Abstract: The invention concerns a digitizing ASIC (3) for an ultrasound scanning unit (2) of an ultrasound system (1), comprising: an array of analogue-to-digital converters (31) adapted to receive ultrasound signals acquired with an ultrasound transducer array and to convert the ultrasound signals into digitized ultrasound data; a memory module (32) operably coupled to the array of analogue-to-digital converters (31) and adapted to store the digitized ultrasound data; a transmitter operably coupled to the memory module (32) and adapted to transfer the digitized ultrasound data stored in the memory module (32) to a remote interface unit (6); and a controller (33) adapted to receive control signals from the interface unit (6), and, responsive to the control signals, configure the operation of components of the ASIC (3) and/or the ultrasound scanning unit (2) by setting operation parameters, wherein the controller (33) is adapted to change operation parameters of the ASIC (3) and/or the ultrasound scanning unit (2) duri

Abstract: A patient monitoring system comprising a memory (104) comprising instruction data representing a set of instructions (106) and a processor (102) configured to communicate with the memory and to execute the set of instructions. The set of instructions, when executed by the processor, cause the processor to obtain patient data about a patient being monitored by the patient monitoring system, obtain previous patient data, determine a difference between the patient data and the previous patient data; and send a message to a user display associated with the patient monitoring system, to cause the user display to adapt content displayed on the user display, based on the determined difference.

Abstract: In an embodiment, a computer-implemented method (100) is described. The method comprises receiving (102) a request associated with a user for information about a client. The method further comprises, in response to the request, generating (104) information indicative of at least one interaction between at least one caregiver and a client context associated with the client based on interaction data obtained responsive to the at least one interaction. The generated information is customized to the user based on a user profile associated with the user.

Abstract: The invention provides a system for assessing ear pathologies in a subject. The system includes an earplug configured to be at least partially inserted in the ear canal of an ear of a subject. The earplug comprises a pressure sensor adapted to generate passive pressure signals representative of passive pressure changes within the ear canal induced by maneuvers performed by the subject, wherein characteristics of the passive pressure signals are representative of one or more ear pathologies.

Abstract: The invention is directed to method for ultrasound (US) imaging using an ultrasound system comprising a US probe (10), wherein the US probe (10) is configured to insonify an imaging region, receive echo signals, digitize the received echo signals and transfer the digitized radiofrequency (RF) data (14) to a data processing unit adapted to beamform the RF data (14). The method comprises acquiring at least one scouting image (15) including an anatomical structure; selecting at least one region of interest (ROI) (16) within the scouting image (15), wherein the at least one ROI (16) includes a portion of the anatomical structure; setting a transmit (TX) scheme (46) and a receive (RX) scheme (48) for US imaging of the imaging region (18), in which the ROI (16) is insonified with different TX and RX settings than the imaging region (18) outside the ROI (16); and acquiring a plurality of US images (26) according to the TX and RX scheme.

Abstract: The invention provides device for detecting potential sinus pathologies, comprising a patch (310), comprising one or more vibration sensing devices (320), configured to be placed on facial bones overlying a sinus of a subject, wherein the patch is configured to obtain facial bone vibration signals generated due to vibrations in facial bones surrounding the sinus, wherein characteristics of the facial bone vibration signals are representative of condition of the sinus. The device further comprises a processing subsystem operationally coupled to the patch and configured to: receive the facial bone vibration signals from the patch during vocalization of sounds by the subject, resulting in resonant frequency vibrations of the facial bones; and determine a physiological measure of the sinus of the subject based on characteristics of the facial bone vibration signals received during said vocalization of sounds by the subject, wherein the facial bone vibration signals comprise the resonant frequency vibrations.

Abstract: According to an aspect, there is provided a computer implemented method for processing data relating to a subject, the method comprising: generating a first query based on contextual information relating to a subject; receiving, from a user, a second query relating to the subject; and processing the first query and the second query to generate an output comprising at least one of: a request for further input from a user; an indication of clinical information relevant to the subject.

Abstract: A system (10) is for performing ECG measurements and comprises a probe (12) with an integrated one or more ECG electrodes (22) and an ultrasound sensing means (18), such as a transducer arrangement. The probe thus provides a mobile ECG electrode which can be sequentially moved between a set of different locations on the body for acquiring ECG measurements from different angles relative to the heart (i.e. different ‘leads’). Positioning of the probe in each required location is guided by a position guidance function which uses ultrasound data acquired by the ultrasound sensing means to locate the probe (with reference to an ultrasound body atlas (28) or map), and uses a stored set of reference body locations to guide a user with guidance information as to how to move the probe to arrive at a next target electrode location. In examples, the user may be guided through a sequence of electrode locations, with ECG data acquired at each one, thereby sequentially building up a set of standard ECG lead measurements.

