EP3679404A1

EP3679404A1 - Device for optically measuring doses of radiation absorbed by a gel dosimeter by means of polarized light

Info

Publication number: EP3679404A1
Application number: EP18796700.5A
Authority: EP
Inventors: Olivier BLEUSE; Yannick BAILLY; Régine GSCHWIND; Libor MAKOVICKA; Kévin LAURENT; François GUERMEUR
Original assignee: Universite de Franche-Comte
Current assignee: Universite de Franche-Comte
Priority date: 2017-09-07
Filing date: 2018-09-07
Publication date: 2020-07-15
Also published as: CA3075230A1; US11099278B2; US20200233097A1; FR3070769A1; WO2019048796A1; JP2020533584A; FR3070769B1

Abstract

The invention relates to a device (2) for measuring radiation doses absorbed by a gel dosimeter (4), comprising in particular a means (22) for polarizing a light beam (8) according to at least two distinct polarization angles, the polarizing means (22) being positioned between a light source (6) and an optical detector (14), a unit (28) for measuring the value of the intensity of the light beam (8), which intensity is measured by the optical detector (14), and a unit (30) for calculating the value of a ratio of intensities of the light beam (8), which intensities are measured by the optical detector (14), for two distinct polarization angles of the light beam (8) that is selected by the polarizing means (22).

Description

POLARIZED LIGHT OPTICAL MEASURING DEVICE OF IRRADIATION DOSES

ABSORBED BY DOSIMETRIC GEL

Technical area

[01] The present invention relates to a device for measuring at least one irradiation dose absorbed by a dosimetric gel, as well as to a method of implementing the measuring device for measuring the value of one or more absorbed doses. by the dosimetric gel. State of the art

[02] Radiotherapy can treat many conditions in a patient without it being necessary to resort to invasive operations. Radiotherapy therefore offers an alternative to surgical techniques to avoid postoperative trauma in the patient.

[03] For this, radiotherapy treats tumor tissue in a patient by exposing them to sufficient radiation doses to irreversibly damage them. The effectiveness of this method therefore requires absolute control of the irradiated area so as not to damage the surrounding healthy tissues. To make sure of this, it is known the use of metrological systems that verify the ballistics of the treatments.

[04] These metrological systems reproduce the volume and the density from the radiological point of view by the use or not of elements equivalent to the tissues of an area that it is desired to treat in a patient. These metrological systems are based on dosimetric gels which have the particularity of changing structure depending on the radiation dose received. After irradiation, the metrological system is analyzed by magnetic resonance imaging (MRI) or optical scanning to obtain two- or three-dimensional views of the interior of the gel. Thus, treatment schedules are validated by metrological systems to ensure that the irradiation doses administered radiate target volumes while sparing healthy volumes. [05] However, this method of MRI analysis is very expensive considering the cost of operation of this technique. It is also difficult to access because of the few machines available. This analytical technique is also limited in evaluating the influence of low doses of irradiation on the structure of a dosimetric gel because of its low sensitivity and low response to low doses of irradiation. In addition, the sensitivity of the metrological system fluctuates according to the ambient temperature. Other optical reading techniques are also subject to artifacts and very long read times.

[06] The present invention therefore aims to provide a device and a method for measuring doses of radiation absorbed by a dosimetric gel that are more precise, faster, less expensive to implement, high availability and with a measurement range covering, on the one hand, the low doses (less than 1 Gy) but also the high doses administered at the target volume, and thus to perform the dosimetric mapping of all the doses administered.

Description of the invention

[07] The invention proposes a device for measuring at least one irradiation dose absorbed by a dosimetric gel, comprising a light source emitting a light beam whose wavelength is modifiable in time, a support for positioning a dosimetric gel in the light beam emitted by the light source and an optical detector of the light beam positioned so that its detection axis forms a diffusion angle with the axis of the light beam at the support.

[08] The invention is remarkable in that the measuring device comprises:

means for polarizing the light beam according to at least two distinct polarization angles, the polarization means being positioned between the light source and the optical detector; and

a unit for measuring the value of the intensity of the light beam measured by the optical detector; and a unit for calculating the value of a ratio of intensities of the light beam, measured by the optical detector, for two distinct and successive polarization angles of the light beam selected by the polarization means.

