ITVI20130149A1 - DEVICE FOR RADIOTHERAPY TREATMENT OF ONCOLOGIC DISEASES - Google Patents

Description

DEVICE FOR RADIOTHERAPY TREATMENT

OF ONCOLOGICAL DISEASES

The present invention relates to a device for the radiotherapy treatment of cancer patients.

More specifically, the invention relates to a device suitable for instantaneous measurement of the dose per pulse emitted during a radiotherapy treatment carried out with charged particles (electrons, protons, carbon ions) and irradiated on organs and tissues downstream of this device; the invention also relates to an intraoperative radiotherapy (IORT) machine equipped with this device.

This is achieved through a system of integrated passive resonant cavities for instant or real time measurement of the output electron beam of a charged particle accelerator for radiotherapy. It is known that intraoperative radiotherapy (IORT) is an innovative technique that is progressively spreading worldwide in the treatment of various neoplastic forms, also thanks to the development of mobile machines; in particular, intraoperative radiotherapy consists of irradiation performed during the surgical removal of the tumor mass, which is generally carried out using a diffuse and uniform beam of electrons with kinetic energy between 4 and 12 MeV as ionizing particles. In particular, IORT is a radiotherapy treatment modality, which consists in administering a high dose (about 1/3 of that of a traditional RT) of radiation to the tumor residue or to the tumor bed surgically exposed through a collimated electron beam.

Among the most feared diseases of our times, there is no doubt that cancer is to be considered of the fore due to the mortality rate that some types of cancer present and the difficulty of treatment.

Tumor, or, less commonly, neoplasm or cancer, if malignant, is a class of diseases characterized by an uncontrolled reproduction of some cells of the organism, which stop responding to the physiological mechanisms of cellular control following damage to their genetic heritage .

A cell, to become a tumor, must go crazy, that is, there must be an error in the system that controls its reproduction.

In fact, all cancerous and precancerous cells present very extensive alterations of their chromosomal structure; in particular, the number of chromosomes present in their nucleus is altered and the chromosomes themselves are damaged, multiple or missing.

The chromosomal alteration of cancer cells is so severe and extensive that it provides evidence that in each case of cancer all cancer cells descend from a single mutated mother cell.

This random genetic disorder explains the extreme variability in appearance, effects, symptoms and prognosis of the many known forms of cancer.

Therefore, although the general mechanism of origin is unique, tumors can manifest a very wide range of evolutions and symptoms.

However, in all of them there is a constant increase in the number of cancer cells, due to the greater speed of cellular reproduction, so that a greater number of cancer cells multiply and fewer of them die, while those that survive continue to multiply.

Usually the growth of a tumor follows a geometric law: it is very slow at first, but accelerates as the tumor mass increases.

The critical size of a tumor is approximately one cubic centimeter; reached this size, the tumor begins to grow very quickly and to give rise to the first symptoms and becomes detectable with medical visits and analyzes; however, the initial symptoms are often ignored or underestimated.

The great speed of reproduction of cancer cells is at the basis of the need and urgency to treat it as soon as possible and as drastically as possible, that is, making sure to eliminate all the "infected" cells with the greatest degree of certainty, since, for that that has been said previously, the tumor can evolve, and therefore be reborn, even from a single mutated cell.

The best known cancer treatment is surgery. With it, if possible, we try to remove what is called a tumor mass, that is, the set of mutated cells, and what surrounds them.

This method of treatment is not always usable or, when used, it is not always sufficient to ensure the desired result.

In fact, it is not possible to know whether the tumor has also affected the surrounding or adjacent cells, which appear healthy; moreover, it is possible that the surgical operation itself leads to the dissemination of cancer cells. For these reasons, chemotherapy and radiotherapy are also used in combination or as an alternative to surgery.

Radiotherapy consists of irradiating, by means of ionizing radiation, the neoplastic tissues and / or adjacent to the neoplasm.

Chemotherapy exploits the specific sensitivity of individual tumors to certain substances and for each patient a personalized mixture of several drugs is studied and almost always, in this mixture, one or more mitosis inhibitors are present to hinder cell proliferation.

However, these are responsible for some serious and unwanted side effects, such as hair loss and hair loss, which afflicts patients undergoing chemotherapy.

Radiation therapy also has undesirable effects. In fact, like chemotherapy, it considerably weakens the body and subjects the patient's healthy organs to its direct effects, even if only partially.

In both cases, therefore, it is important to be able to minimize their application in order not to make the side effects become too relevant.

The technological development of recent years has led, through the development of various technologies and through the use of increasingly sophisticated "imaging" techniques, to optimize the deposition of the dose of ionizing radiation on the target, guaranteeing a safeguard of the healthy tissues of the critical organs. .

