JP2864259B2 - Ultrasound diagnostic equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention transmits an ultrasonic wave into a subject, receives a reflected echo from a diagnostic site, obtains an ultrasonic image from the echo signal, and obtains an electrocardiogram. The present invention relates to an ultrasonic diagnostic apparatus capable of synchronous display, and more particularly to an ultrasonic diagnostic apparatus capable of displaying an ultrasonic image of an arbitrary time phase by inputting a desired electrocardiographic time phase.

[Conventional technology]

As shown in FIG. 5, a conventional ultrasonic diagnostic apparatus of this type includes a probe 1 for transmitting and receiving an ultrasonic wave into a subject, a probe 1 for controlling the probe 1 to transmit an ultrasonic wave, and A transmission / reception controller 2 for amplifying an echo signal reflected and received from the inside of the sample, an A / D converter 3 for digitizing a reflected echo signal output from the transmission / reception controller 2, and an A / D converter 3
A display image memory 4 for temporarily storing image data from the display image for processing and display, and a D / A converter 5 for converting the image data read from the display image memory 4 into analog signals for display. A television monitor 6 for displaying an output signal from the D / A converter 5 as an ultrasonic image;
A plurality of storage image memories 7 for recording and reproducing image data from the A / D converter 3 as an ultrasonic image, and which image is to be reproduced from the plurality of storage image memories 7 is selected. An image selection unit 8, a reproduction operation input unit 9 for inputting instructions such as start, stop, and reproduction direction for reproduction of this image; a heart radio wave detection unit 11 for detecting a heart radio wave of the subject 10; An R-wave trigger detection unit 12 that detects a trigger of an R-wave time phase in the electrocardiographic waveform detected by the radio wave detection unit 11,
The R-wave trigger signal detected by the R-wave trigger detector 12 is
An R-wave trigger memory 13 for storing the binarized data, reading out the binarized data, and transmitting the time phase information to the image selecting section 8 is provided. In FIG. 5, reference numeral 14 denotes a data switch which controls the flow of image data when the image data from the A / D converter 3 is displayed without being recorded, or is recorded, reproduced and displayed. I have.

[Problems to be solved by the invention]

However, in such a conventional ultrasonic diagnostic apparatus,
The ECG synchronous display function for displaying an ultrasonic image of a certain phase synchronously with the ECG can only scan and display one image at the timing of the corresponding phase, and can update an old image that has been updated at any time. It could not be displayed again. Therefore, in order to display an ultrasonic image of a desired time phase, it is necessary to freeze when an image of a desired time phase appears. From this, the inspection has to be performed many times, and the inspection time is long. Also, during the ECG-gated display, even if the abnormal blood flow, which appears rarely, is observed for a moment and the image is frozen, the image immediately before or after the relevant image cannot be arbitrarily specified and observed. Diagnosis could not be made.

Accordingly, an object of the present invention is to provide an ultrasonic diagnostic apparatus that solves such a problem and enables an operator to input a desired electrocardiographic phase and display an ultrasonic image at an arbitrary phase. .

[Means for solving the problem]

In order to achieve the above object, an ultrasonic diagnostic apparatus according to the present invention includes means for controlling a probe to transmit and receive an ultrasonic wave into a subject, digitizing the received reflected echo signal, and processing the image data. Means for performing analog conversion of the image data and displaying the image data; recording means for recording and reproducing a plurality of image data obtained by digitizing the reflected echo signal as an ultrasonic image; Means for detecting and storing time-phase information of the R-wave time phase, and using the time-phase information, reproduces an ultrasonic image of a certain time phase from the recording means, and is capable of displaying an electrocardiographic synchronized display. In the diagnostic apparatus, a time phase input means for inputting an arbitrary electrocardiographic time phase with respect to the time phase information stored in the time phase information storage means, and the electrocardiographic time phase input by the time phase input means. The recorded ultrasound image It is provided with a a selection means for selecting from the stage.

(Operation)

The ultrasonic diagnostic apparatus thus configured inputs an arbitrary electrocardiographic phase with respect to the time phase information stored in the time phase information storage means by the time phase input means, and receives the input by the image selection means. An ultrasonic image corresponding to the electrocardiographic phase is selected from the recording means, and the image is reproduced and displayed on the display means. Thereby, it is possible to specify and display an ultrasonic image of a desired arbitrary time phase.

〔Example〕

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram showing an embodiment of an ultrasonic diagnostic apparatus according to the present invention. This ultrasonic diagnostic apparatus transmits an ultrasonic wave into a subject, receives a reflected echo signal from a diagnostic site, obtains an ultrasonic image based on the echo signal, and can perform electrocardiographically synchronized display. As shown in the figure, a probe 1, a transmission / reception control unit 2, an A / D converter 3, a display image memory 4, a D / A converter 5, a television monitor 6, and a storage image memory 7, image selection unit 8, reproduction operation input unit 9
, An E-wave trigger detecting unit 12, an R-wave trigger memory 13, and a time phase input unit 15 and a specific time phase image selecting unit 16.

