KR102208647B1 - Dose Measurement Device for Brachytherapy - Google Patents

Abstract

According to the present invention, including a radiation irradiation unit installed inside at least one of the body units to irradiate radiation, and a dose measurement unit that measures the radiation dose irradiated from the radiation irradiation unit at a plurality of points, and Disclosed is a dose measuring device for brachytherapy capable of real-time measurement of a radiation dose that is irradiated in proximity to surrounding normal organs.

Description

Dose Measurement Device for Brachytherapy

The present invention relates to a dose measuring device for brachytherapy, and more particularly, to a dose measuring device capable of measuring a dose distribution of an irradiated radiation dose.

As radiotherapy methods for cancer patients, remote radiation therapy and brachytherapy are common. Here, the remote radiation treatment method is a treatment that removes cancer cells by irradiating the patient with radiation from the outside of the patient, and the proximity radiation treatment method removes cancer cells in the body by permanently/temporally inserting a radioactive isotope into the affected part of the patient's body. to be.

On the other hand, external radiation therapy using a linear accelerator is generally performed after confirming that the dose is correctly entered into the desired area for quality control of the patient's therapeutic dose before treatment. Likewise, in the case of brachytherapy in which a radioactive isotope is directly inserted into the human body, it is required not only to control the patient dose quality before treatment, but also to control the dose to confirm whether the correct dose was delivered during treatment.

However, in the case of brachytherapy, since the equipment for detecting the dose received by the patient is insufficient, independent dose management is difficult. Therefore, in order to accurately apply the radiation dose to the patient, the accuracy of radiation treatment and management will be improved through real-time dose measurement. You need skills to be able to.

The present invention is a dose measuring device for brachytherapy, a radiation irradiation unit installed inside at least one of the body units to irradiate radiation, and a dose measuring unit that measures the radiation dose irradiated from the radiation irradiation unit at a plurality of points. The purpose is to enable real-time measurement of the radiation dose to be irradiated in close proximity to the patient's lesions and surrounding normal organs, including.

In addition, there is another object to improve measurement accuracy through dose measurement for a plurality of points.

In addition, there is another object of improving the accuracy of radiation treatment and management through periodic measurement or before treatment in order to accurately apply the radiation dose to the patient.

Still other objects, not specified, of the present invention may be additionally considered within the range that can be easily deduced from the following detailed description and effects thereof.

In order to solve the above problem, a dose measuring device for brachytherapy according to an embodiment of the present invention provides a path for irradiating radiation, and an insertion unit including a plurality of body units having a hollow tubular shape, A radiation irradiation unit installed inside at least one of the body units to irradiate radiation, a dose measurement unit that measures the radiation dose irradiated from the radiation irradiation unit at a plurality of points, and the dose measurement unit is fixed to the body unit It includes a fixed unit.

Here, the dose measuring unit is provided in multiple rows and multiple layers in the longitudinal direction with respect to the path for irradiating the radiation of the body unit, and includes a plurality of scintillation counters to measure the dose of radiation irradiated from the irradiation unit. It includes a scintillation measuring unit and a dose detector located at a lower end of the scintillation measuring unit and detecting a dose of radiation irradiated from the radiation irradiation unit using a photosensitive film or a MOSFET detector.

Here, the fixing unit includes a plurality of fixing parts for fixing the posture of the dose measurement unit, and the plurality of fixing parts are stacked with the scintillation measurement part therebetween, and the plurality of fixing parts are spaced apart between the stacked structures. Including a space portion, the dose detection portion is placed in the spaced portion.

Here, the insertion unit is at least partially inserted into the body, the body unit includes a first body unit to a third body unit, the second body unit and the third body on both sides of the first body unit The first body unit is a structure in which a unit is inserted, and the first body unit is a straight line extending in a linear direction along the longitudinal direction of the tube shape or a bent type bent at least once along the longitudinal direction on one side of the tube shape inserted into the body Includes a contact tip is provided.

Here, the second body unit and the third body unit are a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a bent type bent at least once along the longitudinal direction on one side of the tubular shape inserted into the body And a touch tip provided as a touch tip and a touch block detachably fitted to one end of the touch tip and provided in a cylindrical or spherical shape to fix or support a position of the contact tip.

Here, the bent portion of the touch tip has an angle greater than that of the bent portion of the contact tip, and a length after the bent portion of the touch tip is shorter than a length after the bent portion of the contact tip.

Here, the scintillation measuring unit further comprises a plurality of scintillation supports formed of a flexible fiber material to connect each of the scintillation counters to one end and to be installed in a longitudinal direction with respect to the body unit, the scintillation support, At least a portion is bent in accordance with the bent portions of the first body unit to the third body unit.

Here, the body unit and the fixing unit are formed of at least one of metal, acrylic, and polycarbonate materials.

