JP2007167116A - Ultrasonic diagnosis apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ultrasonic diagnosis apparatus capable of setting the optimum image parameter according to the characteristics of a patient without accumulating pattern data. <P>SOLUTION: In setting the image parameter according to a region to be diagnosed, a patient information obtaining part 19 obtains patient information including the weight and the body fat rate of each patient, and the optimum image parameter, correlated to each information on a number of patients, is registered in a database 20. A database collating part 21 retrieves the patient information on the database most similar to the obtained patient information. When an image parameter selecting part 22 selects the image parameter correlated to the retrieved patient information, an image parameter reading part 23 reads the selected image parameter. Then, an image parameter setting part 24 sets the read image parameter as the set value of the image parameter corresponding to the region to be diagnosed. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention uses an image parameter set in advance according to a diagnosis target part, transmits an ultrasonic wave to the diagnosis target part, and processes a signal obtained by receiving the echo, thereby obtaining a diagnosis target. The present invention relates to an ultrasonic diagnostic apparatus capable of displaying image data of a part.

  In this type of ultrasonic diagnostic apparatus, there are many image adjustment parameters for obtaining easy-to-diagnose image data for various diagnosis target parts (hereinafter also simply referred to as diagnostic parts), that is, image parameters, An examiner or an operator (hereinafter, also simply referred to as an examiner) adjusts image parameters by himself or calls preset image parameters.

  However, as the types of image parameters increase with recent advances in diagnostic technology and the advancement of the performance of ultrasonic diagnostic equipment, it has become difficult for the examiner to input all image parameters directly. Moreover, since the number of combinations has increased even in a method of presetting combinations of image parameters, selection by an examiner has become difficult. Therefore, it is determined which diagnostic part the image obtained by scanning in the past by the ultrasonic diagnostic apparatus is, and the image parameter of the ultrasonic diagnostic apparatus is automatically set to the optimum value using the determination result A parameter setting device is disclosed in Patent Document 1 below.

  As shown in the block diagram of FIG. 5, the ultrasonic diagnostic apparatus provided with the parameter setting apparatus disclosed in Patent Document 1 has an ultrasonic probe 91 connected to an ultrasonic diagnostic apparatus main body 98, and further includes an ultrasonic diagnostic apparatus. A monitor 95 and a scan parameter setting device 97 are connected to the main body 98. The ultrasonic diagnostic apparatus main body 98 includes a transmission / reception circuit 92, a detection circuit 93, a DSC (digital scan converter) 94, and a control unit 96. As shown in the block diagram of FIG. 6, the scan parameter setting device 97 includes an image data reading means 99, an image pattern extraction means 100, a pattern data storage means 101, a search means 102, a diagnostic part output means 103, and Scan data feedback means 104 is provided.

  After describing the general operation of the ultrasonic diagnostic apparatus configured as described above, the scan parameter setting apparatus 97 will be described. The ultrasonic probe 91 transmits an ultrasonic beam to a subject (not shown) and receives the echo. The transmission / reception circuit 92 transmits a drive signal for driving the ultrasonic probe 91 and receives an echo signal received by the ultrasonic probe 91. The detection circuit 93 detects the echo signal received by the transmission / reception circuit 92. The DSC 94 images the echo signal detected by the detection circuit 93 as an ultrasonic image, and the image data is displayed on the monitor 95. The control unit 96 controls the transmission / reception circuit 92, the detection circuit 93, and the DSC 94 in association with each other. As described above, ultrasound can be transmitted to a subject, image data of the subject can be generated based on the obtained echo signal, and the generated image data can be displayed to diagnose a patient.

