KR100963844B1 - An imaging procedure preventing field of view truncation for spect system - Google Patents

Abstract

The present invention provides a single-photon emission tomography apparatus for preventing effective field clipping, which can prevent the field of view from being cut and the signal quality can be improved by improving the signal-to-noise ratio. The photographing method is started. The imaging method is first: after the completion of the long-term position measuring step of obtaining the center point of the detector trajectory by grasping the center position of the organ to be photographed by the patient, and secondly, the detector rotates based on the center point of the rotation obtained in the measuring step. After acquiring the signal, the rotational trajectory determination step determines the minimum concentric circles that do not touch the patient's body as the detector rotational trajectory. Third, the tomography of the detector collects signals at each predetermined angle by rotating the rotational trajectory determined in the above-mentioned stage. Steps. The rotation range and signal collection of the detector during the tomography imaging step may be defined in any section in which the optimization of the image is guaranteed among the 0-360 degree intervals centering on the photographing organ.

The sensitivity and the resolution may be increased by close-up imaging of the organ to be photographed by selectively adding a vertical movement step between the rotation trajectory determination step and the tomography imaging step.

In the vertical movement step, the detector moves vertically from a given point on the rotational track toward the center of the organ to move the maximum distance that will not reach the patient's body, and then rotates the detector for imaging at the next angle after the tomography step is finished. In order to prevent the patient from touching the patient's body, it is divided into a return step that moves vertically toward the orbit.

Through this sequential series of steps, a compact detector provides rotational or vertical movement around the organ and provides an improved tomographic image of the patient without clipping the effective field.

Detector, nuclear medicine, field of view,

Description

AN IMAGING PROCEDURE PREVENTING FIELD OF VIEW TRUNCATION FOR SPECT SYSTEM}

The present technique relates to a method of photographing a single photon emission tomography for preventing effective field cutoff, wherein the center of rotation of the detector is shifted from the patient to the imaging organ in a conventional patient, and at the same time for the tomography of the detector. The present invention relates to a method of photographing a single-photon emission tomography camera which is designed so that its position is as close as possible to the photographing equipment to increase the sensitivity and resolution by using a relatively small detector and to prevent the truncation of the effective field that can be caused by the use of a small detector. .

Diagnostic imaging equipment used in nuclear medicine detects gamma rays generated from gamma sources administered to patients and implements them as images to provide early diagnosis of various diseases. It contributes greatly to the rapid development. These devices are largely divided into a gamma camera using a single photon and a positron emission tomography (PET) using two photons simultaneously. Among these, a single photon emission tomography which collects single photons from various angles of a patient and provides a tomography image. Disclosed is an improved photographing method for improving image quality of a single photon emission computerized tomography (SPECT).

Traditionally, single-photon emitters generally use a relatively large detector because they use a single piece of equipment universally, with no distinction between organs such as brain, heart, lungs, and whole body. FIG. 1 is a simplified diagram of a cross section of such a general purpose device, in which one or two detectors 3 are generally mounted on a gantry and are designed to perform tomography while rotating. Taking the most widely used image of the heart 1 as an example, unnecessary signals from not only the heart 1 but also other organs occupy a large portion in the effective field of the detector 3. In addition, since the center of rotation of the device is centered on the patient's body (2), there is a problem that the bulky detector has difficulty in approaching the patient's body, thereby degrading the quality of the image.

Recently, with the changing demands of various nuclear medicine markets, the production / sale of dedicated equipment for photographing only specific organs has been increasing, and the detector has also been miniaturized. However, the photographing method has become more efficient due to the use of conventional patient-oriented methods. Falling and cropping of the field of view (FOV) also limits the miniaturization of the detector.

The object of the present invention devised in view of the problems of the conventional patient-centered tomography as described above is to move the center of rotation of the detector to the organ rather than the patient in order to prevent the cutting of the effective field that may occur when using a small detector Disclosed is a photographing method of a single photon emission tomography camera which enables tomography.

In addition, another object of the present invention discloses various methods for calculating the rotational trajectory and the vertical movement distance of the detector to enable the proximity or optimal imaging of the detector with respect to the imaging organs in order to improve the sensitivity and resolution.

In order to achieve the object of the present invention as described above, the method of photographing a single-photon emission tomography for preventing effective field cropping is as follows. After completing the step, the second step: through the rotation trajectory determination step of determining the minimum concentric circles as the detector rotation trajectory, the detector rotates with respect to the center point of the rotation obtained in the measuring step and does not touch the patient's body when the signal is acquired, Thirdly, the detector comprises a tomography step of collecting a signal at each predetermined angle by rotating the rotation trajectory determined in the above step. The rotation range and signal collection of the detector during the tomography imaging step may be defined in any section in which the optimization of the image is guaranteed among the 0-360 degree intervals centering on the photographing organ.

