Abstract: A sleep mask is configured to provide light therapy to a subject. The sleep mask provides a comfortable delivery mechanism for the light therapy, and may deliver the light therapy to the subject while the subject is asleep, in the process of going to sleep, and/or waking from sleep. In one embodiment, the sleep mask includes one or more of a shield, a strap, a first lighting module, and/or a second lighting module.

Abstract: The mouthpiece carrier assembly (12) is adapted and configured to receive the upper and lower teeth of the user. The mouthpiece carrier assembly is driven such that the bristles mounted on the teeth-facing surfaces of the mouthpiece assembly contact said surfaces and provide a cleaning effect therefor. A plurality of bristle sections (30, 32, 34, 41, 44) are secured to the teeth-facing portions of the mouthpiece assembly, wherein the bristle sections each have bristles which have a particular configuration and are otherwise adapted to provide effective cleaning for an associated dental region.

Abstract: A computed tomography acquisition method, an imaging system, a computer readable medium provides laterally displacing a radiation detector (204) from a position with centered detector geometry with a centered transverse field of view to a first offset position (212); emitting first radiation by the radiation source (202), detecting the first radiation by the radiation detector (204) and acquiring projection data indicative of the first radiation; rotating the support around the rotational axis (214) by 180°; emitting second radiation by the radiation source (202), detecting the second radiation by the radiation detector (204) and acquiring projection data indicative of the second radiation; displacing the radiation detector (204) from the first offset position to a second offset position (226), with opposite direction and double length of the first displacement (a); emitting third radiation by the radiation source (202), detecting the third radiation by the radiation detector (204) and acquiring projection da

Abstract: The present invention relates to a system (100) for increasing a degree of relaxation of a person (10) using biofeedback. The system (100) comprises a first physiological parameter determining unit (20) for determining a first physiological parameter of the person (10), a reference parameter providing unit (60) for providing a reference parameter, a correlation determining unit (30) for determining a degree of correlation between the first physiological parameter and the reference parameter and a controller (40) for determining a control information based on the determined degree of correlation for controlling a light source unit (50), wherein in a mode of operation of the system the control information is adapted to control the light source unit (50) by dimming the light source unit and/or changing the color of the light from the light source unit to warmer color tones having a lower color temperature when the degree of correlation increases.

Abstract: A method (300) for enabling self-coexistence of devices in a flexible wireless system (200) that includes first and second wireless networks sharing a frequency band. The method includes discovering a second device operable in the second wireless network that overlaps with the first wireless network (S310); reporting the discovered second device to a first device operable in the first wireless network (S320); determining if an adjustment is needed between a first beacon period of the first device and a second beacon period of the second device (S330); and adjusting a first beacon period start time (BPST) of the first device with a second BPST of the second device (S370) if the adjustment is needed.

Abstract: The invention provides a method of processing at least one heart sound signal, and the method comprises the step of: receiving (11) the at least one heart sound signal, segmenting (12) the heart sound signal into a plurality of segments, identifying (13) attribute information for each segment, annotating (14) each segment with corresponding attribute information, and outputting (15) an annotated Phonocardiogram for the at least one heart sound signal. The invention also provides a processing system for implementing the step of the methods as mentioned above.

Abstract: The appliance includes an appliance body (12) as well as a system for producing microbubbles (20) and a system for producing an ultrasound signal beam (22) in a frequency range which activates at least some of the microbubbles. The appliance includes at least one of the following: (a) an array of ultrasound transducer elements (40) which produce a plurality of ultrasound signal beams; (b) an amplitude modulation assembly (51) for modulating the amplitude of the ultrasound signal; and (c) a frequency modulation system (61) for changing the frequency of the ultrasound signals over a selected range, to impact a range of microbubble sizes.

Abstract: A data acquisition method performed by one or more controllers, the method may include receiving information related to a sequence of a plurality of images. The method may further include receiving, from an ultrasonic probe, image information corresponding to a current image of the plurality of images in the sequence. The method may further include determining whether a caliper input has been received, and when it is determined that a caliper input has been received: obtaining coordinate information corresponding to one or more locations in the current image, selecting an other image which is different from, and associated with, the current image, and obtaining one or more coordinates corresponding to one or more locations in the other image. The method may further include saving a report including the image information and the coordinate information corresponding to each image of the plurality of images of the sequence.

Abstract: The present invention provides an improved determination of an acoustic coupling between a loudspeaker (110) and a microphone (120), which results in a better estimate of the acoustic coupling during double talk. This is achieved in a device (100) for determining an acoustic coupling between a far-end talker signal (101) as produced by the loudspeaker (110) and a combined signal (102), which comprises an echo of the far-end talker signal and a near-end talker signal, as picked up by the microphone (120), in which the acoustic coupling is derived from a ratio of changes in an envelope of the combined signal (102) to changes in the envelope of the far-end talker signal (101) in a predetermined time interval. In this way the systematic error during double talk (an estimation of the acoustic coupling that is too large) is not present anymore or at least strongly reduced.

Abstract: A system and method determines the proximity of the target node to the source node from the time required to communicate messages within the node-verification protocol. The node-verification protocol includes a query-response sequence, wherein the source node communicates a query to the target node, and the target node communicates a corresponding response to the source node. The target node is configured to communicate two responses to the query: a first response that is transmitted immediately upon receipt of the query, and a second response based on the contents of the query. The communication time is determined based on the time duration between the transmission of the query and receipt of the first response at the source node and the second response is compared for correspondence to the query, to verify the authenticity of the target node.