Next, the scan parameter setting device 97 will be described. When the image data reading means 99 reads image data from the ultrasonic diagnostic apparatus main body 98, the image pattern extraction means 100 extracts an image pattern from the read image data. The pattern data storage unit 101 stores pattern data corresponding to a plurality of diagnosis parts, and the search unit 102 searches the pattern data storage unit 101 and is similar to the image pattern extracted by the image pattern extraction unit 100. Find the data. Therefore, the diagnostic part output means 103 outputs a diagnostic part corresponding to similar pattern data. The scan data feedback means 104 takes out the image parameter corresponding to the diagnostic part output from the diagnostic part output means 103 from the image parameter storage means (not shown) that stores the image parameters corresponding to a plurality of diagnostic parts, Feedback is made to the control unit 96 of the ultrasonic diagnostic apparatus main body 98. Thereby, the image parameter can be automatically set.
JP-A-4-224738 (paragraphs 0005 and 0006)

  However, when ultrasonically diagnosing a patient, there are various patterns depending on how the probe is applied to the living body. In order to accurately identify which part of the patient is being diagnosed by the scan parameter setting device 97 described above, there is a problem that a large amount of pattern data must be stored in the pattern data storage unit 101. In addition, despite the fact that patient pattern data changes variously depending on body weight, body fat percentage, age, physique, etc., since conventional image parameter setting devices determine image parameters only at the diagnostic site, There was also a problem that it was extremely difficult to set under optimum conditions.

  The present invention has been made to solve the above problems, and provides an ultrasonic diagnostic apparatus capable of setting optimal image parameters according to patient characteristics without accumulating pattern data. With the goal.

In order to achieve the above object, the present invention provides a signal obtained by transmitting an ultrasonic wave to the diagnosis target part and receiving an echo using the image parameter set in advance according to the diagnosis target part. In the ultrasonic diagnostic apparatus capable of displaying the image data of the diagnostic target part by processing
A patient information acquisition unit for acquiring patient information including body weight and body fat percentage for each patient by at least one of setting by a setting device and measurement by a measurement device;
A database in which the optimal image parameters are registered in association with a large number of past patient information;
A database collation unit that collates the patient information acquired by the patient information acquisition unit with a large number of the patient information on the database and searches for the patient information on the database that is closest to the acquired patient information; ,
An image parameter selection unit for selecting the image parameter associated with the patient information on the database searched by the database verification unit;
An image parameter reading unit for reading out the image parameter selected by the image parameter selection unit;
An image parameter setting unit that sets the image parameter read by the image parameter reading unit as a setting value of the image parameter that is set in advance according to the diagnosis target region;
It is characterized by having.
With this configuration, the registered image parameter is selected so as to be most closely associated with the measured patient information, and the image parameter is set as an image parameter for obtaining an image that is easy to diagnose. Can be set according to the patient's characteristics.

In addition, the present invention includes a diagnostic part recognition unit that recognizes a patient's physique and a diagnostic target part to be diagnosed by an examiner based on a probe through which ultrasonic waves are transmitted and video data of the diagnostic target part. Further, the physique and the site to be diagnosed are made part of the patient information.
With this configuration, the image parameter can be set without the examiner inputting the diagnosis target part as patient information.

Furthermore, the present invention includes a database updating unit that additionally registers the patient information and the image parameter associated therewith and updates the database.
With this configuration, it is possible to more accurately set different image parameters for each patient each time the number of diagnoses is increased.

  According to the present invention, the registered image parameter is most closely associated with the measured patient information, and the registered image parameter is set as an image parameter for obtaining an image that is easy to diagnose. There is provided an ultrasonic diagnostic apparatus capable of setting optimal image parameters according to patient characteristics without accumulating pattern data.

Hereinafter, the present invention will be described in detail based on preferred embodiments shown in the drawings.
<First Embodiment>
FIG. 1 is a block diagram showing a configuration of a first embodiment of an ultrasonic diagnostic apparatus according to the present invention. In FIG. 1, an ultrasonic probe 11 that transmits an ultrasonic beam to a diagnosis target part (not shown) of a subject and receives an echo thereof is connected to an ultrasonic diagnostic apparatus main body 18. A monitor 15 for displaying image data is further connected to the ultrasonic diagnostic apparatus body 18. The ultrasonic diagnostic apparatus main body 18 is configured to image a transmission / reception circuit 12 that transmits a drive signal to the ultrasonic probe 11 and receives an echo signal, a detection circuit 13 that detects the received echo signal, and an image of the detected echo signal. A DSC 14 for adding the image data to the monitor 15, a control unit 16, and an image parameter control unit 17.

