DE2151347C3 - Ultrasound imaging device - Google Patents

Description

The invention relates to an ultrasound imaging device with a ultrasound transceiver system for scanning an examination area, in particular in the interior. of a human or animal body, by means of ultrasonic waves and an image display device with a visual mark generator and a visual mark image builder connected to the ultrasonic transceiver system to build a visual mark image corresponding to the ultrasound scan in the examination area, with a Doppler device for formation on the ultrasonic receiver of the ultrasonic transceiver system of Doppler signals from the frequencies of the transmitted and received ultrasonic waves is switched on, which is connected to generate a Doppler signal visual mark image with the visual mark generator (ζ. B. electron beam scanning device) for its control in the sense of generating a visual mark whenever a Doppler signal occurs, according to main patent 20 39 453
In devices of the type mentioned above, care must be taken to ensure that Doppler signals, which originate, for example, from muscle movements or the like of the patient, cannot reach the image display device because these signals are superimposed as interference signals on the vascular image and thus this image

would falsify so. In the device according to the main patent filters are therefore connected downstream of the Doppler device, which determine the frequency spectrum of the occurring Doppler signals limit essentially to frequencies characteristic of the flowing medium.

However, tests in practice have shown that this type of interference signal elimination is not yet optimal is.

The object of the invention is to develop the above-mentioned device in such a way that, if necessary interference signals still largely in the range of the limited frequency spectrum of the Doppler signals have no influence on the image display.

The object is achieved according to the invention by means which detect the point in time at which the Medium flow velocity in the investigation area is at least approximately maximum and to this Time to generate a signal, which a gate circuit downstream of the coupler device briefly

10

15th

opens for Doppler signals

In the device according to the invention, only Doppler signals are displayed which occur during the period of maximum medium flow velocity in the examination area. All signals sooner or later ^occurring: nsbesondere also noise can be suppressed, since the likelihood of spurious signals occur during the period of the maximum of the flow rate is extremely low, therefore a device is provided which is optimally insensitive to glitches

In a first embodiment of the invention, means are provided which determine the time of occurrence the maximum of the medium flow velocity directly from the frequency of the Doppler device determine occurring Doppler signals. The means expediently consist of one on the Doppler device connected frequency monitoring element, which emits the opening signal for the gate circuit when the Doppler frequency exceeds a predetermined limit value

In a second exemplary embodiment of the invention, means are provided which determine the time of occurrence of the maximum of the medium flow rate only as a function of time on the occurrence Preferably Heart-synchronous signals picked up in the area of the investigation, e.g. R-wave of the Electrocardiogram, pulse, heart rate. Timers are expediently used as the means a predeterminable point in time after the occurrence of the heart-synchronous signal, which according to physiological Conditions corresponds to the expected time of occurrence of the maximum of the flow velocity, generate the opening signal for the gate circuit. The expected time of occurrence of the maximum the flow velocity is, for example, about 0.15 seconds behind, based on the electrocardiogram the appearance of an R wave. In the case of heart sounds, the delay time is only approx. 0.11 seconds. The mentioned Time values are empirical values and relate to average normal patients. At from Normal value deviating Wt. "..En in individual patients the setting of the time on the timers must of course be corrected. Corresponding Corrections must also be made if the heart-synchronous signals have decreased in parts of the body that are closer or farther from the heart than the investigation area (consideration the finite pulse wave velocity).

In a third embodiment of the invention, means can finally be used which the Time of occurrence of the maximum of the medium flow velocity as a function of time both from Occurrence of Doppler signals as well as the occurrence of heart-synchronous signals, preferably in the examination area Detected pulse; ignale, determine. A coincidence element should preferably be provided, which the opening impulse when a Doppler signal and the heart-synchronous signal are present at the same time generated for the gate circuit The coincidence element consists expediently of an AND element, which at the same time forms the gate circuit

Further advantages of the invention will become apparent with reference to the drawing, which shows an embodiment of the invention represents, explained in more detail below.

