Abstract: An acceleration sensitive indicator for indicating a centrifugation status of a biological sample, a sample container comprising the indicator, a centrifuge for centrifuging samples and an analytical system for analyzing centrifuged samples are disclosed. The indicator comprises at least one closed chamber, formed between two opposite surfaces, that comprises an indication zone that comprises at least two fluid transfer zones or at least one particle transfer zone. The at least one fluid transfer zone comprises a solid carrier phase and a fluid stabilized in the solid carrier phase or at least one non-stabilized non-Newtonian fluid having thixotropic and/or shear thinning properties. The at least one particle transfer zone comprises a particle stabilizing fluid comprising stabilized dispersed particles. The fluid or particles have a distribution with respect to the indication zone changeable upon application of a g-force above a threshold value, the change of distribution indicating the centrifugation status.

Abstract: A method of individually releasing from an entity one or more members of a sub-group of biological units included in a heterogeneous group of biological units is provided. The method includes binding the group of biological units including the sub-group of biological units to the entity via a linker. Following binding, the location of the one or more members on the entity is determined. Once the location is determined, a localized physical pulse is applied to the one or more members. The localized physical pulse individually releases the one or more members from the entity by dissociating the linker.

Abstract: Systems, methods and multi-well plates comprising an array of wells for thermal treatment of chemical or biological samples are disclosed. Each of the wells comprises a bottom opening, an upper opening, inner side walls extending from the bottom opening to the upper opening, a protrusion extending from the inner side walls into the well with a first cross-sectional area and located at a height from the bottom opening which is smaller than the height from the upper opening. A sample chamber with a second cross-sectional area is formed between the bottom opening and the protrusion. An upper chamber with a third cross-sectional area is formed between the protrusion and the upper opening, and in which the first cross-sectional area is smaller than the third cross-sectional area and smaller than or equal to the second cross-sectional area.

Abstract: A microfluidic processing unit for the automated processing of liquid samples and method thereof are disclosed. In one embodiment, the unit comprises first and second main channels connected to a pump for generating a negative or positive pressure therein; a sample channel which supplies a liquid sample is connectable to a sample vessel containing the liquid sample, the sample channel communicates with the first main channel and is equipped with an on/off valve; one or more reagent channels for supplying one or more reagents, the reagent channels being connectable to reagent vessels containing reagents for reacting with the liquid samples, each of the reagent channels communicating with the first or second main channel and being equipped with an on/off valve; and a reaction chamber for reacting a sample and reagent, the reaction chamber being connected to the first and second main channels via at least one on/off valve.

Abstract: A method for the automated analysis of liquid samples using at least one microfluidic structure is disclosed as well as microfluidic structures, a device having at least one of the microfluidic structures, a kit and a system including such microfluidic device. In one embodiment, the method may comprise: transferring a sample into a first fluid reservoir which is in fluid communication with a second fluid reservoir by a flow channel; spinning the microfluidic structure so as to transport the sample into one or more dead-end recesses or chambers; transferring a control fluid into the structure which generates a barrier to flow and diffusion of the sample contained in the one or more dead-end recesses or chambers; and analyzing the sample contained in the one or more dead-end recesses or chambers.

Abstract: Method and system for carrying out heterogeneous chemical or biological reactions are disclosed. The method comprising providing an analytical device having at least one liquid processing unit having at least one reaction chamber and a first inlet channel in fluid communication with the reaction chamber. The method further comprises supplying to the reaction chamber via the first inlet channel or a second inlet channel analyte capturing particles, supplying to the reaction chamber via the first inlet channel or the second inlet channel a liquid sample containing an analyte of interest, and confining by an equilibrium of forces the analyte capturing particles in a particle rearrangement zone within the reaction chamber. The forces comprise a drag force Fd generated by flowing liquids and a counter-oriented force Fg. The method also comprises capturing analytes present in the liquid sample with the particles in the particle rearrangement zone.