[09] Thus, the measuring device according to the invention makes it possible to calculate at least a ratio of two light intensities of the same zone in a dosimetric gel. Each light intensity corresponds to a specific polarization performed at a distinct moment of the light beam detected by the optical detector. However, the inventors have found that the value of this ratio depends directly on the structure of the dosimetric gel, a structure that changes as a function of the radiation dose absorbed by the gel. As a result, the measurement of this ratio advantageously makes it possible to obtain information on the radiation dose absorbed by the dosimetric gel in a simple, fast and much less expensive manner compared to an analysis technique using an MRI. Advantageously, the intensity measurements of the light beam are made for two distinct polarization angles and at two different times so as to guarantee a strict spatial correspondence between these two measurements.

[10] According to a preferred embodiment of the invention, the value of the diffusion angle is between 10 ° and 350 °, preferably between 30 ° and 120 °, preferably between 30 and 85 ° and / or between 95 ° and 120 °. In other words, the optical detector is positioned so that its detection axis forms an acute angle, right or obtuse with the light beam at the support. In the ranges of values mentioned above, the inventors obtained more precise information on the radiation doses absorbed by a dosimetric gel. In other words, the principle of the invention is to measure a ratio of intensities of the light beam diffused through a dosimetric gel, under one or more angles of observation, for two different polarizations of the incident light beam or two polarizations. different from the collected beam or any combination of these two situations.

[11] According to another embodiment of the invention, the calculation unit is configured to associate with at least one value of the intensity ratio calculated by the calculation unit, a radiation dose value absorbed by a dosimetric gel. According to a preferred embodiment, the calculation unit comprises a memory unit in which is stored a correspondence table between at least one value of a report. of intensity calculated by the unit of measurement and a radiation dose value absorbed by a dosimetric gel.

[12] According to another embodiment of the invention, the light source comprises means for selecting at least two distinct wavelength ranges observable by the optical detector. Preferably, the selection means comprises one or more optical filters enabling these selections. According to a preferred embodiment, the light source comprises at least one laser source or an incoherent source. According to another embodiment of the invention, the biasing means comprises a first polarizer positioned between the light source and the support, and a second polarizer positioned between the support and the optical detector.

[13] According to another embodiment of the invention, the polarization means comprises a first polarizer and a second polarizer, both positioned between the light source and the support. This embodiment promotes the detection of a more intense light signal by the optical detector. According to an alternative embodiment, the biasing means comprises a first polarizer and a second polarizer, both positioned between the support and the optical detector.

[14] According to another embodiment of the invention, the measuring device comprises a diffusing means positioned between the light source and the support, so as to standardize the polarization of the light beam emitted by the light source. Advantageously, this embodiment makes it possible to uniformize the polarization of the light beam before it illuminates a dosimetric gel placed on the support.

[15] According to another embodiment of the invention, the measuring device comprises means for moving the support relative to the detection axis of the detector, preferably preserving the value of the diffusion angle. The means for moving the support are preferably adapted to move a dosimetric gel positioned on the support, in at least two different directions, preferably in a three-dimensional space. Optionally, the moving means can be configured to pivot the support.

[16] According to another embodiment of the invention, the measuring device comprises means for pivoting the optical detector relative to the support, so as to modify the value of the diffusion angle. [17] According to another embodiment of the invention, the measuring device comprises two mirrors in linear or angular oscillations, at frequencies greater than the inverse of the measuring time of the measurement unit, positioned on the path of the light beam between the light source and the optical detector. This particular arrangement of the invention advantageously makes it possible to limit the formation of scabs or chatolements at the level of the unit of measurement, also known under the name of "speckle".

[18] According to another embodiment of the invention, the measuring device comprises in the path of the light beam between the light source and the optical detector, an oscillating mirror for generating a sheet of light in a dosimetric gel present on the support. This embodiment advantageously makes it possible to perform measurements more quickly in different zones of the dosimetric gel. Optionally, the measuring device may comprise several measurement units distributed around the support, so as to simultaneously perform measurements in different areas of the dosimetric gel.

[19] Of course, the various features, variations and embodiments mentioned above may be associated with each other in various combinations, to the extent that they are not incompatible or exclusive of each other.

