IN THE DRAWINGS
FIG. 1 illustrates in block diagram form an ultrasonic diagnostic imaging system constructed in accordance with the principles of the present invention;
FIG. 2 illustrates a spectral Doppler display in which both the peak and mean velocity levels have been traced;
FIG. 3 illustrates a preferred technique for tracing the peak and mean velocity levels in a high line density spectral display;
FIGS. 4
a, 4b, and 4c illustrate a first embodiment of the present invention by which an automated spectral Doppler trace may be manually adjusted; and
FIGS. 5
a, 5b, 5c and 5d illustrate a second embodiment of the present invention by which key points in a spectral Doppler trace are identified and adjusted.
Referring first to FIG. 1, an ultrasound system constructed in accordance with the principles of the present invention is shown in block diagram form. Ultrasonic signals are transmitted by the array transducer 10 of an ultrasound probe and resultant echoes are received by transducer elements. The received echo signals are formed into a single signal or beam by a beamformer 14. The echo signal information is detected by a Doppler detector 16 which produces quadrature I and Q signal components. A number of such signal components from the site in the body being diagnosed are applied to a Doppler processor 18, one form of which is a fast Fourier transform (FFT) processor, which computes the Doppler frequency shift of the received signals. This basic Doppler data is post-processed by a Doppler post processor 20, which further refines the data by techniques such as wall filtering, gain control, or amplitude compression.
Intermittently during the reception of Doppler echoes, B mode echoes are received. These echoes are also formed into I and Q components which may then be amplitude detected by taking the square root of the sum of the squares of the I and Q values in a B mode image processor 64. The B mode image processor also arranges the B mode echoes into a desired display form by scan conversion. The resultant two dimensional image is coupled to a Doppler display processor 30 where it may be displayed in a time interleaved manner with the spectral Doppler data.
The post processed Doppler data is applied to a peak velocity detector 58 and the Doppler display processor 30. The Doppler display processor uses the Doppler data for the display of a real time sequence of spectral line information. The peak velocity detector compares the Doppler data against a noise threshold NOISEth to determine the peak velocity point of a spectral line, as discussed more fully in U.S. Pat. Nos. 5,287,753 and 5,634,465. The peak velocity detector 22 may also perform filtering of the Doppler data and may also be used to identify mean velocity levels as discussed more fully in the '753 patent. The Doppler display processor 30 then provides both an anatomical B mode image and a spectral Doppler display with peak and/or mean velocity values automatically traced as the discussed in the aforementioned patents.
The ultrasound display will also preferably show an ECG trace drawn in response to reception of an R-wave signal. The R-wave is the electrical physiological signal produced to stimulate the heart's contraction, and is conventionally detected by an electrocardiograph (ECG). FIG. 1 shows a set of ECG electrodes 80 which may be affixed to the chest of a patient to detect the R-wave signal. The signal is detected and processed by an ECG signal processor 82 and applied to the Doppler display processor 30, which displays the ECG waveform in synchronism with the scrolling spectral Doppler display. The B mode image can be used to locate and display the point in the patient's anatomy at which the spectral information is acquired.
A typical spectral Doppler display as produced by an embodiment of the present invention is shown in FIG. 2. Such a display generally comprises the Doppler information of discrete sampling periods displayed as a sequence of continuous scrolling spectral lines in a real time versus velocity display as shown in FIG. 2. In the display of FIG. 2, newly generated spectral lines are continually produced at the right side of the display. The sequence of lines moves or scrolls from right to left, with previously generated spectral data on the left and progressively more current data to the right. Each line conveys the range of flow velocities detected in the blood flow at a chosen location in the body at a particular time of Doppler interrogation. The highest velocities shown by lines 100, 200, and 300 would typically occur during the systolic phase of the heart cycle. The intervals 12, 22, and 32 between the systolic phases represent flow velocity during the intervening diastolic phases of heart action.