A dose measuring device for brachytherapy according to another embodiment of the present invention includes an applicator device for inserting an affected area for measuring a dose of the irradiated radiation by inserting it into an affected area to be treated for a preset time, and measuring the dose of the irradiated radiation. The insertion applicator device includes a measurement applicator device that is inserted into the surrounding tissue to measure the amount of radiation in the tissue located around the affected area, and the affected area insertion applicator device provides a path for irradiating radiation, An insertion unit including a plurality of body units having a hollow tubular shape, a radiation irradiation unit installed inside at least one of the body units to irradiate radiation, and the radiation dose irradiated from the radiation irradiation unit at a plurality of points. It includes a dose measuring unit to measure and a fixing unit fixing the dose measuring unit to the body unit.

Here, the applicator for measurement includes a tissue radiation dose measuring unit including a plurality of first scintillation counters to measure the radiation dose of the tissue around the affected part.

Here, the measuring applicator device includes a first measuring applicator device inserted into the urinary system tissue and the affected part insertion applicator device to measure the amount of radiation in the tissue located at the upper end of the affected part into which the affected part insertion applicator device is inserted. It includes a second measuring applicator device that is inserted into the rectal tissue to measure the radiation dose in the tissue located at the lower end of the inserted affected part.

Here, the dose measuring unit is provided in multiple rows and multiple layers in the longitudinal direction with respect to the path for irradiating the radiation of the body unit, and includes a plurality of second scintillation counters to measure the dose of the radiation irradiated from the radiation irradiation unit. It includes a scintillation measuring unit to measure and a dose detector located at a lower end of the scintillation measuring unit and detecting a dose of radiation irradiated from the radiation irradiation unit using a photosensitive film or a MOSFET detector.

Here, the fixing unit includes a plurality of fixing parts for fixing the posture of the dose measurement unit, and the plurality of fixing parts are stacked with the scintillation measurement part therebetween, and the plurality of fixing parts are spaced apart between the stacked structures. Including a space portion, the dose detection portion is placed in the spaced portion.

Here, the insertion unit is at least partially inserted into the body, the body unit includes a first body unit to a third body unit, the second body unit and the third body on both sides of the first body unit The first body unit is a structure in which a unit is inserted, and the first body unit is a straight line extending in a linear direction along the longitudinal direction of the tube shape or a bent type bent at least once along the longitudinal direction on one side of the tube shape inserted into the body Includes a contact tip is provided.

Here, the second body unit and the third body unit are a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a bent type bent at least once along the longitudinal direction on one side of the tubular shape inserted into the body And a touch tip provided as a touch tip and a touch block detachably fitted to one end of the touch tip and provided in a cylindrical or spherical shape to fix or support a position of the contact tip.

Here, the scintillation measuring unit further includes a plurality of scintillation supports formed of a flexible fiber material to connect each of the second scintillation counters to one end and to be installed in a longitudinal direction with respect to the body unit, and the scintillation support At least a portion is bent in accordance with the bent portions of the first to third body units.

Here, the body unit and the fixing unit are formed of at least one of metal, acrylic, and polycarbonate materials.

A dose measuring device for brachytherapy according to another embodiment of the present invention includes an applicator device for inserting an affected area for measuring a dose of the irradiated radiation by inserting it into an affected area to be treated for a predetermined time, and measuring the dose of the irradiated radiation. The dose of the irradiated radiation measured from the measuring applicator device and the applicator device for insertion of the affected area and the measurement applicator device for measuring the amount of radiation in the tissue located around the affected area where the insertion applicator device is inserted And a radiation control device for double-checking the radiation detection by using the radiation dose in the tissue located around the affected part, and controlling the amount of radiation irradiated to the affected part.

As described above, according to embodiments of the present invention, a radiation irradiation unit installed inside at least one of the body units to irradiate radiation, and a dose measuring radiation dose emitted from the radiation irradiation unit at a plurality of points. Including a measurement unit may enable real-time measurement of the amount of radiation irradiated to the patient's lesions and surrounding normal organs in close proximity.

In addition, measurement accuracy can be improved through dose measurement for a plurality of points.

In addition, in order to accurately apply the radiation dose to the patient, it is possible to improve the accuracy of radiation treatment and management before treatment or through periodic measurement.

Even if it is an effect not explicitly mentioned herein, the effect described in the following specification expected by the technical features of the present invention and the provisional effect thereof are treated as described in the specification of the present invention.

1 is a view showing the configuration of a dose measuring device for brachytherapy according to an embodiment of the present invention.
2 is a view showing a cross-section of a dose measuring device for brachytherapy according to an embodiment of the present invention.
3 is a diagram showing the structure of an insertion unit of a dose measuring device for brachytherapy according to an embodiment of the present invention.
4 is a view showing the interior of an applicator device for insertion of an affected part of a dose measuring device for brachytherapy according to an embodiment of the present invention.
5 is a diagram illustrating a dose detector of a dose measuring device for brachytherapy according to an embodiment of the present invention.
6 is a view showing the interior of an applicator device for measurement of a dose measuring device for brachytherapy according to an embodiment of the present invention.

