JP4664661B2 - Radiation therapy management system - Google Patents

Description

  The present invention relates to a radiotherapy management system that manages information related to radiotherapy for performing treatment by irradiating radiation toward an affected area, and particularly relates to a technique for preventing over- and under-irradiation during radiation irradiation.

  Radiotherapy has been widely practiced as a suitable treatment for tumors in subjects. In radiation therapy, the affected area is generally irradiated in multiple portions, and the total dose and each dose depend on various factors such as the affected area and condition, and the patient's age. Determined. Here, the position, state, and the like of the affected part are usually grasped by referring to an image captured in advance by an image diagnostic apparatus such as an X-ray CT apparatus.

  In consideration of both the effect of radiation therapy and patient safety, the total irradiation dose and the value of each irradiation dose need to be determined accurately. Therefore, in radiotherapy, prior to actual treatment, a doctor creates a treatment plan and performs treatment according to the treatment plan.

  Patent Documents 1 and 2 below disclose conventional methods for creating a treatment plan in radiation therapy.

  The radiotherapy planning method described in Patent Document 1 is intended to plan an appropriate prescription condition according to the individual situation of an affected area, and the configuration thereof is applied to each affected area in a subject and radiation irradiation. Set the target prescription dose of irradiation radiation for each unnecessary risk organ, prioritize the prescription of radiation irradiation to the affected area and risk organ, and select the higher priority based on the priority for the area where the affected area or risk organ overlaps Select the target prescription dose, calculate the irradiation dose distribution to the affected area using the inverse plan method based on the set target prescription dose or the selected target prescription dose, and for each affected area and risk organ based on this irradiation dose distribution Calculate the prescription dose of irradiation radiation every time, calculate the evaluation function value that represents the difference between the target prescription dose and the calculated prescription dose, and irradiate the affected area so that this evaluation function value is less than the predetermined value To correct amount distribution, there is a thing.

  In the planning method of this patent document 1, the setting process of the target prescription dose and the prioritization process for the affected part and the risk organ are performed based on the experience of the doctor who is the plan creator. For this reason, since the doctor himself / herself also determines the total irradiation dose and each irradiation dose, there is a possibility that errors based on human factors such as careless mistakes and assumptions may occur.

  Thus, in the method of the literature, since it is not possible to objectively determine the appropriateness of the irradiation dose in creating a treatment plan, it is considered difficult to reliably ensure both the treatment effect and safety. . In addition, since such a mistake is an accidental thing which arises even if it pays attention, it seems that it is difficult to avoid it artificially.

  Furthermore, considering that the actual treatment is performed by a radiation therapy engineer and there are many cases where the doctor is not at the treatment site, there is a possibility that a communication error, etc. may occur between the doctor and the engineer. May even lead to an irradiation accident. Therefore, it can be said that it is difficult to sufficiently ensure the therapeutic effect and safety (particularly the latter) not only at the time of treatment planning but also at the time of treatment.

  In addition, the method described in Patent Document 2 is intended to set an irradiation dose according to prescription data of a dose prescribed by a doctor, and is absorbed in the body with respect to radiation irradiated from each gate toward the target. Calculate the dose distribution, and at least the prescription dose prescribed for the target, prescription data with restricted dose and overdose volume fraction for the attention organ, the ratio of the radiation dose of radiation radiated from each gate to the target, The first evaluation value for the prescription data for the attention organ is calculated based on the absorbed body dose distribution calculated by the absorbed dose distribution calculating means, and the ratio of the irradiation dose at which the first evaluation value satisfies the predetermined condition A value obtained by multiplying the sum of the calculated dose ratio of each gate and the absorbed dose distribution in each gate by the scaling parameter, and prescription data And calculating a second evaluation value for the prescription data for the target and the attention organ, calculating a scaling parameter for which the second evaluation value satisfies a predetermined condition, and calculating at least the calculated scaling parameter, An irradiation dose satisfying the prescription data is obtained by determining the irradiation dose value of each gate based on the ratio of the irradiation dose of the gate and the body absorbed dose distribution for each gate.

  In addition, as the above prescription data, the reference coordinates in the target, prescription dose, maximum dose, minimum dose, underdose volume rate, restricted dose, maximum dose, overdose volume rate, constraints indicating importance for each target and attention organ The weights are listed in that document.

  Since the method shown in Patent Document 2 is configured to match the actual irradiation dose with the prescription data determined by the doctor, when an incorrect prescription data is input, an appropriate treatment plan is created. It was not possible, and as a result, there was a possibility that the therapeutic effect and safety could be problematic. Moreover, it was difficult to suppress an irradiation accident caused by a communication error between a doctor and an engineer.

  By the way, a system for improving the therapeutic effect and safety of radiotherapy is often used in a medical institution such as a large-scale hospital that has sufficient economic margin because of its high introduction cost and running cost. It was a part. However, since such devices and systems contribute to the extremely important matter of “patient safety”, it is considered that they should be operated in many medical institutions.

JP 2003-70921 A JP 2000-70389 A

  The present invention has been made in view of such circumstances, and it is possible to objectively determine the appropriateness of a treatment plan created by a doctor and to carry out radiation therapy in consideration of both treatment effect and safety. An object is to provide a possible radiotherapy management system.

  Another object of the present invention is to provide a radiation therapy management system capable of improving safety by avoiding an irradiation accident caused by a communication error between a doctor and a radiographer. .

  In addition, the present invention provides a radiation therapy management system capable of reducing the cost on the client side for radiation therapy management by providing the radiation therapy management service through the network, thereby promoting the use of the system. This is another purpose.

In order to achieve the above object, the invention according to claim 1 includes a plan input unit for inputting a radiotherapy treatment plan for irradiating the affected area a plurality of times, and a plan storage unit for storing the treatment plan. The plan decision factor information of the radiotherapy treatment plan carried out in the past and the irradiation dose information of each irradiation in the past radiotherapy are input by the plan input unit and the accumulation means for accumulating the information in association with each other. Based on the plan determination factor information of the new treatment plan, the plan determination factor information of the radiation treatment treatment plan performed in the past is searched from the storage means, and the treatment plan of the radiation treatment performed in the past is retrieved. based the dose information associated with planning determinant information and the first search means for search, to said past the dose information retrieved by the first retrieval means Te, determines whether the allowable range calculation means for calculating the allowable range of the total irradiation dose in the new treatment regimen, the allowable range the total irradiation dose of a new treatment plan calculated by the calculating means is included in the allowable range a planned dose determining means for, characterized in that it comprises a.

  The invention according to claim 2 is the radiation therapy management system according to claim 1, wherein when the total dose is not included in the allowable range by the planned dose determination means, A plan correction requesting means for requesting correction of the new treatment plan is provided.

  The invention according to claim 3 is the radiation therapy management system according to claim 1 or 2, wherein the allowable range calculation means calculates the irradiation dose indicated in the searched irradiation dose information. A total irradiation dose for each radiotherapy is calculated for each past radiotherapy, and the allowable range is calculated based on the calculated total irradiation dose for each radiotherapy. To do.

  The invention according to claim 4 is the radiotherapy management system according to claim 3, wherein the allowable range calculation means calculates an average value of the calculated total irradiation doses of the respective radiotherapy. The allowable range including the average value is calculated.

  The invention according to claim 5 is the radiation therapy management system according to any one of claims 1 to 4, wherein a plurality of plan determination factors relating to determination of a treatment plan are stored in advance. Storage setting means, operating means, and factor setting means for setting a plan determining factor selected by the operating means from among the plurality of stored plan determining factors as a management determining factor to be applied to radiation therapy management The first search means searches for the irradiation dose information from the storage means using the plan decision factor information about the management decision factor as a search condition.

Further, the invention according to claim 6 is a server, connected to the server through a network, and stores a plan input means for inputting a radiotherapy treatment plan for irradiating the affected area a plurality of times, and the treatment plan. A radiation treatment management system comprising: a client having a plan storage means for performing a radiation treatment treatment plan plan determination factor information of a radiation treatment performed in the past, and each irradiation in the past radiation treatment. The past dose determination information of the treatment plan corresponding to the plan decision factor information of the new treatment plan inputted by the plan input means of the client; A first search means for searching the irradiation dose information associated with the storage means from the storage means, and the searched past information. Based on dose information, an allowable range calculation means for calculating an allowable range of the total irradiation dose of the new treatment plan, and a planned dose determination means for determining whether the total irradiation dose of the new treatment plan is included in the allowable range It comprises, when it is characterized.

  The invention according to claim 7 is the radiation therapy management system according to claim 6, wherein the server determines that the total irradiation dose is not included in the allowable range by the planned dose determination means. And a plan correction requesting means for requesting correction of the new treatment plan.

  According to an eighth aspect of the present invention, there is provided a plan storing means for storing a radiation treatment treatment plan for irradiating an affected area a plurality of times, and an irradiation control means for controlling a radiation irradiation apparatus for irradiating the radiation. A radiotherapy management system having storage means for accumulating irradiation dose information in radiation irradiation performed in the past by the radiation irradiation device, and before the current irradiation by the radiation irradiation device, in the current irradiation A second retrieval unit that retrieves the irradiation dose information in the past irradiation based on the treatment plan including the current irradiation, from the storage unit; The accumulated dose up to the current irradiation is calculated by adding the set value of the irradiation dose for the current time and the searched information on the past irradiation dose. Cumulative dose calculation means, and cumulative dose determination means for determining whether the calculated cumulative dose exceeds a predetermined value, wherein the irradiation control means is configured so that the cumulative dose does not exceed the predetermined value. When the determination is made, the radiation irradiation apparatus is caused to perform the current irradiation.