In accordance with the principles of the present invention, FIG. 2 illustrates a spectral line display in which the peak velocity of each spectral (vertical) line has been identified and the peaks connected by the solid display line 60. As FIG. 2 shows, the spectral line peak velocities can be identified and displayed as the spectral lines occur and are displayed, thereby providing a real time continuous display of traced peak spectral velocities. For each displayed spectral line which satisfies a noise immunity test a mean velocity value is also calculated and displayed. A variety of techniques are known for calculating mean velocity as discussed in the aforementioned '753 patent. The mean velocity is marked on the spectral line display, also concurrently with the initial appearance of the spectral line at the right-hand side of the spectral line display. FIG. 2 shows a dashed line 62 which connects the calculated mean velocity values of the displayed spectral lines.
The peak and mean velocity values may be traced with separately distinguished lines as shown in FIG. 2, or by differently colored lines. A preferred way to visually trace the peak and mean velocity values in a monochromatic high density spectral line display is shown in FIG. 3. In this FIGURE the spectral lines 70 are displayed in shades of gray against a white background 72. The peak velocity line 80 is displayed as a sequence of black dots, each marking the peak velocity on its associated spectral line. The mean velocity values are marked by blanking the mean velocity positions on the respective spectral lines, thereby effectively leaving a white line running through the spectral lines 70 as indicated at 82. This technique takes advantage of rapid, high density production and display of spectral lines, in which the spectral lines 70 are displayed virtually adjacent to each other, thereby resembling a continuous band of gray shading below the peak velocity line 80. The white mean velocity line 82 is thus distinctly displayed in contrast to the surrounding gray shading of the spectral lines. One skilled in the art will realize that the display of FIG. 3 is generally shown with black/white reversal in the typical ultrasound display.
In accordance with the principles of the present invention, an automated tracing on a spectral display can be adjusted by the user as illustrated by FIGS. 4a-4c. In this first embodiment the peak velocities of spectral lines 70 in FIG. 4a have been traced by the line 80, corresponding to the peak velocity display line 60 in FIG. 2. The real time spectral display can be stopped (frozen) on the display screen by actuation of the “freeze” button on the ultrasound system control panel 99. Alternatively, a previously recorded real time spectral display can be replayed and frozen on the screen. In either case, the ultrasound system will automatically delineate the extent of the spectral lines of one heart cycle by vertical lines 92, 94 known as “goalposts.” The goalpost lines may be placed by examining the spectral waveform or trace for the end diastole minima. Alternatively, the goalpost lines may be located by relating the ECG trace to the spectral display when an ECG trace is available. The ultrasound system will then use the information of this heart cycle for calculations and measurements. If the user does not want to accept this heart cycle or prefers another, he may click on another heart cycle in the spectral display to reposition the goalpost lines 92, 94, or drag the vertical goalpost lines with a screen cursor to frame a different heart cycle in the spectral display. The graphics on the lower left of the display show the numeric values of certain data points of the selected heart cycle and any calculations the user desires to see. In this example the graphics show the peak systolic velocity (PSV) value of −58.9 cm/sec, the end diastolic velocity (EDV) value of −12.9 cm/sec, and the resistivity index (RI) of 0.78.
However, suppose that the user feels that the trace 80 has been incorrectly drawn. The user may doubt the calculated RI value, for instance, which may lead to the belief that the trace 80 is not accurately drawn. In such case, the user clicks on the “Edit Trace” menu item, which may be shown on the image display screen or on a touchscreen panel of the ultrasound system, or may be a separate control on the control panel 99. This selection will cause a series of control points 82, 86 to appear on the trace 80 of the selected heart cycle, as shown in FIG. 4b. In this embodiment the control points comprise a series of small markers 82 and larger markers 82′, 82″, and 86. The larger markers in this embodiment are located at key timing points of the heart cycle. In this case the marker 82′ marks the peak systolic velocity point on the trace 80, the marker 82″ marks the end systolic velocity point on the trace, and the marker 86 marks the end diastolic point on the trace. Also appearing on the screen is a cursor 84 which may be manipulated by a user control on the control panel 99 such as a trackball or mouse.
