Abstract: A defibrillator includes a module having a portion of the high-voltage components of the defibrillator attached to a substrate and encased in a dielectric material. In one embodiment the defibrillating shock is delivered by a high voltage H-bridge circuit which utilizes four controllably switched semiconductor devices such as IGBTs.

Abstract: Apodization control techniques for a microbeamformer including a plurality of microbeamformer channels each including a transducer, a microbeamformer transmitter for driving the transducer, a microbeamformer receiver for receiving signals from the transducer and usually a delay element for delaying the received transducer signals. To improve the generation of waveforms by the transducers, the voltage provided to the microbeamformer transmitters is adjusted and/or the current provided by the microbeamformer transmitters is adjusted. The microbeamformer channels can also be grouped together into patches and/or clusters with the patches and clusters being provided with a common voltage source or current.

Abstract: A third matching layer (140) affording wide bandwidth for an ultrasound matrix probe is made of polyethylene, and may extend downwardly to surround the array (S360) and attach to the housing to seal the array (S370).

Abstract: A physiological parameter analysis system (10) detects ECG electrode wire misplacement. The system (10) includes a transformation component (32) that transforms original ECG information and combinations thereof from a first ECG lead system to a second ECG lead system and an inverse transformation component (34) that derives ECG information in the first ECG lead system from the transformed ECG information and the combinations thereof. The system (10) further includes an analysis component (38) that determines a correct ECG lead configuration in the first ECG lead system from among the original ECG information and the combinations thereof based on the derived ECG information.

Abstract: A defibrillator for providing both defibrillating energy and pacing energy to a patient is described. In delivering the defibrillating energy, electrical energy is stored by a charge capacitor and the stored energy is then coupled to the patient to provide a defibrillating pulse. To deliver pacing energy to a patient, an electrical energy circuit generates electrical energy that is filtered by the charge capacitor and delivered to the patient as pacing energy. The magnitude of the pacing energy delivered to the patient is monitored by a controller, which adjusts the generation of the electrical energy based on the magnitude of the pacing energy in order to provide adequate pacing energy to the patient.

Abstract: A modular automated external defibrillator (AED) system includes a base unit and at least one interconnected module. The base unit typically includes a functional circuit and includes an interface that couples the functional circuit to the module. Likewise, the module includes an interface that couples the module to the base unit By manufacturing such modular AED models instead of one-piece, i.e., integrated, AED models, a manufacturer can reduce the cost and complexity of its manufacturing process. Furthermore, the manufacturer may be able to bring such a modular AED to market more quickly than it could bring an integrated model of the AED to market. Moreover, a modular AED allows the manufacturer and customer flexibility in respectively providing and selecting feature sets. In addition, a customer can obtain replacements for broken modules, and the manufacturer can provide cheaper upgrades by upgrading a module or base unit instead of upgrading the entire AED.

Abstract: The present invention provides a self-storing medical electrode (10) that does not require packaging, enclosures, or other means to house and to protect various electrode components. According to one aspect, the invention provides an electrode comprising an electrode body having first and second sides, wherein the first side comprises a barrier layer (15) comprising a heat-sealable material and the second side comprises a conductive layer (16). The electrode further comprises an electrically conductive gel layer (18) disposed on the electrode body and which is further in electrical communication with the conductive layer (16).

Abstract: A curved two-dimensional array transducer includes a layer of piezoelectric material overlaying a layer of ASICs which is attached to a backing wing. The piezoelectric material is diced in orthogonal azimuth and elevation directions to form a two-dimensional array of transducer elements, with the dicing cuts in the elevation direction extending through the ASIC layer so that the piezoelectric layer and the ASIC layer can be bent in the azimuth direction. The backing wing provides a flexible substrate which can be bent while supporting the ASIC layer and piezoelectric elements. In a second example the piezoelectric layer and ASIC layer are attached to opposite sides of flex circuit which provides the flexible substrate after the piezoelectric layer and ASIC layer are diced.

Abstract: An ultrasonic diagnostic imaging system and method are described by which a user can delineate a region of interest (122, 128) in a colorflow Doppler image. The ultrasound system processes the Doppler pixel information of the region of interest (122, 128) to produce a spectrogram illustrating motion at the region of interest (122, 128) as a function of time. In a preferred embodiment the Doppler pixel information is processed by histograms to produce the spectrogram data.

Abstract: A three dimensional ultrasonic diagnostic imaging system is operated to guide or observe the operation of an invasive medical device (30) in three dimensions. An interventional system (20) is used to operate the invasive medical device (30) and produces spatially-based information relating to the activity of the invasive medical device (30). The spatially-based information from the interventional system (20) is merged into the three dimensional ultrasonic image data to produce a live three dimensional image of the invasive medical device (30) or its activity. In one embodiment the locations where the activity of the invasive medical device (30) is performed is recorded and displayed in the three dimensional ultrasonic image. The three dimensional ultrasonic image may be shown as an anatomical volume rendered image or as a wire frame model (130) of the anatomy. In another embodiment an integrated three dimensional ultrasonic imaging and invasive device system is described.

Abstract: An ultrasound transducer includes one or more microbeamformer integrated circuit chips, an array of acoustic elements, and a redistribution interconnect coupled via conductive elements between the one or more integrated circuit chips and the array of acoustic elements. The one or more microbeamformer integrated circuit chips each include a plurality of bond pads separated from adjacent ones thereof by a first pitch set. The acoustic elements of the array are separated from adjacent ones thereof by a second pitch set, the second pitch set being different from the first pitch set. In addition, the redistribution interconnect couples on a first side of the redistribution interconnect to the one or more microbeamformer integrated circuit chips via conductive elements. The redistribution interconnect couples on a second side to the array of transducer elements via conductive elements.