The probe 1 transmits and receives ultrasonic waves to and from the subject 10, and has a built-in transducer that is a source of ultrasonic waves and receives a reflected wave and converts it into an electric signal. . The transmission / reception control unit 2 controls the probe 1 to transmit an ultrasonic wave and amplifies an echo signal reflected and received from the inside of the subject 10. And a receiving amplifier circuit and a control circuit for them. The A / D converter 3 digitizes the reflected echo signal output from the transmission / reception control unit 2. The display image memory 4 temporarily stores the image data from the A / D converter 3 for display.
Freezes (stops) the image or performs various image processing. The D / A converter 5 converts the image data read from the display image memory 4 into an analog signal for display. The television monitor 6 serves as a display unit for displaying an output signal from the D / A converter 5 as an ultrasonic image.

The storage image memory 7 serves as a recording means for recording and reproducing the image data from the A / D converter 3 as an ultrasonic image, and can continuously record a predetermined number of images or a predetermined number of images. Thus, for example, it comprises a plurality of memories. The image selection unit 8 selects which of the plurality of ultrasonic images recorded in the storage image memory 7 is to be reproduced, and corresponds to an image specified by a reproduction operation input unit 9 described later. You choose what you want to do.
The reproduction operation input section 9 is for instructing the image selection section 8 to reproduce a picture and for inputting instructions such as start, stop, and reproduction direction of the reproduction. Note that in FIG.
Reference numeral 14 denotes a data switch for controlling the flow of image data when the image data from the A / D converter 3 is displayed in real time without being recorded, or is recorded in the storage image memory 7 and reproduced and displayed. ing.

Further, the electrocardiogram detecting unit 11 detects an electrocardiographic waveform as shown in FIG. 2A using an electrocardiograph attached to the arm and the leg of the subject 10. The R-wave trigger detection unit 12
The time phase (generally referred to as “R-wave time phase”) at the start of cardiac contraction (this is shown as an R-wave in FIG. 2A) in the electrocardiographic waveform detected by the heart-wave detector 11 A trigger signal, that is, an R-wave trigger signal Rt shown in FIG. 2 (b) is detected. And the R-wave trigger memory 13
The value of the R-wave trigger signal Rt detected by the R-wave trigger detection unit 12 at the time of steep rising is “1”, and the other values are “0”.
, And serves as time-phase information storage means for reading out the binary data and sending it as time-phase information to the image selecting section 8.

Here, in the present invention, as shown in FIG.
A specific time phase image selection unit 16 is connected to the wave trigger memory 13, and a time phase input unit 15 is connected to the specific time phase image selection unit 16. The time phase input unit 15 serves as time phase input means for inputting an arbitrary electrocardiographic time phase with respect to the time phase information stored in the R-wave trigger memory 13 and has a numerical key, a dial switch, and the like. The operator can directly input an electrocardiographic time phase, which is particularly necessary information for observing a circulatory organ such as a heart, in addition to a reproducing function found in a general recording / reproducing apparatus. The specific time phase image selection unit 16 serves as an image selection means for selecting an ultrasonic image corresponding to the electrocardiographic time phase input from the time phase input unit 15 from the storage image memory 7. This allows the operator to enter the time phase input
A desired electrocardiographic phase can be directly designated by 15, and an ultrasonic image corresponding to the specific electrocardiographic phase can be immediately selected and displayed on the television monitor 6.

Next, an operation of displaying an ultrasonic image in a desired time phase in the ultrasonic diagnostic apparatus thus configured will be described with reference to FIG. 3 and FIG. Here, as shown in FIG. 3 (a), the image numbers i, i + 1, i + 2,..., I + n, i + n + 1,.
It is assumed that a plurality of ultrasonic images have been recorded in advance in this order. In addition, the R-wave trigger memory 13 contains the data shown in FIG.
As described in (c), binarized data is stored corresponding to the rising timing of the R-wave trigger signal Rt (see FIG. 3 (b)). Then, assuming that the number of images that can be stored in one heartbeat is n and the image number of the image in the oldest R-wave time phase is i, the image number of the image in the R-wave time phase after one heartbeat is i + n. . At this time, the delay time of each recorded image from the R-wave time phase corresponds to the image numbers i, i + 1, i + 2, ..., i + n-1, i + n, i + n + 1, ... shown in FIG. As shown in FIG. 3 (c), 0, t ₁ , t ₂ ,..., Tn _-l , 0, t ₁ ,.

In such a state, a procedure for selecting a specific time phase image when a delay time from the R wave time phase shown in FIG. 3C is used as a means for specifying an arbitrary time phase will be described. First, in the steps of FIG. 4, the operator operates the numeric keys, dial switches, and the like of the time phase input unit 15 shown in FIG. 1 to input a desired delay time x. Then, the input signal of the delay time x is transmitted to the specific time phase image selection unit 16 shown in FIG. At the next step, the delay time x is limited so as not to exceed the time tn _-l corresponding to one heartbeat. That is, when x is compared with tn- _l , if x is equal to or less than tn- _l, it is left as it is, and if x exceeds tn- _l , for example,
In the case of tn, when the remainder of dividing x by tn is “0”, x = 0. Furthermore, the number of the next step, a limited delay time x as described above, and time tn _-l corresponding to one heartbeat, the stored image in the one heartbeat (n-
From 1), the offset image number j indicating the number of the image corresponding to the delay time x from the R-wave phase image is calculated by the following equation.

