Abstract: A device for shaking and sampling biological liquids that is able to take a sample of a biological liquid in a tube including a shaker designed to mix a rack holding one or more tubes by performing a succession of tilting movements between two shaking positions. The shaker is also arranged to tilt beyond the shaking position furthest away from the insertion position of a rack to discharge same by gravity.

Abstract: A device for medical analyses with cellular impedance signal processing comprises a memory (4) arranged to receive pulse data sets, each pulse data set comprising impedance value data that are associated each time with a time marker, these data together representing a curve of cellular impedance values that are measured as a cell passes through a polarized opening, a computer (6) arranged to process a pulse data set by determining a rotation value indicating whether the cell from which this pulse data set has been taken has undergone a rotation during its passage through the polarized opening, and a classifier (8) arranged to retrieve from the computer (6) a given pulse data set, and to use the resulting rotation value to classify the given pulse data set in a rotation pulse data set group (10) or a rotationless pulse data set group (12).

Abstract: A biological analysis system comprising at least one inlet and one outlet, at least two biological analysis devices connected to one another by a conveyor defining a closed circuit, each biological analysis device comprising a region for the exchange of tube holding racks with the conveyor. The conveyor and the at least one inlet of the biological analysis system comprise a reader of an identifier of a tube holding rack which reader is designed to communicate an identifier it has read to a controller of the biological analysis system, which controller is designed to apply a specific treatment to a tube holding rack identified by the reader of the conveyor and the identifier of which has not previously been read by the reader of the at least one inlet of the biological analysis system.

Abstract: A biological analysis system comprises at least two biological analysis devices connected to one another by a conveyor defining a closed circuit, each biological analysis device comprising at least one inlet and one outlet for racks of tubes, and at least one exchange region for exchanging racks of tubes with the conveyor, which exchange region is distinct from the inlet and from the outlet. The inlet of at least two biological analysis devices each form an inlet of the biological analysis system for racks of tubes, and the outlet of at least two biological analysis devices each form an outlet of the biological analysis system for racks of tubes. The biological analysis system further comprises a controller designed to command the transfer of a rack of tubes received in the biological analysis system via the conveyor to another biological analysis device according to the operations to be performed on the tubes in that rack and/or according to a respective workload status of the biological analysis devices.

Abstract: A method for characterizing a particle present in a sample, the sample lying between an image sensor and a light source and the sensor lying in a detection plane, includes illuminating the sample with the light source which emits an incident light wave propagating along a propagation axis, and acquiring an image of the sample with the sensor. The sensor is exposed to an exposure light wave. The image includes a plurality of elementary diffraction patterns each corresponding to one particle. The method also includes reconstructing a complex image representative of a complex amplitude of the light wave on a reconstruction surface passing through the sample, based on the acquired image; selecting a region of interest of the complex image corresponding to a particle of interest; forming an extracted image based on the region of interest; and characterizing the particle of interest depending on the extracted region of interest.

Abstract: An edible composition, an aerosol composition, a flavor composition, a fragrance composition, or an inhalable composition includes an organosulfur compound such as prenyl mercaptan, 2-methylthiophene, 3-methylthiophene, dimethyl disulfide, diprenyl disulfide, 3-methyl-2-buten-1-yl thiolacetate, 3-methyl-1-[(3-methyl-2-buten-1-yl)sulfanyl]-2-butene, prenylmethylthiol (1-(methylsulfanyl)-3-methyl-2-butene), prenyl thioacetate, thiogeraniol, dimethyl sulfide, or a combination of any two or more thereof, and a primary terpene compound selected from the group consisting of myrcene, ?-caryophyllene, limonene, ?-pinene, ?-pinene, valencene, ocimene, terpinolene, or a combination of any two or more thereof.

Abstract: A device for preparing a solution from a sample and a reagent, the device includes a microfluidic array having a sample supply inlet, a reagent supply inlet, a discharge outlet, a solution collection outlet, a sampling zone to which the inlets are connected, first and second preparation chambers connected to the sampling zone, arranged to either side of the sampling zone such that the liquid flowing from one preparation chamber to the other flows through the first sampling zone, the first preparation chamber having a volume that is variable between a minimum volume and a calibrated volume. The device includes valves interrupting the flow of the fluid at least at the two inlets and the collection and discharge outlets.