Hereinafter, a dose measuring device for brachytherapy according to the present invention will be described in more detail with reference to the drawings. However, the present invention may be implemented in various different forms, and is not limited to the described embodiments. In addition, in order to clearly describe the present invention, parts irrelevant to the description are omitted, and the same reference numerals in the drawings indicate the same members.

The suffixes "module" and "unit" for components used in the following description are given or used interchangeably in consideration of only the ease of preparation of the specification, and do not have meanings or roles that are distinguished from each other by themselves.

The present invention relates to a dose measuring device for brachytherapy.

1 is a view showing the configuration of a dose measuring device for brachytherapy according to an embodiment of the present invention.

Referring to FIG. 1, a dose measuring device 1 for brachytherapy according to an embodiment of the present invention includes an applicator device 10 for insertion of an affected part, an applicator device 20 for measurement, and a radiation control device 30 do.

The dose measuring device 1 for brachytherapy is a treatment verification device that is inserted into a cavity structure of the human body and enables accurate measurement of the dose to be irradiated in proximity in real time. That is, it is a device that measures the dose of proximity radiation used to measure the radiation dose for quality control of brachytherapy radiation treatment.

The dose measuring device 1 for brachytherapy according to an embodiment of the present invention provides a measuring unit having a scintillation counter having three types that is inserted into the intracavity structure of the human body, so that it is applied to the lesion of the patient and the surrounding normal organs. Real-time measurement and evaluation of the radiation dose to be irradiated in close proximity is possible.

In addition, measurement accuracy can be improved through dose measurement for a plurality of points.

The applicator device 10 for insertion of the affected part is inserted into the affected part to be treated for a predetermined time and irradiated with radiation, and the dose of the irradiated radiation is measured.

The applicator device for insertion of an affected part capable of measuring a dose according to the present invention is divided into three types, and each type has a hollow tube shape in common.

It is possible to measure the radiation dose by using an applicator to irradiate radiation into the patient's body, so that it is possible to measure the radiation dose while performing the existing brachytherapy without additional equipment, which can contribute to the improvement of treatment quality.

The insertion unit 100 provides a path for irradiating radiation, and includes a plurality of body units having a hollow tubular shape. The plurality of body units may be provided as an assembly type, or may be provided integrally.

The insertion unit 100 is a body of an applicator that is inserted into a human body and applicable to brachytherapy in which radiation is irradiated.

The insertion unit 100 is illustrated as being formed of polycarbonate and acrylic materials. Due to these material characteristics, the insertion unit 100 is excellent in flexibility, insulation, fire extinguishing, acid resistance, impact resistance, and transparency when inserted into the interior of the human body.

The insertion unit 100 includes a first body unit 110, a second body unit 120, and a third body unit 130. The combination of the first body unit to the third body unit enables accurate measurement of the dose distribution that is closely irradiated using a tandem located in the center and an oboid-coupled applicator device located on both sides.

The insertion unit 100 is at least partially inserted into the body, and the second body unit 120 and the third body unit 130 are fitted on both sides of the first body unit 110.

The first body unit 110 is a contact provided on one side of a tubular shape 111 inserted into the body in a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a bent type bent at least once along the longitudinal direction Includes tip 112.

The second body unit 120 is a touch provided on one side of the tubular shape 121 inserted into the body in a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a bent type bent at least once along the longitudinal direction It includes a touch block 124 that is detachably fitted to one end of the tip and is provided in a cylindrical or spherical shape to fix or support the position of the contact tip.

The third body unit 130 is a touch provided on one side of the tubular shape 131 inserted into the body in a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a bent type bent at least once along the longitudinal direction It includes a touch block 134 that is detachably fitted to one end of the tip and is provided in the form of a cylinder or a sphere and provided to fix or support the position of the contact tip.

The scintillation measuring unit 310 is provided in multiple rows and multiple layers in the longitudinal direction with respect to the path for irradiating the radiation of the body unit, and includes a plurality of scintillation counters 311 and irradiated from the radiation irradiation unit. Measure the dose of radiation.

The measurement applicator device 20 is inserted into the surrounding tissue to measure the radiation dose in the tissue located around the affected area in which the affected area insertion applicator device is inserted.

The measurement applicator device 20 may include a scintillation fiber-optical fiber combination that can be inserted into a medical conduit and a rectum so as to measure the amount of radiation irradiated to surrounding normal organs.

The measurement applicator device 20 includes a tissue radiation dose measuring unit 530 including a plurality of first scintillation counters 531 to measure the radiation dose of the tissue around the affected area.