  The invention according to claim 9 is the radiation therapy management system according to claim 8, wherein when the cumulative dose is determined to be greater than the predetermined value by the cumulative dose determination means, An irradiation dose correction requesting means for requesting correction of the irradiation dose at this time is provided.

  The invention according to claim 10 is the radiotherapy management system according to claim 8 or claim 9, wherein the cumulative dose is determined to be greater than the predetermined value by the cumulative dose determination means. In some cases, an irradiation prohibiting processing means for prohibiting the irradiation of radiation by the radiation irradiation apparatus is provided.

  The invention according to claim 11 is the radiotherapy management system according to claim 10, wherein when the cumulative dose is determined to be greater than the predetermined value by the cumulative dose determination unit, the system is predetermined. Means for transmitting a message requesting the input of the password to a predetermined doctor terminal, and the irradiation prohibition processing means cancels the prohibition of the irradiation of the radiation when the password is input. To do.

  The invention according to claim 12 is the radiotherapy management system according to claim 8, wherein the dose of the current irradiation performed by the radiotherapy apparatus is stored as the dose information. It is further characterized by further comprising means for accumulating.

  The invention according to claim 13 is a server, connected to the server through a network, and a plan storage means for storing a radiation treatment treatment plan for irradiating the affected area a plurality of times, and a radiation for irradiating the radiation. A radiation treatment management system including a client having an irradiation control means for controlling the irradiation apparatus, wherein the client sets the irradiation dose in the current irradiation before the current irradiation by the radiation irradiation apparatus. The server includes an irradiation dose acquisition means for acquiring the irradiation dose information in the radiation irradiation performed in the past by the radiation irradiation device, and a past based on the treatment plan including the current irradiation. Second search means for searching the irradiation dose information in irradiation from the storage means; and the irradiation line of the client A cumulative dose calculating means for calculating a cumulative dose until the current irradiation by adding the set value of the current irradiation dose acquired by the acquiring means and the searched irradiation dose information in the past; A cumulative dose determining means for determining whether the calculated cumulative dose exceeds a predetermined value, wherein the irradiation control means of the client is configured such that the cumulative dose is determined by the cumulative dose determining means of the server. When it is determined that the value is not exceeded, the radiation irradiation apparatus is caused to perform the current irradiation.

  The invention according to claim 14 is the radiation therapy management system according to claim 13, wherein the server determines that the accumulated dose exceeds the predetermined value by the accumulated dose determining means. In some cases, there is provided irradiation dose correction requesting means for requesting correction of the current irradiation dose.

  According to the present invention described in each of claims 1 to 7, the allowable range of the total irradiation dose of the new treatment plan is calculated based on the past irradiation dose information corresponding to the newly inputted treatment plan. In addition, when the total irradiation dose is included in the allowable range, the new treatment plan is stored. Therefore, the validity of the treatment plan created by the doctor can be determined by the allowable range obtained from the past data. Here, the total irradiation dose of the treatment plan is a value that is larger than the lower limit of the permissible range, so that the therapeutic effect is taken into account. Sex is also considered.

  Further, according to the present invention described in each of claims 8 to 14, the cumulative dose until the current irradiation is calculated immediately before the radiation irradiation, and the cumulative dose does not exceed a predetermined value. Control is performed so that the current irradiation can be performed. Therefore, it is possible to confirm the suitability of the set value of the current irradiation dose immediately before the radiation engineer performs the irradiation. Therefore, it is possible to avoid an irradiation accident caused by a communication error between a doctor and a radiographer, and to improve the safety of radiation therapy.

  In addition, according to the present invention described in claim 6 or claim 7, since the server on the network executes the process of determining the suitability of the total irradiation dose of the newly inputted treatment plan. The function on the client side installed on the medical institution side can be simplified. Furthermore, according to this server, a radiation therapy management service can be provided to a plurality of medical institutions at a time. Therefore, the cost borne by each medical institution can be reduced, and the use promotion of the system can be expected.

  According to the present invention as set forth in claim 13 or claim 14, since the server on the network executes the process of determining the suitability of the irradiation dose at the time of radiation irradiation, it is installed on the medical institution side. The client side functions can be simplified. Furthermore, according to this server, a radiation therapy management service can be provided to a plurality of medical institutions at a time. Therefore, the cost borne by each medical institution can be reduced, and the use promotion of the system can be expected.

  An example of a preferred embodiment of the present invention will be described in detail with reference to the drawings.

  Hereinafter, first and second embodiments of the present invention will be described. The first embodiment relates to the present invention when a local network such as a hospital LAN is used. On the other hand, the second embodiment relates to a configuration in which a part of the processing according to the present invention is performed by a server on the WAN using a wide area network (WAN) such as the Internet.

<First Embodiment>
A first embodiment of a radiation therapy management system according to the present invention is configured as a part of a radiation therapy system as shown in FIG. The radiation therapy system is a system for performing a series of treatments from diagnosis to radiation irradiation for creating a treatment plan.

  An outline of the flow of radiation therapy is shown in FIG. In radiation therapy, before actually irradiating radiation, the affected part is diagnosed by referring to an image taken by an image diagnostic apparatus (S101). Then, a treatment plan including the irradiation dose for each time is created and input to the system (S102). The treatment plan is, for example, “total 30 times from Monday to Friday over 6 weeks, total irradiation dose 60 Gy (gray), 2 Gy daily”. Actual radiotherapy is performed according to the treatment plan. That is, the irradiation is repeated until the number of irradiations in the treatment plan is reached, and the treatment ends (S103, 104).

  The treatment plan is determined by a doctor in consideration of various factors. The determinants include, for example, the patient's age, primary site, treatment site, pathological tissue, radiation irradiation level, radiation irradiation method (opposite 2 gates, 4 opposing gates, etc.), focal depth, presence or absence of double cancer, and Degree of overlap, type of treatment (fresh, relapse, isolated metastasis, etc.), treatment policy (symptomatic treatment, palliative treatment, semi-radical treatment, etc.), treatment method (radiation alone, combined use of surgery and radiation, etc.), etc. There is. Hereinafter, these will be referred to as “plan determining factors”. The “plan determining factor” includes at least one of the factors listed above.

[overall structure]
Now, the configuration of the present embodiment shown in FIG. 1 will be described. The radiotherapy system 1000 manages various types of information related to radiotherapy in addition to an image diagnostic apparatus 1001 such as an X-ray CT apparatus that captures a diagnostic image of an affected area, and a radiation irradiation apparatus 1002 that irradiates the affected area with radiation. The radiotherapy management system 1 for performing the configuration includes a plan input device 2, a treatment management device 3 connected to the database 4, and a treatment device 5 connected to the radiation irradiation device 1002.

  The image diagnosis apparatus 1001, the plan input apparatus 2, the treatment management apparatus 3, and the treatment apparatus 5 are connected to each other through a LAN: L so as to communicate with each other. LAN: L is connected to the Internet N and can communicate with a doctor terminal 6 used by a doctor or the like. The doctor terminal 6 is, for example, a portable terminal such as a mobile phone or a computer installed in a doctor's home.

  In the present embodiment, the plan input device 2, the treatment management device 3, and the treatment device 5 are individual devices, but any two or three of these devices are regarded as a single device. It may be configured. Further, the database 4 is directly connected only to the treatment management apparatus 3, but it may be a network storage directly connected to the LAN: L, and is commonly managed by the treatment management apparatus 3 and the plan input apparatus 2. It may be a configuration. Further, the database 4 may be a storage device such as a hard disk drive built in the treatment management apparatus 3. LAN: L may be either a wired LAN using a communication line or a wireless LAN using radio waves.

[Configuration of the plan input device]
The plan input device 2 is an example of a “plan input unit”. The plan input device 2 includes a computer terminal for inputting a radiation treatment plan and operates according to a predetermined control program. As shown in FIG. 2, the plan input device 2 includes a control unit 20, a user interface 21, and a communication interface (I / F) 22.

  The user interface 21 is provided with input devices such as a keyboard 211 and a mouse 212, and a display 213 such as an LCD or CRT. The communication I / F 22 includes an interface circuit for transmitting and receiving various data through the LAN: L.

  The control unit 20 includes a CPU, a memory, a hard disk drive, and the like built in the plan input device 2. The hard disk drive stores the above-described control program in advance. The control unit 20 includes a display control unit 201 that displays various screens such as a plan input screen for treatment plan input on the display 213, an input data processing unit 202 that processes data input to the plan input screen, and a LAN. A communication control unit 203 that controls data transmission / reception through L is provided.

  A user (doctor, engineer, etc.) operates the keyboard 211 and the mouse 212 to input information on the plan input screen. The input data processing unit 202 makes the input treatment plan and the plan determination factor (described above) of the plan into a set of data. This data is transmitted to the treatment management apparatus 3 through LAN: L by the communication I / F 22. Hereinafter, the treatment plan transmitted from the plan input device 2 to the treatment management device 3 may be referred to as a “treatment plan related to registration”.

[Configuration of treatment management device and database]
Next, the configuration of the treatment management device 3 and the database 4 will be described. FIG. 3 shows an example of the configuration of the treatment management device 3 and the database 4.

[Database]
First, the database 4 will be described. The database 4 includes a treatment plan storage unit 41 (plan storage unit), a treatment result storage unit 42, a factor setting list storage unit 43 (factor storage unit), and a factor storage unit 44 (storage unit).

  The treatment plan storage unit 41 and the treatment result storage unit 42 are respectively the same as the conventional ones. The treatment plan storage unit 41 stores a treatment plan. The treatment result storage unit 42 stores detailed information on radiation irradiation performed by the radiation irradiation apparatus 1002 based on the treatment plan stored in the treatment plan storage unit 41. The detailed information includes patient information such as a patient name that is not stored in the factor storage unit 44 described later. Further, this detailed information is associated with a treatment plan or the like by an identification key described later.