During the photographing, a vertical shifting step may be added between the rotational trajectory determination step and the tomography imaging step to increase sensitivity and resolution by close-up photographing of the target organ.

In the vertical movement phase, the detector moves vertically from a given point on the rotational track toward the center of the organ to move the maximum distance not to reach the patient's body, and then rotates the detector for imaging at the next angle after the tomography stage is finished. It is divided into a return step that moves vertically to the orbit to prevent contact with the patient's body.

In this sequential series of steps, a compact detector provides rotational or vertical movement around the organ, providing a truncated, improved patient tomography image.

 The method for obtaining the rotational trajectory and the vertical movement distance of the detector which are the core of the present invention will be described in detail below.

In this way, the small detector moves along a rotational trajectory centering on the organ to be photographed and photographs the organ in close contact with the patient's body, eliminating unnecessary signals from other organs, and scattered gamma ray signals. Since the signal to noise ratio is increased by reducing the detection of, it is possible to obtain a good image with improved resolution and sensitivity.

In addition, as the rotational center of the detector moves to the long-term center, the image is possible with equipment equipped with a small effective field detector, which can be expected to have side effects such as cost reduction of equipment, restriction of installation space, and ease of adding mobile functions. have.

Hereinafter, with reference to the accompanying drawings, a method of photographing a single photon emission tomography apparatus for preventing effective field cropping, which is a preferred embodiment of the present invention, will be described in detail.

2 is a state diagram illustrating a method of photographing a single-photon emission tomography apparatus for preventing effective field cropping, which is a preferred embodiment of the present invention, and the height of the detector is reduced than it is to help understand the position and movement of each step of the detector; Schematic. As shown, a method of photographing a single-photon emission tomography apparatus for preventing effective field cropping, which is a preferred embodiment of the present invention, will be described with reference to one of the organs as an example.

The long-term position measuring step of finding the center point of the rotational track H of the detector 10 centered on the heart is completed by grasping the center position of the heart 1 which is one of the organs to be photographed and the appearance of the patient body 2. .

At this time, as the method of determining the center position of the heart, (A) calculate the distance between the long axis and the short axis by considering the cross-sectional shape of the patient's body as an ellipse, and then estimate the location of the heart based on statistical data, ( B) How to determine the position of the heart by performing a prescan from two angles, the front (or back) and the left side of the patient, before starting the imaging using a single-photon emission detector (SPECT) detector , (C) It can be performed by one or several combinations of the methods of determining the location of the heart based on the images of other imaging equipment such as x-ray (CT) or LRI (MRI).

In order to improve the sensitivity and resolution, the vertical movement step, which can be selectively performed between the long-term position measurement and the tomography stage, is a vertical trajectory (centered around the heart 1) with a detector located on the rotational trajectory (H). A vertical movement step is performed in which the detector 10 is brought into close contact with the patient's body 2 by moving vertically toward the heart 1 along I).

In this case, the method of obtaining the vertical movement distance as close as possible to the patient's body is as follows: (A) Pre-shooting using the actual detector is performed to calculate the rotational trajectory and the distance to the surface of the patient directly from each photographing angle and mount the position sensor. Method to define the vertical movement distance of the actual detector, (b) CT, MRI or optical scan to find the patient surface using the image, and then define the distance between the detector and its rotational movement distance There are ways to do it.

The vertical movement distance may be performed by one or several combinations of the above methods.

According to the method described above, if the distance from the center of the body 2 to the detector 10, that is, the vertical moving distance is determined according to the position of the detector 10, the detector 10 is drawn out to the position of the detector 10 to the patient's body. Make sure they are in close contact. When the detector 10 is in close contact with the body of the patient and the photographing position is determined, the photographing step of performing the photographing by operating the detector 10 is performed. When shooting is completed, the detector 10 is vertically moved along the vertical trajectory I so that the detector 10 can be moved to the next position without touching the body, and the detector 10 is rotated to the next position along the rotation trajectory H. The moving step is performed and the steps are sequentially performed to complete the imaging of the heart 1.

As described above, when the photographing is performed by using the photographing method of the single-photon emission tomography apparatus for preventing effective field cropping according to the present invention, since the detector is moved around the organ to be photographed, the compact detector having a small effective field of view 10 Even if you can shoot without cutting the image.

