JP2644996B2 - Nuclear medicine data processing equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Field of Industrial Application) The present invention relates to a nuclear medicine data processing apparatus for displaying an RI distribution image on a display based on nuclear medicine diagnostic data collected over time. .

(Prior Art) When collecting nuclear medicine diagnostic data (hereinafter simply referred to as data) of a subject with a scintillation camera, data collection for performing optimal positioning of the subject, so-called persistent collection, is performed in advance. For this purpose, data collected over time is sequentially stored in a collection memory and then displayed on a display (monitor) as an RI (radio isotope) distribution image. In this case, the data stored in the acquisition memory includes the number of γ-rays from the RI in the subject and the position information thereof, and the data amount (count number) sequentially increases.

By the way, since the amount of data stored in the acquisition memory increases with time, if this is displayed as it is on the display as an RI distribution image, the image at the beginning of data acquisition will be pale and the image at the end of data acquisition will be dark. Very difficult to observe. Therefore, in order to obtain an easily observable image, the gray level on the display must always be manually adjusted frequently.

In order to eliminate such a defect, a nuclear medicine data processing apparatus which automatically adjusts the gray level is disclosed in Japanese Patent Application Laid-Open No. 59-8867.
No. 5 proposes this. In this device, the highest level gradation data is detected in the pixels of the pixel data stored in the acquisition memory (display memory), and the predetermined gradation data (count) -shade (gray) as shown in FIG. among many level conversion table of levels, so as to display on the display is converted to the highest level gray level corresponding to this by selecting a specific level conversion table f (a ₁₎ corresponding to for example a ₁ ing.

(Problems to be Solved by the Invention) However, in the level conversion table used in such a conventional apparatus, the relationship between the gradation data and the gray level, that is, the count-gray relationship is a linear relationship. There is a problem that it is difficult to observe a part of the subject having a relatively low gray level. For example, in the case of an organ such as the liver where it is difficult for RI to collect in the peripheral part, the amount of data collected in this part is small, so that the gray level is low. On the other hand, the highest level is determined by the total amount of data sequentially stored in the acquisition memory, and thus is a considerably high value. Therefore, since the relative difference between the gray levels of the two is considerably large, the outline of the liver or the like is displayed faintly, making it difficult to observe.

The present invention has been made in view of the above-described problems, and has as its object to provide a nuclear medicine data processing apparatus capable of increasing the gray level even in a part having a relatively small data collection amount.

[Structure of the Invention] (Means for Solving the Problems) In order to achieve the above object, the present invention provides an acquisition memory for storing nuclear medicine diagnostic data acquired over time by a scintillation camera; Based on data
A nuclear medicine data processing apparatus having a display for displaying an RI distribution image, based on data of a desired area of the acquisition memory, calculating means for determining a parameter for gradation conversion, and the acquisition memory based on the parameter. Conversion means for performing tone conversion on the nuclear medicine diagnostic data output from the at least, and at least for the data in the low count area with a small data collection amount to increase the gray level at the time of display display. A nuclear medicine data processing device is provided.

(Function) Of the collected nuclear medicine diagnostic data, the data in the low count area is converted to increase the gray level for display display, and the RI distribution image is displayed on the display. However, the gray level is emphasized, and a display that is easy to see can be displayed.

(Embodiment) FIG. 1 is a block diagram showing an embodiment of a nuclear medicine data processing apparatus according to the present invention. Reference numeral 1 denotes a scintillation camera which emits radiation irradiated from the RI in the subject, for example, an analog signal including the position and number information of γ-rays, that is, pixel data represented by X and Y position signals and UNB (unblank) signals. Output to / D converter 2. The A / D converter 2 stores the pixel data in the collection memory 3 in real time by converting the analog signal into a digital signal. The pixel data collected in this way includes digital X and Y position data indicating the position of each pixel and the number of γ rays counted at the pixel, that is, digital gradation data. Numeral 4 is a level detecting means which is composed of a high-speed specialized array processor and reads out image data stored in the acquisition memory 3 for each pixel at predetermined time intervals, and reads out a desired area (region of interest) of these pixels, for example, the whole area or a part thereof. An average value (AVE) and a standard deviation value (SD) of the area are calculated, and the gradation data is output every predetermined frame time. Reference numeral 5 denotes an arithmetic means, which is composed of a dedicated array processor, and calculates and determines a parameter for displaying an RI distribution image at an optimum gray level on a display 7 based on the average value and the standard deviation value. For example, as shown in the count-gray conversion table in FIG. 2, a count-gray conversion function K such as described below, which raises (lifts) the gray level particularly in a low count area (corresponding to a part having a small data collection amount). To determine.