  The factor setting list storage unit 43 includes the patient's age, primary site, treatment site, pathological tissue, radiation irradiation level, radiation irradiation method, lesion depth, presence / absence of multiple cancers, degree of duplication of multiple cancers, type of treatment A list of the above-mentioned plan determining factors such as a treatment policy and a treatment method is stored.

  The factor accumulating unit 44 stores information on plan determination factors corresponding to the treatment plans stored in the treatment plan storage unit 41. The factor accumulation unit 44 stores the irradiation dose at that time each time radiation irradiation is performed by the radiation irradiation apparatus 1002. This irradiation dose is stored in association with information on the plan determination factor of the treatment plan that is the basis of the irradiation.

  The information on the plan determining factor and the irradiation dose for each time are associated with each other using an identification key described later. That is, in the factor accumulation unit 44, for each treatment plan stored in the treatment plan storage unit 41, information on the plan decision factor (plan decision factor information) and each time of radiation irradiation performed based on the treatment plan The irradiation dose information (irradiation dose information) is stored in association with each other by the identification key.

  “Plan decision factor” represents a factor name (“age”, etc.), and “Plan decision factor information” represents specific information about the requirement (eg, “50 years old” for requirement “age”). To do.

[Treatment management device]
The treatment management apparatus 3 includes a control unit 30, a factor setting component 31, a treatment plan management component 32, an irradiation dose management component 33, a user interface 34, and a communication I / F 35.

  Similar to the plan input device 2, the user interface 34 includes input devices such as a keyboard 341 and a mouse 342, and a display 343 such as an LCD or CRT. The communication I / F 35 includes an interface circuit for transmitting and receiving various data through the LAN: L. Although not shown, the user interface 34 can be provided with an audio output unit (including an audio output circuit, a speaker, etc.) that outputs various types of audio.

(Control part)
The control unit 30 includes a CPU, a memory, a hard disk drive, and the like built in the treatment management device 3. The hard disk drive stores a predetermined control program in advance. The control unit 30 controls a display control unit 301 that displays various screens such as a treatment plan management screen and a radiation dose management screen by the radiation irradiation apparatus 1002 on the display 343, and data transmission / reception through the LAN: L. And a communication control unit 302 is provided.

  In addition, the control unit 30 performs overall control of the treatment management apparatus 3, and particularly controls the operations of the factor setting component 31, the treatment plan management component 32, and the irradiation dose management component 33. Further, the control unit 30 executes a password verification process and an issuance process, which will be described later, and a message transmission process for requesting the input of the password.

(Factor setting component)
The factor setting component 31 performs processing for setting a plan determination factor to be applied to treatment planning and irradiation dose management, and includes a CPU that executes the control program. The factor setting component 31 is provided with a factor setting unit 311 which is an example of “factor setting means”.

  The display control unit 301 of the control unit 30 causes the display 343 to display a list of plan determination factors stored in the factor setting list storage unit 43 in response to a request from the user. The user operates the mouse 342 or the like to select a desired plan determination factor from the displayed list. Here, a plurality of plan determination factors can be selected. As an example of the above processing, the display control unit 301 displays a check box corresponding to each plan determination factor in the list, and the user clicks the check box of a desired plan determination factor with the mouse 342 to check the check mark. The planning decision factor is selected by inputting. The selection result is sent from the user interface 34 to the control unit 30.

  The factor setting unit 311 receives the above selection result and gives selection identification information such as a flag to the plan determination factor selected by the user. The plan determination factor to which the selection identification information is given is selectively used when performing treatment plan management or irradiation dose management. The setting of the above plan determination factors is executed by, for example, an administrator of the system 1 or the like. Hereinafter, the plan determining factor selected and set by the factor setting unit 311 may be referred to as “management determining factor”.

(Treatment plan management component)
The treatment plan management component 32 manages the treatment plan and the plan decision factors transmitted from the plan input device 2, and includes a CPU that executes the control program. The treatment plan management component 32 performs a process for determining whether or not the total irradiation dose indicated by the treatment plan related to registration is appropriate as the management process for the treatment plan and the like.

  The treatment plan management component 32 assigns a unique identification key to each treatment plan related to registration. That is, this identification key is information for identifying each treatment. Thus, the multiple doses comprising each treatment can be related by the same identification key, and multiple treatments for the same patient are distinguished by different identification keys. The identification key assignment process may be executed by the input data processing unit 202 (see FIG. 2) of the plan input device 2.

  The treatment plan management component 32 includes a database (DB) search unit 321 (first search unit), an allowable dose range calculation unit 322 (allowable range calculation unit), a planned dose determination unit 323 (planned dose determination unit), a treatment plan A storage processing unit 324 (plan storage processing means) and a plan correction request unit 325 (plan correction request means) are provided.

(DB search part)
The DB search unit 321 is configured to include the CPU of the treatment management apparatus 3, searches the factor accumulation unit 44 using the search condition based on the plan determination factor information of the treatment plan related to registration, and the past corresponding to the search condition To obtain the irradiation dose information. More specifically, the DB search unit 321 searches the plan determination factor information stored in the factor storage unit 44 for items that meet the search condition, and is associated with each searched plan determination factor. Obtain irradiation dose information. The association is made by an identification key. The search by the DB search unit 321 is performed using the management decision factor selected and set by the factor setting unit 311.

  In this manner, the DB search unit 321 acquires irradiation dose information in the past treatment performed with each plan determination factor information corresponding to the search condition. As described above, the irradiation dose information is stored for each irradiation constituting the treatment, and each irradiation is associated with an identification key. Therefore, the irradiation dose information acquired by the DB search unit 321 is Associated with each treatment.

  The search condition will be specifically described. As this search condition, for example, one of the following two search conditions can be applied.

  First, as a first search condition, there is a method of exact match search. That is, this is a method of searching the factor accumulation unit 44 for information that matches all the factors of the management decision factors as corresponding to the plan decision factor information of the treatment plan related to registration.

  As a second search condition, there is a weighted search method. In other words, each factor of management determinant is weighted according to its importance, and management with a large weight (that is, high importance) as corresponding to the plan determinant information of the treatment plan related to registration This is a method of searching the factor accumulation unit 44 for a match of the usage decision factors.

  For example, when age, primary site, treatment site, pathological tissue, irradiation level, irradiation method, and lesion depth are set as management determinants, using the first search condition, the DB search unit 321 The irradiation dose information associated with the plan determination factor information in which the information of all these factors matches the plan determination factor information of the treatment plan related to registration is acquired. As described above, when the first search condition is used, irradiation dose information in the past treatment having the same management determination requirements is acquired.

  On the other hand, when the weight as shown in FIG. 4 is set as the second search condition (the greater the number, the higher the importance), for example, the primary site, the treatment site, and the irradiation method (weight most important) = 5 (Required requirement) is searched, and one of the most important requirements that does not match is searched for a pathological tissue of weight = 4 and the irradiation level (next important requirement) is matched, and further, the most important requirement Among those that do not match one of the following and one of the next important requirements, a search is made for a case where the lesion depth of weight = 3 matches. When such a second search condition is used, irradiation dose information in the past treatment that matches requirements with higher importance is acquired.

(Dose tolerance calculation part)
Next, the dose tolerance range calculation unit 322 will be described. The dose tolerance range calculation unit 322 is configured to include the CPU of the treatment management apparatus 3, and based on the irradiation dose information in the past treatment acquired by the DB search unit 321, the radiation exposure dose tolerance range (dose tolerance range). ) Is calculated. Here, irradiation dose information is information showing the irradiation dose in each time of radiation irradiation which comprises one treatment as mentioned above. The dose tolerance calculation unit 322 of the present embodiment particularly calculates the tolerance of the total irradiation dose in the treatment plan. The upper limit of the calculated allowable range is set for the purpose of preventing excessive irradiation of the radiation, and the lower limit is set for the purpose of preventing the excessive irradiation of the radiation.

  This allowable dose range calculation unit 322 adds the irradiation doses indicated in the irradiation dose information acquired by the DB search unit 321 for each treatment, and calculates the total irradiation dose in each searched treatment. Here, the discrimination between one treatment and another treatment can be performed with reference to the aforementioned identification key.

  When a plurality of treatments are searched, the allowable dose range calculation unit 322 calculates, for example, the average value of the calculated total irradiation doses of the respective treatments, and sets this as the reference value T. At this time, when multiple calculated total irradiation doses are compared, if there is an irradiation dose (singular value) that is significantly different from the others, the average of the treatments excluding the treatment of that singular value A value may be calculated. The reference value T is not limited to an average value, and a median value, a weighted average value, or the like may be applied. When only one treatment is searched, the total irradiation dose calculated for the treatment is used as a reference value.

  Further, the dose tolerance range calculation unit 322 sets a dose tolerance range including the calculated reference value T. For this purpose, for example, the allowable dose range calculation unit 322 sets a predetermined allowable displacement amount Δ (for example, 10 Gy) before and after the reference value T, and obtains the allowable dose range (T−Δ, T + Δ). The obtained dose tolerance range is associated with the treatment plan via the identification key and stored in, for example, the treatment plan storage unit 41 of the database 4.

  Note that the allowable displacement amount does not have to be the same before and after the reference value T. For example, when the safety of treatment is more important, the displacement amount on the upper limit side can be set small. When the therapeutic effect is important while accepting some risks, the lower limit displacement amount can be set small (or the upper limit displacement amount can be increased). In addition to the predetermined value as described above, the allowable displacement amount is a ratio (%) set in advance such as 10% (0.9T, 1.1T) before and after the reference value T, for example. Etc. may be applied.