The measuring applicator device 20 includes a first measuring applicator device 21 inserted into the urinary system tissue to measure the amount of radiation in the tissue located at the upper end of the affected part into which the affected part insertion applicator device is inserted, and the affected part insertion applicator It includes a second measuring applicator device 22 that is inserted into the rectal tissue to measure the radiation dose in the tissue located at the lower end of the affected part where the device is inserted.

The first measurement applicator device 21 and the second measurement applicator device 22 are respectively located inside the first insertion unit 511 and the second insertion unit 521 corresponding to the body inserted into the affected part. It includes a scintillation counter 531.

In addition, the first measuring applicator device 21 and the second measuring applicator device 22 are provided with a first stopper 513 and a second stopper 523 on the outside, respectively, so that the position can be fixed after being inserted into the body. have.

Dose measurement in the normal long-term medical conduit and workplace is possible in real time, which can contribute to improvement of treatment quality and reduction of side effects.

The radiation control device 30 includes a control processor and a server to detect radiation using the dose of the irradiated radiation measured from the affected area insertion applicator device and the measurement applicator device and the radiation dose within the tissue located around the affected area. Is double-checked, and the amount of radiation irradiated to the affected area is adjusted.

By using a scintillation fiber as the main measurement device and inserting a radiation-sensitive film and a semiconductor sensor (MOSFET, etc.) for double verification, it is possible to perform independent measurement to increase precision.

Specifically, the radiation control device 30 is electrically connected to a tissue dose measurement unit including the dose measurement unit 300 of the applicator device 10 for insertion of the affected part and the first scintillation counter 531 of the applicator device 20 for measurement. It is connected to receive the radiation dose measured through the dose measurement unit 300 in real time, and it is possible to check the radiation dose in real time.

In addition, when the radiation dose is adjusted through the radiation control device 30, radiation is irradiated from the radiation source 34 through a connection part connected by wires 31, 32, and 33, respectively.

2 is a view showing a cross-section of a dose measuring device for brachytherapy according to an embodiment of the present invention.

Specifically, (a) of FIG. 2 is a cross-sectional view of the applicator device 10 for insertion of an affected part, and FIG. 2(b) is a side cross-sectional exploded view of the applicator device 10 for insertion of an affected part.

One tubular shape shown in FIG. 2 represents a part of an applicator device for inserting an affected part, and as shown in FIG. 3, at least three tubular units are assembled to constitute an applicator device for inserting an affected part.

2, the applicator device 10 for insertion of the affected part of the dose measuring device 1 for brachytherapy according to an embodiment of the present invention includes an insertion unit 100, a radiation irradiation unit 200, and a dose measurement It includes a unit 300 and a fixed unit 400.

The applicator device 10 for insertion of the affected part is inserted into the affected part to be treated for a predetermined time and irradiated with radiation, and the dose of the irradiated radiation is measured.

The insertion unit 100 provides a path for irradiating radiation, and includes a plurality of body units having a hollow tubular shape.

The radiation irradiation unit 200 is installed inside at least one of the body units to irradiate radiation. The radiation irradiation unit 200 may be inserted in the longitudinal direction along the central axis of the body unit.

In one embodiment of the present invention, it has been described that both the first body unit to the third body unit include the radiation irradiation unit 200, but the radiation irradiation unit 200 is located only in the first body unit to irradiate radiation. , The second body unit and the third body unit may be provided to measure the dose.

The dose measuring unit 300 measures the radiation dose irradiated from the radiation irradiation unit at a plurality of points.

The dose measuring unit 300 includes a scintillation measuring unit 310 and a dose detecting unit 320.

The scintillation measuring unit 310 is provided in multiple rows and layers with respect to the body unit in the longitudinal direction, and includes a plurality of scintillation counters 311 to measure the dose of radiation irradiated from the irradiation unit.

It is preferable that the scintillation measuring unit 310 has different lengths and is arranged in multiple rows in a spiral shape.

In addition, it is provided in a form that has different lengths and is wrapped around the radiation irradiation unit in a twisted shape, so that the dose can be measured at more various locations.

The dose measuring unit 300 is arranged in multiple layers and multiple rows to measure the radiation dose irradiated to the lesion at a plurality of points at the same time, which is advantageous in improving the reliability of treatment by accurate dose measurement.

The dose measuring unit 300 may measure the irradiation dose of the radiation source or the absorbed dose of the subject.

In addition, each of the scintillation counters 311 is connected to one end, and includes a plurality of scintillation supports 313 formed of a flexible fiber material so as to be installed in a longitudinal direction with respect to the body unit.

Each of the plurality of scintillation counters 311a, 311b, 311c, 311d, and 311e is arranged in multiple layers, and is arranged in a position that deviates from each other, so that the radiation dose irradiated to the lesion can be simultaneously measured at a plurality of points.