Therefore, for the reasons set out above, a common element to every particle accelerator intended for radiotherapy is the need to include a system for real-time measurement of the ionizing radiation output and the dose of ionizing radiation to be sent to the target for each pulse of radiation emitted. The main object of the present invention is therefore to provide a device for the radiotherapy treatment of oncological patients, which allows the radiation output of a medical accelerator of charged particles to be measured in real time.

Another object of the present invention is to provide a device for the radiotherapy treatment of cancer patients, whose minimum characteristics are suitable for complying with the technical standard EN 60601-2-1, ed. III.

A further purpose of the invention is to create a device for the radiotherapy treatment of cancer patients, which uses a measurement system composed of two subsystems, independent of each other and at least one of which cross-over, according to the requirements of the technical standard EN 60601- 2-1.

These and other objects are achieved by a device for the radiotherapy treatment of cancer patients according to the attached claim 1; other detailed technical characteristics are contained in the subsequent claims.

Another object of the present invention is a machine for the treatment of intraoperative radiotherapy (IORT), which incorporates the device for the radiotherapy treatment of oncological patients as described above according to claim 10.

Advantageously, the treatment device which is the subject of the present invention is advantageous with respect to traditional devices, which are based on ionization chambers and whose problems have long been known and well present in the literature, especially for accelerators dedicated to IORT, where it is not It is possible to use sufficiently massive scattering filters to obtain an almost uniform fluence on the surface of the chamber.

Furthermore, the proposed device, as will be illustrated below, allows a direct measurement of a physical observable, the current, immediately correlated to the dose deposition on the target.

Finally, the proposed device is intrinsically linear and not subject to saturation phenomena as can happen for monitor cameras.

The present invention will now be described, for illustrative but not limitative purposes, according to a preferred embodiment thereof, with particular reference to the attached figures, in which:

Figure 1 is a perspective view of the device for the radiotherapy treatment of cancer patients, according to the present invention; - Figure 2 is a perspective view from above of the device for the radiotherapy treatment of cancer patients, according to the present invention; - Figure 3 is a top plan view of the device for the radiotherapy treatment of cancer patients, according to the present invention; Figure 4 is a first side view of the device for the radiotherapy treatment of cancer patients, according to the present invention; Figure 5 is a second side view of the device for the radiotherapy treatment of cancer patients, according to the present invention; figure 6 is a third side view of the device for the radiotherapy treatment of cancer patients, according to the present invention; Figure 7 is a partial and partially sectional view of the device for the radiotherapy treatment of cancer patients connected to a source of charged particles of an accelerator of an intraoperative radiotherapy (IORT) machine, according to the present invention.

With reference to the aforementioned figures, the device for the radiotherapy treatment of oncological patients, according to the present invention, is placed at the outlet of the medical accelerator of charged particles and consists of a crossing system consisting of two independent subsets, which allow to obtaining a real-time reading of the dose of particles leaving the accelerator, intrinsically proportional to the deposition of the aforementioned dose on the target.

In particular, the device includes two or more passive resonant cavities 10, each of which tuned to the same resonant frequency of the way in which the accelerating guide 11 operates and mechanically integral with each other, so as to be able to be simultaneously thermostated.

The signal is picked up by means of a capacitive pick-up 12 (loop or coil), placed in the vicinity of the internal diameter of the cavities 10; moreover, the cavities 10 are oriented so as to have the surface perpendicular to the lines of the magnetic field generated by the passage of the beam current.

The device can obviously be implemented for any radiofrequency accelerating structure, regardless of the working frequency (L, S, C or X band); in particular, the device provides a direct measure of the dose for all medical accelerators that use charged particles, whether they are electrons, protons, ions.

The operation of the device for the radiotherapy treatment of cancer patients is essentially the following.

The current accelerated by an electron accelerator (LINAC) powered by a radiofrequency source (klystron, magnetron) can always be represented as a Fourier series of sine only, with a fundamental frequency equal to the frequency ω0 of the operating mode of the accelerating guide, in the following way:

The magnetic field generated by the electron beam in correspondence of the loop results to be given by:

while the field actually detected, due to the filtering effect of the resonant cavity, results

,

where d is the distance between the electron beam and the center of the loop, µ0 is the magnetic permeability of the vacuum and the first harmonic.

The passive resonant cavities 10 are tuned in such a way as to have a resonance frequency equal to ω0 at the desired operating temperature and the voltage measured at the ends of the loop is thus given by:

,

being A the area of the coil.

The signal, integrated over time by means of a special electronic circuit, therefore provides an intrinsically proportional measure to the charge carried by the beam and, therefore, to the dose deposition.

The metal material of each resonant cavity 10 is chosen so as to simultaneously comply with the need to ensure efficient thermostating of the double resonant cavity; moreover, two resonant cavities 10 are used for measuring the beam current.