[20] The invention also relates to a method for measuring at least one irradiation dose absorbed by a dosimetric gel using a measuring device described above, implementing the following steps:

positioning a dosimetric gel on the support so that the light beam emitted by the light source illuminates the dosimetric gel at a first wavelength;

orienting the optical detector so that its detection axis passes through the gel and forms an angle of diffusion with the light beam;

determination by the unit of measurement of the light intensity observed by the optical detector;

modifying the polarization angle of the light beam by means of polarization means and / or modification of the wavelength of the light beam; new determination by the unit of measurement of the light intensity observed by the optical detector;

estimation by the computing unit of the value of a ratio between the two intensities measured by the optical detector;

identification in a correspondence table by the unit for calculating an irradiation dose absorbed by a dosimetric gel from the value of the intensity ratio estimated by the calculation unit.

[21] Advantageously, the invention provides a method for directly measuring an irradiation dose absorbed by a dosimetric gel, in the sense that no dose field reconstruction is necessary. Indeed, unlike the indirect measurement methods of the absorption of an irradiation dose, based on a measurement of the absorption of the light intensity of a beam passing through a dosimetric gel, it is not necessary to perform a series of measurement lines in the entire volume of the gel, the results of which integrate the absorption of doses over the entire path of the light beam and therefore require a complex reconstruction to estimate a local irradiation value.

[22] According to a variant of the measurement method, the following steps are implemented

a) positioning a dosimetric gel on the support so that the light beam emitted by the light source illuminates the dosimetric gel at a first wavelength;

b) orienting the optical detector so that its detection axis passes through the dosimetric gel and forms a diffusion angle with the light beam; c) determination by the unit of measurement of the light intensity observed by the optical detector;

d) changing the polarization angle of the light beam using the biasing means;

e) re-determination by the unit of measurement of the light intensity observed by the optical detector;

f) estimation by the calculation unit of the value of a ratio between the two intensities measured, called the polarization rate; g) changing the value of the wavelength of the light beam emitted by the light source and / or modifying the scattering angle;

h) reproducing steps c) to g) several times in succession in order to obtain polarization rates for different pairs of values of wavelength and scattering angle;

i) modeling by the calculation unit of a theoretical polarization rate as a function of the size of the diffusing structures present in the dosimetric gel;

j) identification by the computing unit of a size of diffusing structures present in each modeling theoretical polarization rates;

k) identification in a correspondence table by the calculation unit of an irradiation dose absorbed by a dosimetric gel from the value of the intensity ratio estimated by the calculation unit.

[23] Advantageously, the invention proposes a direct measurement method which is not based on a phenomenon of absorption of the light beam by the dosimetric gel. As a result, the measurements obtained by the invention do not exploit the variation of the absorption as a function of the wavelength of the light beam emitted by the light source.

[24] According to another embodiment of the invention, the preceding steps are repeated for a dosimetric gel irradiated at different and known doses, in order to establish a correspondence table. In other words, the present invention also relates to a method for calibrating or establishing a correspondence table for a type of dosimetric gel subjected to different known irradiation doses.

[25] According to another embodiment of the invention, the diffusion angle of the detector is changed according to the wavelength range of the selected light beam by a selection means.

[26] According to another embodiment of the invention, the support is moved between each measurement series so as to obtain the irradiation doses absorbed by the dosimetric gel in a two-dimensional plane, preferably in a volume in millimeters. three dimensions. Description of figures

[27] The invention will be better understood, thanks to the following description, which refers to preferred embodiments, given by way of non-limiting examples, and illustrated by the following figures:

- Figure 1 shows a top view of a measuring device according to the invention;

FIG. 2 illustrates a correspondence curve associating, at different values of ratio R, irradiation doses absorbed by a polymer-type dosimetric gel.

Description of Detailed Embodiments of the Invention

[28] As a reminder, the invention provides a device and a method for measuring radiation doses absorbed by a dosimetric gel that are more accurate, faster and less expensive to implement.