In addition, each of the plurality of scintillation counters is connected to one end of the plurality of scintillation supports 313a, 313b, 313c, 313d, and 313e.

The dose detection unit 320 is located at the lower end of the scintillation measuring unit, and detects the dose of radiation irradiated from the radiation irradiation unit using a photosensitive film or a MOSFET detector.

Here, the scintillation measurement unit 310 is a measurement unit including a scintillation fiber and an optical fiber, and the dose detection unit 320 is inserted into a radiation-sensitive film to independently verify the dose.

Since the dose detection unit 320 can verify and compare the dose using a photosensitive film, which is a third means, independently of the measuring device of the scintillation fiber-optical fiber combination, more accurate treatment verification is possible.

By measuring the radiation dose irradiated from the radiation irradiation unit by the dose measuring unit 300 having a scintillation counter provided in a body unit that can be inserted into the human body, accurate measurement of the radiation dose directly applied to the lesion of the patient becomes possible.

The dose detector is placed in the spaced space, including a spaced space between a structure in which a plurality of fixing parts are stacked. In the conventional case, the dose is detected using only a scintillation measuring unit equipped with a scintillation counter, but according to an embodiment of the present invention, it is possible to detect the dose by a combination of other methods including a dose detector between spaced apart spaces. The dose can be detected from any position on the applicator.

The dose detection unit 320 may be made of a flexible material so as to be placed in a curved structure between spaced spaces.

The fixing unit 400 fixes the dose measuring unit to the body unit.

The fixing unit 400 includes a plurality of fixing parts 410 and 420 for fixing the posture of the dose measuring unit, and the plurality of fixing parts are stacked with the scintillation measuring part therebetween, and the plurality of fixing parts are stacked. Including a spaced space between the, the dose detection unit is placed in the spaced space.

Here, the number of the plurality of fixing parts is not limited to the illustrated example.

Specifically, the dose detection unit 320 is positioned in close contact between the first fixing unit 410 and the second fixing unit 420, and the second fixing unit 420 locates the radiation irradiation unit in the center.

The first fixing part 410 and the second fixing part 420 are detachable and can be assembled, and the first fixing part includes a hemispherical shape 413, and both sides to fix the second fixing part 420 It includes a fixing part 411 on.

The second fixing portion has a stepped portion and includes a fitting portion 421 so as to be inserted and fitted inside the first fixing portion.

The fixing parts 410 and 420 correspond to the shapes of the body units having a cylindrical tubular shape, and each has a cylindrical tubular shape. In addition, it has a bent tubular shape corresponding to the shape of each of the body units extending by bending each other.

Since the fixing unit is formed of at least one of polycarbonate and acrylic materials, it is possible to prevent interference with radiation irradiation and dose measurement.

The insertion unit 100 and the fixing unit 400 are preferably formed of at least one of metal, acrylic, and polycarbonate materials.

Here, the scintillation counters have a length L1 of 1mm to 3mm, respectively, and in each arrangement, the scintillation counters are disposed so as to be pushed by 2mm to 6mm (L2), respectively, as the scintillation counters are positioned to be offset.

It is preferable that the width W1 of the radiation irradiation unit is 1 mm to 3 mm. It is preferable that the width W2 up to the second fixing portion 420 is 5mm to 7mm.

It is preferable that the width of the space in which the scintillation measurement unit is located and the width W3 of the spaced space in which the dose detection unit is placed are 0.5mm to 2mm. It is preferable that the width W4 to the portion where the dose measuring unit is fixed is 6mm to 8mm. It is preferable that the width W5 of each of the body units is 9mm to 11mm.

It is preferable that the width W6 from the radiation irradiation unit to the scintillation measurement unit is 1 mm to 4 mm, and the width W7 from the dose detection unit is 1 mm to 4 mm.

In addition, it is preferable that the step W8 is 1 mm to 3 mm.

3 is a view showing the structure of an insertion unit of a dose measuring device for brachytherapy according to an embodiment of the present invention.

3, the insertion unit 100 of the dose measuring device 1 for brachytherapy according to an embodiment of the present invention includes a first body unit 110, a second body unit 120, and a third It includes a body unit 130.

The insertion unit 100 provides a path for irradiating radiation, and includes a plurality of body units having a hollow tubular shape.

The insertion unit 100 is at least partially inserted into the body, and the second body unit 120 and the third body unit 130 are fitted on both sides of the first body unit 110.

The first body unit 110 is a contact provided on one side of a tubular shape 111 inserted into the body in a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a bent type bent at least once along the longitudinal direction Includes tip 112.

The second body unit 120 is a touch provided on one side of the tubular shape 121 inserted into the body in a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a bent type bent at least once along the longitudinal direction It includes a tip 122 and a touch block 124 that is detachably fitted to one end of the touch tip and is provided in a cylindrical or spherical shape to fix or support a position of the contact tip.