Abstract: The invention relates to a method for counting particles, particularly blood cells, in a sample, using a lensless optical imaging device. The sample is arranged between a light source and an image sensor. The sample is illuminated by a light source and an image is acquired by the image sensor, said image sensor being exposed to a light wave called an exposition wave. A digital propagation operator is applied to the acquired image so as to obtain a complex amplitude of the exposition wave according to a surface facing the image sensor. An image, called a reconstructed image, is formed from the modulus and/or the phase of said complex amplitude, on which image the particles to be counted appear in the form of regions of interest. The method then comprises a step of selecting the regions of interest corresponding to the particles to be counted.

Abstract: Rotary position sensors are provided. In one example implementation, a rotary position sensor can include a first member and a second member, one of the first and second members having a transmit aerial and a receive aerial and the other of the first and second members having an intermediate coupling element. The receive aerial has at least one receive conductive winding arranged to form a first set of current loops and a second set of current loops. The intermediate coupling element comprises a conductive material arranged in a pattern. The pattern of the intermediate coupling element and the layout of the first and second set of current loops are mutually arranged such that any electromotive force induced in the first set of current loops by a background magnetic field is substantially balanced by an electromotive force induced in the second set of current loops by the background magnetic field.

Abstract: New improved formulations are described, comprising at least one composition, with or without another composition, in which the at least one composition is an inhibitor of lipid A deacetylase resulting in permeabilization of an outer membrane of a susceptible microorganism to which it is provided to. The another composition is a streptogramin. Said at least one composition, alone or in combination, may be used to improve and/or treat a wide variety of bacterial infections, providing better efficacy, bioavailability, and/or pharmacokinetics, as compared with at least other or alternative inhibitors of lipid A deacetylase. When provided to a susceptible microorganism as a combination described herein, of the at least one composition and the another composition, the combination may be provided independently or may be provided together (co-combined in a same formulation, or in different formulations).

Abstract: A method for producing a radiofluorinated compound having an aromatic or heteroaromatic ring carrying [18F] fluorine as first substituent, a bonding unit, which can bind to a peptide or peptide mimetic, and a spacer group connected via bond A1 to the bonding unit and via bond A2 to the ring, wherein the bonding unit has second substituent(s) —OH, —CONH, and/or —COOH. The steps include (a) providing a precursor having the ring carrying a substituent Y, bonding unit with the second substituent(s), and spacer group, wherein substituent Y is —N+(R1R2R3), —NO2, —Cl, —Br, —F, or —I, and R1, R2, and R3 are independently C1-C6 alkyl; and (b) reacting the precursor with a [18F] fluoride anion in the presence of an activation salt to the radiofluorinated compound, which has a cation N+(R4R5R6R7) with R4, R5, R6, and R7 being independently C1-C6 alkyl, wherein the substituent Y is replaced by [18F] fluoride.

Abstract: The invention relates to a method for counting particles, particularly blood cells, in a sample, using a lensless optical imaging device. The sample is arranged between a light source and an image sensor. The sample is illuminated by a light source and an image is acquired by the image sensor, said image sensor being exposed to a light wave called an exposition wave. A digital propagation operator is applied to the acquired image so as to obtain a complex amplitude of the exposition wave according to a surface facing the image sensor. An image, called a reconstructed image, is formed from the modulus and/or the phase of said complex amplitude, on which image the particles to be counted appear in the form of regions of interest. The method then comprises a step of selecting the regions of interest corresponding to the particles to be counted.

Abstract: Novel antimicrobial compositions comprise at least a form of a fosfomycin (or suitable analogs, or derivatives thereof), and at least one sulfonamide (or suitable analogs, or derivatives thereof), and/or at least one diaminopyridine (or suitable analogs, or derivatives thereof). Said antimicrobial compositions generally include two or more of said components as a novel combination, provided in a single combination or formulation, or provided independently with overlapping exposures of the two or more components. These novel compositions, when provided as the two or more components, are effective against susceptible microorganisms, and are effective against susceptible drug-resistant microorganisms (e.g., bacteria, parasites), including multi-drug resistant bacteria.

Abstract: A method for holographic characterization of a particle contained in a sample, based on an image, or hologram, of the sample obtained by an image sensor when the sample is illuminated by a light source. The hologram is the subject of a holographic reconstruction, to obtain a reference complex image, representative of the light wave transmitted by the sample in a reconstruction plane. A holographic propagation operator is applied to the reference complex image, to obtain a plurality of secondary complex images, from which a profile is determined describing the change in an optical feature of the light wave transmuted by the sample along the axis of propagation of the light wave.