  Here, the preset allowable displacement (value,%, etc.) data is stored in advance in the hard disk drive of the control unit 30 of the treatment management apparatus 3.

(Planned dose judgment section)
The planned dose determination unit 323 is configured to include the CPU of the treatment management apparatus 3, and the irradiation dose (particularly the total irradiation dose) included in the treatment plan is within the dose tolerance range obtained by the dose tolerance range calculation unit 322. To determine whether it is included.

  When the irradiation dose is included in the allowable range, the control unit 30 operates the treatment plan storage processing unit 324. On the other hand, if it is not included, the plan correction request unit 325 is operated.

(Treatment plan storage processing unit)
The treatment plan storage processing unit 324 is configured to include the CPU of the treatment management device 3, and executes a process for causing the treatment plan storage unit 41 of the database 4 to store a new treatment plan.

(Planned correction request section)
The plan correction request unit 325 is configured to include the CPU of the treatment management apparatus 3 and displays a message (for example, “correct the treatment plan”) requesting the user (physician, engineer, etc.) to correct the treatment plan. A command to be displayed on 343 and a command to output a warning sound and a warning message to a voice output unit (not shown) are transmitted to the control unit 30. The control unit 30 receives the command and controls the user interface 34 to output the message, warning sound, and the like. Further, a command for displaying a message requesting correction of the treatment plan may be transmitted to the plan input device 2 and output to the display 213 or the like.

  As an example of the process of the plan correction request unit 325, a command that causes the doctor terminal 6 to transmit a message requesting correction of the treatment plan may be sent to the control unit 30. When adopting the configuration, the control unit 30 transmits a message to the doctor terminal 6 via the Internet N. Furthermore, in consideration of a case where radiation is irradiated immediately after registration of a treatment plan, the control unit 30 may transmit a signal for prohibiting radiation irradiation based on the treatment plan to the treatment apparatus 5.

(Irradiation dose management component)
The irradiation dose management component 33 performs processing for managing the suitability of the irradiation dose immediately before irradiating the patient with radiation using the radiation irradiation apparatus 1002, and includes a CPU that executes the control program. .

  The irradiation dose management component 33 includes a DB search unit 331 (second search unit), a cumulative dose calculation unit 332 (cumulative dose calculation unit), a cumulative dose determination unit 333 (cumulative dose determination unit), and a treatment result storage processing unit 334. In addition, an irradiation dose correction requesting unit 335 (irradiation dose correction requesting means) is provided.

(DB search part)
The DB search unit 331 is configured to include the CPU of the treatment management device 3 and is input from the treatment device 5 immediately before irradiation by the radiation irradiation device 1002 (irradiation preparation information described later; identification key and current key). The factor accumulation unit 44 of the database 4 is searched based on (including the irradiation dose), and the irradiation dose information of the past irradiation performed based on the treatment plan including the current irradiation is acquired. Here, irradiation dose information is created for each radiation irradiation, and is associated with each treatment plan by an identification key. For example, when the current irradiation is the Nth irradiation in the treatment plan, the DB search unit 331 acquires irradiation dose information in each irradiation from the first to the (N−1) th irradiation based on the treatment plan. .

(Cumulative dose calculation unit)
The accumulated dose calculation unit 332 adds all the irradiation doses indicated in the past irradiation dose information acquired by the DB search unit 331 and the current irradiation dose (irradiation preparation dose) included in the irradiation preparation information, The cumulative dose of the irradiation dose and the current irradiation preparation dose is calculated.

(Cumulative dose determination section)
The cumulative dose determination unit 333 acquires the dose tolerance range stored in the treatment plan storage unit 41 or the like from the database 4 and determines whether the cumulative dose calculated by the cumulative dose calculation unit 332 exceeds the upper limit of the dose tolerance range. Determine whether.

  When the accumulated dose does not exceed the upper limit of the allowable range, the control unit 30 operates the treatment result storage processing unit 334. On the other hand, when it exceeds, the irradiation dose correction request | requirement part 335 is operated. Here, the upper limit of the allowable dose range corresponds to the “predetermined value” of the present invention.

(Treatment result storage processing unit)
The treatment result storage processing unit 334 is configured to include the CPU of the treatment management device 3, and performs a process of storing the irradiation dose irradiated by the radiation irradiation device 1002 in the factor accumulation unit 44 of the database 4 as the irradiation dose information described above. . The storing process is executed for each irradiation, and stored irradiation dose information is stored for each irradiation of radiation. Irradiation dose information for each irradiation is stored in association with each treatment plan via an identification key. In this way, the treatment result storage processing unit 334 constitutes “means for accumulating irradiation dose in the accumulation means” according to the present invention. In addition, the treatment result storage processing unit 334 performs processing for storing the detailed information of radiation irradiation in the treatment result storage unit 42.

(Planned correction request section)
The irradiation dose correction request unit 335 is configured to include the CPU of the treatment management device 3 and issues a message (for example, “correct the irradiation dose”) requesting the user (doctor, engineer, etc.) to correct the irradiation dose. A command to be displayed on the display 343, a command to output a warning sound and a warning message to a voice output unit (not shown), a command to cause the doctor terminal 6 to transmit a message requesting correction of a treatment plan, and the like are transmitted to the control unit 30. Perform the process.

  The control unit 30 receives the command and controls the user interface 34 to output the message, warning sound, and the like. Further, the control unit 30 transmits a message to the doctor terminal 6 via the Internet N. Message transmission to the doctor terminal 6 is performed by e-mail or the like, for example. When LAN: L is connected to a telephone line, a voice message may be sent to a cellular phone such as a doctor.

  Further, when receiving a command from the irradiation dose correction request unit 335, the control unit 30 transmits a signal (irradiation lock signal) for prohibiting radiation irradiation by the radiation irradiation apparatus 1002 to the treatment apparatus 5. When receiving the irradiation lock signal, the therapeutic device 5 locks the irradiation process by the radiation irradiation device 1002.

  Further, when a message is transmitted to the doctor terminal 6, a message requesting input of a password for releasing the irradiation lock may be transmitted at the same time. This password is set in advance. The doctor or the like who has received the message operates the doctor terminal 6 to input a password and transmits it to the treatment management apparatus 3. The control unit 30 of the treatment management device 3 collates the transmitted password and transmits an irradiation lock release signal to the treatment device 5 so that radiation can be irradiated.

  Furthermore, in consideration of security in information management, it is desirable that this password can be used only once. Therefore, when a password is input, the password can be invalidated and a new password can be issued and transmitted to the doctor terminal 6 by e-mail or telephone. Such processing relating to the password is executed by the control unit 30.

[Configuration of treatment apparatus and radiation irradiation apparatus]
The block diagram of FIG. 5 represents an example of the configuration of the treatment apparatus 5. In addition, since the radiation irradiation apparatus 1002 has the same structure as the conventional one, the description regarding the detail is abbreviate | omitted.

  The treatment apparatus 5 is a computer terminal used as a console of the radiation irradiation apparatus 1002 and operates according to a predetermined control program. The therapeutic device 5 includes a control unit 50, a user interface 51, and a communication I / F 52.

  The user interface 51 is provided with input devices such as a keyboard 511 and a mouse 512 and a display 513 such as an LCD or CRT. The communication I / F 52 includes an interface circuit for transmitting and receiving various data through the LAN: L.

  The control unit 50 includes a CPU, a memory, a hard disk drive, and the like built in the treatment apparatus 5. The hard disk drive stores the above-described control program in advance.

  The control unit 50 acquires an irradiation control unit 501 (irradiation control means) that performs processing such as operation control of the radiation processing apparatus 1002 and setting of an irradiation dose and an irradiation site, and an irradiation dose set by the irradiation control unit 501. In addition, the irradiation preparation information transmission unit 502 (irradiation dose acquisition means) that transmits the irradiation preparation information (described above) to the treatment management apparatus 3 and the radiation irradiation operation of the radiation processing apparatus 1002 are prohibited in response to a request from the treatment management apparatus 3 The display control unit 504 displays various screens such as an operation screen for operating the radiation processing apparatus 1002 and an irradiation prohibition processing unit 503 (irradiation prohibition processing unit) that performs processing to cancel the prohibition state. And a communication control unit 505 for controlling data transmission / reception through the LAN: L.

  When a user (engineer or the like) of the treatment apparatus 5 performs treatment by the radiation processing apparatus 1002, he / she inputs information such as an identification key of the treatment and a current irradiation dose by operating the keyboard 511 and the mouse 512. The input information is stored in a hard disk drive or the like of the control unit 50.

[Processing procedure]
An example of a procedure of processing executed by the radiation therapy management system 1 having the above configuration will be described with reference to FIGS. First, the treatment plan registration process input by the plan input apparatus 2 will be described with reference to FIG. 6, and the process executed at the time of radiation irradiation will be described with reference to FIGS. 7 and 8.

[Treatment plan registration process]
The treatment plan registration process shown in FIG. 6 will be described. This process is mainly executed by the treatment plan management component 32 of the treatment management apparatus 3.

  When the treatment plan created by the doctor is input (S1), the plan input device 2 transmits the treatment plan to the treatment management device 3 (S2).

  When the treatment plan is received from the plan input device 2, the treatment plan management component 32 of the treatment plan device 3 issues an identification key for this treatment plan (S3). Various types of information related to the treatment plan are associated with the identification key and used for processing. The control unit 30 sends the plan determination factor information included in the treatment plan to the treatment plan management component 32.

