Abstract: In order to quantitatively characterize biological objects, for example individual cells, a stimulus is applied to a biological object (8) in a contactless fashion. A measurement and a further measurement are performed on the biological object (8) in order to ascertain a response of the biological object (8) to the stimulus, wherein the measurement and the further measurement comprise detecting Raman scattering on and/or in the biological object (8) and/or capturing data using digital holographic microinterferometry (DHMI). The biological object (8) is characterized according to a result of the measurement and is sorted if needed. The stimulus can be applied by means of a laser beam that creates optical tweezers or an optical trap, by means of ultrasonic waves or an electric or magnetic radio frequency field.

Abstract: The present invention relates to vitro method for analysing a liquid sample as to the presence, identity and properties of microbes comprising: a) isolating microbes from the liquid sample; b) analysing said microbes spectroscopically by means of spontaneous Raman spectroscopy; and c) determining antibiotic susceptibility of said microbes spectroscopically by means of spontaneous Raman spectroscopy. The present invention also refers to device for analysing a liquid sample as to the presence, identity and properties of microbes, wherein the device comprises as a first unit (i) a chip comprising a filtering unit and an antibiotics exposure unit capable of determining the susceptibility of microbes to an antibiotic; as a second unit (ii) a Raman spectroscopy system; and as a third unit (iii) an evaluation module which is coupled to the Raman spectroscopy system.

Abstract: The present invention relates to an in vitro method for analysing liquid samples as to the presence, identity and properties of a virus comprising: a) analyzing said liquid samples for a virus spectroscopically by means of spontaneous Raman spectroscopy; and b) comparing the spectroscopic data to a database and identifying said virus. The present invention further relates to an in vitro method for analyzing exosomes in a liquid sample of a subject comprising: a) isolating exosomes from the liquid sample; b) analyzing said exosomes spectroscopically by means of spontaneous Raman spectroscopy; and c) obtaining a Raman spectrum for said exosomes. The present invention also refers to a device for analysing a liquid sample as to the presence, identity and properties of viruses; and to a device for analyzing exosomes in a liquid sample.

Abstract: The present invention relates to an in vitro method for determining the transfection of a cell or group of cells, wherein said determination is performed spectroscopically. The determination comprises recording at least one Raman spectrum by means of Raman spectroscopy of the cell or group of cells. Furthermore, the present invention relates to a device for determining the transfection of a cell or group of cells, wherein the device comprises as a first unit (i) a microscope system in order to visualize the cells, as a second unit (ii) a Raman spectroscopy system in order to record a Raman spectrum of a cell or group of cells, and as a third unit (iii) an evaluation module which is coupled to the Raman spectroscopy system and which is configured to determine by means of the recorded Raman spectrum whether a cell or group of cells has been transfected.

Abstract: In order to check a material for transplantation, at least one Raman spectrum (41, 42) of the material is detected. An electronic evaluation device determines an information, from which depends a suitability of the material for use during the transplantation, by evaluating the at least one Raman spectrum (41, 42).

Abstract: A method and device for quality controlling a blood-based product. In order to control the quality of a blood-based product which comprises an erythrocyte concentrate, a thrombocyte concentrate, a granulocyte concentrate, a leukocyte concentrate, whole blood and/or blood plasma, a Raman spectrum is recorded. By means of evaluating the Raman spectrum, it is determined whether the blood-based product can be used for a transfusion.

Abstract: The invention relates to a device (1) for detecting and/or evaluating a pathological condition comprising a Raman spectroscopy system (10) and an electronic evaluation device (20), which is configured to perform a detection and/or evaluation of the pathological condition in accordance with an evaluation of at least one Raman spectrum detected in stroma.

Abstract: The invention relates to a device for analyzing biological objects comprising a Raman spectroscopy system for capturing at least one Raman spectrum. The device comprises an arresting apparatus, which is designed to at least temporarily arrest the biological objects. An electronic computing apparatus is designed to determine a reaction of a biological object arrested by the arresting apparatus to at least one substance in accordance with an evaluation of the at least one Raman spectrum.

Abstract: The present invention relates to an in vitro method for determining the transfection of a cell or group of cells, wherein said determination is performed spectroscopically. The determination comprises recording at least one Raman spectrum by means of Raman spectroscopy of the cell or group of cells. Furthermore, the present invention relates to a device for determining the transfection of a cell or group of cells, wherein the device comprises as a first unit (i) a microscope system in order to visualize the cells, as a second unit (ii) a Raman spectroscopy system in order to record a Raman spectrum of a cell or group of cells, and as a third unit (iii) an evaluation module which is coupled to the Raman spectroscopy system and which is configured to determine by means of the recorded Raman spectrum whether a cell or group of cells has been transfected.