  After describing the schematic operation of the first embodiment configured as described above, the details of the image parameter control unit 17 will be described. The ultrasonic probe 11 transmits an ultrasonic beam to a diagnosis target region of a subject (not shown) and receives the echo. The transmission / reception circuit 12 transmits a drive signal for driving the ultrasonic probe 11 and receives an echo signal received by the ultrasonic probe 11. The detection circuit 13 detects the echo signal received by the transmission / reception circuit 12. The DSC 14 images the echo signal detected by the detection circuit 13 as an ultrasonic image, and the image data is displayed on the monitor 15. The control unit 16 controls the transmission / reception circuit 12, the detection circuit 13, and the DSC 14. The image parameter control unit 17 controls the image parameters and transmits the image parameters to the control unit 16. As described above, ultrasonic waves are transmitted to the diagnosis target part of the subject, image data of the subject is generated based on the obtained echo signal, and the generated image data is displayed to diagnose the patient. be able to.

  FIG. 2 is a block diagram showing a detailed configuration of the image parameter control unit 17. The patient information acquisition unit 19 acquires patient information by using a setting or measurement device from an external setting device, and a lot of past patient information. The database 20 in which the optimum image parameters are registered in association with each other, the patient information measured by the patient information acquisition unit 19 and a large amount of patient information on the database are collated, and the most approximate to the measured patient information A database collation unit 21 for retrieving patient information on the database 20 to be performed, an image parameter selection unit 22 for selecting an image parameter associated with the patient information on the database 20 retrieved by the database collation unit 21, and the image Image parameter readout for reading out the image parameter selected by the parameter selection unit 22 23, and an image parameter setting unit 24 for setting image parameters read by the image parameter reading unit 23, the control unit 16 as an image parameter for obtaining diagnostic easy image.

  The operation of the image parameter control unit 17 configured as described above will be described below. Patient information includes body weight, body fat percentage, age, sex, physique, and site to be diagnosed. Of these, age, gender, physique, site to be diagnosed, etc. are initially set by the examiner, and weight and body fat. The rate is measured using a measuring device. The patient information acquisition unit 19 includes a setting device such as an operation panel for setting the age, sex, physique, diagnosis target site, and the like, and a measuring device for measuring weight, body fat percentage, and the like. As a measuring device to measure body weight and body fat percentage, install on the chair where the patient sits or the bed where the patient lies and measure the weight, and install on the chair or bed and have the patient hold it It can be composed of a metallic grip for examining body fat. Therefore, as patient information, a body weight of 60 kg, a body fat percentage of 20%, a 20-year-old male, muscularity, a carotid artery, and the like are input as a diagnosis target part. The database 20 includes a plurality of patient information for each of various patients who have been diagnosed in the past, and an optimal image parameter for the patient information (the examiner has the most easily diagnosed image when the patient is diagnosed). And the image parameters at the time of image acquisition recognized and registered in the database).

On the other hand, as image parameter items, an appropriate signal level range is selected from the received signal gain, the dynamic range of the received signal, the persistence representing the frame correlation, the transmission output, the contour enhancement, and the echo signal to make the image easy to see. Reject, oscillation frequency, scanning line density, pulse repetition frequency, gray map which is a function to arbitrarily set the halftone (tone) between white and black of the image, color map in color mode plant mode, electrocardiographic mode Alternatively, there is a sweep speed which is a time axis sweep speed in the Doppler mode. The database collation unit 21 collates the patient information acquired by the patient information acquisition unit 19 with a large number of patient information on the database, and searches for the patient information on the database 20 that is closest to the measured patient information. The image parameter selection unit 22 selects an image parameter associated with the patient information on the database 20 searched by the database collation unit 21. Therefore, the image parameter reading unit 23 reads the image parameter selected by the image parameter selection unit 22. The image parameter setting unit 24 sets and reflects the image parameter read by the image parameter reading unit 23 as an image parameter for obtaining an image easy to diagnose. In addition, the image data can be further improved by inputting from the operation panel an image parameter whose value has been fine-tuned by the examiner with reference to the set image parameter, and set as a new image parameter. May be.
In addition, the “optimal image parameter” is the most suitable for the information on the patient (the patient who is about to be diagnosed or the patient the examiner is paying attention to) among the plurality of past patient information in the database 20. It is an image parameter when acquiring the most easily diagnosed image when diagnosing a patient with approximate patient information, but if there are a lot of approximate patient information, the diagnosis target part when diagnosing those patients further Among the image parameter groups used to display the image data corresponding to the above, the statistically most frequently used parameter or the center value of the image parameter group may be used.

