DE4012760A1 - Ultrasonic Doppler method for gallstone lithography - uses analysis of Doppler frequency shift to detect velocity and calculating size of tracked particles - Google Patents

Abstract

The ultrasonic doppler device allows the size of the stone particles to be determined by measuring their sinking rate, using ultrasonic waves of given frequency. The frequency shift exhibited by the reflected waves is evaluated to calculate the particle velocity. The particle dia. is calculated from the particle velocity. Pref. the doppler signal is fed to a filter for analysis within a number of different frequency intervals, respective counters recording the number of particles of each size, with summation before supplying to a display. ADVANTAGE - Accurate evaluation of stone particles during lithotripsy.

Description

The invention relates to a method for indirect Determination of the size of gallstone particles by Measuring their sink rate during the litho tripsie using ultrasound as well as a device to carry out the procedure.

In lithotripsy produce repeatedly applied Shock waves in the body stones briefly high pressure tensions, through the respective outer layers of the  Body stones are blasted off (chipping effect). On this way the stones can be crushed successively will. This creates numerous organs Debris of various sizes. For a stone For example, debris is up to two thousand bumps wave impulses necessary, which are at a distance of about one Second (ECG triggered).

This process is assisted by the doctor for two reasons an ultrasound or X-ray imaging process observed: On the one hand, it must be guaranteed that the - usually the largest - stone in focus the shock shaft equipment, that is, precise aiming must be guaranteed. On the other hand, the success of the Treatment controlled and the time of its termination be determined. Too long a treatment would be too lead to unnecessary tissue stress and a too short, increases the risk of blockage of the bile ducts and make further treatment necessary.

The control of the stone mining is at the beginning of a loading plot still relatively easy because it is initially are clearly recognizable objects. The most common through the diameter of the same is about 18 mm. With smaller ob However, size determination is becoming increasingly difficult riger. At the end of treatment, however, should be ensured be that only particles with a size of one up to two millimeters in the organ volume, which e.g. B. can be dissipated naturally (Ab fraction criterion).  

In known imaging methods for more precise assessment of the size of small objects, it is disadvantageous that
first, that particles that are piled up on the organ floor are no longer easily recognizable as individuals in the picture because their contours are difficult to assign. For example, a large structured stone often cannot be distinguished from a collection of small stones;
secondly, that one to two millimeter large objects for all imaging processes used in this context with their dimensions are close to the resolution limit of the imaging method, that is, due to the principle blurring of the point image, are difficult to avoid;
third, that relatively high demands must be placed on the imaging quality of the imaging device, which makes the acquisition and maintenance correspondingly expensive;
fourth, that settings of the imaging device, for example the focus of the ultrasound scanner, often have to be checked and / or corrected;
fifthly, that the time of whirling up of the stones after an impact is too short and their speeds are too high to be able to recognize small particles in size sufficiently well during movement in the image;
sixthly, that the attending physician's attention and experience must meet certain requirements.

The object of the present invention is that mentioned above ten disadvantages of a direct, in today's practice largely subjective assessment of particle size bypass from the ultrasound or x-ray image the doctor to monitor success and determine the optimal time for an end of treatment ease.

The object is achieved in that the particle sizes from that with an ultrasound double the sink rate measured with which the stones or stone debris after the Swirling up by the shock wave impulse in the organ liquid falling to the ground.

As you can see, the stones or breakage pieces at the impact either directly, or at Steinan accumulations more or less indirectly, that is, through Secondary impacts, thrown into the organ volume. Typical is a whirling up of practically all particles, whereby a part in motion up to a maximum of about 0.5 seconds remains. Here, the percentage of particles that flies high or long enough for the invention Ultrasound measurement can be used.

In test trials, the falling speeds were measured with long, d. H. very narrow band sound impulses in time  distance of about 0.2 msec (so-called pulsed stere Doppler). The use of continuous sound is also possible (continuous Doppler).

Because the movement impulses mainly from the particles can go out and not from the organ fluid, one can approximately consider the liquid to be dormant.

Then in the last phase of the movement there is the particles fall down due to the hydrody Named ratios for which the viscosity of the gal fluid, the density of the body and the Reynold ′ important number, a simple function correlation between the diameter d and the Velocity V the body, which is used here.

For particle diameters, empirically this results in 1-10 mm

d = const. V²

With

const. = 3.54 · 10 ^-3 sec ^² cm ^-1 (CGS)

A stone size measuring device according to the invention summarizes because of the not very high yield of soaring Particles the results, for example, of each last hundred shots in a size distribution together and presents them as a histogram. The immit However, measurable measurement can also be carried out by an acoustic Signal are displayed.