In addition, when the detector 10 moves vertically around the engine to be photographed to narrow the distance between the measuring equipment and the detector, the sensitivity and the resolution are improved.

Similarly, the photographing method of the single-photon emission tomography apparatus for preventing effective field cropping, which is a second preferred embodiment of the present invention, moves along a rotational trajectory centered on the engine without vertically moving the detector 10 as shown in FIG. 3. While taking a certain position of the heart (1) can also be used.

When the photographing is performed by using the photographing method of the single-photon emission tomography apparatus for preventing effective field cropping, which is the second preferred embodiment of the present invention, the detector 10 is moved around the organ to be photographed, which has a small effective field. Even with a small detector 10 it is possible to take a picture without cropping.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is a state diagram illustrating a simplified patient-centered imaging method of a conventional single-photon emission tomography apparatus for preventing effective field clipping;

Figure 2 is a state diagram showing an example in which the truncation phenomenon of the image disappears when photographing with a long-term center trajectory which is a preferred embodiment of the present invention by a small detector.

Figure 3 is a state diagram showing a photographing method of a single photon emission tomography for preventing effective field cut-out excluding the vertical movement step of a second preferred embodiment of the present invention.

** Description of the symbols for the main parts of the drawings **

1: heart 2: body

10: detector H: rotational trajectory

I: vertical trajectory

Claims (10)

delete After the patient's appearance and the central position of the organ to be photographed are identified, the organ position measuring step of finding the center point of the detector rotational trajectory centering on the organ is completed. After completing the rotation trajectory determination step of matching the center point of the rotational trajectory obtained in the measuring step with the center point of the photographing apparatus and defining the minimum concentric circle as the rotational trajectory of the detector that does not touch the patient's body when the detector rotates, A vertical movement step of vertically moving the detector to a predetermined position toward the center of the organ for close-up of the organ in each angle photographing so as to sequentially photograph the tomogram of the organ at each predetermined angle; A tomography step of photographing when the position of the detector closest to the organ is determined in the vertical movement step; And A return step of vertically moving the image to complete the movement with the rotation trajectory determined in the rotation trajectory determination step without contacting the body after the photographing is completed; The photographing method of the single-photon emission tomography for preventing effective field cutout, characterized in that by sequentially performing the detector to move along the rotation trajectory centered on the trachea. The long-term position measuring step of claim 2 A long-term position measuring step of calculating the length and length of the trunk by measuring the appearance of the patient as an ellipse and inferring the size and position of the heart based on statistics; A method of photographing a single photon emission tomography camera for preventing effective field cropping, characterized in that to obtain a center point of the detector rotational trajectory. The long-term position measuring step of claim 2 A long-term position measuring step of determining the position of the heart by performing a prescan at two angles orthogonal to the front side (or back side) and the left side of the patient before starting the imaging with the detector; A method of photographing a single photon emission tomography camera for preventing effective field cropping, characterized in that to obtain a center point of the detector rotational trajectory. According to claim 2, wherein the long-term position measuring step, A long-term position measuring step of obtaining an external shape of the body and a center point of the detector rotational trajectory by looking at an anatomical image of the patient, such as X-ray, Citi, and MR; A method of photographing a single photon emission tomography camera for preventing effective field cropping, characterized in that to obtain a center point of the detector rotational trajectory. The method of claim 2 wherein the vertical movement step An effective movement characterized by a vertical movement step that considers the patient's appearance as an ellipse and defines the distance between the patient's appearance (ie, ellipse) and the rotational trajectory obtained at the rotational trajectory step at each photographing angle as the vertical movement distance of the detector. Method of photographing single photon emission tomography for preventing field of view. The method according to claim 2, wherein a detector equipped with a position sensor that directly calculates the distance between the rotational trajectory and the patient's surface at each photographing angle by performing pre-photographing using the actual detector to obtain the vertical moving distance of the actual detector. Method for photographing a single photon emission tomography for preventing effective field clipping. The method of claim 2 wherein the vertical movement step According to the external trajectory of the patient inferred by using other imaging equipments such as M eye, Citi or optical imaging equipment, it is a vertical movement step of vertically moving toward the center of the organ so that the detector can reach the maximum without touching the patient's body. Method for photographing a single photon emission tomography for preventing effective field clipping. delete The method of claim 2, wherein the range of the tomography step and the collection of the signal can be defined in any section in which the optimization of the image is guaranteed in the 0-360 degree section using the center of the photographing organ as the rotation center. Method of photographing single photon emission tomography for preventing field of view.

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