Flashlight view of an anatomical structure

The invention claimed is: 1. A method for imaging an anatomical structure and displaying a flashlight view of the anatomical structure on a display, comprising: acquiring an initial spatial representation of the anatomical structure, wherein the initial spatial representation of the anatomical structure is a 3-D image of the anatomical structure, and displaying at least part of the 3-D image of the anatomical structure on a display; positioning an instrument in proximity to the anatomical structure by inserting the instrument through a vein or artery; determining a location of the instrument by measuring spatial and orientation coordinates of a tip of the instrument; generating: (i) a reconstruction region image, wherein the reconstruction region image corresponds to a portion of the 3-D image of the anatomical structure, wherein the reconstruction region image is a 2-D image representing a planar section of the anatomical structure, wherein the 2-D reconstruction region image is overlaid on the corresponding portion of the 3-D image of the anatomical structure on the display, and wherein the 3-D image of the anatomical structure and the reconstruction region image have the same scale and are different portions of a single composite image of at least part of said anatomical structure; and (ii) an icon of the tip of the instrument based on the spatial and orientation coordinates of the tip of the instrument, wherein the icon is displayed on the display within the reconstruction image and in a position corresponding to the current location of the tip of the instrument with respect to the anatomical structure; setting a size parameter of the reconstruction region via a graphic user interface (GUI) on the display, wherein the size of the reconstruction region image of the anatomical structure is from 10%-50% of the area of the 3-D image of the anatomical structure on the display; wherein one or more different display parameters are used to display the 3-D image of the anatomical structure and the reconstruction region image, and wherein the different display parameters are chosen from intensity, color, resolution, and transparency in order to visibly distinguish elements within the reconstruction region image from elements of the 3-D image of the anatomical structure which are outside of the reconstruction region image on the display; wherein the position of the reconstruction region on the display and with respect to the 3-D image of the anatomical structure is defined in relation to the position of the tip of the instrument, and wherein the reconstruction region is moved on the display and with respect to the 3-D image of the anatomical structure to follow movement of the tip of the instrument; wherein the step of setting the size parameter of the reconstruction region comprises: displaying a plurality of handles associated with the icon on the GUI, wherein each of the handles is a movable element on the GUI; an operator moving at least one of the handles on the GUI and thereby adjusting at least one of a shape and a size of the reconstruction region and thereby changing one or more boundaries of the reconstruction region; and after said adjustment, displaying the reconstruction region on the display according to said operator adjustment, and moving the reconstructions region on the display to follow movement of the tip of the instrument while the instrument is moved within the anatomical structure wherein the reconstruction region is delineated, including the boundaries of the reconstruction region, using the icon and arrows associated with the icon, together with a pointing device, wherein the ends of the arrows are the handles. 2. The method according to claim 1 , wherein the instrument comprises a catheter configured to generate an ultrasound beam, and wherein the reconstruction region is shaped and oriented in relation to a direction of the ultrasound beam. 3. The method according to claim 1 , wherein the reconstructions region is shaped as a spherical lune. 4. The method according to claim 1 , wherein the anatomical structure is a heart; the method further comprising capturing an electrocardiogram (ECG) signal, and based on the ECG signal, capturing successive images at a same time point with respect to periodic contraction of the heart. 5. The method of claim 1 , wherein the initial spatial representation comprises at least one of a Carto map, a Computed Tomographic (CT) image, and a magnetic resonance (MR) image. 6. The method of claim 1 , wherein the initial spatial representation providing the 3-D image of the anatomical structure comprises an ultrasound image, and wherein the 2-D reconstruction region image depicts a circular section of said ultrasound image; wherein the circular section of the ultrasound image is centered on the icon of the tip of the instrument. 7. The method of claim 1 , wherein the instrument comprises a catheter having a catheter tip; wherein the anatomical structure is a heart; wherein an operator inputs at least one of a shape and a size for the reconstruction region, and the reconstruction region is displayed on the display according to said at least one of shape and size; wherein said positioning of the instrument comprises moving the catheter in the heart; wherein the reconstruction region image is registered with the catheter tip, and moves on the display with the catheter tip. 8. A computer software product for imaging an anatomical structure and displaying a flashlight view of the anatomical structure on a display, comprising a tangible computer-readable medium in which computer instructions are stored, which instructions, when read by a computer operatively linked to an instrument positioned in proximity to an anatomical structure and to a display, cause the computer to perform the method according to claim 1 . 9. Apparatus for imaging an anatomical structure and displaying a flashlight view of the anatomical structure, comprising: a display having a graphic user interface (GUI); an instrument which is configured to be positioned in proximity to the anatomical structure, the instrument being inserted through a vein or artery; and a processor, which is configured to be coupled to the instrument, and which is arranged to acquire an initial spatial representation of the anatomical structure as a 3-D image of the anatomical structure, to determine a location of the instrument by measuring spatial and orientation coordinates of a tip of the instrument, to generate, in response to the spatial and orientation coordinates of the tip of the instrument: (i) a reconstruction region image, wherein the reconstruction region image corresponds to a portion of the 3-D image of the anatomical structure, wherein the reconstruction region is a 2-D image representing a planar section of the anatomical structure, wherein the reconstruction region image is overlaid on the corresponding portion of the 3-D image of the anatomical structure on the display, and wherein the 3-D image of the anatomical structure and the reconstruction region image have the same scale and are different portions of a single composite image of at least part of said anatomical structure; and (ii) an icon of the tip of the instrument based on the spatial and orientation coordinates of the tip of the instrument, wherein the icon is displayed on the display within the reconstruction image and in a position corresponding to the current location of the tip of the instrument with respect to the anatomical structure; wherein the reconstruction region image is 10%-50% of the area of the 3-D image of the anatomical structure on the display, wherein one or more image display parameters being used in the reconstruction