Then, in the next step, the image number of the R-wave time phase is added to the offset image number j obtained as described above, and the image number of the specific time phase specified by inputting the desired delay time x is next calculated. Ask like.

i + j, i + n + j, i + n + 2j,... (2) The processing of the above steps,... is executed by the specific temporal phase image selecting unit 16 shown in FIG.

As described above, an image of a specific time phase corresponding to the desired delay time, that is, an arbitrary electrocardiographic phase input from the time phase input unit 15 is selected by the specific time phase image selection unit 16, and the selection signal Is sent to the storage image memory 7, the image corresponding to the image number is read out, and displayed on the television monitor 6. At this time, by performing operations such as frame advance and frame return by operation of the reproduction operation input unit 9,
It is also possible to easily reproduce and display images of adjacent time phases before and after the specific time phase specified by the operator. In the case where the recordable time of the storage image memory 7 is longer than one heartbeat, a plurality of images are obtained by the above equation (2). Select
What is necessary is just to display on the television monitor 6.

In addition, the image at the specific time phase can be specified by inputting an arbitrary time phase as a delay time (see FIG. 3 (c)) from the R wave time phase of the electrocardiographic waveform shown in FIG. 2 (a). Therefore, the input operation is the same as the ECG synchronous display function in the conventional device,
The operator can operate easily.

〔The invention's effect〕

Since the present invention is configured as described above, an arbitrary electrocardiographic time phase is input to the time phase information stored in the time phase information storage means (13) by the time phase input means (15), An ultrasonic image corresponding to the inputted electrocardiographic time phase is selected from the recording means (7) by the phase image selecting means (16), and the image can be reproduced and displayed on the display means (6). . Therefore, the operator can directly specify an image of a desired arbitrary time phase and immediately select and display an ultrasonic image of a specific time phase corresponding to the image. Therefore, instead of repeating the operation of adjusting the timing to the timing to be observed as in the past and freezing and inspecting the image, it is only necessary to perform a single inspection on the subject and collect and reproduce the image data. Is fine. Therefore, the examination time can be shortened, and the restraining time for the subject can be shortened. Also, even if an abnormal blood flow, which appears rarely, is momentarily observed during the ECG-gated display and the image is frozen, the image immediately before or immediately after the corresponding image is designated by the time phase input means (15). Can be selected and observed. Therefore, a detailed and sufficient diagnosis can be made.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of an ultrasonic diagnostic apparatus according to the present invention, FIG. 2 is a timing chart showing detection of an electrocardiographic waveform and an R-wave trigger signal, and FIG. 3 is recorded in a storage image memory. FIG. 4 is an explanatory diagram showing the relationship between the image number of the ultrasound image and the delay time from the R-wave time phase, FIG. 4 is a PAD diagram showing a procedure for inputting an arbitrary time phase and selecting an image of a specific time phase, FIG. 5 is a block diagram showing a conventional ultrasonic diagnostic apparatus. 1 ... probe, 2 ... transmission / reception control unit, 3 ... A / D converter, 4 ... image memory for display, 5 ... D / A converter, 6 ...
... TV monitor, 7 ... Image memory for storage, 8 ... Image selection unit, 9 ... Reproduction operation input unit, 10 ... Subject, 11 ...
Heart radio wave detection unit, 12 R wave trigger detection unit, 13 R wave trigger memory, 15 time phase input unit, 16 specific time phase image selection unit.

──────────────────────────────────────────────────続 き Continuing from the front page (72) Inventor Toshihiko Kono 2-1 Shinjuyo-ji, Kashiwa City, Chiba Prefecture Hitachi Medical Corporation Osaka Plant Kashiwa Branch Plant (56) References JP-A-62-183750 (JP, A) (58) Field surveyed (Int.Cl. ⁶ , DB name) A61B 8/00 G01N 29/06

Claims (1)

(57) [Claims] 1. A means for controlling a probe to transmit and receive an ultrasonic wave into a subject, a means for digitizing the received reflected echo signal and processing the image data, and a means for converting the image data into an analog signal. Display means for displaying, recording means for recording and reproducing a plurality of image data obtained by digitizing the reflected echo signal as an ultrasonic image, and detecting time-lapse information of the R-wave time phase by detecting a heart radio wave of the subject. Means for storing, in the ultrasonic diagnostic apparatus capable of reproducing an ultrasonic image of a certain time phase from the recording means using the time phase information and performing ECG synchronous display, the time phase information is stored in the time phase information storage means. Time phase input means for inputting an arbitrary electrocardiographic time phase with respect to the time phase information, and selecting means for selecting an ultrasonic image corresponding to the electrocardiographic time phase inputted by the time phase input means from the recording means It is characterized by having provided That the ultrasonic diagnostic apparatus.