Abstract: A microfluidic element for analyzing a bodily fluid sample for an analyte contained therein is provided, the element having a substrate, a channel structure that is enclosed by the substrate, and a cover layer, and is rotatable around a rotational axis. The channel structure of the microfluidic element includes a feed channel having a feed opening, a ventilation channel having a ventilation opening, and at least two reagent chambers. The reagent chambers are connected to one another via two connection channels in such a manner that a fluid exchange is possible between the reagent chambers, one of the reagent chambers having an inlet opening, which has a fluid connection to the feed channel, so that a liquid sample can flow into the rotational-axis-distal reagent chamber. At least one of the reagent chambers contains a reagent, which reacts with the liquid sample.

Abstract: A cuvette for photometric measurement of liquids is provided comprising a body having outer walls and an inner space for receiving liquids, the body comprising an upper part comprising an upper open top portion, an upper front wall, an upper back wall, and two upper side walls. The upper walls form four upper inner edges and an upper open bottom portion with a first substantially rectangular cross-section in a plane A-A, a lower measurement chamber comprising a lower closed bottom portion, a lower front wall, a lower back wall, and two lower side walls. The lower walls form four lower inner edges and a lower open top portion with a second substantially rectangular cross-section in a plane B-B smaller than the first substantially rectangular cross-section in the plane A-A, wherein at least the lower front wall and the lower back wall are at least in part substantially planar and substantially parallel to each other.

Abstract: A method for the automated analysis of liquid samples using at least one microfluidic structure is disclosed as well as microfluidic structures, a device having at least one of the microfluidic structures, a kit and a system including such microfluidic device. In one embodiment, the method may comprise: transferring said sample into a first fluid reservoir which is in fluid communication with a second fluid reservoir by a flow channel; spinning said microfluidic structure so as to transport said sample into one or more dead-end recesses or chambers; transferring a control fluid into the structure which generates a barrier to flow and diffusion of said sample contained in said one or more dead-end recesses or chambers; and analyzing said sample contained in said one or more dead-end recesses or chambers.

Abstract: A system for the automated analysis of liquid samples having one or more processing units for reaction between the samples and one or more reagents to thereby obtain reaction products is disclosed. Disclosed also are a sample unit for supplying the samples to the one or more processing units; a reagent unit equipped with plural reagent vessels containing one or more reagents for mixing with the samples; a distribution unit for distributing fluids including the one or more reagents provided with plural distribution lines, at least some of which are connected to the reagent vessels and the one or more processing units; and at least one analytical unit for analyzing the samples based on the reaction products, in which the analytical unit may include at least one detector for detecting the reaction products.

Abstract: A microfluidic processing unit for the automated processing of liquid samples and method thereof are disclosed. In one embodiment, the unit comprises first and second main channels connected to a pump for generating a negative or positive pressure therein; a sample channel which supplies a liquid sample is connectable to a sample vessel containing the liquid sample, the sample channel communicates with the first main channel and is equipped with an on/off valve; one or more reagent channels for supplying one or more reagents, the reagent channels being connectable to reagent vessels containing reagents for reacting with the liquid samples, each of the reagent channels communicating with the first or second main channel and being equipped with an on/off valve; and a reaction chamber for reacting a sample and reagent, the reaction chamber being connected to the first and second main channels via at least one on/off valve.

Abstract: Centrifugal force based microfluidic systems for the automated analysis of fluids involving the use of magnetically responsive particles and methods thereof are disclosed. A magnet is fixed to a supporting device of the system in correspondence to a retention zone of the system so as to rotate therewith and to generate a magnetic field which magnetically manipulates the magnetically responsive particles contained in a reaction chamber of the system.

Abstract: Systems, methods and multi-well plates comprising an array of wells for thermal treatment of chemical or biological samples are disclosed. Each of the wells comprises a bottom opening, an upper opening, inner side walls extending from the bottom opening to the upper opening, a protrusion extending from the inner side walls into the well with a first cross-sectional area and located at a height from the bottom opening which is smaller than the height from the upper opening. A sample chamber with a second cross-sectional area is formed between the bottom opening and the protrusion. An upper chamber with a third cross-sectional area is formed between the protrusion and the upper opening, and in which the first cross-sectional area is smaller than the third cross-sectional area and smaller than or equal to the second cross-sectional area.