FR2631810A1 - Method for numerical calibration of a radiology installation, and numerical calibration installation for implementing the method - Google Patents

Abstract

Radiology installation, more especially intended for angiography or angioplasty procedures, comprising a table 1 of at least substantially horizontal general position, on which may rest the body of a patient to be examined, which table is carried by table support means 2 which can be moved and locked using table drive means which incorporate locking, and means for controlling the position of the table; an arch 3, in particular isocentric, supporting at its two ends means 4 for emitting a beam of X-rays and means 5 for receiving the said beam, which are carried by arch support means 6 which can be moved and locked using arch drive means which incorporate locking, and means for controlling the position of the arch; means 7 for storing, processing, visually displaying images, which means are associated with reception means, in particular means for reception by numerical analysis, by virtue of a computer 8; and a computer, associated with the means for controlling the position of the table and of the arch, characterised in that it also comprises calibration means intended to know the magnification and distortion coefficients of the installation, as well as the scale of the images obtained for the relative positions of the table and the emission and reception means, and in that it makes it possible to know, at any moment, the parameters defining the relative positions of the table 1, the emission means 4 and the reception means 5.

Description

METHOD FOR THE DIGITAL CALIBRATION OF A RADIOLOGY FACILITY
AND INSTALLATION OF CALIBRATION NIMERIOUE FOR THE IMPLEMENTATION
OF THE PROCESS
The invention relates to a method for digital calibration of a radiology installation, more specifically intended for angiography and angioplasty procedures, and to the installation for implementing this method.

A radiology installation is already known comprising a general position table at least substantially horizontal adjustable and lockable, on which the body of a patient to be examined can rest ~ an arch, in particular isocentric, supporting at its two ends emission means an X-ray beam (at the lower end below the table) and means for receiving said beam (at the upper end above the table and known to those skilled in the art under the name of 'amplifier) also adjustable and lockable; storage means, processing ~ visualization of the images associated with the reception means, in particular by digital analysis of the images produced, thanks in particular to a computer. Support means for the table and the roll bar are movable and lockable using means drive and control means.

With such a known installation, it is possible to place the body of a patient to be examined on the table and adjust the position of the table and / or the hoop for a certain relative position corresponding to certain spacings and certain angles of incidence and this, according to the needs imposed by the desired examination.

Several developments have been made recently to these installations. First of all, the image scanning technique facilitated the implementation of the installation with regard to image processing. Next, it has been proposed to automate the movements of the table and the roll bar using a control computer (see document FR 2 588 745).

In addition, recently, angioplasty procedures have been developed which consist in first identifying, under angiographic control, the existence of a stenosis in the patient and then introducing a balloon into the artery at the location of this stenosis. of appropriate size whose swelling, repeated if necessary several times, makes it possible to increase the size of the artery.

The proper execution of these angioplasty procedures would require rapid and precise knowledge of the internal diameters or calibers of the artery in a healthy portion and in the place of a stenosis. Indeed, in particular, the size of the balloon to be used is a function of these internal diameters.

However, the currently used radiology facilities allow only a relative appreciation of the dimensions but not their absolute knowledge during direct reading of the image. And this knowledge of dimensions in absolute value is all the more important as the relative table-arch positions are in infinite number.

The essential object of the invention is therefore to allow direct evaluation, at any time and for any relative table-arch position, of the exact dimensions in absolute value of what appears on the image obtained.

The technical measure proposed for this main object is the prior calibration of the installation.