  The DB search unit 321 of the treatment plan management component 32 searches the factor accumulation unit 44 using predetermined search conditions (exact match search, weighted search, etc.) based on the plan determination factor information, and each time in the corresponding past treatment. Is acquired (S4). Irradiation dose information is associated with each treatment by an identification key.

  The dose tolerance range calculation unit 322 adds the irradiation dose shown in the acquired irradiation dose information for each treatment with reference to the identification key, calculates the total irradiation dose in each past treatment searched, and A reference value is calculated by taking an average, and a dose tolerance range is obtained based on this reference value and the aforementioned allowable displacement amount (S5).

  The planned dose determination unit 323 compares the total irradiation dose of the treatment plan related to registration with the dose tolerance range obtained in step S5, and determines whether or not the total irradiation dose is included in the dose tolerance range. (S6).

  When the total irradiation dose of the treatment plan related to registration is included within the allowable dose range (S6; Y), the treatment plan storage processing unit 324 stores the treatment plan in the treatment plan storage unit 41 of the database 4 ( S7), the treatment plan registration process is terminated.

  On the other hand, when the total irradiation dose of the treatment plan related to registration is not included in the allowable dose range (S6; N), the plan correction request unit 325 displays a message requesting correction of the treatment plan on the display 343 or the like. (S8).

  When the treatment plan is corrected and input to the plan input device 2 (S9), the treatment management device 3 receives the corrected treatment plan and determines whether the total irradiation dose is included in the dose tolerance range. (S6). This determination regarding the total irradiation dose is repeated until the total irradiation dose is corrected so as to fall within the allowable dose range. When the total irradiation dose reaches a value within the allowable dose range, the treatment plan is stored in the treatment plan storage unit 41 (S7), and the treatment plan registration process is terminated.

  In addition, when the plan determination factor information is changed at the time of correcting the treatment plan, it is desirable that the dose allowable range is recalculated. At this time, a new identification key may be issued to distinguish from the treatment plan before correction.

[Treatment during irradiation]
Processing executed at the time of radiation irradiation shown in FIGS. 7 and 8 will be described. This process is mainly executed by the radiation dose management component 33 of the treatment management apparatus 3.

  A user (engineer or the like) of the treatment apparatus 5 inputs information such as an identification key of the treatment plan from the user interface 51 as a preparation stage for performing the treatment by the radiation irradiation apparatus 1002 (S11). The irradiation control unit 501 of the treatment apparatus 5 refers to the treatment plan in the database 4 and the adjustment result of the irradiation dose by the user, etc., and sets the irradiation dose and the like for the affected part (S12). The irradiation preparation information transmitting unit 502 transmits irradiation preparation information including the set irradiation dose (irradiation preparation dose) and an identification key to the treatment management apparatus 3 (S13).

  The DB search unit 331 of the radiation dose management component 33 of the treatment management apparatus 3 searches the factor accumulation unit 44 of the database 4 based on the identification key of the irradiation preparation information, and the irradiation dose information in the past irradiation based on the treatment plan. Is acquired (S14).

  The cumulative dose calculation unit 332 calculates the cumulative dose up to the current irradiation by adding the irradiation dose shown in each acquired past irradiation dose information and the irradiation preparation dose included in the irradiation preparation information (S15). The cumulative dose determination unit 333 acquires the allowable dose range from the database 4 and determines whether the calculated cumulative dose exceeds the upper limit of the allowable dose range (S16).

  When the accumulated dose does not exceed the upper limit of the allowable range (S16; Y), the control unit 30 transmits a signal indicating that the irradiation preparation dose can be irradiated to the treatment apparatus 5 (S17). The user of the treatment apparatus 5 operates the user interface 51 to perform radiation irradiation (S18). When irradiation is performed, a signal indicating completion of irradiation is transmitted from the treatment device 5 to the treatment management device 3. The treatment result storage processing unit 334 of the treatment management apparatus 3 stores the currently irradiated dose in the factor accumulating unit 44 as the irradiation dose information (S19), and the process ends. At this time, the detailed information of the current irradiation is stored in the treatment result storage unit 42 of the database 4 (the same applies hereinafter).

  On the other hand, when the accumulated dose exceeds the upper limit of the allowable range (S16; N), the irradiation dose correction requesting unit 335 sends a command requesting correction of the irradiation dose to the control unit 30 (S20). Upon receiving this command, the control unit 30 transmits an irradiation lock signal to the treatment apparatus 5 to prohibit the irradiation process by the radiation irradiation apparatus 1002 (S21), and for example, sets an irradiation lock release password to the doctor terminal 6. An electronic mail including a message requesting input is transmitted (S22).

  When a doctor who receives the message inputs a password and transmits it to the treatment management apparatus 3 (S23), the control unit 30 verifies the transmitted password (S24).

  When the transmitted password is correct (S24; Y), the control unit 30 transmits an irradiation lock release signal to the treatment device 5 so that radiation can be irradiated (S25). At this time, the password is invalidated and a new password is issued and transmitted to the doctor terminal 6 by e-mail. When the irradiation is performed (S18), the treatment result storage processing unit 334 stores the current irradiation dose in the factor accumulation unit 44 (S19), and the process ends.

  On the other hand, when the transmitted password does not match (S24; N), the control unit 30 transmits a message requesting re-input of the password to the doctor terminal 6 (S26). When the password is re-input (S23), the control unit 30 verifies the re-input password (S24). This authentication process using a password is repeated until a correct password is input. When a correct password is input (S24; Y), the control unit 30 transmits an irradiation lock release signal to the treatment apparatus 5 so that radiation can be irradiated (S25), and when irradiation is performed (S18). The treatment result storage processing unit 334 stores the current irradiation dose in the factor accumulation unit 44 (S19). This is the end of the process.

[Function and effect]
The operational effects of the present embodiment as described above will be described. First, according to the radiation treatment management system 1 of the present embodiment, a dose tolerance range is calculated based on the irradiation dose of the past treatment according to the treatment plan related to registration, and the total irradiation dose of the treatment plan related to registration is calculated as follows. When the dose is within the allowable range, the treatment plan is registered. Further, when the total irradiation dose is not within the allowable dose range, the treatment plan is not registered, and the correction is requested. Therefore, since the validity of the treatment plan created by the doctor can be objectively determined from the past data, it is possible to carry out radiotherapy that appropriately considers both the treatment effect and safety. In addition, since the dose tolerance range corresponding to the plan determination factor information is calculated for each treatment plan related to registration, it is possible to determine whether the total irradiation dose is possible with high accuracy.

  In addition, the radiation treatment management system 1 calculates the cumulative dose of the previous dose and the set value of the current dose (irradiation preparation dose) immediately before the radiation is irradiated, and the cumulative dose falls within the allowable dose range. It judges whether or not it exceeds, and acts so as to allow irradiation of radiation when it does not exceed. Further, when the accumulated dose exceeds the allowable dose range, the radiation irradiation is prohibited. Furthermore, when the accumulated dose exceeds the allowable dose range, a message requesting input of a password for canceling irradiation prohibition is transmitted to the doctor, and the irradiation prohibition state is not canceled unless the correct password is input. Thereby, the irradiation dose can be confirmed immediately before the irradiation. Therefore, it is possible to avoid an irradiation accident caused by a communication error between a doctor and a radiographer, and to improve the safety of treatment.

  In addition, if the password is changed every time it is used, it is possible to avoid the situation where an engineer etc. remembers the password and inputs it by himself, so it is possible to avoid an irradiation accident and to improve safety. Rise.

[Modification]
The transmission destination of the password input request message for canceling the prohibition of radiation irradiation is not limited to the doctor terminal 6 of the doctor in charge of the treatment. For example, it can be configured to transmit to a terminal such as a doctor who performs treatment with the doctor in charge or a doctor who supervises the doctor in charge. By doing so, for example, even if the doctor in charge is on a business trip or on vacation, the irradiation prohibited state can be canceled, so that the correction of the irradiation dose and the current irradiation can be performed quickly.

  In addition, when the treatment plan is changed during the treatment, such as when the treatment effect is not as planned or when the treatment site is changed by re-examination by the image diagnostic apparatus 1001, the irradiation dose in the previous irradiation is changed to a new treatment. It is preferable that the configuration is reflected in the plan. For example, the first to nth irradiation dose information before the change is set as the first to nth irradiation dose information of a new treatment plan, and the total irradiation dose of the new treatment plan is determined and the cumulative dose is calculated. Can be configured to be executed using the first to nth irradiation dose information. Note that the treatment plan can be changed not only by the plan input device 2 but also by the treatment management device 3 or the like.

  Moreover, although it is comprised so that an irradiation preparation dose may be acquired from the setting value of the irradiation dose by the irradiation control part 501, and irradiation preparation information is produced | generated, it is not limited to this. For example, the radiation irradiation apparatus 1002 can be configured to detect a setting value by means for setting an irradiation dose (switch, dial, etc.) and acquire an irradiation preparation dose from the detection result.

  Further, the treatment management apparatus 3 may have only one of the treatment plan management component 32 and the irradiation dose management component 33. In that case, only one of the treatment plan registration process and the process at the time of radiation irradiation is executed.

<Second Embodiment>
The second embodiment of the present invention relates to the present invention configured to perform a part of processing by a server on a wide area network (WAN) such as the Internet. Hereinafter, the same components as those of the first embodiment will be described using the same reference numerals.

[overall structure]
FIG. 10 shows an outline of the overall configuration of a radiation therapy system 1000 ′ including the radiation therapy management system 1 ′ of the present embodiment. Similar to the first embodiment, the radiation therapy system 1000 ′ includes a plan input device 2, a therapy management device 3 ′, and a database 4 as a radiation therapy management system 1 ′ in addition to the diagnostic imaging device 1001 and the radiation irradiation device 1002. ′ And the therapeutic device 5. The plan input device 2, the treatment management device 3 ′, the database 4 ′, and the treatment device 5 are examples of “clients”.