[29] Figure 1 illustrates an embodiment of a measuring device 2 according to the invention, radiation doses absorbed by a dosimetric gel 4. For this, the measuring device comprises a light source 6 emitting a light beam 8 along an optical axis 9 towards a support 10. According to the present example, the light source is of white light type (for example a xenon source) which coupled with monochromatic filters selects a only wavelength between 200 nm and 700 nm or a system coupling lasers for wavelengths between 350 and 700 nm. The light source 6 comprises a selection means 7 making it possible to emit light beams in distinct wavelength ranges, for example at the following wavelengths: 350 nm, 432 nm, 534 nm, 576 nm and 634 nm. nm. By way of example, the selection means 7 may comprise one or more narrow-band optical filters. Whatever the configuration envisaged, the polarization of the incident beam must be known, in the absence of precision, it is assumed that the incident beam is unpolarized or of circular polarization. [30] The measuring device 2 also comprises a divider 8A of the light beam 8, interposed between the light source 6 and the support 10. The divider 8A is configured to deflect a small portion 8B of the light beam 8 to an optical detector 8C to check the constancy of the light beam 8.

[31] The support 10 allows the positioning in the light beam 8 of a transparent container 12 containing the dosimetric gel 4. According to the present example, the support is a precision motorized plate allowing the displacement of the support along three distinct axes so to be able to expose different zones of the dosimetric gel 4 to the light beam 8. Optionally, the support may comprise an axis of rotation in order to expose different faces of the dosimetric gel 4 to the light beam 8. According to a preferred embodiment, the support 10 is motorized to allow remote modification of the area of the dosimetric gel 4 which is illuminated by the light beam 8.

[32] The measuring device 2 also comprises an optical detector 14 for measuring the luminous intensity of the filtered light beam (or not), according to the presence (or absence) of the elements 24 and 26.

[33] The optical detector 14 is mounted on an arm 16 pivoting around the support 10 so that the detection axis 18 of the optical detector forms a diffusion angle α with the axis 9 of the light beam 8 at the support 10 In other words, the optical detector 14 is oriented so as to capture the intensity of a light beam 20 scattered by aggregates 21 present in the dosimetric gel 4. By the term "aggregate" is also meant microdomains formed by radioformed polymers, or any element that has absorbed the radiation dose. The size of the aggregates depends on the dose of radiation received by the dosimetric gel.

[34] According to a preferred embodiment, the arm 16 is motorized so as to be able to remotely modify the value of the diffusion angle a. The value of the diffusion angle α is between 10 ° and 170 °, preferably between 30 ° and 60 °. According to the present example, the value of the diffusion angle α is 90 °.

[35] The measuring device 2 also comprises a polarization means 22 of the light beam according to at least two distinct polarization angles. According to the present example, the biasing means 22 comprises a first linear polarizer 24 and a second linear polarizer 26 both mounted on the movable arm 16 so as to be positioned between the support 10 and the optical detector 14. The first and second polarizers are oriented so that their transmission axis forms a polarization angle β between 10 ° and 170 °, preferably of the order of 90 °. Thus, the polarizers make it possible to modify the polarization angle β of the light beam 20 diffused by the dosimetric gel 4 before being detected by the optical detector 14.

[36] According to an alternative embodiment of the invention not shown, the first polarizer 24 could be positioned between the light source 6 and the support 10 or the two polarizers could be positioned between the light source and the support.

[37] According to another embodiment of the invention not shown, two polarizers could be positioned between the light source 6 and the support 10 and two other polarizers could be positioned between the support 10 and the optical detector 14.

[38] The optical detector 14 is thus oriented towards the support 10 so as to be able to capture the intensity of a light beam 20 scattered by aggregates 21 present in the dosimetric gel 4. To allow an accurate measurement of the value of this intensity, the optical detector 14 is connected to a measurement unit 28. It should be noted that according to the present example, the biasing means 22 makes it possible to choose two successive polarizations of the light beam 20 so as to guarantee a strict spatial correspondence between the light intensity measurements made by the measuring unit 28.

[39] The measurement unit 28 is connected to a calculation unit 30 configured to calculate the value of a ratio of intensities of the light beam 20 diffused by the dosimetric gel 4, measured by the optical detector 14, for two angles distinct polarization of the light beam selected by the biasing means 22.