To this end, the invention first proposes a method for calibrating a radiology installation, more specifically intended for angiography or angioplasty procedures, radiology installation comprising a general position table at least substantially horizontal , on which the patient's body to be examined can rest, movable and lockable; a particularly isocentric hoop supporting at its two ends means for emitting an X-ray beam and means for receiving said beam, movable and lockable ~ means of storage, processing, display of images associated with the means of reception , in particular by digital analysis of the images produced, using an image analysis computer; and a computer for receiving and controlling the positions of the table and the transmission and reception means connected to the image analysis computer; angiography or angioplasty procedures in which the patient's body is placed on the table, the relative positions of the table and of the X-ray emission and reception means (amplifier) are adjusted, it is implemented the means of storage, processing, visualization of images, characterized in that before an angiography or angioplasty procedure and in the absence of a patient on the table, the installation is calibrated so as to know its coefficients enlargement and distortion and therefore the scale of the images obtained, and, for this purpose: for the relative positions of the table and of the transmission and reception means (i) The table and the transmission means are placed and reception
(amplifier), in a first relative position (ii) In this first relative position, we interpose on the
X-ray beam, a calibrated grid opaque to
X-rays, the center of which is aligned with the center of
the amplifier, at least substantially parallel to the
amplifier plan; the center of the grid
finding, in this first relative position of the
table and amplifier equidistant from the plane
from the table and the center of the amplifier; (iii) In this first relative position and in the presence of
this grid, the storage means are used,
processing, viewing, a short time to get
an image of the grid (iv) We compare the dimensions and surfaces of the grid
calibrated and its image in order to know, for this
first relative position, 'the coefficients
magnification and distortion and image scale
(v) Then place the table and the means of transmission and
reception (amplifier) in a second position
relative different from the first and not too far apart (vi> In this second relative position, we rule the case
the position of the grid to adapt it if
necessary -in particular we move it then we block it in
position- and we also implement the means of
storage, processing, visualization, to know, to
this second position, the magnification coefficients
and distortion and the scale of the image produced (vii) The parameters characterizing are transmitted to the computer
the relative positions of the table, of the transmission means
and reception (amplifier) as well as the values
corresponding enlargement and
distortion and scale.

(viii) The coefficients of enlargements and of
distortion as well as the scale for any position
relative intermediate between the first and the
second relative positions when necessary; (ix) We repeat the previous steps for others
relative positions and relative positions
desired intermediaries (x) We store the coefficients of enlargement and
distortion, scales and parameters characterizing
the different relative positions, as well as the values
interpolated.

 The invention then proposes a radiology installation, more specifically intended for angiography or angioplasty procedures, comprising a general position table at least substantially horizontal, on which the body of a patient to be examined can be supported, carried by movable and lockable table support means, thanks to table drive means with locking and means for controlling the position of the table; an arch, in particular an isocentric arch, supporting at its two ends means for emitting an X-ray beam and means for receiving said beam, carried by movable arch support means which can be locked by means of drive means roll bar with blocking and means for controlling the position of the roll bar; means for storing, processing, viewing the images associated with the reception means, in particular by digital analysis, using a computer for analyzing the images; and a computer associated with the means for controlling the position of the table and the roll bar, characterized in that it also firstly comprises calibration means intended to know the coefficients of enlargement and of distortion of the installation as well as the scale of the images obtained for the relative positions of the table and of the transmission and reception means ~ and secondly, an interface capable of allowing the transmission of the digital values characterizing any relative position of the table and of the transmission and reception means (amplifier) and, on the other hand, the control of the movements of the table and of the transmission and reception means on the basis of instructions from the computer.

The invention will be better understood thanks to the description which follows with reference to the accompanying drawings in which - Figure 1 is a purely schematic perspective view
of a radiology installation according to the invention.

- Figure 2 is a diagram illustrating the calibration according to
the invention.

- Figure 3 is one of the possible interface diagrams.

The invention relates to a radiology installation comprising (FIG. 1) a table i of general position at least substantially horizontal, on which the body of a patient to be examined can rest, carried by table support means 2 that can be moved and locked, thanks to table drive means with locking and means for controlling the position of the table; a hoop 3, in particular isocentric, supporting at its two ends means of emission 4 of an X-ray beam and means of reception 5 (amplifier) of said beam, carried by hoop support means 6 movable and lockable using hoop drive means with locking and means for controlling the position of the hoop; means 7 for storing, processing, viewing images associated with the reception means, in particular by digital analysis, using a computer 8 for analyzing images; and a computer 9 associated with the means for controlling the position of the table and the roll bar and which can be connected to the computer 8.

Such an installation as just described is perfectly known to those skilled in the art and for this reason does not require any further detailed explanations. This is especially true for the support, drive and control means of the table and the hoop which are not in themselves the subject of the invention. The transmission means 4 are generally located at the lower end of the hoop 3 and under the table i while the reception means 5 (amplifier) are generally located at the upper end of the hoop and above table 1 and, in operation of the installation, placed directly in contact with the patient resting on table 1 and this in the desired area. Table 1, and the roll bar 3 and the transmission 4 and reception 5 means can be moved in various combinable sliding and / or rotating movements so that the position of the X-ray beam relative to the table 1 can be adjusted, not only with regard to the two axes (length and width) of the latter above - especially for movement along the patient's body - but also in incidence.

In a manner also known per se, the reception means 5 (amplifier) are generally placed, in operation, in the immediate vicinity of the patient's body, as already indicated.