  As described above, according to the first embodiment of the present invention, by setting or measuring and inputting patient information including a diagnosis target part, it is associated with patient information that most closely approximates this patient information. Since the optimum image parameters are set, the optimum image data can be set corresponding to the diagnosis target part without accumulating the patient pattern data.

  In the first embodiment, weight, body fat percentage, age, gender, physique, diagnosis target part, etc. are used as patient information. However, only the weight and body fat percentage among these can be used as patient information. Compared with the case where the (examiner) sequentially sets, image parameters that can provide image data that are much easier to diagnose are set, and further, the more information that is used from among the age, sex, physique, diagnosis target part, etc. Appropriate image parameters are set.

<Second Embodiment>
FIG. 3 is a block diagram showing a detailed configuration of an image parameter control unit 17A that executes the function instead of the image parameter control unit 17 shown in FIG. 2 as a second embodiment of the ultrasonic diagnostic apparatus according to the present invention. FIG. The image parameter control unit 17A shown in FIG. 3 newly adds a diagnostic part recognition unit 25 that preferentially inputs a physique and a diagnosis target part to the components of the image parameter control unit 17 shown in FIG. The point I did is different.

  The diagnostic region recognition unit 25 has information on general body shape, layout information indicating the position of an anatomical internal organ, and external information of the probe, and further, image data obtained by capturing a patient in three dimensions. Acquired imaging device. This imaging apparatus can be configured by, for example, one camera installed on the ceiling on the bed on which the patient lies at the time of diagnosis and two cameras installed on the left and right of the bed, respectively. Then, the patient's physique is determined based on the video data of the three cameras, and the type, position and angle of the probe are recognized, and the diagnosis target part is specified by collating with the layout information indicating the position of the internal organs.

  The operation of the second embodiment configured as described above will be described below. The same elements as those of the image parameter control unit 17 shown in FIG. In particular, the following description will focus on the difference in configuration of the image parameter control unit 17A from the image parameter control unit 17 in particular. The diagnosis part recognition unit 25 determines the physique of the patient based on the video data of the three cameras, further recognizes the type of probe, its position and angle, and compares it with layout information indicating the position of the internal organs to be diagnosed Identify the site. The database verification unit 21 includes patient information obtained by combining the physique information and diagnosis target site information of the patient recognized by the diagnostic site recognition unit 25 with the body weight and body fat rate acquired by the patient information acquisition unit 19, and a large number on the database 20. The patient information on the database 20 that most closely matches the measured patient information is searched. The image parameter selection unit 22 selects an image parameter associated with the patient information on the database 20 searched by the database collation unit 21, and the image parameter reading unit 23 reads the image parameter selected by the image parameter selection unit 22. . The image parameter setting unit 24 sets the image parameter read by the image parameter reading unit 23 as an image parameter for obtaining an image easy to diagnose.

  In this manner, according to the second embodiment, the diagnostic site recognition unit 25 recognizes the site diagnosed by the examiner and the patient's physique, so that the examiner performs the diagnosis target site and physique at the beginning of the examination. Since the image parameters of the diagnosis target part can be set without inputting the image data, the examiner can obtain image data that makes it easy to diagnose various diagnosis target parts without setting many parameters for image adjustment by himself / herself. Obtainable.

<Third Embodiment>
FIG. 4 shows, as a third embodiment of the ultrasonic diagnostic apparatus according to the present invention, an image parameter that executes its function instead of the image parameter control unit 17A constituting the second embodiment shown in FIG. It is a block diagram which shows the detailed structure of the supervision part 17B. 4, the same parts as those in FIG. 3 are denoted by the same reference numerals, and the description thereof is omitted. The image parameter control unit 17B shown in FIG. 4 is different from the image parameter control unit 17A shown in FIG. 3 in that a database update unit 26 for updating patient information registered in the database 20 is added.