Abstract: The invention relates to a device for analyzing biological objects comprising a Raman spectroscopy system for capturing at least one Raman spectrum. The device comprises an arresting apparatus, which is designed to at least temporarily arrest the biological objects. An electronic computing apparatus is designed to determine a reaction of a biological object arrested by the arresting apparatus to at least one substance in accordance with an evaluation of the at least one Raman spectrum.

Abstract: The invention relates to a device (1) for detecting and/or evaluating a pathological condition comprising a Raman spectroscopy system (10) and an electronic evaluation device (20), which is configured to perform a detection and/or evaluation of the pathological condition in accordance with an evaluation of at least one Raman spectrum detected in stroma.

Abstract: In order to check a material for transplantation, at least one Raman spectrum (41, 42) of the material is detected. An electronic evaluation device determines an information, from which depends a suitability of the material for use during the transplantation, by evaluating the at least one Raman spectrum (41, 42).

Abstract: In order to quantitatively characterize biological objects, for example individual cells, a stimulus is applied to a biological object (8) in a contactless fashion. A measurement and a further measurement are performed on the biological object (8) in order to ascertain a response of the biological object (8) to the stimulus, wherein the measurement and the further measurement comprise detecting Raman scattering on and/or in the biological object (8) and/or capturing data using digital holographic microinterferometry (DHMI). The biological object (8) is characterized according to a result of the measurement and is sorted if needed. The stimulus can be applied by means of a laser beam that creates optical tweezers or an optical trap, by means of ultrasonic waves or an electric or magnetic radio frequency field.

Abstract: A method and device for quality controlling a blood-based product. In order to control the quality of a blood-based product which comprises an erythrocyte concentrate, a thrombocyte concentrate, a granulocyte concentrate, a leukocyte concentrate, whole blood and/or blood plasma, a Raman spectrum is recorded. By means of evaluating the Raman spectrum, it is determined whether the blood-based product can be used for a transfusion.

Abstract: In order to quantitatively characterize biological objects, for example individual cells, a stimulus is applied to a biological object in a contactless fashion. A measurement and a further measurement are performed on the biological object in order to ascertain a response of the biological object to the stimulus, wherein the measurement and the further measurement comprise detecting Raman scattering on and/or in the biological object and/or capturing data using digital holographic microinterferometry (DHMI). The biological object is characterized according to a result of the measurement and is sorted if needed. The stimulus can be applied by means of a laser beam that creates optical tweezers or an optical trap, by means of ultrasonic waves or an electric or magnetic radio frequency field.

Abstract: A sample container (20) for receptacle devices for receiving biological objects that may be used for example as collecting devices (30) in laser microdissection systems is described, in which the sample container (20) has a coding (23) with the aid of which the sample holder in the laser microdissection system can be unambiguously identified in order subsequently to be able to allocate correctly biological objects (43) to be dissected to individual receptacle containers (31) of the identified receptacle device (30) or of the identified sample holder (20), so as to carry out a fully automated microdissection procedure.

Abstract: The present invention relates to a microscope table (1) having a recess (6) for receiving at least one object-holder means. Said recess (6) is dimensioned in such a way that it is suitable for receiving a standard microtiterplate. For this purpose, said recess preferably comprises a substantially rectangular region with a length of at least 86 mm and a width of at least 128.3 mm. The device also relates to an insert for holding at least one object-holder means, which insert has a substantially rectangular shape with a width and length which correspond to the width and length, respectively, of a standard microtiterplate.

Abstract: The present invention relates to a microscope table (1) having a recess (6) for receiving at least one object-holder means. Said recess (6) is dimensioned in such a way that it is suitable for receiving a standard microtiterplate. For this purpose, said recess preferably comprises a substantially rectangular region with a length of at least 86 mm and a width of at least 128.3 mm. The device also relates to an insert for holding at least one object-holder means, which insert has a substantially rectangular shape with a width and length which correspond to the width and length, respectively, of a standard microtiterplate.

Abstract: In order to allow automatic separation and recovery of biological or non-biological objects from a mass, which is located on a mount (3), by means of laser irradiation, a collecting apparatus (2) is proposed which has control means (7, 50) for automatic production of adjustment signals for the adjustment means (13), wherein the adjustment means adjust and hence position, as a function of these adjustment signals, a holding unit (19) having at least one collecting means (21) which is or are used for collecting an object which is released from the mass.

Abstract: A sample container (20) for receptacle devices for receiving biological objects that may be used for example as collecting devices (30) in laser microdissection systems is described, in which the sample container (20) has a coding (23) with the aid of which the sample holder in the laser microdissection system can be unambiguously identified in order subsequently to be able to allocate correctly biological objects (43) to be dissected to individual receptacle containers (31) of the identified receptacle device (30) or of the identified sample holder (20), so as to carry out a fully automated microdissection procedure.