Abstract: The invention is a method for estimating a representative volume of particles of interest (10 i) immersed in a sample, the sample extending in at least one plane, referred to as the sample plane (P 10), the sample comprising a sphering agent, capable of modifying the shape of the particles, the method comprising the following steps: a) illuminating the sample by means of a light source (11), the light source emitting an incident light wave (12) propagating towards the sample (10) along a propagation axis (Z); b) acquiring, by means of an image sensor (16), an image (I 0) of the sample (10), formed in a detection plane (P 0), the sample being arranged between the light source (11) and the image sensor (16), each image being representative of a light wave (14) referred to as an exposure light wave, to which the image sensor (16) is exposed under the effect of illumination; c) using the image of the sample (I 0), acquired during step b), and a holographic propagation operator, to calculate a complex expression (

Abstract: A device for agitating and collecting biological liquid samples comprises an agitator of racks of tubes and a sampling apparatus capable of collecting a biological liquid sample in a tube. The device also comprises a scheduler arranged to specify an order of sampling from the tubes independently of the order in which the tubes are positioned in the respective racks and the order in which the racks are inserted into the device. The scheduler is arranged to control the agitator and the sampling apparatus to process the tubes in accordance with the sampling order.

Abstract: A method for producing a radiofluorinated compound having an aromatic or heteroaromatic ring carrying [18F] fluorine as first substituent, a bonding unit, which can bind to a peptide or peptide mimetic, and a spacer group connected via bond A1 to the bonding unit and via bond A2 to the ring, wherein the bonding unit has second substituent(s) —OH, —CONH, and/or —COOH. The steps include (a) providing a precursor having the ring carrying a substituent Y, bonding unit with the second substituent(s), and spacer group, wherein substituent Y is —N+(R1R2R3), —NO2, —Cl, —Br, —F, or —I, and R1, R2, and R3 are independently C1-C6 alkyl; and (b) reacting the precursor with a [18F] fluoride anion in the presence of an activation salt to the radiofluorinated compound, which has a cation N+(R4R5R6R7) with R4, R5, R6, and R7 being independently C1-C6 alkyl, wherein the substituent Y is replaced by [18F] fluoride.

Abstract: A method for producing a radiofluorinated compound having an aromatic or heteroaromatic ring carrying [18F] fluorine as first substituent, a bonding unit, which can bind to a peptide or peptide mimetic, and a spacer group connected via bond A1 to the bonding unit and via bond A2 to the ring, wherein the bonding unit has second substituent(s) —OH, —CONH, and/or —COOH. The steps include (a) providing a precursor having the ring carrying a substituent Y, bonding unit with the second substituent(s), and spacer group, wherein substituent Y is —N+(R1R2R3), —NO2, —Cl, —Br, —F, or —I, and R1, R2, and R3 are independently C1-C6 alkyl; and (b) reacting the precursor with a [18F] fluoride anion in the presence of an activation salt to the radiofluorinated compound, which has a cation N+(R4R5R6R7) with R4, R5, R6, and R7 being independently C1-C6 alkyl, wherein the substituent Y is replaced by [18F] fluoride.

Abstract: A device for counting particles comprises a detector arranged to produce an electrical measurement signal in response to the passage of one or more particles, and a comparator arranged to compare the measurement signal with a threshold signal and to increment a counting value when the measurement signal exceeds the threshold signal, characterized in that it furthermore comprises a threshold-adjusting circuit that applies a lowpass filter to the measurement signal, and that is connected to the comparator in order to use the resulting signal as threshold signal.

Abstract: A method for identifying a state of a cell contained in a sample, including: illuminating the sample using a light source by producing an incident light wave propagating toward the sample; then acquiring, using a matrix-array photodetector, an image of the sample, the sample being placed between the light source and the matrix-array photodetector such that the matrix-array photodetector is exposed to a light wave resulting from interference between the incident light wave and a diffraction wave produced by each cell; applying a numerical reconstruction algorithm to the image acquired by the matrix-array photodetector, to estimate a characteristic quantity of the light wave reaching the matrix-array detector, at a plurality of distances from the matrix-array photodetector. The value of the characteristic quantity, or its variation as a function of distance, allows the state of the cell to be determined from among predetermined states.