  The diagnostic imaging apparatus 1001, the plan input apparatus 2, the treatment management apparatus 3 ′, and the treatment apparatus 5 are connected to each other through a LAN: L so as to communicate with each other. LAN: L is connected to WAN: W such as the Internet, and can communicate with the server 10 and the doctor terminal 6, respectively. The radiation treatment management system 1 ′ of the present embodiment also includes a server 10.

  The diagnostic imaging apparatus 1001, the radiation irradiation apparatus 1002, the plan input apparatus 2 (see FIG. 2), the treatment apparatus 5 (see FIG. 5), and the doctor terminal 6 have the same configurations as those in the first embodiment. Hereinafter, the configuration of the treatment management apparatus 3 ′, the database 4 ′, and the server 10 will be described.

  In the present embodiment, the server 10 performs management of setting information of the plan determination factor, management of the treatment plan, and management of the irradiation dose. Although not shown in FIG. 10, a plurality of radiation therapy management systems are connected to the server 10 via WAN: W. The plurality of systems are installed in a plurality of different medical institutions, and the server 10 is configured to individually manage information processed in each system. That is, the server 10 supplies the setting information of the above-described plan determination factor, the treatment plan, and the irradiation dose management service to a plurality of medical institutions. At the time of data communication between the server 10 and the treatment management device 3 ′ etc., device identification information of the treatment management device 3 ′ is transmitted together with communication data. The server 10 determines the information from which treatment management device 3 ′ based on the device identification information, and executes the process individually for each treatment management device 3 ′. In addition, the server 10 stores address information (IP address or the like) of each treatment management device 3 ′, and transmits data using this address information.

[Configuration of treatment management device and database]
With reference to FIG. 11, the structure of treatment management apparatus 3 'and database 4' is demonstrated.

[Database]
The database 4 'is provided with a treatment plan storage unit 41 and a treatment result storage unit 42 similar to those in the first embodiment.

[Treatment management device]
The treatment management device 3 'is a device for registering treatment plans and treatment results in the database 4', and updating, deleting, and outputting these data as necessary. The treatment management device 3 ′ includes a factor setting control component 36 in addition to the control unit 30, the user interface 34, and the communication I / F 35 similar to those in the first embodiment.

  The factor setting control component 36 is configured to include the CPU of the treatment management apparatus 3 ′, and the factor setting control unit 361 controls the setting process of the plan determination factor.

  The factor setting control unit 361 is an administrator of the radiation therapy management system 1 ′, such as display control of the setting screen for the plan determination factor, processing of input data for the setting screen, and control of data transmission / reception with the server 10. Executes various controls for setting the planning decision factor.

[Server configuration]
The configuration of the server 10 will be described with reference to FIG. The server 10 has the same configuration as the treatment management apparatus 3 of the first embodiment, and includes a control unit 11, an information storage unit 12, a factor setting component 13, a treatment plan management component 14, an irradiation dose management component 15, and a communication. An I / F 16 is included.

  The information storage unit 12 includes a factor setting list storage unit 121 and a factor storage unit 122 similar to those of the database 4 of the first embodiment.

  Similar to the control unit 30 of the first embodiment, the control unit 11 is provided with a communication control unit 111 that controls data transmission / reception through WAN: W by the control unit communication I / F 16. The control unit 11 also performs overall control of the server 10, password issuing processing for canceling the prohibition of radiation irradiation of the radiation irradiation apparatus 1002, password verification processing, and the like.

  The factor setting component 13 performs the same operation as the factor setting component 31 of the first embodiment, and includes a factor setting unit 131. The factor setting unit 131 sets a management decision factor in the same manner as the factor setting unit 311 of the first embodiment, based on information transmitted to and received from the factor setting control component 36 of the treatment management device 3 ′.

  The management decision factor setting process is executed, for example, in the following procedure. First, when the user requests setting of the plan determination factor from the setting screen displayed on the display 343 of the treatment management apparatus 3 ′, a request signal is transmitted to the server 10. The factor setting unit 311 of the server 10 transmits the list of plan determination factors stored in the factor setting list storage unit 121 to the treatment management apparatus 3 ′. The display control unit 301 of the treatment management apparatus 3 ′ displays the list of plan determination factors on the display 343. The user operates the mouse 342 or the like to select a desired plan determination factor from the displayed list. The factor setting control unit 361 receives the selection result and gives selection identification information such as a flag to the plan determination factor selected by the user. The plan determination factor to which the selection identification information is given is selectively used when performing treatment plan management or irradiation dose management.

  The treatment plan management component 14 has the same configuration as the treatment plan management component 32 of the first embodiment, and includes a DB search unit 141, a dose tolerance calculation unit 142, a planned dose determination unit 143, and a treatment plan storage processing unit 144. And a plan correction requesting unit 145. The treatment plan storage processing unit 144 performs processing for transmitting a signal permitting storage of the treatment plan in the database 4 ′ to the treatment management device 3 ′. The treatment plan management component 314 also assigns a unique identification key to each treatment plan related to registration.

  The irradiation dose management component 15 has the same configuration as the irradiation dose management component 33 of the first embodiment, and includes a DB search unit 151, a cumulative dose calculation unit 152, a cumulative dose determination unit 153, and a treatment result storage processing unit. 154 and an irradiation dose correction requesting unit 155.

[Processing procedure]
An example of the procedure of the process executed by the radiation therapy management system 1 ′ as described above will be described with reference to FIGS. First, a treatment plan registration process input by the plan input apparatus 2 will be described with reference to FIG. 13, and then a process executed at the time of radiation irradiation will be described with reference to FIGS. In the processing procedure described below, data exchange with the server 10 on the client (hospital) side is executed by the treatment management apparatus 3 ′, but the present invention is not limited to this.

[Treatment plan registration process]
The treatment plan registration process shown in FIG. 13 will be described. The processing is mainly executed by the treatment management apparatus 3 in the first embodiment, but is executed mainly by the treatment plan management component 14 of the server 10 in the present embodiment.

  When the treatment plan created by the doctor is input (S31), the plan input device 2 transmits the treatment plan to the treatment management device 3 '(S32). The treatment management apparatus 3 ′ creates a copy of the treatment plan related to the registration, and transfers this copy to the server 10 (S33). At this time, a copy of only the information on the plan determination factor information and the total irradiation dose included in the treatment plan related to registration may be transmitted.

  When the server 10 receives the treatment plan (copy) from the treatment management device 3 ', the treatment plan management component 14 issues an identification key for this treatment plan (S34). The control unit 11 sends the plan determination factor information included in the treatment plan to the treatment plan management component 14.

  The DB search unit 141 of the treatment plan management component 14 searches the factor accumulation unit 122 using predetermined search conditions based on the plan determination factor information, and acquires irradiation dose information of each irradiation in the corresponding past treatment. (S35).

  The dose tolerance range calculation unit 142 obtains a dose tolerance range based on the irradiation dose indicated in the acquired irradiation dose information and a preset allowable displacement amount (S36). The determined dose tolerance is stored in the factor storage unit 122 in association with the treatment plan by the identification key.

  The planned dose determination unit 143 compares the total irradiation dose of the treatment plan related to registration with the dose tolerance range obtained in step S36, and determines whether or not the total irradiation dose is included in the dose tolerance range. (S37).

  When the total irradiation dose of the treatment plan related to registration is included within the allowable dose range (S37; Y), the treatment plan storage processing unit 144 treats a signal permitting storage of the treatment plan (storage permission signal). The data is transmitted to the management device 3 '(S38). When receiving the storage permission signal, the control unit 30 of the treatment management apparatus 3 ′ stores the treatment plan related to registration in the treatment plan storage unit 41 of the database 4 ′ (S39), and ends the treatment plan registration process.

  On the other hand, when the total irradiation dose of the treatment plan related to registration is not included within the allowable dose range (S37; N), the plan correction request unit 145 treats a signal (correction request signal) for requesting correction of the treatment plan. The data is transmitted to the management device 3 ′ (S40). When receiving the correction request signal, the treatment management apparatus 3 ′ causes the display control unit 301 to display a message requesting correction on the display 343 (S41).

  When the treatment plan is corrected and input to the plan input device 2 (S42), the treatment management device 3 transmits a copy of the corrected treatment plan to the server 10 (S43).

  The server 10 determines whether or not the total irradiation dose of the corrected treatment plan is included within the allowable dose range (S37). This determination regarding the total irradiation dose is repeated until the total irradiation dose is corrected so as to fall within the allowable dose range. When the total irradiation dose reaches a value within the allowable dose range, a storage permission signal is transmitted to the treatment management device 3 '(S38). When receiving the storage permission signal, the control unit 30 of the treatment management apparatus 3 ′ stores the treatment plan related to registration in the treatment plan storage unit 41 of the database 4 ′ (S39), and the treatment plan registration process is ended.

[Treatment during irradiation]
Processing executed at the time of radiation irradiation shown in FIGS. 14 and 15 will be described. This process is mainly executed by the treatment management apparatus 3 in the first embodiment, but in the present embodiment, the process is executed mainly by the irradiation dose management component 15 of the server 10.

  When information such as a treatment plan identification key is input by the user of the treatment apparatus 5 during the treatment by the radiation irradiation apparatus 1002 (S51), the irradiation control unit 501 sets the irradiation dose and the like (S52). The irradiation preparation information transmitting unit 502 transmits irradiation preparation information including the set irradiation dose (irradiation preparation dose) and an identification key to the treatment management apparatus 3 ′ (S53). The treatment management apparatus 3 ′ creates a copy of the irradiation preparation information and transfers it to the server 10 (S54).