The third body unit 130 is a touch provided on one side of the tubular shape 131 inserted into the body in a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a bent type bent at least once along the longitudinal direction It includes a tip 132 and a touch block 134 that is detachably fitted to one end of the touch tip and is provided in a cylindrical or spherical shape and provided to fix or support the position of the contact tip.

It is preferable that the second body unit 120 and the third body unit 130 are provided in a similar shape.

The first body unit 110 includes a central coupling portion 115, and the second body unit 120 and the third body unit 130 each have a first outer coupling portion 125 and a second outer coupling portion ( 135).

The central coupling portion 115 includes a first hole on the inside, and the first outer coupling portion 125 and the second outer coupling portion 135 form a second hole upon coupling, thereby fastening the fastening member 117 According to this, the first hole and the second hole are placed on the same axis and assembled.

Accordingly, the first body unit 110, the second body unit 120, and the third body unit 130 are assembled by forming a height difference.

The combination of the first body unit to the third body unit makes it possible to accurately measure the dose distribution that is irradiated in close proximity using a tandem and oboid coupling type applicator device.

4 is a view showing the interior of an applicator device for insertion of an affected part of a dose measuring device for brachytherapy according to an embodiment of the present invention.

4, the applicator device 10 for insertion of the affected part of the dose measuring device 1 for brachytherapy according to an embodiment of the present invention includes an insertion unit 100, a radiation irradiation unit 200, and a dose measurement It includes a unit 300 and a fixed unit 400.

4(a) shows the inside of the first body unit 110, and FIG. 4(b) shows the inside of the second body unit 120.

The insertion unit 100 provides a path for irradiating radiation, and includes a plurality of body units having a hollow tubular shape.

The insertion unit 100 is at least partially inserted into the body, and the second body unit 120 and the third body unit 130 are fitted on both sides of the first body unit 110.

The first body unit 110 is a contact provided on one side of a tubular shape 111 inserted into the body in a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a bent type bent at least once along the longitudinal direction Includes tip 112.

The first body unit 110 includes a first lead 113 having a hemispherical shape, and the second body unit 120 includes a second lead 123 having a hemispherical shape.

The first lead 113 and the second lead 123 have a hemispherical shape and are coupled to a portion inserted into the human body, and seal the inside of the first body unit and the second body unit.

The first lead 113 and the second lead 123 can be sealed so that the radiation irradiation unit 200 does not deviate in the direction in which the body unit is inserted into the body, and by having a hemispherical shape, it is smooth without friction inside the human body. Guide the body unit to be inserted.

The second body unit 120 is a touch provided on one side of the tubular shape 121 inserted into the body in a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a bent type bent at least once along the longitudinal direction It includes a tip 122 and a touch block 124 that is detachably fitted to one end of the touch tip and is provided in a cylindrical or spherical shape to fix or support a position of the contact tip.

Here, the bent portion A2 of the touch tip 122 has an angle greater than that of the bent portion A1 of the contact tip 112, and a length L5 after the bent portion of the touch tip is the contact tip It is preferably shorter than the length (L3) after the bent portion of. Here, it is preferable that the length L5 after the bent portion of the touch tip is 2 to 4 cm, and the length L3 after the bent portion of the contact tip is 5 to 7 cm.

In addition, the tubular length (L4) of the first body unit and the tubular length (L6) of the second body unit are preferably the same, preferably 15 to 25mm.

The radiation irradiation unit 200 is installed inside the body unit to irradiate radiation.

The radiation irradiation unit 200 may be inserted in the longitudinal direction along the central axis of the body unit. That is, it is provided inside the body unit so as to be parallel to the direction in which the insertion unit 100 is inserted into the human body to irradiate radiation. At this time, the radiation irradiation unit 200 is inserted along the central axis of the body unit, and is sealed inside the body unit by the first lead 113 and the second lead 123.

The dose measuring unit 300 measures the radiation dose irradiated from the radiation irradiation unit at a plurality of points.

The dose measuring unit 300 includes a scintillation measuring unit 310 and a dose detecting unit 320.

The scintillation measuring unit 310 is provided in multiple rows and layers with respect to the body unit in the longitudinal direction, and includes a plurality of scintillation counters 311 to measure the dose of radiation irradiated from the irradiation unit.

In addition, each of the scintillation counters 311 is connected to one end, and includes a plurality of scintillation supports 313 formed of a flexible fiber material so as to be installed in a longitudinal direction with respect to the body unit.

At least a portion of the scintillation support 313 is bent in accordance with the bent portions of the first body unit to the third body unit.

5 is a view showing a dose detector of a dose measuring device for brachytherapy according to an embodiment of the present invention.

