Abstract: An annuloplasty ring comprising an elongated curved member defining a ring-shape having an at rest size and shape to fit against the annulus of the mitral valve in a heart, the member having a substantial saddle shape wherein the annular height to width ratio is in the range of 5% to 50%.

Abstract: An ultrasonic imaging system and method are described for quantification and display of myocardial wall thickening. The endocardial and epicardial borders in an image sequence are defined over a heart cycle and changes in the distance between the borders are tracked at specified locations around the myocardium over the heart cycle, The changes in distance are presented to the user in a graphical format, preferably together with another measure of the cardiac cycle such as chamber volume variation, ejection fraction, or the ECG waveform. The changes in the distance of chord lengths across the myocardium provide a direct indication of wall thickness variation at the specified locations. Preferably the tracking of the specified locations over the heart cycle is done by speckle tracking. The inventive technique can also represent strain at the specified locations of the myocardium.

Abstract: Ultrasound image processing system including a processor (16) for receiving a sequence of ultrasound image frames each including an object with a border and causing the ultrasound image frames to be displayed, and a user input device (20) for designating variable local regions of the displayed ultrasound image frames. A border detection algorithm (22) detects the border of the object in the ultrasound image frames and a target additive gain (TAG) tool (24) selectively adjusts pixel intensity in at least one local region of the ultrasound image frames with an unclear or non-existent border segment in order to make the pixel intensity more uniform. A more uniform pixel intensity improves the discerning of the border of the object via the border detection algorithm (22). Once the border of the object is sufficiently discernible, the object can be reviewed or quantified. If the object is the heart, the LV volume can be determined.

Abstract: An annuloplasty ring comprising an elongated curved member defining a ring-shape having an at rest size and shape to fit against the annulus of the mitral valve in a heart, the member having a substantial saddle shape wherein the annular height to width ratio is in the range of 5% to 50%.

Abstract: A trigger generator for supplying a trigger signal to a medical device. The generator includes a respiratory signal device associated with the subject that generates a respiratory signal representing the flow of gas into and out of the subject's lungs during the subject's breathing cycle. A trigger generator integrates the respiratory signal and generates a trigger signal when the integrated respiratory signal has a value representing a selected point in the subject's breathing cycle.

Abstract: A system and method of ultrasound quantification acquires acoustic image data from anatomic locations distributed in more than 2 dimensions, and uses a segmentation algorithm to provide real-time volume measurements. A 2D array is used to acquire two orthogonal (bi-plane) 2D images simultaneously. The images are segmented individually to determine the volume borders using any number of acoustic algorithms. The borders from the two bi-plane images are mathematically combined to give a volume measurement. A control processor controls the system to thereby obtain instant feedback of the segmented image data and enhance the volume measurements of the image. The system and method is extended to a number of simultaneous 2D images and to a full 3D volume acquisition.

Abstract: A system and method for identifying and selecting a volume of interest within a volume rendered image is disclosed. In one embodiment, the invention collects acoustic data, develops a three dimensional (3D) ultrasound image from the collected acoustic data, renders the ultrasound image on a display, modifies selected portions of the acoustic data, and displays the modified acoustic data in the form of a highlighted region on the rendered ultrasound image, wherein the highlighted region defines an included volume.

Abstract: A system and method of ultrasound quantification acquires acoustic image data from anatomic locations distributed in more than 2 dimensions, and uses a segmentation algorithm to provide real-time volume measurements. A 2D array is used to acquire two orthogonal (bi-plane) 2D images simultaneously. The images are segmented individually to determine the volume borders using any number of acoustic algorithms. The borders from the two bi-plane images are mathematically combined to give a volume measurement. A control processor controls the system to thereby obtain instant feedback of the segmented image data and enhance the volume measurements of the image. The system and method is extended to a number of simultaneous 2D images and to a full 3D volume acquisition.