Where a is the maximum count and a = α · AVE + β · SD
(Α and β are coefficients).

b: Determined by the system with the maximum gray value.

c: coefficient x: count number 6 is a level conversion means consisting of a dedicated array processor, reads out image data for each frame from the acquisition memory 3 in pixel order, and converts the conversion function which is a parameter determined by the calculation means 5 K is input, and the gradation data of each pixel is converted into a gray level for displaying on the display 7. As a result, the RI distribution image of the desired part of the subject is displayed on the display 7, and the brightness of each pixel is displayed at the gray level converted by the level conversion unit 6.

 Next, the operation of the present embodiment will be described.

Pixel data is collected in real time from the scintillation camera 1 via the A / D converter 2 and stored in the collection memory 3. The pixel data is sequentially read out by the level calculation means 4, and the average value and standard deviation value of a desired area in the pixel are calculated and output to the calculation means 5 as gradation data. The calculating means 5 calculates the above-described count-Gray conversion function K as a parameter for converting the gradation data into a gray level based on the average value and the standard deviation value. In this conversion function K, the maximum count a of the gray (shade) level is calculated as follows: a = α · AVE + β · SD
As described above, the determination based on the average value AVE and the standard deviation value SD makes it possible to set the maximum count value lower than the value determined by the total sum of the data collection amounts as in the related art.

Further, as is clear from the above equation, the coefficient can be arbitrarily set by adjusting the coefficients a and b. The gray value corresponding to the maximum count number a becomes the maximum value of the gray level, and is set to a gradation level of, for example, 512, 256 or the like on the system.

The level conversion means 6 sequentially receives pixel data from the collection memory 3 and converts the gradation data in the pixel data according to the count-Gray conversion coefficient K input from the arithmetic unit 5 along the characteristic curve of FIG. Then, an RI distribution image is displayed on the display 7 in real time at an optimum gray level.

As is clear from FIG. 2, the count-gray relationship according to the present invention is not a linear relationship as in the prior art, but a relationship such that gray in a relatively low count region is enhanced. The maximum count a is set to be low in consideration of the average value and the standard deviation value. Therefore, for these reasons, the gray level can be emphasized (increased) in the peripheral part of the organ such as the liver where the data collection amount is small, and the outline thereof can be clearly displayed.

Therefore, the positioning of the subject is facilitated, and can be performed by automatic adjustment without manual adjustment.

[Effects of the Invention] As described above, according to the present invention, even in a region where the data collection amount is relatively small, the gray level is emphasized and displayed, so that the RI distribution image can be displayed in an easily viewable manner.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a nuclear medicine data processing apparatus according to an embodiment of the present invention, and FIG. 2 is a block diagram showing the principle of the present invention.
FIG. 3 is a characteristic diagram showing the principle of the conventional example. 3 ... collection memory, 4 ... level calculation means, 5 ... calculation means, 6 ... level conversion means.

Claims (1)

(57) [Claims] 1. A nuclear medicine data processing device comprising: a collection memory for storing nuclear medicine diagnostic data collected over time by a scintillation camera; and a display for displaying an RI distribution image based on the data in the collection memory. Calculating means for determining a parameter for gradation conversion based on data in a desired area of the collection memory; and performing gradation conversion on the nuclear medicine diagnostic data output from the collection memory based on the parameter. A nuclear medicine data processing apparatus, comprising: conversion means for performing gradation conversion for increasing data at least in a low-count area with a small amount of data collection.