The dose detection unit 320 is located at the lower end of the scintillation measuring unit, and detects the dose of radiation irradiated from the radiation irradiation unit using a photosensitive film or a MOSFET detector.

Since the dose detection unit 320 can verify and compare the dose using a photosensitive film, which is a third means, independently of the measuring device of the scintillation fiber-optical fiber combination, more accurate treatment verification is possible.

In the conventional case, the dose is detected using only a scintillation measuring unit equipped with a scintillation counter, but according to an embodiment of the present invention, it is possible to detect the dose by a combination of other methods including a dose detector between spaced apart spaces. The dose can be detected from any position on the applicator.

FIG. 5A shows a photosensitive film, FIG. 5B shows a MOSFET detection unit, and FIG. 5C shows a TLD detection unit.

In the embodiment according to (a) of FIG. 5, the photosensitive film portion 321 is located between the spaced space portions, and the distribution of the irradiation dose is obtained.

It is preferable that the photosensitive film part 530 inserts a radiation photosensitive film (eg, EBT3). Side effects from radiation exposure can be checked, exposure dose can be checked according to whether the film is discolored, and radiation dose can be controlled.

The photosensitive film part 530 has excellent spatial resolution, can measure relative dose, and can analyze the exposure amount 8 hours after irradiation.

In the embodiment according to (a) of Figure 5, the MOSFET (MOSFET) detection unit 323 inserts a MOSFET (Metal Oxide Field Effect Transistor) dosimeter 322 measuring the irradiation dose at the top.

In the embodiment according to (c) of FIG. 5, the TLD detection unit 324 inserts a Thermoluminescence Dosimeter (TLD) dosimeter 326 into each of the spaces 325 covered by zones. As the dosimeter is located for each area, it is possible to check the dose distribution according to the location, and it is provided to be bent in the spaced apart.

In addition, a photosensitive film, a MOSFET detection unit, and a TLD detection unit may be arranged in combination according to the amount of radiation to be detected.

In addition, it can be employed as one of various dosimeters capable of measuring radiation dose, such as an OSLD (Optically Stimulated Luminescence Dosimeter) dosimeter.

6 is a view showing the interior of an applicator device for measurement of a dose measuring device for brachytherapy according to an embodiment of the present invention.

6(a) shows the inside of the first measurement applicator device 21, and FIG. 6(b) shows the inside of the second measurement applicator device 22.

The measurement applicator device 20 is inserted into the surrounding tissue to measure the radiation dose in the tissue located around the affected area in which the affected area insertion applicator device is inserted.

The measurement applicator device 20 may include a scintillation fiber-optical fiber combination that can be inserted into a medical conduit and a rectum so as to measure the amount of radiation irradiated to surrounding normal organs.

The measuring applicator device 20 includes a first measuring applicator device 21 inserted into the urinary system tissue to measure the amount of radiation in the tissue located at the upper end of the affected part into which the affected part insertion applicator device is inserted, and the affected part insertion applicator It includes a second measuring applicator device 22 that is inserted into the rectal tissue to measure the radiation dose in the tissue located at the lower end of the affected part where the device is inserted.

The first measurement applicator device 21 and the second measurement applicator device 22 are respectively provided on the inside of the first insertion unit 511 and the second insertion unit 521 corresponding to the body inserted into the affected part. It includes a tissue radiation dose measuring unit 530 that measures the radiation dose of the tissue around the affected part, including first scintillation counters 531.

The tissue radiation dose measuring unit 530 is provided in multiple rows and multiple layers in the longitudinal direction of the body unit, and includes a plurality of first scintillation counters 531 to measure the dose of radiation irradiated from the irradiation unit. In addition, a plurality of scintillations formed of a flexible fiber material to be connected to each of the first scintillation counters 531 to one end and installed in the longitudinal direction with respect to the first and second insertion units 511 and 521 It includes supports 533.

In addition, the first measuring applicator device 21 and the second measuring applicator device 22 are provided with a first stopper 513 and a second stopper 523 on the outside, respectively, so that the position can be fixed after being inserted into the body. And a third lead 512 and a fourth lead 522 having a hemispherical shape, respectively.

Dose measurement in the normal long-term medical conduit and workplace is possible in real time, which can contribute to improvement of treatment quality and reduction of side effects.

The above description is only an embodiment of the present invention, and those of ordinary skill in the technical field to which the present invention pertains may be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the scope of the present invention is not limited to the above-described embodiments, and should be construed to include various embodiments within the scope equivalent to those described in the claims.