[40] According to the present example, the computing unit 30 also comprises a memory unit 32 in which a correspondence table is stored between several values of intensity ratios calculated by the measurement unit and dose values of irradiation absorbed by a dosimetric gel. In this case, the measurement unit 28, the calculation unit 30 and the memory unit 32 are integrated in a central unit 34 computer or microcomputer type. The central unit 34 is connected to a display screen type display device 36, in order to enable a user of the measurement device 2 to read an irradiation dose value determined from the beam intensity measurements. bright 20 and correspondence table.

[41] According to a preferred embodiment, the motorized stage, the motorized arm and the selection means are also connected to the central unit 34 in order to allow the automation by the central unit of a measurement method described herein. -Dessous.

[42] It should be noted that a measuring device 2 according to the invention may simultaneously comprise a plurality of optical detectors 14 positioned around the support 10 so as to form observation angles of different values. This embodiment, not shown, advantageously makes it possible to multiply the observation angles of the dosimetric gel 4 in order to reduce the acquisition time of the intensity measurements in order to establish more rapidly a spatial representation of the irradiation doses absorbed by the gel. dosimetry 4.

[43] It should be noted that the detection of the two polarizations can be carried out simultaneously by dividing the beam 20 according to its two polarization components and simultaneously using two optical detectors 14 (one for each component).

[44] The invention also relates to a method for measuring at least one irradiation dose absorbed by a dosimetric gel 4 using a measuring device 2 described above.

[45] According to the present example, the measurement method implements a step of positioning a dosimetric gel 4 on the support 10 so that the light beam 8 emitted by the light source 6 illuminates an area of the dosimetric gel 4 with a known polarization. The optical detector 14 is subsequently oriented so that its detection axis 18 passes through the dosimetric gel 4 and forms a diffusion angle α with the light beam 8 so as to detect a light beam 20 scattered by aggregates 21 present in the gel Dosimetry 4. The measurement unit 28 then determines a first light intensity li observed by the optical detector 14 at a first polarization angle β 1 of the light beam by the polarization means 22. The polarization angle of the light beam 8 is then modified with the biasing means 22 to allow the measurement unit 28 to measure a new value of luminous intensity l ₂ observed by the optical detector 14 according to a second angle β ₂ of polarization. From these two intensity values, the computing unit 30 estimates the value of a ratio R between the two intensities measured for two distinct polarization angles. The value of this ratio is then compared by the calculation unit to a correspondence table in order to determine from the value of this ratio R an irradiation dose absorbed by the dosimetric gel 4. The value of this dose of irradiation is then displayed on the display device to communicate this information to a user of the measuring device 2.

[46] The computing unit 30 estimates the value of the ratio R between two light intensities by first subtracting the background noise of the optical detector 14, in one of the following ways:

khk ^~

R = - or R = - or R = - or R =

kk + k ^~ ; 2

khk ^~ k + h

R = - A or R = A or R = A or R

k + k ^~

[47] It should be noted that the inventors have observed that the accuracy of the measurements obtained by the measuring device 2 described above varies according to the nature of the dosimetric gel and also depends on the wavelength range of the device. light beam illuminating the sample, the difference between the polarization angles βι and β _{2 as} well as the value of the scattering angle a. Therefore, the invention also relates to a method of establishing a correspondence table mentioned above, consisting of reproducing the previous steps with dosimetric gels whose irradiation dose is known beforehand. Thus, for each type of dosimetric gel, it is possible to determine, empirically, the wavelength ranges of the light beam 8, the differences between the polarization angles βι and β _{2 as} well as the values of the scattering angle α allowing obtain precise measurements of the radiation dose absorbed by a dosimetric gel. In other words, these values are likely to change depending on the nature of the dosimetric gel and the amount of irradiation absorbed.

[48] For this, the computing unit 30 may comprise an automated method of establishing correspondence tables by varying the value of the parameters. mentioned above. Thus, the measuring device 2 according to the invention allows a simple and fast determination of the optimal values of these parameters as a function of each type of dosimetric gel.