Abstract: A mechanism for controlling how assistance is provided to a caregiver or clinician. Information about a workload and amount of information available to the caregiver is obtained. This information is processed to determine a recommended level of assistance that should be provided to the caregiver. The operation of an assistance tool, which may be run by a processing system, is modified based upon the recommended level of assistance.

Abstract: A system is provided for detecting lung abnormalities in a subject. The system comprises a first sensor, for sensing a first acoustic signal generated by, or applied to, the subject and an arrangement of one or more second sensors for detecting a plurality of second acoustic signals from the lungs of the subject, wherein the second acoustic signals comprise attenuated versions of the first acoustic signal after passing through the lungs of the subject. The system further comprises a processor, wherein the processor is configured to determine a respective signal attenuation between the first acoustic signal and at least a subset of the plurality of second acoustic signals and process the signal attenuations thereby to detect a lung abnormality.

Abstract: An acoustic sensing apparatus and method are disclosed for acoustically surveying the chest area of a subject, and in particular the rib cage. In use the apparatus is placed on the chest, and it includes an arrangement of one or more sound sensors for sensing acoustic signals received from inside the chest. Based on the signal intensities picked up at a plurality of different locations across the chest, the different locations are each classified by a controller as either rib-aligned or intercostal space-aligned. The controller is further adapted to identify one or more sound intensity hotspots (42) within the signal intensity distribution to locate one or more anatomical objects or regions of interest within the chest, such as the heart mitral valve, the heart tricuspid valve, heart aortic valve, and the pulmonary artery as key areas for an auscultation procedure.

Abstract: An ultrasound transducer unit (12), e.g. probe, is configured with a friction guiding function. The transducer unit (12) comprises a vibration generating means (20) at a tissue contact area, and has means for sensing a sliding direction of the transducer unit across a tissue surface (42) at which the contact area is incident. The tissue surface may be an external skin surface or an internal tissue surface, e.g. in case of a catheter. A control means is operable to control the vibration of the vibration generator to adjust a level of friction at the tissue contact area. This is used by the control means to implement a friction guiding function for guiding a user in sliding the unit across the incident surface, e.g. toward a target location (44), based on controlling the friction level responsive to sensed sliding direction, for instance providing lower friction when sliding is in a target direction, while leaving other directions with relative higher frictional resistance.

Abstract: A method includes searching a single file, which includes a plurality of device log files for one or more devices, based on a template file that at least indicates a sub-set of log data of interest, generating reference data for each of the log data of interest that is located in the single file, and storing the reference data in a data structure. A computing system (102) includes a memory (114) that stores one or more instructions (120) including a log file processing module (126), and a processor (116) that executes the one or more instructions, which causes the processor to: filter log data based on a template file that indicates streams of data of interest; dynamically change the amount of data of interest based on the debug level; store the streams of data of interest; and display, in response to an input signal, a sub-set of the stored virtual stream of data of interest.

Abstract: The present application relates to a system and method for measuring a pulse wave of a subject. The system comprises: a first sensor array and a second sensor array for respectively sensing a corresponding pulse wave of a first and a second artery of the subject, each of the first sensor array and the second sensor array comprising a plurality of sensors for respectively acquiring a plurality of first signals indicating a vibration of the skin; a deriving unit configured to derive, for each of the first sensor array and the second sensor array, a second signal representing the corresponding pulse wave from the plurality of first signals; and a first calculating unit configured to calculate a pulse transit time between the first artery and the second artery from the second signal derived for the first sensor array and the second signal derived for the second sensor array. An embodiment of this invention can improve accuracy of pulse wave measurement.

Abstract: A method and a device for classifying cardiac arrhythmia, using an electrocardiogram (ECG) signal, are provided. The method includes receiving the ECG signal representing an electrical activity of a heart of an individual over a period of time, the ECG signal including ECG beats. The method further includes converting each of the ECG beats into symbols. The method further includes identifying an arrhythmia class indicating a type of cardiac arrhythmia associated with the individual from arrhythmia classes indicating respective types of cardiac arrhythmia based on the symbols representing each of the ECG beats.

Abstract: Seamless data transmission methods and apparatuses for seamless data transmission in ubiquitous health care environment are provided. The method to provide seamless data transmission includes receiving data collected by a sensor at a primary gateway; transmitting the data to a server; searching for backup gateways when the data transmission is interrupted; and selecting a backup gateway based on characteristics of the backup gateway.

Abstract: A method and a device for classifying cardiac arrhythmia, using an electrocardiogram (ECG) signal, are provided. The method includes receiving the ECG signal representing an electrical activity of a heart of an individual over a period of time, the ECG signal including ECG beats. The method further includes converting each of the ECG beats into symbols. The method further includes identifying an arrhythmia class indicating a type of cardiac arrhythmia associated with the individual from arrhythmia classes indicating respective types of cardiac arrhythmia based on the symbols representing each of the ECG beats.