Abstract: Quantified measures of a volumetric object in the body can be made ultrasonically by acquiring concurrent biplane images of two different image planes of the object. Corresponding borders of the volumetric object are traced using automatic border detection. The border tracings are used in their planar spatial relationship to compute a graphical model of the volumetric object. The volume of the graphical model may be computed by the rule of disks, and a graphical or numerical display of the changing volume with time displayed. A user interface comprises both real time biplane images, the real time graphical model, and the quantified measures.

Abstract: A defibrillator, equipped with a battery power source, is described which is arranged to operate in any one of both a first mode and a second mode, the battery power source comprising at least two voltage sources. The voltage sources are arranged to be connected in parallel to each other when the defibrillator is operating in a first mode, and in series with each other when the defibrillator is operating in a second mode. The invention can be implemented by a battery pack for a defibrillator. This arrangement allows both voltage sources to be drawn down at the same rate which lengthens the overall life of the batteries. A more efficient use of battery power is thereby obtained. The invention ultimately extends the projected life of the batteries and when applied to an automatic external defibrillator increases the shelf life of the defibrillator.

Abstract: An ultrasound imaging system transmits a broad beam of ultrasound into tissues that are perfused with blood containing microbubbles. The ultrasound has an intensity that is sufficient to destroy the microbubbles in the tissues. A plurality of ultrasound imaging beams are then transmitted into the tissues over a sufficient period to allow the tissues to re-perfuse, and reflections from the transmitted imaging beams are processed to provide a perfusion image. The transmitted microbubble-destroying ultrasound may be in the form of a single beam or a plurality of beams that insonify a substantially larger area than the area insonified by the transmitted imaging beams. As a result, the microbubbles are all destroyed at substantially the same time, and the imaging ultrasound is transmitted only into regions of the tissues from which ultrasound reflections will be received.

Abstract: A method and apparatus for training a user to operate an external defibrillator, usable in a therapy or training mode, which includes an energy source; an electrode interface responsive to an electrode arrangeable on a release liner and configured for placement on a subject; and an energy delivery system operable to selectively deliver electrical energy from the energy source to the electrode via the electrode interface. The method includes: when the electrode is coupled to the electrode interface, receiving an input signal from the electrode, prior to placement of the electrode on the subject; based on the input signal, identifying a degree of electrical connectivity along an electrical path including the electrode; based on the determined degree of electrical conductivity, advancing the external defibrillator from a first training state to a second training state; and issuing a training state notification indicating advancement from the first training state to the second training state.

Abstract: A single-handle cordless internal defibrillator includes a pair of paddles, and a pair of electrodes that are respectively connected to a first-end portion of the pair of paddles. The pair of paddles has a second-end portion in communication with a single-handle, with a least one paddle of the pair of paddles being pivotable about a pivot arranged between the one paddle and the single-handle. A regulator arm in communication with the pivot adjusts the pivot of at least one paddle about the pivot so that the distance between the electrodes is variable by moving the regulator arm, and defibrillator circuitry is arranged within the single-handle. A dual-handle structure also provides tangle-free and clutter-free applications as the defibrillator circuitry is self-contained in the handle/handles or paddles of the defibrillator, eliminating the need for long cables which obstruct and can contaminate an operating room.

Abstract: An automatic external defibrillator electrode package includes a coded conductive label that uniquely identifies the type of automatic electrode contained therein. Pins on the defibrillator body make electrical contact with the conductive label when the package is attached to the defibrillator. These pins sense the shape of the conductive label to ascertain the electrode type, thereby enabling the AED to automatically set the proper operating mode.

Abstract: A multilingual defibrillator is capable of concurrently providing audible prompts for the operation of the defibrillator in multiple languages. The defibrillator includes a memory for storing data files representative of audible prompts in a plurality of languages. A controller is coupled to the memory and configured to select data files of audible prompts in first and second languages and generate first electrical signals and second electrical signals representative of the audible prompts in the first and second languages, respectively. First and second audible sound generators are coupled to the controller to receive respective electrical signals and configured to generate audible output in response to the respective electrical signals.

Abstract: An ultrasonic diagnostic imaging system is described in which two planes of a volumetric region which are in different elevation planes are scanned in real time. In one embodiment the two planes are scanned with less than the maximum number of scanlines which the transducer can transmit in a single plane. A user control enables the two planes to be moved laterally without moving the transducer probe. In another embodiment each image plane contains a color box depicting flow or motion in the same respective position in the image. The color boxes of the two images can be sized and positioned in tandem so that both are in the same corresponding area of the two images.

Abstract: A myocardial contrast echo exam is performed by the use of a two dimensional array transducer probe. The probe is held against a selected acoustic window of the body and first and second image planes through the heart are imaged and the plane orientations stored. Settings to optimize the images may also be stored for the two plane orientations. A contrast agent is infused and the resting heart scanned through the acoustic window. Upon actuation of a user control the ultrasound system automatically acquires images of the selected image planes through the acoustic window. Stress is applied to the heart to increase the heart rate and automatic acquisition sequence is repeated to acquire the images with the heart under stress. The at-rest and stress images may be compared to analyze the reperfusion of the myocardium of the heart.