  The DB search unit 151 of the radiation dose management component 15 of the server 10 searches the factor storage unit 122 of the information storage unit 12 based on the received irradiation preparation information identification key, and performs irradiation in the past irradiation based on the treatment plan. Dose information is acquired (S55).

  The cumulative dose calculation unit 152 calculates the cumulative dose up to the current irradiation by adding the irradiation dose shown in each acquired past irradiation dose information and the irradiation preparation dose included in the irradiation preparation information (S56). The cumulative dose determination unit 153 refers to the identification key, acquires the allowable dose range of the treatment plan from the factor storage unit 122, and determines whether the cumulative dose calculated in step S55 exceeds the upper limit of the allowable dose range. Judgment is made (S57).

  When the accumulated dose does not exceed the upper limit of the allowable range (S57; Y), a signal indicating that irradiation can be performed with the irradiation preparation dose is transmitted from the server 10 to the treatment management device 3 '(S58), and the treatment device 5 is used. (S59). When radiation irradiation is performed (S60), a signal indicating the completion of irradiation is transmitted from the treatment device 5 to the treatment management device 3 'and transferred to the server 10 (S61). The treatment result storage processing unit 154 of the server 10 stores the irradiation dose irradiated this time as the irradiation dose information in the factor accumulation unit 44 (S62), and the processing ends. At this time, the detailed information of the current irradiation is stored in the treatment result storage unit 42 of the database 4 '(the same applies hereinafter).

  On the other hand, when the accumulated dose exceeds the allowable range (S57; N), a command for requesting correction of the irradiation dose is sent from the irradiation dose correction requesting unit 155 to the control unit 11. (S63). Upon receiving this command, the control unit 11 transmits an irradiation lock signal to the treatment management device 3 ′ (S64). The treatment management device 3 ′ transfers this irradiation lock signal to the treatment device 5 to prohibit the irradiation processing by the radiation irradiation device 1002 (S65), and further requests the doctor terminal 6 to input the irradiation lock release password. An electronic mail including a message to be transmitted is transmitted (S66).

  The input password is transmitted to the treatment management apparatus 3 '(S67) and transferred to the server 10 (S68). The control unit 11 of the server 10 collates the received password (S69).

  If the password is correct (S69; Y), an irradiation lock release signal is transmitted from the server 10 to the treatment management apparatus 3 '(S70). The treatment management device 3 ′ transfers this irradiation lock release signal to the treatment device 5 so that it can irradiate radiation (S71). At this time, the used password is invalidated, and a new password is issued and transmitted to the doctor terminal 6 by e-mail. When irradiation is performed (S60), a signal indicating the completion of irradiation is transferred from the treatment apparatus 5 to the server 10 via the treatment management apparatus 3 '(S61). The treatment result storage processing unit 154 of the server 10 stores the irradiation dose irradiated this time as the irradiation dose information in the factor accumulation unit 44 (S62), and the processing ends.

  On the other hand, if the password does not match (S69; N), the server 10 transmits a message requesting re-input of the password to the treatment management apparatus 3 '(S72). The treatment management device 3 ′ transfers the message to the doctor terminal 6 (S73). The re-input password is transmitted to the treatment management apparatus 3 '(S67) and transferred to the server 10 (S68). The control unit 11 of the server 10 collates the received password (S69). This authentication process using a password is repeated until a correct password is input. When a correct password is input (S69; Y), an irradiation lock release signal is transmitted from the server 10 to the treatment management device 3 '(S70). The treatment management device 3 ′ transfers this irradiation lock release signal to the treatment device 5 so that it can irradiate radiation (S71). When irradiation is performed (S60), a signal indicating the completion of irradiation is transferred from the treatment apparatus 5 to the server 10 via the treatment management apparatus 3 '(S61). The treatment result storage processing unit 154 of the server 10 stores the irradiation dose irradiated this time in the factor accumulation unit 44 as irradiation dose information (S62). The process at the time of radiation irradiation is thus completed.

[Function and effect]
According to the radiation treatment management system 1 of the present embodiment, similarly to the first embodiment, it is possible to carry out radiation treatment that appropriately considers both the therapeutic effect and safety, Irradiation accidents caused by miscommunication between the two can be avoided, and the safety of treatment can be improved.

  In addition, the present embodiment is configured to provide a service to a system in a medical institution by executing processing related to radiation therapy management by a server. Therefore, as in the first embodiment, compared to the case where all the configurations according to the present invention are incorporated in a system in a medical institution, an equivalent service can be enjoyed at a low cost. It is also expected to be introduced to medical institutions.

[Modification]
In the above embodiment, data transmission / reception with the server 10 is performed by the treatment management device 3 ′, and data from other devices is transmitted to the server 10 via the treatment management device 3 ′. Although the data is configured to be transmitted to the other device via the treatment management device 3 ′, the data may be directly transmitted and received between the other device and the server 10. For example, an irradiation lock signal or an irradiation lock release signal can be configured to be transmitted directly from the server 10 to the treatment device 5, and a message requesting a password (re-) input is directly transmitted from the server 10 to the doctor terminal 6. Can be configured to Moreover, it can also comprise so that the password input from the doctor terminal 6 may be directly transmitted to the server 10.

  The configuration described in detail above discloses an example for suitably carrying out the present invention, and does not exclude modifications within the scope of the gist of the present invention.

<Application to dose management of drugs>
In the embodiment described in detail above, management of radiation dose has been described, but the same configuration can be applied to drug dose management.

  As the drug to be managed, for example, an anticancer drug or the like that is administered in a predetermined amount over a predetermined period is assumed. In the treatment using such a drug, a plan (administration plan) of the dose and administration period (administration timing) is usually determined in advance, and the treatment is usually performed according to the administration plan. In addition, the administration plan is determined in consideration of various plan determining factors such as the patient age, the affected area, and the drug to be used, in the same manner as the radiotherapy treatment plan.

  Hereinafter, a procedure for dose management according to the first embodiment will be described. In the configuration for executing this processing procedure, “radiation” in the first embodiment is replaced with “drug”, “irradiation” is replaced with “administration”, and “irradiation dose” is replaced with “dose”. Is.

[Dosage plan registration process]
When the administration plan created by the doctor is input, an identification key is issued for this administration plan. Various types of information related to the administration schedule are associated with this identification key and provided for processing.

  Based on the plan decision factor information of the administration plan, the dose information of each time in the past treatment is acquired, and the total dose is calculated by adding the information for each treatment, and the administration allowable range is obtained. It is determined whether or not the total dose of the administration plan related to registration is included in the administration tolerance.

  When the total dose of the administration plan related to registration is included in the administration allowable range, the administration plan is stored in the database, and the process is terminated.

  On the other hand, when the total dose of the administration plan related to registration is not included in the administration allowable range, a message requesting correction of the administration plan is displayed. When the corrected administration plan is input, it is determined whether or not the total dose is within the allowable dose range. This determination regarding the total dose is repeated until the total dose is corrected to be within the dose tolerance. When the total dose reaches a value within the allowable dose range, the administration plan is stored in the database, and the process is terminated.

[Treatment at the time of drug administration]

  When a nurse or the like inputs information such as an identification key and dosage of the administration plan immediately before administration, dosage information on past administration based on the administration plan is acquired from the database based on the identification key. Next, the cumulative dose up to the current dose is calculated by adding the dose indicated in each dose information and the input current dose, and is this cumulative dose included in the allowable dose range? Judge whether or not.

  When the cumulative dose is within the allowable dose range, a message indicating that the dose is appropriate is output. When a nurse or the like performs the current administration, the current dose is stored as dose information in the database, and the process ends.

  On the other hand, when the cumulative dose is not included in the allowable dose range, a command requesting correction of the dose is generated, and a message prohibiting the administration is output. When a drug is automatically administered by a device, a signal prohibiting the administration is sent to the device, and the device can be placed in a dose-inhibited state. Further, an electronic mail including a message requesting input of a password for canceling the prohibition of administration is transmitted to the doctor terminal. When a doctor who receives the message enters a password, the password is verified.

  When the transmitted password is correct, a message indicating that the administration prohibition state has been released is output. In addition, a signal for canceling the prohibition of administration is transmitted to the device so that the administration is possible. When the administration is performed, the current dose is stored in the database, and the process is terminated.

  On the other hand, if the transmitted password does not match, a message requesting re-input of the password is transmitted to the doctor terminal. When the password is re-entered, the password is verified. This authentication process using a password is repeated until a correct password is input. When the correct password is entered, a message indicating that the administration prohibited state has been released is output. In addition, a signal for canceling the prohibition of administration is transmitted to the device so that the administration is possible. When the administration is performed, the current dose is stored in the database, and the process is terminated.

  According to the drug administration management system as described above, the administration tolerance is calculated based on the past treatment dosage according to the administration plan related to registration, and the total administration dose of the administration plan related to registration is within the tolerance. If this is not the case, the amendment is requested without registering the administration plan, so the validity of the administration plan prepared by the doctor can be judged from past data, and both the treatment effect and safety can be determined. It is possible to perform a medicinal treatment with consideration.

  In addition, the cumulative dose up to this time is calculated immediately before administration, and it is determined whether or not the cumulative dose exceeds the allowable range. If it exceeds, the administration is prohibited. Furthermore, since a message requesting input of a password for canceling prohibition is transmitted to the doctor and the administration prohibition state is not canceled unless the correct password is input, the dose can be confirmed immediately before administration. Therefore, a medication accident caused by a communication error between a doctor and a nurse can be avoided, and the safety of treatment is improved.