[49] By way of example, the inventors have thus been able to establish a correspondence curve illustrated in FIG. 2, associating at different values of ratio R, irradiation doses absorbed by a polymer-type dosimetric gel. Specifically, these measurements were performed on a dosimetric gel of nMAG type polymers with 2% w / w, methacrylic acid (MMA), gelatin (% w / w) (Type A, 300, Sigma Aldrich). The dosimetric gel is illuminated by a laser light source or by a white light emitting a light beam at a power of between 0 and 150 mW, whose wavelength range is between 200 and 700 nm, in the the present case 634 nm for 11 and 532 nm for 12. The difference between the angles, polarization βι and β ₂ is of the order of 90 ° and the value of the diffusion angle a is centered on 90 °.

[50] From this correspondence curve, the measuring device 2 described above makes it possible very quickly and easily to accurately measure the level of radiation doses absorbed by a dosimetric gel of the same nature, much cheaper by compared to currently used techniques.

[51] According to an alternative embodiment of the measurement method described above, the calculation unit 30 performs several times the calculation of the ratio R described above for the same sample. Prior to calculating a new ratio R, the wavelength and / or the scattering angle of the light beam 20 are modified. We thus obtain a set of values of ratio R ₍ j _{j) kr} as defined below (or in paragraph § [46]) and named polarization ratio ratio:

- ^Iijk

¹ ijr

With,

li _jk corresponding to a value of the intensity of the light beam measured by the optical detector 14, for a wavelength i, a diffusion angle j and a polarization angle of the light beam equal to k, and - Ij _j r corresponding to a value of the intensity of the light beam measured by the optical detector 14, for a wavelength i, j a scattering angle and a polarization angle of the light beam equal to r, the value of r is different from the value of k.

[52] According to another step, for each polarization ratio ratio R (ij) kr calculated above, the calculation unit 30 performs a theoretical calculation of the value of this polarization rate as a function of the size of the structures. diffusing agents present in the dosimetric gel. This theoretical calculation is carried out using the TMatrix method as described in the following document: "Scattering, absorption and emission of light by small particles" - Michael I. Mishchenko, Larry D. Travis, Adrew A. Lacis - Cambridge University Press . Preferably, this theoretical calculation is carried out in the context of the Mie theory which corresponds to the limiting case where the diffusing structures have a size parameter tending towards 3.

[53] According to another step, the computing unit 30 identifies the theoretical size of the diffusing structures common to each theoretical calculation of the polarization ratio ratio previously produced.

[54] According to another step, the computing unit 30 associates with this theoretical size common to each theoretical calculation of the polarization ratio ratio, an irradiation dose present in a correspondence table associated with the dosimetric gel and prerecorded by the memory unit 32.

Claims

A device (2) for measuring at least one radiation dose absorbed by a dosimetric gel (4), comprising:

A light source (6) emitting a light beam (8) whose wavelength is modifiable in time;

A support (10) for positioning a dosimetric gel (4) in the light beam (8) emitted by the light source (6);

An optical detector (14) of the light beam (8), positioned so that its detection axis (18) forms a diffusion angle (a) with the axis of the light beam (8) at the support (10) ;

characterized in that the measuring device (2) comprises:

A polarization means (22) of the light beam (8) according to at least two distinct polarization angles, the polarization means (22) being positioned between the light source (6) and the optical detector (14); and

A measurement unit (28) for the value of the intensity of the light beam (8) measured by the optical detector (14); and

A calculation unit (30) for the value of an intensity ratio of the light beam (8) measured by the optical detector (14), for two distinct and successive polarization angles of the light beam (8) selected by the polarizing means (22) and / or for two distinct and successive wavelengths of the light beam (8), the computing unit (30) is configured to associate at least one value of the intensity ratio calculated by the computing unit (30), a radiation dose value absorbed by a dosimetric gel

(4).

2. Measuring device (2) according to the preceding claim, characterized in that the value of the diffusion angle (a) is between 10 ° and 350 °, preferably between 30 ° and 85 ° or between 95 ° and 120 °.

3. Measuring device (2) according to one of the preceding claims, characterized in that the computing unit (30) comprises a memory unit (32) in which is stored a correspondence table between at least one value d an intensity ratio calculated by the measurement unit (28) and a radiation dose value absorbed by a dosimetric gel (4).

Measuring device (2) according to one of the preceding claims, characterized in that the light source (6) comprises a selection means (7) of at least two distinct and observable wavelength ranges. the optical detector (14).

