, at least in the area of the connecting surface. The two polymer substrates are connected by pressing together the connecting surfaces under pressure and at a temperature corresponding to at least the glass transition temperature of the material of one of the polymer substrates at the connecting surface, wherein a diffusion of polymer chains takes place between the connecting surfaces by the self-assembling polypeptide and a solid connection is formed between the two connecting surfaces. A sealed microfluidic cartridge includes a polymer cartridge and a sealing film connected by such a method.

Abstract: A fluidic module for switching liquid from a liquid retaining area into which liquid can be introduced into downstream fluidic structures includes at least two fluid paths fluidically connecting the liquid retaining area to the downstream fluidic structures. One of the two fluid paths includes a siphon channel. The downstream fluidic structures are not vented or only vented via a vent delay resistor, such that when the liquid is introduced into the liquid retaining area, an enclosed gas volume results in the downstream fluidic structures. By adjusting the ratio of a centrifugal pressure effected by a rotation of the fluidic module and a pneumatic pressure prevailing in the gas volume, the liquid can be retained in the liquid retaining area or can be transferred into the downstream fluidic structures via the siphon channel wherein venting takes place via the other one of the fluid paths.

Abstract: A fluid handling device has fluidic structures having inlet and outlet chambers and a connecting duct fluidically connecting the two. In a first state, the inlet chamber is completely or partly filled with at least a liquid and partly filled with a compressible medium, and the outlet chamber is at least partly filled with the compressible medium. One of the inlet chamber and the outlet chamber has such a venting duct that a flow resistance/volume product of venting of the chamber for the compressible medium amounts to at least 6700 N·s/m2, the other of the inlet chamber and of the outlet chamber being vented. An actuator for actuating the fluidic structures is to cause a pressure difference of at least 30 Pa between the compressible media within the inlet and outlet chambers, so as to thereby switch a valve device implemented into the connecting duct.

Abstract: A fluidic module for switching liquid from a liquid retaining area into which liquid can be introduced into downstream fluidic structures includes at least two fluid paths fluidically connecting the liquid retaining area to the downstream fluidic structures. One of the two fluid paths includes a siphon channel. The downstream fluidic structures are not vented or only vented via a vent delay resistor, such that when the liquid is introduced into the liquid retaining area, an enclosed gas volume results in the downstream fluidic structures. By adjusting the ratio of a centrifugal pressure effected by a rotation of the fluidic module and a pneumatic pressure prevailing in the gas volume, the liquid can be retained in the liquid retaining area or can be transferred into the downstream fluidic structures via the siphon channel wherein venting takes place via the other one of the fluid paths.

Abstract: A fluid handling device has fluidic structures having inlet and outlet chambers and a connecting duct fluidically connecting the two. In a first state, the inlet chamber is completely or partly filled with at least a liquid and partly filled with a compressible medium, and the outlet chamber is at least partly filled with the compressible medium. One of the inlet chamber and the outlet chamber has such a venting duct that a flow resistance/volume product of venting of the chamber for the compressible medium amounts to at least 6700 N·s/m2, the other of the inlet chamber and of the outlet chamber being vented. An actuator for actuating the fluidic structures is to cause a pressure difference of at least 30 Pa between the compressible media within the inlet and outlet chambers, so as to thereby switch a valve device implemented into the connecting duct.