In FIG. 1 is an ultrasonic transceiver system 1 recorded, (Jessen transmitter is fed by a high-frequency pulse generator 2 and into the

40

45

65 Direction of the axis ζ of a spatial, right-angled coordinate system x, y, ζ emits an ultrasonic beam 3 of ultrasonic pulses.The ultrasonic system 1 is displaceable along the axis χ of the coordinate system such that the ultrasonic beam 3 is displaced parallel to itself. This shift causes the ultrasonic beam 3 to reach a body 4 lying in the beam path of the ultrasonic transmitter, e.g. B. the liver of a patient, with a blood vessel 5, in a cutting plane that lies in the χ, ζ plane of the coordinate system, scanned line by line x, z-plane parallel planes to be scanned one after the other in time.

When passing through the ultrasonic pulses of a line in the body 4 are in the different depths of the Body generates echo pulses which are detected on a Doppler device 6 as Doppler signals when they either from the flowing blood of the vascular system 5 (useful signals) or from otherwise moving parts of the Body 4 (Störsignsle) originate. For at least partial elimination of any Interfering signals, a filter 7 of adjustable bandwidth is connected downstream of the Doppler device 6. The filter 7 limits the frequency spectrum of the Doppler signals essentially to that which is characteristic of the flowing blood Frequencies and thus switches interfering signals outside the limited frequency spectrum Frequencies off. Interference signals that are within the limited frequency spectrum pass through however, the filter 7 is undisturbed.

For the purpose of eliminating such interference signals, the am Output of the filter 8 resulting limited Doppler signals (after normalization by a Schmitt trigger 8) a gate circuit 9 fed. This gate circuit is only at certain times for the (normalized) Doppler signals open when the blood flow velocity in the vascular system is 5 is maximum in each case. The opening time for the gate circuit 9 is a function of the Occurrence of the R-wave in the area of the Body 4 taken electrocardiogram through the end of a monosubile flip-flop 10 with the occurrence of the R-wave generated voltage pulse of a given duration (approx. 0.15 seconds). With the end of this voltage pulse, another monostable trigger stage 11 is triggered, which the Gate circuit 9 is about 0.7 to 0.1 seconds long Supply voltage pulse which represents the opening pulse for the gate circuit 9. The EKG becomes the Tilting stage 10 is added via a & cmme 12. Those with 13 14 and 14 represent the setting elements for the individual pulse durations of the flip-flops 10 and 14, respectively. lidar.

According to the embodiment according to FIG. 1, therefore, the gate 9 is in each case about 0.15 see after the occurrence of an R-wave for about 0.7 to 0.1 see open the occurring in this time interval (maximum blood flow in the vascular system de ^r 5) Doppler signals are the Wehnelt Cylinder 15 is fed to an oscilloscope tube 16 as light pulse pulses

To build up images on the oscilloscope screen according to the ultrasound scan of the body A total of three deflection generators 18, 19 and 20 are provided for the electron beam of the tube 16. Of the Deflection generator 18 generates one of the different

Exercise of the ultrasound system 1 in the y-direction is proportional Deflection voltage, the deflection generator 19 one of the displacement of the ultrasonic beam in the x-direction proportional deflection voltage and the generator 20 a triggered by the high-frequency pulse generator 2, sawtooth voltage increasing proportionally to the propagation speed of the ultrasound in the body 4. If only the representation of the vascular system in a sectional plane of the body 4 is desired, then it must by closing the switches 21 and 22 (to be operated by switch button 23) the generator 19 to the vertical Deflection plate pair 24 and the sawtooth generator 20 to the horizontal deflection plate pair 25 of the tube 16 be switched on. If a total image is desired, the normally open contact switches 26 and 27 (to * actuate the generator 18 on the pair of vertical deflection plates 24 and the generator 19 by pressing button 28) connected to the pair of horizontal baffles 25

According to FIG. 2, the in F i g. 1 gate circuit complex shown in dashed lines by an AND element 29 must be replaced. The AND gate 29 are connected to a first input 30 directly on the Output of the Schmitt trigger 8 occurring Doppler signals as well as a second input 31 directly Blood pulse signals taken from the body 4 are supplied. The AND element 29 generates only then Output signals at its output 32 when a pulse signal is present at input 31 and at the same time Input 30 Doppler signals occur. Since the time of occurrence of pulse signals at input 31 of the AND element 23 in time with the maximum of the flow velocity of the blood in the vascular system 5 coincides, so there are 29 light pulse pulses for the tube 16 at the output 32 of the AND element, which are only equivalent to Doppler signals from this blood speed range.