1: Dosage measuring device for brachytherapy
10: Applicator device for insertion of the affected part
20: measurement applicator device
30: radiation control device
100: insertion unit
200: irradiation unit
300: dose measurement unit
400: fixed unit

Claims (18)

delete delete delete delete delete delete delete delete An applicator device for inserting the affected part for irradiating the radiation by inserting it into the affected part to be treated for a predetermined time and measuring a dose of the irradiated radiation; And
Includes; a measurement applicator device inserted into the surrounding tissue to measure the radiation dose in the tissue located around the affected area where the affected part insertion applicator device is inserted,
The applicator device for inserting the affected part,
An insertion unit that provides a path for irradiating radiation and includes a plurality of body units having a hollow tubular shape;
A radiation irradiation unit installed inside at least one of the body units to irradiate radiation;
A dose measurement unit that measures the radiation dose irradiated from the radiation irradiation unit at a plurality of points; And
Including; a fixed unit for fixing the dose measurement unit to the body unit,
The measurement applicator device,
Includes; a tissue radiation dose measuring unit configured to measure the radiation dose of the tissue surrounding the affected part, including a plurality of first scintillation counters,
The measurement applicator device,
A first measuring applicator device inserted into the urinary system tissue to measure the amount of radiation in the tissue located at the upper end of the affected part into which the affected part insertion applicator device is inserted; And
And a second measuring applicator device inserted into the rectal tissue to measure the radiation dose in the tissue located at the lower end of the affected part in which the affected part insertion applicator device is inserted. delete The method of claim 9,
The dose measuring unit,
A scintillation measuring unit provided in multiple rows and multiple layers in a longitudinal direction with respect to a path for irradiating radiation of the body unit, including a plurality of second scintillation counters, to measure a dose of radiation irradiated from the irradiation unit; And
And a dose detector positioned at a lower end of the scintillation measuring unit and configured to detect a dose of radiation irradiated from the radiation irradiation unit using a photosensitive film or a MOSFET detector. The method of claim 11,
The fixing unit,
And a plurality of fixing portions for fixing the posture of the dose measuring unit, and the plurality of fixing portions are stacked with the scintillation measuring portion therebetween, and including a spaced space portion between the stacked structures of the plurality of fixing portions The dose measuring device, characterized in that the dose detector is placed in the space part. The method of claim 11,
The insertion unit is at least partially inserted into the body,
The body unit includes a first body unit to a third body unit, and has a structure in which the second body unit and the third body unit are fitted on both sides of the first body unit,
The first body unit,
And a contact tip provided on one side of the tubular shape inserted into the body in a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a contact tip bent at least once bent along the longitudinal direction. Measuring device. The method of claim 13,
The second body unit and the third body unit,
A touch tip provided on one side of the tubular shape inserted into the body in a straight line extending in a linear direction along the longitudinal direction of the tubular shape or a bent type bent at least once along the longitudinal direction; And
And a touch block detachably fitted to one end of the touch tip and provided in the shape of a cylinder or a sphere to fix or support the position of the contact tip. The method of claim 14,
The bent portion of the touch tip has an angle greater than that of the bent portion of the contact tip, and a length after the bent portion of the touch tip is shorter than a length after the bent portion of the contact tip . The method of claim 14,
The scintillation measuring unit,
The second scintillation counter is connected to one end, and a plurality of scintillation supports formed of a flexible fiber material so as to be installed in a longitudinal direction with respect to the body unit; further includes,
The scintillation support,
Dose measurement device, characterized in that at least a portion is bent in accordance with the bent portion of the first body unit to the third body unit. The method of claim 9,
The body unit and the fixing unit is a dose measuring device, characterized in that formed of at least one of metal, acrylic, and polycarbonate material. An applicator device for inserting the affected part for irradiating the radiation by inserting it into the affected part to be treated for a predetermined time and measuring a dose of the irradiated radiation;
A measurement applicator device inserted into the surrounding tissues to measure the radiation dose in the tissue located around the affected area in which the affected area insertion applicator device is inserted; And
Using the dose of the irradiated radiation measured from the affected part insertion applicator device and the measuring applicator device and the amount of radiation in the tissue located around the affected part, radiation detection is double-checked, and the amount of radiation irradiated to the affected part is adjusted. Including; radiation control device;
The applicator device for inserting the affected part,
An insertion unit that provides a path for irradiating radiation and includes a plurality of body units having a hollow tubular shape;
A radiation irradiation unit installed inside at least one of the body units to irradiate radiation;
A dose measurement unit that measures the radiation dose irradiated from the radiation irradiation unit at a plurality of points; And
Including; a fixed unit for fixing the dose measurement unit to the body unit,
The measurement applicator device,
Includes; a tissue radiation dose measuring unit configured to measure the radiation dose of the tissue surrounding the affected part, including a plurality of first scintillation counters,
The measurement applicator device,
A first measuring applicator device inserted into the urinary system tissue to measure the amount of radiation in the tissue located at the upper end of the affected part into which the affected part insertion applicator device is inserted; And
And a second measuring applicator device inserted into the rectal tissue to measure the radiation dose in the tissue located at the lower end of the affected part in which the affected part insertion applicator device is inserted.

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