For measuring the speed of moving particles is the known ultrasonic Doppler method  in principle particularly suitable, (once because of the pre parts of a frequency measurement and the other because un desired location information (e.g. echoes of unmoved Object structures) relatively easily by filtering under can be pressed, which results in a favorable signal / interference Ratio leads). Conventional, e.g. B. medical Doppler devices or Doppler-capable ultrasound scanners are however to follow from for the present measurement task cannot be used for reasons or only to a limited extent,

• - firstly because if they are for penetration depths of a few centimeters are designed to achieve a high lateral spatial resolution in the vessel Representation with narrow directional lobes or focused work. Since only particles are recorded here, which are recorded in the correspondingly small Ob volume, such as the scan level of a Doppler capable B-image scanner, move is the measurement loot low;
• - secondly, the relatively short duration of the mes send event and the unpredictable place that this with a Doppler-capable B-picture Scanner no longer or not captured precisely enough is, because for the Doppler measurement each Volu menstruation in the entire field of vision several times be groped;
• - furthermore the signal evaluation and the result representation with conventional Doppler devices of Solution of this task not adapted.

The imaging control used in lithotripsy device can be used for speed measurement after the Doppler Principle to be used if it is a Doppler capable ultrasound device, in which the internal Control of the array elements briefly modified can be. A scanner is used in this context referred to as "Doppler capable" if the Doppler measurement be carried out with the same oscillator arrangement with which the B-picture is also taken.

The following should always measure in the vertical direction will. Otherwise, only components of the sinkge speed recorded (which takes into account the calculation can be).

Details of the invention are given below an embodiment in connection with the described drawings.

From the drawings shows:

Figure 1a is a schematic representation of the process with a doppler enabled B-mode scanner as a basic unit.

FIG. 1b and probe according to the invention ausgebil detes sound field at a doppler capable linear array scanner with modified control element;

FIG. 1c example of a doppler capable linear array scanner with sound optically modified probe;

Fig. 2 and 3 functionally operating independently of an imaging ultrasonic scanner Doppler systems with single resonators for the transmitting and receiving operation.

The basic circuit diagram shown in FIG. 1a contains a known Doppler-capable B-image scanner as the basic device, which is combined with an evaluation unit 1-5 for evaluating the Doppler frequency signal.

The evaluation unit consists of an N-channel frequency filter, at the outputs of which there are event counters 2 for the particles. The counting rate can either be stored in a histogram memory 3 and displayed optically with the device 4 or acoustically with the device 5 . For further implementation of the measuring method according to the invention, the basic device is, for. B. selected and modified as follows:

Fig. 1b shows the inventive sound field in a linear array scanner in the event that no change to the probe 1 is made. The element control of the probe 1 is - with a brief shutdown of the normal imaging mode - for the Doppler transmission process so modified that all elements of the array - or a larger group in the middle - are controlled so that a wide, z. B. creates plane wavefront 2 , which runs through the part of the object 3 located in the scan plane. The "wave fronts", shown in simplified form as lines, each replace sequences of wave trains that are dependent on the pulse length.

For the reception of the echo wave 8 an element group 5 z. B. turned on in the middle of the array, which is small enough to achieve low directional selectivity in the X direction. The measurement yield is less than 100 percent in this embodiment. For a curved linear array, the geometry of the wave field results from the curvature of the array bar.

The signal processing takes place initially by means of electronic measures known per se, such as admixing of the quartz-controlled reference frequency etc. by the device. To determine the speeds with the inventive evaluation unit in Fig. 1a, it is useful if the analysis of the low-frequency Dopp lersignal to a small number of fixed frequencies, for. B. ten, so that the evaluation unit as a z. B. can describe ten-channel frequency filter 1 , which is switched to an event counter 2 for the particles. The count rates can be stored in a histogram memory 3 and displayed by a display unit 4 . The selected frequency ranges are selected so that the stone size is shown in the histogram on the functional relationship between stone size and sinking speed. An acoustic signal generator 5 shows the immediately measured result, and the display range can be selected (e.g. only particles with α <2 mm).

The evaluation unit shown in Fig. 1a ( 1 to 5 ) is also used in all the following embodiments ver.

Fig. 1c shows an embodiment in which a Doppler-capable linear array scanner is also used for the stone size determination. Here, the maximum possible measurement yield is achieved by a sound-optical change in the array probe. According to the invention, who at two points in the array of the probe 1 , preferably at the edges, at the expense of the B-image face two small, z. B. square groups of ele elements reserved exclusively for the stone size determination.