The point in time of the maximum blood flow rate can also be derived directly from the occurring Doppler signals are derived themselves. For this purpose, according to Figure 2, only between the Input terminals 30 (connection directly to the output of the filter 7) and 31 a frequency monitoring element 33 (e.g. frequency meter with downstream frequency limit indicator) are switched on, which at the input 31 of the AND gate 29 emits a voltage pulse when the frequency of the Doppler signals exceeds a predetermined limit value

The parallel scanning described in the exemplary embodiment (so-called. Parallel scan) of the body 4 can of course also by other types of scanning, eg. B. ciu .- "h the so-called divergent scan, convergent scan or a mixed scan. As a result, more favorable angles of incidence of the Ultrasonic pulses can be achieved in individual vascular arms of the vascular system 5, which also increases the image reproduction the entire vascular system is improved.

1 sheet of drawings

Claims (11)

Patent claims: ■ 1. Ultrasound imaging device with an ultrasound transceiver system for scanning an examination area, in particular inside a human or animal body, by means of Ultrasonic waves and an image display device with a visual mark generator and an am Ultrasonic transceiver system switched on Visual mark image building device for building up a visual mark image in accordance with the ultrasonic scanning in the study area, with the ultrasound receiver of the ultrasound transceiver system a Doppler device for the formation of Doppler signals from the frequencies of the transmitted and received ultrasonic waves is turned on, which is used to generate a Doppler signal visual mark image with the visual mark generator (ζ. B. electron beam scanning device) its control in the sense of generating a visual mark whenever a Doppler signal occurs is connected, according to main patent 20 39 453, characterized by means (10, 11 or 33 or 29), which record the point in time at which the medium flow velocity in the investigation area (4) is at least approximately maximum and at this point in time generate a signal which a gate circuit (9) connected downstream of the Doppler device (6) briefly opens for Doppler signals 2. Apparatus according to claim 1, characterized by means (33) which indicate the time of occurrence of the Maximum of the medium flow velocity directly from the frequency of the Doppler device (6) determine occurring Doppler signals. 3. Apparatus according to claim 1, characterized by means (10, 11), which the time of occurrence of the Maximum of the medium flow rate only as a function of time on occurrence Heart-synchronous signals picked up preferably in the area of the examination area (4), e.g. Determine the R wave of the electrocardiogram, pulse, heart rate. 4. Apparatus according to claim 1, characterized by means (29) which indicate the time of occurrence of the Maximum of the medium flow rate as a function of time both on the occurrence of Doppler signals as well as the occurrence of cardiac synchronous signals, preferably in the examination area (4) detected pulse signals. 5. Apparatus according to claim 2, characterized in that the means (33) on the Doppler device (6) connected frequency monitoring element is used, which the opening signal for the Gate circuit (ζ. B. in training 29) emits when the Doppler frequency is a predetermined Exceeds limit. 6. Apparatus according to claim 3, characterized in that timing elements are used as means (10, 11) are that at a specifiable point in time after the occurrence of the heart-synchronous signal, which according to physiological conditions, the expected time of occurrence of the maximum flow velocity corresponds to generate the opening signal for the gate circuit (9). 7. Apparatus according to claim 6, characterized in that the time of generation of the opening signal by the end of one of a monostable Tilting stage (lö) mii ueiii Aüufeten of the heart synchro- NEN signal generated voltage pulse is fixed. 8. Apparatus according to claim 7, characterized in that the opening signal by the one another monostable flip-flop (11) generated with the end of the pulse of the first flip-flop (10) Voltage pulse is formed 9. Apparatus according to claim 8, characterized in that the duration of the voltage pulse opening time of the gate circuit (9) 10. Apparatus according to claim 4, characterized in that a coincidence element is used as the means (29) is used, which is when a Doppler signal and the cardiac synchronous Signal generates the opening pulse for the gate circuit 11. Apparatus according to claim 10, characterized in that the coincidence element (29) is an AND element is used, which at the same time forms the gate circuit