  Further, if the processing is performed by the server as in the second embodiment, the cost for the system is reduced, so that the system operation can be promoted.

It is a block diagram showing an example of the whole structure of 1st Embodiment of the radiotherapy management system which concerns on this invention. It is a block diagram showing an example of composition of a plan input device contained in a 1st embodiment of a radiotherapy management system concerning the present invention. It is a block diagram showing an example of composition of a treatment management device and a database contained in a 1st embodiment of a radiation treatment management system concerning the present invention. It is a figure showing an example of the search conditions in the search process of the database by the treatment management apparatus contained in 1st Embodiment of the radiotherapy management system which concerns on this invention. 1 is a block diagram illustrating an example of a configuration of a treatment apparatus included in a first embodiment of a radiation treatment management system according to the present invention. It is a flowchart showing an example of the process which 1st Embodiment of the radiotherapy management system which concerns on this invention performs. It is a flowchart showing an example of the process which 1st Embodiment of the radiotherapy management system which concerns on this invention performs. It is a flowchart showing an example of the process which 1st Embodiment of the radiotherapy management system which concerns on this invention performs. It is a flowchart showing the flow of radiation therapy. It is a block diagram showing an example of the whole structure of 2nd Embodiment of the radiotherapy management system which concerns on this invention. It is a block diagram showing an example of composition of a treatment management device and a database contained in a 2nd embodiment of a radiation treatment management system concerning the present invention. It is a block diagram showing an example of a structure of the server contained in 2nd Embodiment of the radiotherapy management system which concerns on this invention. It is a flowchart showing an example of the process which 2nd Embodiment of the radiotherapy management system which concerns on this invention performs. It is a flowchart showing an example of the process which 2nd Embodiment of the radiotherapy management system which concerns on this invention performs. It is a flowchart showing an example of the process which 2nd Embodiment of the radiotherapy management system which concerns on this invention performs.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 1 'Radiation treatment management system 2 Plan input device 3, 3' Treatment management device 30 Control part 31 Factor setting component 311 Factor setting part 32 Treatment plan management component 321 Database search part 322 Dose tolerance range calculation part 323 Plan dose determination part 324 Treatment plan storage processing unit 325 Plan correction request unit 33 Irradiation dose management component 331 Database search unit 332 Cumulative dose calculation unit 333 Cumulative dose determination unit 334 Treatment result storage processing unit 335 Irradiation dose correction request unit 34 User interface 35 Communication interface 4 4 'database 41 treatment plan storage unit 42 treatment result storage unit 43 factor setting list storage unit 44 factor accumulation unit 5 treatment device 50 control unit 501 irradiation control unit 502 irradiation preparation information transmission unit 503 irradiation prohibition processing unit 6 Teacher terminal 10 Server 11 Control unit 12 Information storage unit 121 Factor setting list storage unit 122 Factor accumulation unit 13 Factor setting component 131 Factor setting unit 14 Treatment plan management component 141 Database search unit 142 Dose tolerance range calculation unit 143 Plan dose determination unit 144 Treatment plan storage processing unit 145 Plan correction request unit 15 Irradiation dose management component 151 Database search unit 152 Cumulative dose calculation unit 153 Cumulative dose determination unit 154 Treatment result storage processing unit 155 Irradiation dose correction request unit 16 Communication interface 1000 Radiation therapy system 1001 Image Diagnostic device 1002 Radiation irradiation device L LAN
N Internet W WAN

Claims (14)

A plan input means for inputting a radiotherapy treatment plan for irradiating the affected area with radiation multiple times;
Plan storage means for storing the treatment plan;
Storage means for accumulating in association the plan determination factor information of the treatment plan of the radiation therapy performed in the past and the irradiation dose information of each irradiation in the past radiation treatment,
Based on the plan decision factor information of the new treatment plan input by the plan input means, the plan decision factor information of the treatment plan of the radiation therapy performed in the past is retrieved from the storage means, and the past is implemented in the past a first retrieval means for search the dose information associated with planning determinant information of the radiation therapy treatment plan is,
An allowable range calculating means for calculating an allowable range of the total irradiation dose in the new treatment plan based on the past irradiation dose information searched by the first search means ;
Plan dose determination means for determining whether the total irradiation dose of the new treatment plan calculated by the allowable range calculation means is included in the allowable range ;
A radiation therapy management system comprising:   The plan correction requesting means for requesting correction of the new treatment plan when the total dose is determined not to be included in the allowable range by the planned dose determination means. The radiation therapy management system described.   The allowable range calculating means calculates the total irradiation dose for each of the radiation treatments by adding the irradiation dose indicated in the searched irradiation dose information for each of the past radiation treatments, The radiotherapy management system according to claim 1 or 2, wherein the allowable range is calculated based on a total irradiation dose for each radiotherapy.   The radiotherapy according to claim 3, wherein the allowable range calculation unit calculates an average value of the calculated total irradiation doses of the respective radiotherapy, and calculates the allowable range including the average value. Management system. Factor storage means for storing in advance a plurality of plan determination factors related to the determination of a treatment plan;
Operation means;
Factor setting means for setting a plan determining factor selected by the operating means from the stored plurality of plan determining factors as a management determining factor to be applied to radiation therapy management;
Further comprising
The first search means searches the irradiation dose information from the storage means using the plan decision factor information about the management decision factor as a search condition.
The radiation therapy management system according to any one of claims 1 to 4, wherein Server,
A client connected to the server through a network and having plan input means for inputting a radiation therapy treatment plan for irradiating the affected area a plurality of times; and a plan storage means for storing the treatment plan;
A radiation therapy management system comprising:
The server
A storage means for storing the plan determination factor information of the treatment plan of the radiation therapy performed in the past and the irradiation dose information of each irradiation in the past radiation therapy in association with each other,
The storage unit is searched for the irradiation dose information associated with the plan decision factor information of the past treatment plan corresponding to the plan decision factor information of the new treatment plan input by the plan input unit of the client. A first search means;
An allowable range calculating means for calculating an allowable range of the total irradiation dose of the new treatment plan based on the searched past irradiation dose information;
Plan dose determination means for determining whether the total irradiation dose of the new treatment plan is included in the allowable range ;
Comprising
A radiation therapy management system characterized by that.   The server includes a plan correction requesting unit that requests correction of the new treatment plan when the total dose is determined not to be included in the allowable range by the planned dose determination unit. The radiation therapy management system according to claim 6. A plan storage means for storing a radiotherapy treatment plan for irradiating the affected area with radiation over a plurality of times;
Irradiation control means for controlling a radiation irradiation apparatus for irradiating radiation;
A radiation therapy management system comprising:
An accumulating unit for accumulating irradiation dose information in radiation irradiation performed in the past by the radiation irradiation device;
Before the current irradiation by the radiation irradiation device, comprising an irradiation dose acquisition means for acquiring a set value of the irradiation dose in the current irradiation,
A second search means for searching for the irradiation dose information in the past irradiation based on the treatment plan including the current irradiation from the storage means;
A cumulative dose calculating means for calculating the cumulative dose until the current irradiation by adding the acquired setting value of the current irradiation dose and the searched past irradiation dose information;
Cumulative dose determination means for determining whether the calculated cumulative dose exceeds a predetermined value;
With
The irradiation control means causes the radiation irradiation apparatus to perform the current irradiation when it is determined that the cumulative dose does not exceed the predetermined value.
A radiation therapy management system characterized by that.   9. The irradiation dose correction requesting unit that requests correction of the current irradiation dose when the cumulative dose determination unit determines that the cumulative dose exceeds the predetermined value. The radiation therapy management system described in 1.   9. An irradiation prohibition processing unit for prohibiting radiation irradiation by the radiation irradiation apparatus when the cumulative dose determination unit determines that the cumulative dose exceeds the predetermined value. The radiation therapy management system according to claim 9. A means for transmitting a message requesting input of a predetermined password to a predetermined doctor terminal when the cumulative dose determination means determines that the cumulative dose exceeds the predetermined value;
The irradiation prohibition processing means cancels the prohibition of radiation irradiation when the password is input.
The radiation therapy management system according to claim 10.   9. The radiation therapy management system according to claim 8, further comprising means for storing the irradiation dose of the current irradiation performed by the radiation therapy apparatus in the storage means as the irradiation dose information. Server,
A client having a plan storage means for storing a treatment plan of radiation therapy for irradiating the affected area with radiation a plurality of times, and an irradiation control means for controlling the radiation irradiation apparatus for irradiating the radiation, connected to the server through a network;
A radiation therapy management system comprising:
The client comprises an irradiation dose acquisition means for acquiring a setting value of an irradiation dose in the current irradiation before the current irradiation by the radiation irradiation device,
The server
An accumulating unit for accumulating irradiation dose information in radiation irradiation performed in the past by the radiation irradiation device;
A second search means for searching for the irradiation dose information in the past irradiation based on the treatment plan including the current irradiation from the storage means;
The cumulative dose until the current irradiation is calculated by adding the set value of the current irradiation dose acquired by the irradiation dose acquisition means of the client and the searched past irradiation dose information. Cumulative dose calculation means to
Cumulative dose determination means for determining whether the calculated cumulative dose exceeds a predetermined value;
With
The irradiation control means of the client causes the radiation irradiation apparatus to perform the current irradiation when the cumulative dose determination means of the server determines that the cumulative dose does not exceed the predetermined value.
A radiation therapy management system characterized by that.   The server includes an irradiation dose correction requesting unit that requests correction of the current irradiation dose when the cumulative dose determination unit determines that the cumulative dose exceeds the predetermined value. The radiation therapy management system according to claim 13.

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