Abstract: An apparatus for applying energy to an object includes an arrangement of energy emitting elements for outputting energy to the object. At least some of the energy emitting elements are configured to emit energy to the object independently from each other.

Abstract: A method for radiotherapy monitoring is provided. The method comprises calculation of treatment-guiding indices of side-effects based on processing image derived descriptors and measurement values of selected disease specific biomarkers and optionally questionnaire data. A computer program product is also provided.

Abstract: A method includes generating a kinetic parameter value for a VOI in a functional image of a subject based on motion corrected projection data using an iterative algorithm, including determining a motion correction for projection data corresponding to the VOI based on the VOI, motion correcting the projection data corresponding to the VOI to generate the motion corrected projection data, and estimating the at least one kinetic parameter value based on the motion corrected projection data or image data generated with the motion corrected projection data. In another embodiment, a method includes registering functional image data indicative of tracer uptake in a scanned patient with image data from a different imaging modality, identifying a VOI in the image based on the registered images, generating at least one kinetic parameter for the VOI, and generating a feature vector including the at least one generated kinetic parameter and at least one bio-marker.

Abstract: A method for radiotherapy monitoring is provided. The method comprises calculation of treatment-guiding indices of side-effects based on processing image derived descriptors and measurement values of selected disease specific biomarkers and optionally questionnaire data. A computer program product is also provided.

Abstract: A method includes generating a kinetic parameter value for a VOI in a functional image of a subject based on motion corrected projection data using an iterative algorithm, including determining a motion correction for projection data corresponding to the VOI based on the VOI, motion correcting the projection data corresponding to the VOI to generate the motion corrected projection data, and estimating the at least one kinetic parameter value based on the motion corrected projection data or image data generated with the motion corrected projection data. In another embodiment, a method includes registering functional image data indicative of tracer uptake in a scanned patient with image data from a different imaging modality, identifying a VOI in the image based on the registered images, generating at least one kinetic parameter for the VOI, and generating a feature vector including the at least one generated kinetic parameter and at least one bio- marker.

Abstract: The present invention relates to an apparatus for applying energy to an object, wherein the apparatus comprises an arrangement (7) of energy emitting elements (19) for outputting energy to the object. At least some of the energy emitting elements (19) are adapted for emitting energy to the object independently from each other.

Abstract: The present invention relates to a system (1) and method for detecting and predicting a syncope event. Furthermore the invention relates to a computer program (13) to be executed in a computer (5, 17), said computer (5, 17) being part of a system (1) for detecting and predicting a syncope event. It is an object of the present invention to provide a simple and reliable technique for detecting and predicting the occurrence of syncope events. This object is achieved according to the invention by a method of detecting and predicting a syncope event, the method comprising the steps of continuously obtaining (100) the pulse wave patterns (3) from the upper vascular system of the user (4), determining (101) from the pulse wave patterns (3) a measure (21) of the blood flow to the user's brain, and generating (103) an alarm signal (6), if the blood flow measure indicates the future occurrence of a syncope.

Abstract: An electrode assembly arranged to carry out a bioelectrical interaction with an individual, said electrode assembly comprising a conductive material having a contact surface arranged to be brought into contact with a receiving area of the individual's skin, said conductive material being electrically connectable to a suitable electronic device to enable said interaction, the electrode assembly having an impedance control means arranged to measure and control the impedance of the receiving area of the individual's skin prior to an event of the bioelectrical interaction.

Abstract: A monitoring device (21) arranged to measure a signal (S1) representative of a physiological condition of the individual by means of a suitably arranged sensor (22) and to automatically modify a contact pressure (P) of said sensor meeting real-time requirements. For this purpose the sensor (22) is supported by a piece of elastic material, the monitoring device further comprising an actuator (27) arranged to interact with the piece of elastic material upon receipt of a control signal (CS) from a control unit (25). The control unit (25) is arranged to analyze the signal (S1) from the sensor (22) and to decide on an alteration of the contact pressure (P). For this purpose the control means (25) comprises a logic unit (25a) arranged to carry out a suitable signal analysis. Preferably, the monitoring device (21) is arranged with a further sensor (23), a signal (S3) of which is also provided for analysis to the control unit (25).

Abstract: The invention relates to a wearable device arranged for enabling a bioelectrical interaction with an individual when being brought into contact with the individual's skin I, said device comprising electrodes 2 arranged to carry out said interaction by means of a first electrical signal, said electrodes comprise motion artifact detection means 4. The electrode assembly 1 comprises electrode 2 arranged to carry out a bioelectrical interaction with the individual by means of measuring an electrical signal on the body of the individual I and/or applying an electrical signal to the body of the individual. In order to enable said bioelectrical interaction the electrode 2 is provided with an electrical cable 2a. According to the invention, the electrode 2 is arranged with a pr 4. The pressure sensor 4 is arranged to measure a normal force component of an external force applied to the electrode due to movement of the individual.

Abstract: The invention relates to a distress signaling system, a body area network for enabling a distress signaling, a method for signaling a condition of a distress and a vehicle arranged with the distress signaling system. The distress signaling system 10 according to the invention comprises monitoring means 11 arranged in a vehicle in order to monitor a vital sign of a seated passenger by means of a sensor 12 arranged to measure a signal representative to said sign. The monitoring means 11 are preferably arranged to perform a continuous monitoring of the vital sign of the passenger and are further arranged to provide a corresponding signal to the front-end electronics 20 of the system 10. The front-end electronics 20 is arranged to analyze the signal from the monitoring means 11. For that purpose the front-end electronics 20 comprises a data processing means 21 arranged to process the measured signal in order to yield data representative to a condition of the passenger.

Abstract: The invention relates to a wearable device arranged for enabling a bioelectrical interaction with an individual when being brought into contact with the individual's skin I, said device comprising electrodes 2 arranged to carry out said interaction by means of a first electrical signal, said electrodes comprise motion artifact detection means 4. The electrode assembly 1 comprises the electrode 2 arranged to carry out a bioelectrical interaction with the individual by means of measuring an electrical signal on the body of the individual I and/or applying an electrical signal to the body of the individual. In order to enable said bioelectrical interaction the electrode 2 is provided with an electrical cable 2a. According to the invention, the electrode 2 is arranged with a pressure sensor 4. The pressure sensor 4 is arranged to measure a normal force component of an external force applied to the electrode due to movement of the individual.

Abstract: The invention relates to a system (1) for monitoring a conductivity in a volume. The system according to the invention is suited to be used for industrial and medical applications. The system (1) comprises a resonant circuit (2,4,10) comprising a conductive coil (4) driven by a power supply means (8), said conductive coil being arranged to induce an oscillating magnetic field in the volume. The power supply means (8) is arranged to measure a power loss of said resonant circuit due to the conductivity in the volume. The conductive coil (4) is arranged to be integrated into an insulating fabric (9). Preferably the conductor forming the conductive coil is interwoven with threads of fabric. For medical applications it is preferable that the system is integrated into a bodywear, for example a T-shirt.

Abstract: An electrode assembly arranged to change the impedance of the skin area (12a, 12) under the contacting surface (11) of the electrode (10). For this purpose the body of the electrode (10) comprises the impedance control means (14) arranged to discharge an amount of the electrolyte from a depot (14). This can be controlled by the discharge means (16) arranged to induce a force of the depot (14). Preferably, the discharge means operate with an ignitable pressurized gas (15) or with settable fibers. The electrode 10 is provided with pores (13) to conduct the electrolyte from the depot (14) to the inter space (12a) between the contacting surface (11) and the receiving area of the skin (12).