The response of the measurement system is independent of the environmental conditions (temperature, pressure and humidity) and, furthermore, the main advantage of the system in question is the linearity of the response with respect to the current, at a given predetermined energy; this makes the system in question preferable to the use of ionization chambers.

The two resonant cavities 10 are made to measure independently of each other, according to the requirements of the technical standard EN 60601-2-1.

The request implies that electromagnetic isolation between the two cavities is guaranteed.

The scattering parameter S12 measured between the two cavities 10 must be less than -30dB; this guarantees that the maximum possible variation of the electrical signal measured at the output interface (identifiable with the connection connector of the loop on which the transmission line that carries the signal in question to the acquisition device is inserted) of one of the two cavities 10 , caused by the other cavity, is less than 0.1%.

The device according to the invention achieves this result in at least three different ways:

a) through the use of a beam transport channel, which joins the two cavities 10, of such length and diameter that the above condition on the electromagnetic insulation is respected and that the cross section of the beam of charged particles along the path traveled inside the resonant cavity system is less than the radius (or section) of the transport channel in question;

b) by inserting a third resonant cavity, placed between the two cavities 10, tuned to a significantly different frequency;

c) through a geometry of the beam transport channel that inside it dampens the electromagnetic field at the resonant frequency of the integrated cavities taken individually.

Furthermore, the sizing of the loop must be such as to guarantee:

• an adequate signal / noise ratio;

• electromagnetic isolation between the two cavities. The implementation of this system varies depending on:

• working frequency of the accelerating guide, which determines, as a first approximation, the dimensions of each resonant cavity;

• the atmosphere inside the system (air, specific mixture of gas or vacuum);

• the type of charged particle in question.

The solution presented in the figures refers to an accelerating guide for electrons operating at 2998 MHz, with a system of resonant cavities integrated in the air. The attached figures also refer to cavities 10 made in S band, resonant at 2998 MHz, decoupled from each other, separately tunable and globally thermostated, as well as each of them equipped with a magnetic pick-up 12.

The illustrated system consists in particular of two resonant cavities with circular sections with cylindrical drift channel; the drift channel that integrates the two cavities consists of a cylinder with an internal diameter of 20 mm and a height of 24 mm and the coils have a rectangular section with a side equal to 3 mm and a second side variable in the range of values 2-4 mm.

From the above description the characteristics of the device for the radiotherapy treatment of oncological patients, which is the object of the present invention, are clear, as are the advantages.

Finally, it is clear that numerous other variations can be made to the device in question, without thereby departing from the novelty principles inherent in the inventive idea, just as it is clear that, in the practical implementation of the invention, the materials, the shapes and the dimensions of the illustrated details may be any according to requirements and the same may be replaced with other technically equivalent ones, without thereby departing from the relative scope of protection as defined by the attached claims.

Claims (10)

CLAIMS 1. Device for the radiotherapy treatment of cancer patients, said device being placed at the exit of an accelerating guide of a radiofrequency medical accelerator of charged particles and being constituted by a crossing system consisting of two independent subsets, which allow to obtain a real-time reading of the dose of said charged particles leaving said accelerator, said dose leaving said accelerator being intrinsically proportional to the dose of charged particles deposited on a target, characterized in that said device includes two or more resonant cavities passive (10), each of which tuned to the same resonant frequency as the way in which the accelerating guide (11) of said charged particle accelerator operates, said resonant cavities (10) being mechanically integral with each other, so as to be able to be simultaneously thermostated. 2. Device as claimed in claim 1, characterized in that a signal is picked up by means of a capacitive pick-up (12), placed in the vicinity of the internal diameter of said cavities (10). 3. Device as claimed in at least one of the preceding claims, characterized in that said resonant cavities (10) are oriented so as to have the surface perpendicular to the lines of the magnetic field generated by the beam current. 4. Device as per at least one of the preceding claims, characterized in that said passive resonant cavities (10) are tuned to a resonant frequency equal to the frequency of the operating mode of said accelerating guide, at a predetermined operating temperature. 5. Device as claimed in at least one of the preceding claims, characterized in that each cavity (10) is made of metallic material. 6. Device as per at least one of the preceding claims, characterized in that said device includes two resonant cavities (10) for measuring the beam current, made to measure independently of each other. 7. Device as claimed in at least one of the preceding claims, characterized in that the scattering parameter S12 measured between said two cavities (10) is lower than -30dB. 8. Device as claimed in at least one of the preceding claims, characterized in that a transport channel for the beam of charged particles joins said two resonant cavities (10). 9. Device as per at least one of the preceding claims, characterized in that a third resonant cavity is placed between said two cavities (10) and is tuned to a frequency other than the tuning frequency of said two cavities (10). 10. Intraoperative radiotherapy (IORT) machine comprising a radiotherapy treatment device as per at least one of claims 1-9.