The computer 8 allowing the digital analysis of the images and the computer 9 for controlling the table 1 and the hoop 3 are the same or separate but are functionally and / or structurally connectable to each other. They naturally include the appropriate control means, the central unit, the peripherals, etc., and are loaded with the appropriate program or programs.

The means 7 are shown in FIG. 1 as comprising one or more display screens. Naturally, they may include other temporary or permanent display means as well as means for storing the images obtained.

Subsequently, the term "relative position of the table 1 and the hoop 3" denotes a certain defined position of the table 1 and of the transmission 4 and reception 5 (amplifier) means, characterized by situations with respect to two axes of table 1, at the angles of incidence of the X-ray beam relative to the upper plane P of table 1 (reference plane) as well as to the spacings in the vertical direction of the means 4, 5 relative to the table 1.

It is understood that these relative positions are in unlimited number and that for each of them there is a certain value of the coefficient of enlargement and distortion as well as a certain scale.

By scale is meant, in the context of the present invention, the distance separating two image points on the screen of the means 7 compared to the real distance between the two origin points of the image. For example the diameter of the image of an artery in relation to the effective diameter of the artery itself.

According to the calibration method according to the invention of the radiology installation thus defined, before an angiography or angioplasty procedure and in the absence of a patient on the table 1, the installation is calibrated so as to know its enlargement and distortion coefficients and therefore the scale of the images obtained, and, for this purpose: for the relative positions of the table 1 and of the transmission and reception means 4, 5 (i) We place the table 1 and the means of transmission and
reception 4, 5, in a first relative position (ii) In this first relative position, on the
X-ray beam, a grid 10 calibrated and opaque to
X-rays, the center of which is aligned with the center of
the amplifier, at least substantially parallel to the
amplifier plan; the center of the grid
finding, in this first relative position of the
table and amplifier equidistant from the plane
of the table and the center of the amplifier (iii) In this first relative position and in the presence of
this grid 10, the emission means are used and
receiving 4, 5 and the means 7 for storage, processing,
viewing, a short time to get a picture of
grid 10 ;; (iv) We compare the dimensions and surfaces of the grid 10
calibrated and its image in order to know, for this
first relative position, the coefficients
magnification and distortion and image scale
completed (v) Then place table 1 and the means of transmission and
reception 4, 5 in a second relative position
different from the first and not too far apart (vi) In this second relative position, we adjust the
position of the grid 10 to adapt it and we put
also use the transmission and reception means
4, 5 and the means 7 for storage, processing,
visualization, to know, for that second
position, the coefficients of enlargement and
distortion and scale of the image performed and this
in accordance with the Procedure already described; ; (vii) The parameters characterizing in
relative positions of the table, transmission means and
reception (amplifier) and the values
corresponding enlargement and
distortion and scale.

(viii) The coefficients of enlargements and of
distortion as well as the scale for any position
relative intermediate between the first and the
second relative positions when necessary; (ix) We repeat the previous steps for others
relative positions and relative positions
desired intermediaries (x) We store the coefficients of enlargement and
distortion, scales and parameters characterizing
the different relative positions, as well as the values
interpolated.

The relative positions in which the measurements are made are either taken at random, or correspond to conventional positions of investigation, or result from an increment of the parameters defining a position.

The difference between two relative positions in which a measurement is made is within the reach of those skilled in the art depending in particular on ~ the calculation means used for the interpolation, the precision desired for the calculations of the values by interpolation. , of the importance of the variation of the coefficients and scales sought compared to the variation of the parameters defining the positions.

To interpose the grid 10, as provided in step (ii), two opaque x-ray balls (lead) are placed in the center of the grid 10 and in the center of the amplifier 5 , 11 and 12 respectively, so that they are aligned and superimposed, the grid 10 being carried by a hanger 13 notably carried by the amplifier 5. In this way the grid 10 is parallel to the plane of the amplifier 5, permanently . In addition, (see FIG. 2B more specifically) the spacings between the center of the grid and on the one hand the plane of the amplifier 5 and on the other hand the plane P of the table 1 are equal.

An installation according to the invention is therefore characterized in that it also includes calibration means intended to know the coefficients of enlargement and distortion of the installation as well as the scale of the images obtained for the relative positions of the table and means of transmission and reception.

Preferably, the invention uses a computer 9 capable of performing the desired interpolations as well as the storage of the coefficients and scales for each position. This computer 9 is distinct or not from that 8 processing the images and I or controlling the relative displacements, but it is associated with it.