The group 2 provided for the transmission process receives a spherical diverging lens 3 as an attachment, which is dimensioned such that the transmission sound bundle 3.1 becomes sufficiently wide and covers the entire object 5 .

The group is controlled in phases so that the Sound beam is aligned to the center of the object.

The group 6 provided for reception receives a spherical converging lens 7 as an attachment, which maps the object center to the transducer level. The aperture of this lens has to be optimized. The elements of the reception group are z. B. switched so that the receiving lobe is aligned with the center of the object.

If there is sufficient echo intensity, one can forego the focus when receiving and realize a receiver by attaching a pinhole directly in front of the receiving element group 6 , which has a low directional selectivity due to its small (effective) dimensions.

A further possibility in the case of sufficient echo intensity is to reserve a very small group of elements in the middle of the transmission group 2 (provided with the diverging lens) exclusively for the reception process. According to the invention, a strip diaphragm interrupted in the middle is attached above this very small group of elements, so that only the middle part is exposed to the sound and in this way an approximately square receiver is realized, which due to its small dimensions has a reception lobe sufficiently wide in both lateral directions points. The transmission function is only slightly disturbed by the lack of some elements.

The apertures can of course be omitted if the Doppler Receiving elements from the outset from the probe manufacturer correctly dimensioned for the present method that are.

In the case of a curved linear array, the geometry of the arrangement is obtained by curvature of the array bar from FIG. 1c.

In FIGS. 2 and 3 devices are shown as exporting approximately examples, which are functionally independent from an imaging ultrasound scanner and hold mono transducer for the transmission and reception ent. The maximum measurement yield is also achieved here.

The transducer 1 in Fig. 2 consists of a convexly curved, relatively large single transducer 2 , which generates a divergent sound beam 3 the size of the object 4 , and the receiving transducer 5 located in a central bore, which is wide due to its small dimensions Indicative function. The Doppler electronics generates electronic methods known per se, the low-frequency Doppler signal (A-scan Doppler), which is fed to the evaluation unit 6 , which corresponds to the evaluation unit in Fig. 1a.

The measurement yield is also advantageous Embodiments not shown here, in which the transmit probes contain mono transducers that the diver Gentle sound bundle due to the curvature of the surface the small transducer dimensions, or with the help of a Generate attachment lens, and where the functional separately used reception probes with mono transducers are small dimensions or sound lenses with collecting effect included as a resolution.

Fig. 3 shows transmit and receive transducers of the speed measuring device as units which are functionally independent of a B-image scanner. However, they are structurally integral components of the linear array probe of the imaging control device. The maximum measurement yield is achieved here. The field of view of the B-image display is fully preserved.

The transmission element 2 is formed as a bar interrupted in the middle of a maximum of the length of the array, attached to the side of the linear array of the probe 1 and generates a cylinder shaft 3 aligned with the object 4 . The Z. B. square receiving element 5 , which can be provided with a converging lens, not shown here, is located in the gap between the segments 2 .

In the case of a curved linear array, which is not shown here, the configuration of the additional oscillator is analogously obtained by the corresponding curvature of the array bar of the arrangement in FIG. 3. In this case, the transmitting element is curved in an arc and the Transmit wavefront is a torus section. The differences in the geometry of the transmission wave field are irrelevant for determining the stone size.

Claims (23)