In this example the user feels that the peak systolic velocity point is actually higher than depicted by the automatically drawn trace 80. The user will then “grab” the control point 82′ and “drag” it up to the desired velocity level as shown in FIG. 4c. As the control point 82′ is repositioned, the trace 80 and other control points 82 on the trace follow along with the repositioned control point 82′. This is done by recalculating the trace 80 on-the-fly by a spline interpolation technique, whereby the relocation of one point on the trace causes neighboring points on connecting spline curves to be automatically adjusted to provide a smooth trace. As the control points 82, 82′ and trace 80 are repositioned by the user, display values and calculations associated with the trace are also updated and recalculated on-the-fly. In this example it can be seen that the PSV value has been automatically updated to −89.8 cm/sec, the location of the repositioned control point 82′ in FIG. 4c, and the RI value has been affected by the adjustment and recalculated to 0.86. Thus, the user can visually see the adjustment he is making to the automatic trace 80 and can simultaneously see the effects of his adjustment on displayed and calculated values. These new display and calculated values can give the user confidence in the accuracy of his adjustments or lead to their further refinement by subsequent adjustment.
FIGS. 5
a-5d illustrate a second embodiment of the present invention. In FIG. 5a the lines 70 of a spectral display have their peak velocity values traced by a trace line 80 and a heart cycle is delineated by the goalpost lines 92, 94. The numeric display shows another key point in the spectral display, the mean diastole velocity (MDV). Three other calculations are also displayed, the pulsatility index (PI), the systolic/diastolic ratio (S/D), and the time-averaged peak velocity (TAPV).
In FIG. 5b the trace 80 has been supplemented with the addition of the display and identity of the key timing points of PSV, ESV, MDV, and EDV (end diastolic velocity). The key timing points to be displayed and identified can be chosen by the user and their location in time identified from the ECG waveform. The key timing points may also be calculated from the automatic tracing algorithm described in the aforementioned patents, which finds local maxima and minima as related to both the shape of the Doppler spectrum and the ECG waveform. The key timing points are displayed if the user chooses to show them (by turning them “on” via the control panel or user interface). The key timing points drive the results such as PSV, EDV and their derivative calculations. In this example it is seen that the PSV point is not located at the systolic peak of the tracing 80. In such case the user may reposition the point along the trace (i.e., in time) by grabbing the PSV point with the screen cursor and sliding the PSV marker to the systolic peak of the trace 80 as shown in FIG. 5c. The graphics are updated correspondingly. It can be seen that the PSV value has increased from −204 cm/sec to −272 cm/sec in this example, and that the dependent RI, PI and S/D calculations have changed also.
Alternatively or additionally, the user may feel that the trace 80 is incorrectly drawn. In such case the user may grab the trace 80 with a cursor 88 and drag the trace to the desired amplitude as shown in FIG. 5d. As in the previous example, the trace 80 is recalculated and display on-the-fly, giving the appearance that the user is stretching the trace line to its new location. Alternatively, the user may click at one point on the trace and redraw a portion of the trace manually with a screen pointer until reconnecting with the trace at another point on the trace. In this example the user has redrawn the spectral peak on either side of the cursor 88. The newly recalculated graphic values at the left of the display show that this repositioning of the peak velocity trace has affected three of the four displayed calculations. In this embodiment there are no discrete control points for the user to grab. Instead, each point on the trace 80 may be grabbed and repositioned by the user's cursor to adjust the position of the automated spectral trace. Following the adjustment of the trace 80, key points are automatically adjusted to their optimal locations based on the tracing algorithm. However, if the automatic placement of the key points is deemed unsatisfactory, the user may reposition the key timing points on the trace manually. For instance, the PSV may be repositioned to the new systolic peak of the trace 80 in FIG. 5d.
Patent Application
20080039725