  The operation of the third embodiment configured as described above will be described below with a focus on portions that differ from the second embodiment in particular. The database update unit 26 can additionally register new patient information and image parameters corresponding to the patient information with respect to the patient information registered in the database 20 and the image parameters corresponding to the patient information. is there. In this case, each value such as body weight, body fat percentage, age, sex, physique, and part to be diagnosed is additionally registered in the database update unit 26 as patient information, and a new image is created by the examiner or operator corresponding to this patient information. When a parameter is set, this new image parameter is additionally registered. Thus, every time an image parameter corresponding to patient information is newly set, the image parameter used last time can be provided for the next selection.

  Thus, according to the third embodiment, every time an image parameter is newly set by the database updating unit 26, patient information and an optimal image parameter corresponding to this patient information are additionally registered. Therefore, the effect that it becomes possible to set more accurately the image parameter which changes with patients whenever the frequency | count of a diagnosis is increased is acquired.

  The present invention relates to a patient information acquisition unit that acquires patient information including body weight and body fat percentage for each patient, a database in which optimum image parameters are registered in association with a large number of patient information, and acquired patients A database collation unit that searches for patient information on a database that is closest to the information, an image parameter selection unit that selects image parameters associated with the patient information on the searched database, and an image that reads the selected image parameters Since it has a parameter reading unit and an image parameter setting unit that uses the read image parameter as the setting value of the image parameter according to the diagnosis target region, it can be used according to the characteristics of the patient without accumulating pattern data. Therefore, it is useful as an ultrasonic diagnostic apparatus capable of setting optimal image parameters.

The block diagram which shows the structure of 1st Embodiment of the ultrasound diagnosing device which concerns on this invention. The block diagram which shows the detailed structure of the image parameter control part which comprises the 1st Embodiment of this invention The block diagram which shows the detailed structure of the image parameter control part which comprises the 2nd Embodiment of this invention The block diagram which shows the detailed structure of the image parameter control part which comprises the 3rd Embodiment of this invention Block diagram showing the configuration of a conventional ultrasonic diagnostic apparatus Block diagram showing a detailed configuration of a scan parameter setting device of a conventional ultrasonic diagnostic apparatus

Explanation of symbols

11 Ultrasonic probe 12 Transmission / reception circuit 13 Detection circuit 14 DSC
DESCRIPTION OF SYMBOLS 15 Monitor 16 Control part 17, 17A, 17B Image parameter control part 18 Ultrasound diagnostic apparatus main body 19 Patient information acquisition part 20 Database 21 Database collation part 22 Image parameter selection part 23 Image parameter reading part 24 Image parameter setting part 25 Diagnosis site recognition Part 26 Database Update Department

Claims (3)

The image data of the diagnostic target part is processed by processing a signal obtained by transmitting an ultrasonic wave to the diagnostic target part and receiving an echo using an image parameter set in advance according to the diagnostic target part. In an ultrasonic diagnostic apparatus capable of displaying,
A patient information acquisition unit for acquiring patient information including body weight and body fat percentage for each patient by at least one of setting by a setting device and measurement by a measurement device;
A database in which the optimal image parameters are registered in association with a large number of past patient information;
A database collation unit that collates the patient information acquired by the patient information acquisition unit with a large number of the patient information on the database and searches for patient information on the database that is closest to the acquired patient information; ,
An image parameter selection unit for selecting the image parameter associated with the patient information on the database searched by the database verification unit;
An image parameter reading unit for reading out the image parameter selected by the image parameter selection unit;
An image parameter setting unit that sets the image parameter read by the image parameter reading unit as a setting value of the image parameter set in advance according to the diagnosis target region;
An ultrasonic diagnostic apparatus comprising:   A diagnostic part recognition unit for recognizing a physique of a patient and a diagnostic target part diagnosed by an examiner based on a probe to which an ultrasonic wave is transmitted and video data of the diagnostic target part, and the recognized physique and the diagnosis The ultrasonic diagnostic apparatus according to claim 1, wherein a target site is a part of the patient information. The ultrasonic diagnostic apparatus according to claim 1, further comprising a database update unit configured to additionally register the patient information and the image parameter associated with the patient information and update the database.