Abstract: A handpiece (32) defines a bore (62) in which a proximal end (56) of a catheter or other interventional instrument (30) is received. An insulating support (70) supports an interventional instrument which carries an interventional instrument winding (54) in, but spaced from, the internal bore (62). A handpiece winding (64) disposed along the bore interacts with the transmission line winding (54) to form an inductive coupling with the transmission line. After the handpiece is slid axially to adjust the inductive coupling between the windings (54, 64), a locking mechanism functions in such a manner that the interventional instrument is inhibited from axial sliding motion relative to the handpiece while permitting rotation of the interventional instrument relative to the handpiece thus maintaining the inductive coupling while allowing optimal handling of the device.

Abstract: An adjustable headgear assembly (10) for securing a respiratory interface device (26) to the head of a patient that includes a head-gear member (12) that fits over the crown and back portion of a human head. The headgear member (12) has upper side portions (14) positionable above and forward of the ears of a human head and lower side portions (16) positionable below the ears and along the back portion of the head. A pair of upper retention members (20) are provided. Each pair of upper retention members (20) extends downwardly and forwardly from the upper side portions (14). A pair of lower retention members (30) extend forwardly and upwardly from each of the side portions. Each pair of upper (20) and lower (30) retention members are structured to engage a respiratory interface device (26).

Abstract: An interventional instrument (24) for use in performing an interventional procedure includes: a balloon (30) disposed proximate to a tip of the interventional instrument that inflates and anchors in a lumen of a fluid conduit during the interventional procedure; and one or more susceptibility markers (34) disposed proximate to the tip of the interventional instrument. A magnetic resonance scanner (10) is configured to image at least the tip of the interventional instrument during the interventional procedure using a magnetic resonance imaging sequence in which fluid flow (40) through the fluid conduit past the inflated balloon produces an extended magnetic resonance image artifact (42).

Abstract: A sleep mask is configured to provide light therapy to a subject. The sleep mask provides a comfortable delivery mechanism for the light therapy, and may deliver the light therapy to the subject while the subject is asleep, in the process of going to sleep, and/or waking from sleep. In one embodiment, the sleep mask includes one or more of a shield, a strap, a first lighting module, and/or a second lighting module.

Abstract: A method (300) for performing link adaptation of wireless links in a wireless network. The method comprises generating a first enhanced link adaptation (ELA) information element (100) by the transmitter (S310); sending the first ELA information element to at least one receiver (S320); upon reception of a second ELA information element at the transmitter, determining optimal transmission parameters for the transmitter, wherein the second ELA information element is generated and sent by the at least one receiver in response to the first ELA information element (S370).

Abstract: A sleep mask is configured to provide light therapy to a subject. The sleep mask may provide a comfortable delivery mechanism for the light therapy, and may deliver the light therapy to the subject while the subject is asleep, in the process of going to sleep, and/or waking from sleep. In one embodiment, the sleep mask includes one or more of a shield, a strap, a first lighting module, and/or a second lighting module.

Abstract: The present invention relates to a method of reducing occurrence of masked nodes in a communication network comprising at least three communication nodes operating in the same frequency band and wherein a first node and a second node are within a radio communication range of each other, a third node being within the radio communication range of the second node, but outside the range of the first node. First control information is exchanged between the first node and the second node for establishing a data communication link between them. Then the second node detects intention of the third node to establish a data communication link and prevents the third node from establishing the data communication link.

Abstract: A system (100) and method (400) of acoustic imaging receives an acoustic signal that is scanned to interrogate a target volume within a subject (430), processes the received acoustic signal to produce three-dimensional acoustic image data for a region of interest within the target volume (450); and quantifies the contrast of the three-dimensional acoustic image data in the region of interest at a sampling time that is offset by a selected time period with respect to a time when a contrast enhancement medium is introduced into the subject's circulatory system (480). In one embodiment, quantification is performed by setting an intensity threshold (410), and determining a percentage of voxels of the three-dimensional acoustic image data for the region of interest which have an intensity value greater than the intensity threshold (470).

Abstract: A magnetic field gradient coil assembly comprises: a structural former (20, 70, 90, 110); one or more magnetic field gradient coils (22, 24) disposed on or in the structural former; cooling conduits (52, 76, 92, 116) disposed on or in the structural former and configured to flow cooling fluid for removing heat generated by the one or more magnetic field gradient coils; and a radio frequency power amplifier (40, 42, 98) disposed on or in the structural former.

Abstract: A blender arm includes a tubular body equipped at one end with a connection for a power unit. The blender arm further includes a rotary shaft having a tool at the end opposite to the connection end. A peripheral protection is provided around the tool. The rotary shaft with the tool is attached movably in axial direction to the tubular body so that the tool may be positioned in a retracted position for operation or a protracted position for cleaning, without having to touch the tool with the hands. The blender arm may further include a resilient element, functionally connected to the tubular body and the rotary shaft, for moving the rotary shaft between the protracted and retracted positions. When the rotary shaft is releases, the tool automatically returns to the retracted position.