It should be noted that the calibration thus described can be carried out originally before the first implementation of the installation and then checked at regular time intervals in order to ensure the consistency of the values obtained or, if necessary, the correct (especially in case of modification or replacement of the camera and / or its lens).

The invention also provides that during the subsequent implementation of the installation, after calibration, the values of coefficients and scales are displayed on the screen of the means 7, during operation and this for any particular relative position of the table. 1 and the hoop 3 as well as means 4, 5. This display can be instantaneous thanks to the calibration carried out beforehand, and thanks to the interface existing between the radiological installation and the computer 9.

In the case of angioplasty, the practitioner can therefore, thanks to the invention, have immediate and precise knowledge of the real dimension of a stenosis as well as of healthy portions of the artery comprising this stenosis. He can therefore use the appropriate balloon, without risk of error, without the need for trial and error and without delay.

Naturally, the invention implies that at all times the relative position of the hoop table 3 is known, which is made possible by the computer 8 which is able, at any time on the one hand to know the relative position of the table 1 hoop 3 I means 4/5 /; and on the other hand control the relative movements. Generally, there is provided on the one hand means for displaying the parameters defining a relative position, in particular on the screen of the means 7, and, on the other hand, means for entering the desired values for the parameters defining a position relative, such as a keyboard, or a mouse or a voice induction control system or the like. A suitable software of the computer makes it possible to control the suitable movements of the table 1 and of the roll bar 3 as a function of an initial relative position and the relative position thus defined.

Where appropriate, means are also provided for storing the parameters of a particular relative position, in particular repetitive.

According to a possible variant implementation of the invention, the parameters defining a relative position of the hoop table 3 are as follows (FIG. 3)
- Table height 1 (X)
- Table position 1 antero posterior (Y)
- Table 1 side position (Z)
- Average reception height 5 (H)
- Average reception rotation 5 (fol)
- Average reception angle 5 (r)
- Field (C)
Each of these parameters as well as others, if any, may vary between extreme limits. -The parameters corresponding to a dimension or an angle vary continuously. The field generally varies in a discrete way, being able to take some values (for example-three).

The values of the parameters correspond to adjustable levels of analog potentiometers POT of the drive means of table 1 and hoop 3.

A suitable circuit allows the transmission to the computer used for the calibration of the values of the parameters corresponding to the relative position table hoop 3.

This circuit can be the subject of numerous variant embodiments. For example if we refer expressly to fig 3 it may include an amplification stage AMPLI for normalizing the voltage values of analog potentiometers already mentioned; a transmission circuit comprising the mixing of the MIX signals, an S / N sampler / switch, an analog / digital A / D converter, ending at the bottom of the computer 9 which includes a DATA BASE database making it possible to associate with specific values of the parameters of a relative position - that is to say at a determined relative position - the values of the coefficients of enlargement and distortion and the scale of the image. These values of the coefficients and this scale are obtained, as described, by interpolation from a few tested values.

According to another characteristic, the invention is well suited to a real-time angioplasty procedure. Initially, when taking a picture, after injection of the contrast medium, the operator stores the image and the parameters defining the relative position of the radiological installation, and continues his examination by repeating this procedure a certain number of time. At the end of the examination, the operator recalls the images to choose those corresponding to the best incidence for performing the angioplasty. Thanks to the calibration process according to the invention, it can qualitatively measure the diameter of the artery in its healthy and stenosated portions, by direct analysis of the image.

 Finally, the relative portions having been stored at the same time as the image, it can automatically reposition the installation in the position corresponding to the image acquisition position.

According to another characteristic, the installation is well suited to an arterography procedure of the lower limbs in which an injection is made into the artery followed by a modification of the elementary relative position itself followed by an injection and 'another modification of the relative position and so on. In this case, it is also possible to provide an injection control computer (in particular quantitatively) in connection with the control computer for the relative positions.

 According to another characteristic, the software allowing the change of the relative positions according to instructions given by the operator comprises a security consisting in limiting the amplitude of the displacements according to limits corresponding to the morphology of the body of a patient on the table 1, so as to thus avoid any interference between the patient's body and the reception means 5. In addition, pressure sensors are provided on the reception means 5 so that when they are acted upon, which indicates an interference between the receiving means 5 and a fixed part: table 1 or body of the patient - the movements are stopped.