5. Measuring device (2) according to one of the preceding claims, characterized in that the biasing means (22) comprises a first polarizer (24) positioned between the light source (6) and the support (10), and a second polarizer (26) positioned between the support (10) and the optical detector (14).

6. Measuring device (2) according to one of claims 1 to 4, characterized in that the biasing means (22) comprises a first polarizer (24) and a second polarizer (26), both positioned between the source of light (6) and the support (10), or between the support (10) and the optical detector (14).

7. Measuring device (2) according to one of the preceding claims, characterized in that it comprises a diffusing means positioned between the light source (6) and the support (10), so as to standardize the polarization of the beam light (8) emitted by the light source (6).

8. Measuring device (2) according to one of the preceding claims, characterized in that it comprises means for moving the support (10) relative to the detection axis (18) of the detector, preferably preserving the value of the diffusion angle (a).

9. Measuring device (2) according to one of the preceding claims, characterized in that it comprises means for pivoting the optical detector (14) relative to the support (10), so as to modify the value of the scattering angle (a).

10. Measuring device (2) according to one of the preceding claims, characterized in that it comprises two mirrors in linear or angular oscillations, at frequencies greater than the inverse of the measurement time of the measurement unit ( 28), positioned in the path of the light beam between the light source (6) and the optical detector (14).

11. A method for measuring at least one irradiation dose absorbed by a dosimetric gel (4) using a measuring device (2) according to one of the preceding claims, implementing the following steps:

- positioning a dosimetric gel (4) on the support (10) so that the light beam (8) emitted by the light source (6) illuminates the dosimetric gel (4) at a first wavelength;

- Orienting the optical detector (14) so that its detection axis (18) passes through the dosimetric gel (4) and forms a diffusion angle (a) with the light beam (8);

determination by the measuring unit (28) of the light intensity observed by the optical detector (14);

modifying the polarization angle of the light beam (8) by means of the biasing means (22) and / or modifying the wavelength of the light beam (8);

- re-determination by the measuring unit (28) of the light intensity observed by the optical detector (14);

estimating by the calculation unit (30) the value of a ratio between the two intensities measured;

- Identification in a correspondence table by the calculation unit (30) of an irradiation dose absorbed by a dosimetric gel (4) from the value of the intensity ratio estimated by the calculation unit (30). ).

12. Method for measuring at least one dose of irradiation absorbed by a dosimetric gel (4) using a measuring device (2) according to one of claims 1 to 11, implementing the steps following: a) positioning a dosimetric gel (4) on the support (10) so that the light beam (8) emitted by the light source (6) illuminates the dosimetric gel (4) at a first wavelength;

b) orienting the optical detector (14) so that its detection axis (18) passes through the dosimetric gel (4) and forms a diffusion angle (a) with the light beam (8);

c) determining by the measuring unit (28) the light intensity observed by the optical detector (14);

d) changing the polarization angle of the light beam (8) by means of polarization means (22);

e) re-determination by the measuring unit (28) of the light intensity observed by the optical detector (14);

f) estimation by the computing unit (30) of the value of a ratio between the two measured intensities, called the polarization rate;

g) changing the value of the wavelength of the light beam (8) emitted by the light source and / or modifying the scattering angle (a);

i) modeling by the calculation unit (30) of a theoretical polarization rate as a function of the size of the diffusing structures present in the dosimetric gel;

j) identification by the computing unit (30) of a size of scattering structures present in each modeling theoretical polarization rates;

k) identification in a correspondence table by the calculation unit (30) of an irradiation dose absorbed by a dosimetric gel (4) from the value of the intensity ratio estimated by the calculation unit ( 30).

13. Measuring method according to claim 11 or 12, characterized in that the preceding steps are repeated for a dosimetric gel (4) irradiated at different and known doses, in order to establish a correspondence table.

Measuring method according to claim 11 to 13 with the aid of a measuring device (2) according to one of claims 4 to 10, characterized in that the diffusion angle (a) of the detector is modified. according to the wavelength range of the light beam (8) selected by a selection means (7).

15. Measuring method according to one of claims 11 to 14, characterized in that the support (10) is moved between each measurement series so as to obtain the irradiation doses absorbed by the dosimetric gel (4) in a plane in two dimensions, preferably in three dimensions.