Abstract: The present invention relates to a method of loading a fluid into a fluidic element, wherein the method is performed in a fluidic system comprising the fluidic element, wherein the method comprises determining a volume that has flown into the fluidic element since a start time tstart, and at a switching time tswitch, switching the fluidic system to an operating state to stop flow into the fluidic element. The present invention also relates to a fluidic system configured for performing the method, and to a corresponding computer program product.

Abstract: A method for determining a state of a fluidic system can include measuring back pressures in the fluidic system at different times and determining a state of the fluidic system. The determination is based on at least the measured back pressures and on additional status information indicative of at least one status of the fluidic system at at least one of the different times.

Abstract: The present invention relates to a method of operating a fluidic system, wherein the fluidic system comprises a fluidic resistive element, wherein the method comprises a defined volume flow step, wherein in the defined volume flow step, a defined volume of a fluid is forced to flow out of the fluidic resistive element, wherein the defined volume is the fluid flowing out of the fluidic resistive element in a first time interval defined by a time tstart and a time tend, wherein the defined volume flow step comprises: at the time tstart, switching the system from a first operating state to a second operating state, to bring a pressure in the fluidic resistive element from a first pressure value to a second pressure value, the second pressure value exceeding the first pressure value, and at a time treduce, which is after the time tstart and not later than the time tend, switching the system to a third operating state to bring the pressure in the fluidic resistive element to a third pressure value, the third press

Abstract: A method for determining a state of a fluidic system can include measuring back pressures in the fluidic system at different times and determining a state of the fluidic system. The determination is based on at least the measured back pressures and on additional status information indicative of at least one status of the fluidic system at at least one of the different times.

Abstract: The present invention relates to a method for monitoring, wherein the sample injector comprises a sample storage portion and a volume displacement device. The method comprises obtaining a pressure characteristic indicative for a pressure of the sample storage portion. In addition, the method comprises obtaining a displacement characteristic indicative for a displacement volume of the volume displacement device, when the volume displacement device is fluidically connected to the sample storage portion. Based on the obtained pressure characteristic and the obtained measured displacement characteristic the method comprises determining at least one result. In addition, the present invention relates to a sample injector, sample injector system and a system configured to carry out the method.

Abstract: In a first aspect, the present invention relates to a method of testing a fluidic system. The method comprising applying a fluid with an input fluidic characteristic to the fluidic system, while the fluidic system is in a first configuration, and measuring an output fluidic characteristic. The method also comprises comparing the measured output fluidic characteristic to a reference. In a further aspect the present invention relates to a testing system configured for testing a fluidic system.

Abstract: A method for measuring a flow of a fluid in a tube includes heating the fluid in the tube with a heating element. A first signal is measured with a first temperature sensing element at a first location. A second signal is measured with a second temperature sensing element at a second location. At least one temperature signal is calculated based on the first signal and the second signal. The at least one temperature signal includes a difference temperature signal and a sum temperature signal. The difference temperature signal is calculated based on a difference between the second signal and the first signal. The sum temperature signal is calculated based on a sum of the second signal and the first signal. The flow is derived based on the difference temperature signal, the sum temperature signal, or a combination thereof.

Abstract: A method for determining a state of a fluidic system can include measuring back pressures in the fluidic system at different times and determining a state of the fluidic system. The determination is based on at least the measured back pressures and on additional status information indicative of at least one status of the fluidic system at at least one of the different times.

Abstract: A method for measuring a flow of a fluid in a tube includes heating the fluid in the tube with a heating element. A first signal is measured with a first temperature sensing element at a first location. A second signal is measured with a second temperature sensing element at a second location. At least one temperature signal is calculated based on the first signal and the second signal. The at least one temperature signal includes a difference temperature signal and a sum temperature signal. The difference temperature signal is calculated based on a difference between the second signal and the first signal. The sum temperature signal is calculated based on a sum of the second signal and the first signal. The flow is derived based on the difference temperature signal, the sum temperature signal, or a combination thereof.

Abstract: This invention relates to certain dendrimer compounds. In particular, this invention relates to novel dendrimer compounds that can be elaborated to give increasingly large and complex compounds. These elaborated compounds can be attached to, or can encapsulate within, active agent(s) so as to beneficially modify the characteristics of that active agent. Alternatively, the elaborated compounds can themselves be beneficially modified into therapeutic agents by the attachment of inactive agents.

Abstract: This invention relates to certain dendrimer compounds. In particular, this invention relates to novel dendrimer compounds that can be elaborated to give increasingly large and complex compounds. These elaborated compounds can be attached to, or can encapsulate within, active agent(s) so as to beneficially modify the characteristics of that active agent. Alternatively, the elaborated compounds can themselves be beneficially modified into therapeutic agents by the attachment of inactive agents.

Abstract: This invention relates to certain dendrimer compounds. In particular, this invention relates to novel dendrimer compounds that can be elaborated to give increasingly large and complex compounds. These elaborated compounds can be attached to, or can encapsulate within, active agent(s) so as to beneficially modify the characteristics of that active agent. Alternatively, the elaborated compounds can themselves be beneficially modified into therapeutic agents by the attachment of inactive agents.

Abstract: The following invention is directed to macromolecules having controlled stoichiometry and topology, processes for their production, and applications for their use. The macromolecules have a controlled functional moiety stoichiometry and include at least one dendritic motif having a surface layer formed from at least one surface building unit and at least one subsurface layer formed from at least one building unit, the surface building unit and building units having a hydrocarbon backbone bearing a carbonyl group and at least one amine group; and at least two different functional moieties on the building unit and/or surface building unit; where functional moiety stoichiometry refers to the number and type of functional moieties.

Abstract: The following invention is directed to macromolecules having controlled stoichiometry and topology, processes for their production, and applications for their use. The macromolecules have a controlled functional moiety stoichiometry and include at least one dendritic motif having a surface layer formed from at least one surface building unit and at least one subsurface layer formed from at least one building unit, the surface building unit and building units having a hydrocarbon backbone bearing a carbonyl group and at least one amine group; and at least two different functional moieties on the building unit and/or surface building unit; where functional moiety stoichiometry refers to the number and type of functional moieties.

Abstract: The following invention is directed to macromolecules having controlled stoichiometry and topology, processes for their production, and applications for their use. The macromolecules have a controlled functional moiety stoichiometry and include at least one dendritic motif having a surface layer formed from at least one surface building unit and at least one subsurface layer formed from at least one building unit, the surface building unit and building units having a hydrocarbon backbone bearing a carbonyl group and at least one amine group; and at least two different functional moieties on the building unit and/or surface building unit; where functional moiety stoichiometry refers to the number and type of functional moieties.

Abstract: The following invention is directed to macromolecules having controlled stoichiometry and topology, processes for their production, and applications for their use. The macromolecules have a controlled functional moiety stoichiometry and include at least one dendritic motif having a surface layer formed from at least one surface building unit and at least one subsurface layer formed from at least one building unit, the surface building unit and building units having a hydrocarbon backbone bearing a carbonyl group and at least one amine group; and at least two different functional moieties on the building unit and/or surface building unit; where functional moiety stoichiometry refers to the number and type of functional moieties.

Abstract: A &bgr;-D-glucofuranose compound which is 1,2,3,5,6-penta-O-propanoyl-&bgr;-D-glucofuranose, preferably in crystalline form, is prepared from D-glucose. The compound is prepared by reacting D-glucose with boric acid, or an equivalent thereof, followed by treatment with a propanoylating reagent, preferably propanoic anhydride. The compound is useful for the preparation of other compounds, such as glucofuranosides.