Claims (3)

1. Method for calibrating a radiology installation, plus  specially intended for angiography procedures or  angioplasty, radiology installation including a  at least substantially general position table (1)  horizontal, on which the patient's body can rest  examine, movable and lockable; a hoop (3) in particular  isocentric supporting at its two ends means  emission (4) of an X-ray beam and means of  receiving (5) of said beam, movable and lockable; of  means (7) for storing, processing, viewing images  associated with reception means, in particular by analysis  digital, using a computer (8); and a computer (9)  for controlling the positions of the table (1) and the means  transmission and reception (4, 5) connected to the computer (8)  angiography or angioplasty procedures in which  we place the body of a patient on the table (1), we adjust the  relative positions of the table (1) and the transmission means  and reception (4, 5) of X-rays, the  means (7) for storing, processing, viewing images,  characterized in that before an angiography procedure or  angioplasty and in the absence of a patient on the table (1)  we calibrate the installation in order to know its  magnification and distortion coefficients and therefore  the scale of the images obtained, and, for this purpose: for  relative positions of milk (1) and means of emission  and reception (4, 5):  (i) Place the table (1) and the means of transmission and  reception (4, 5), in a first relative position;  (ii) In this first relative position, we interpose  on the X-ray beam, a calibrated grid (10)  and opaque to X-rays, the center of which is aligned with  the center of the amplifier; the center of the grid  being, in this first relative position of  the table and the amplifier at equal distance between  the table plan and the center of the amplifier.  of scale.  magnification and distortion coefficients and  (4,5) as well as the corresponding values of  transmission and reception means (amplifier)  characterizing in relative positions of the table, the  of distortion and the scale of the image produced (vii) ~ The parameters are transmitted to the computer (9)  second position, the magnification coefficients and  processing, visualization, to know, for this  reception (4,5) and the storage means (7),  also use the transmission and  position of the grid (10) to adapt it and put  distant (vi) In this second relative position we adjust the  relative different from the first and not too much  and receiving (4, 5) in a second position  the image produced (v) We then place the table (1) and the transmission means  magnification and distortion and the scale of  this first relative position, the coefficients  (10) calibrated and its image in order to know, for  to obtain an image of the grid (10); (iv) We compare the dimensions and surfaces of the grid  storage, processing, viewing, a short time  transmission and reception (4,5) and the means (7) of  of this grid (10), the means are implemented (iii) In this first relative position and in the presence  as well as the interpolated values.  characterizing the different relative positions,  distortion, scales, and parameters  (x) We store the coefficients of enlargement and  desired intermediaries  relative positions and relative positions  (ix) We repeat the previous steps for others  the second relative positions when necessary  relative intermediate between the first and  distortion as well as the scale for any position (viii) The coefficients of enlargements and of 2. Radiology installation, more specifically intended for  angiography or angioplasty procedures, including  at least substantially general position table (1)  horizontal, on which a patient's body can rest  to be examined, carried by table support means (2)  movable and lockable, thanks to drive means  table with blocking and means for controlling the  table position; an arch (3), in particular isocentric,  supporting at its two ends emission means (4)  an X-ray beam and means (5) for receiving the  called #beam, carried by hoop support means (6)  movable and lockable thanks to drive means  roll bar with blocking and means for controlling the  position of the roll bar; storage means (7),  processing, visualization of images associated with the means of  reception, in particular by digital analysis, thanks to a  computer (8); and a computer associated with the means of  table and hoop position control,  characterized in that it also includes means  calibrations intended to know the coefficients  enlargement and distortion of the installation as well as  the scale of the images obtained for the relative positions of  the table and means of transmission and reception and in this  that it makes it possible to know the parameters at any time  defining the relative positions of the table (1), the  transmission (4) and reception (5) means. 3. installation according to claim 2, characterized in that the calibration means comprise a calibrated and opaque X-ray grid interposed on the X-ray beam, substantially parallel to the reception means (5) and whose center is equal distance from these receiving means (5) and from the table (1); means for comparing the dimensions and surfaces of the calibrated grid and its image and therefore obtaining the enlargement and distortion coefficients as well as the scale for the relative position of the table and the transmission and reception means; means for interpolating the enlargement and distortion coefficients as well as the scale for any relative position intermediate between two different relative positions and not too far apart; and means making it possible to transfer the enlargement and distortion coefficients as well as scales for the various relative positions to storage means and the parameters making it possible to characterize the relative position of the table (1) -and means of transmission (4) and reception (5), which also makes it possible to control the relative positions on the basis of instructions from the computer (9).