1. A method for determining the size of stone particles in the body fluid of an organ, characterized in that
that the particles which are whirled up in the liquid during the lithotripsy as a result of the individual shock wave impulses are acted upon in the sinking phase by ultrasound with a sufficiently narrow frequency bandwidth,
that the frequency shift of the reflected ultrasound resulting from the stone movement due to the Doppler effect is measured,
that the particle velocity is calculated from the frequency shift and the angle between the sound direction and the vertical, if this deviates from 0 or 180 degrees, and
that from the particle speed of the particle diameter is calculated, which is proportional to the square of the speed under the vorlie conditions. 2. The method according to claim 1, characterized in that that the Doppler signal through a frequency filter is analyzed with N frequency intervals that the Particles of different sizes assigned by N.  Event counters counted and totaled in N memories whose content is displayed. 3. The method according to claim 1 and / or 2, characterized ge indicates that the measurement result as a histogram the particle diameter of the last n Shots, with z. B. n = 100, continuously together is captured and presented. 4. The method according to claim 1, 2 or 3, characterized ge indicates that the result of the current on cell measurement using z. B. in millimeters adjustable limits for the desired display range of particle diameter by a sig nalton is displayed. 5. The method according to at least one of the preceding claims, characterized in that a measuring unit with the known electronic basic function of an ultrasonic Doppler system, a pulse or continuous Doppler, an evaluation unit ( 1-5 ) is connected downstream, the consists of an N-channel frequency filter ( 1 ), an event counter ( 2 ) and a histogram memory ( 3 ), both with N channels or memory locations, a display unit ( 4 ) for the graphical display of the histogram, e.g. B. a screen, a light emitting diode field or a plasma display, and the acoustic signal generator ( 5 ) for the display of the currently measured particle diameter. 6. The device according to at least one of claims 1 to 5, characterized in that the evaluation unit ( 1-5 ) with a Doppler-capable linear array scanner, for. B. a scanner used in lithotripsy as a control device is combined, the element control can be modified briefly such that when sending a device in X-Rich wide, z. B. flat wave ( 2 ) is generated, which sweeps the entire part of the object ( 3 ) lying in the scan plane. 7. The device according to claim 6, characterized in that the linear array probe, for example, a control scanner used in lithotripsy while maintaining the element arrangement has an attachment of lenses ( 3 , 7 ) for the shaping of the transmitting and receiving lobes. 8. The device according to claim 6, characterized in net that by switching on a small Ele mentgruppe z. B. in the middle of the array at Em pfang a receiver is realized based on the small dimension in the X direction is insensitive. 9. Apparatus according to claim 6 and 7, characterized in that at the edge of the linear array ( 1 ) a first element group ( 2 ) with a spherical Zer scattering lens ( 3 ) is combined as a transmitter such that one in X and Y -Direction diverging wave ( 4 ) for sonication of the entire object ( 5 ) is generated and that a second group of elements ( 6 ) on z. B. other edge of the linear array is provided as a receiver. 10. The device according to claim 6, 7 and 10, characterized in that instead of the spherical Zer scattering lens, a cylindrical lens is provided with the refractive power in the Y direction, while the beam deflection in the X direction electronically by appropriate phase-shifted control of the array elements ( 2 ) is done. 11. The device according to claim 6 and 7, 10 or 11, characterized in that the receiving group ( 6 ) with a spherical or a cylindrical collecting lens ( 7 ), the latter is combined with refractive action in the Y direction, the lenses being the object center map onto the array surface and have an optimized aperture. 12. The apparatus according to claim 6 to 12, characterized records that a very small group of elements with a perforated or interrupted slit diaphragm is seen so that a receiving element is created that because of its small effective dimensions a slight sense of direction in the X and Y directions possesses. 13. The device according to at least one of claims 6 to 13, characterized in that a because of Insensitivity to direction sufficiently small,  round or square receiver with the array bar of the probe is arranged. 14. The apparatus according to claim 5, characterized in net that radio from the imaging ultrasound scanner tionally separate transmit and receive transducers are seen. 15. The apparatus according to claim 5, 14, characterized records that provided as a transmitter mono vibrator are used to create a divergent sound bundle are convexly curved. 16. The apparatus according to claim 5, 14, characterized records that to create a divergent Sound beam when sending a lens in front of the Transducer is attached. 17. The apparatus according to claim 5, 14, characterized records that to create a divergent Sound beam when sending the transducers accordingly small dimensions. 18. The apparatus according to claim 5, 14-17, characterized records that when operating with functionally separate mono transducers of the receiving transducers as a result optimization of directional sensitivity is relatively small. 19. The apparatus of claim 5, 14-18, characterized records that when operating with functionally separate ten mono transducers mechanically into one are summarized as a probe.   20. The apparatus of claim 5, 14 to at least 18, characterized in that the transmitter oscillator is designed as a relatively wide ring that the encloses smaller reception transducer. 21. The apparatus according to claim 5, 14-20, characterized records that the transducer is from a litho tripsie control scanner functionally independent Speed measuring device with the probe of the Control device is connected or with this one forms a mechanical unit. 22. The apparatus of claim 5, 14 to at least 21, characterized in that the transmitting and receiving oscillators of the measuring device in the form of a bar interrupted in the middle ( 2 ) next to the linear array of the probe ( 1 ) are attached, the Receiving element ( 5 ) is located in the gap. 23. The device according to claim 5, 14-22, characterized records that transmit and receive transducers of Measuring device for a curved linear array probe in the form of a bow interrupted in the middle shaped bar next to the array the receiving element being in the gap finds.