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Linear Accelerators

Linear Accelerators. Chapter 7 W/L Chapter 9 S/S. Radiation Therapy Equipment. Low-energy machines: Uses x-rays generated at voltages up to 300kVp Grenz rays 10-15kVp Treatment of inflammatory disorders (Langerhans’ cells), Bowen’s disease, patchystage mycosis fungoides, herpes simplex

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Linear Accelerators

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  1. Linear Accelerators Chapter 7 W/L Chapter 9 S/S

  2. Radiation Therapy Equipment • Low-energy machines: Uses x-rays generated at voltages up to 300kVp • Grenz rays • 10-15kVp • Treatment of inflammatory disorders (Langerhans’ cells), Bowen’s disease, patchystage mycosis fungoides, herpes simplex • Contact therapy • Superficial skin lesions • Endocavitary treatments for curative intent (rectal) • hemangiomas • Superficial equipment • 50-150kVp • Skin cancer and tumors no deeper than 0.5 cm • Orthovoltage machines • 150-500kVp • Skin, mouth, and cervical carcinoma • Experience limitation in the treatment of lesions deeper than 2 to 3 cm.

  3. Limitations of Low Energy Machines • Can not reach deep-seated tumors with an adequate dosage of radiation. • Do not spare skin and normal tissues.

  4. Central Axis Depth Dose • Central axis depth dose and physical penumbra are related to beam quality. • The central axis depth dose distribution for a specific beam depends on the energy. • Isodose curve: a line representing various points of similar value in a beam along the central axis and elsewhere • The depth of an isodose curve increases with beam quality • The absorbed dose in the medium outside the primary beam is greater for low-energy beams than for those of a higher energy. • Limited scatter outside the field for megavoltage beams occurs because of predominantly forward scattering of the beam.

  5. Linear Accelerator • Treatment machine that uses high-frequency electromagnetic waves to accelerate charged particles such as electrons to high energies via a linear tube. • Charged particles travel in straight lines as they gain energy from an alternating electromagnetic field. • Higher energy beams can be generated with greater skin sparing, field edges are more sharply defined with less penumbra and computer technology shapes the treatment beam and personnel receive less exposure to radiation leakage.

  6. History • 1948: A working 1MV linear accelerator was installed at the Fermi Institute in Chicago. • Mile long waveguide ran under University Boulevard at the University of Chicago. • 1948: the British Ministry of Health brought together the three main groups in England who were working on the linac. • Medical Research Council • Atomic Energy Research Establishment • Metropolitan Vickers Electric Company • 1952: linac installed at Hammersmith Hospital in London, first treatment in 1953 with an 8MV beam. • 1956: first clinically used in the US at the Stanford University Hospital. • 1961: The first 100 cm SAD fully isocentric linear accelerator was manufactured and installed in the US.

  7. Accelerator Generations • Early Accelerators (1953-1961): • Extremely large and bulky • Limited gantry motion • Second Generations (1962-1982): • 360 degree rotational • Allow treatment to a patent from any gantry angle • Improvement in accuracy and dose delivery • Third generation accelerators: • Improved accelerator guide • Magnet systems • Beam-modifying systems to provide wide ranges of beam energy, dose rate, field size • Operating modes with improved beam characteristics • Highly reliable • Compact design • May include: dual photon energies, multileaf collimation, several electron energies & electronic portal verification systems

  8. Modulator cabinet Console Drive Stand Klystron Waveguide Circulator Water-cooling system Gantry Electron gun Accelerator structure Treatment head Bending magnet Flattening filter Scattering foil Treatment couch Other accessories Components

  9. Modulator Cabinet • Modulator cabinet: contains components that distribute and monitor primary electrical power and high-voltage pulses to the magnetron or klystron • Located in the treatment room • Three major components: • The fan control: automatically turns the fans off and on as the need arises for cooling the power distribution • Auxiliary power-distribution system: contains the emergency off button that shuts off the power to the treatment unit. • Primary power-distribution system

  10. Console • Console electronic cabinet: provides a central location for monitoring and controlling the linac • Take the form of a digital display, push button panel or video display terminal (VDT) • All interlocks must be satisfied for the machine to allow the beam to be started • Provides a digital display for prescribe dose (monitor units), mechanical beam parameters such as collimator setting or gantry angle

  11. Drive Stand • Drive Stand: a stand containing the apparatus that drives the linear accelerator • Open on both sides with swinging doors for easy access to gauges, valves, tanks, and buttons • Klystron/Magnetron: power source used to generate electromagnetic waves for the accelerator guides • Waveguide: hollow tube-like structure that guide the electromagnetic waves from the magnetron to the accelerating guide where electrons are accelerated • Circulator: directs the RF energy into the waveguide and prevents any reflected microwaves from returning to the klystron • Water-cooling system: allows many components in the gantry and drive stand to operate at a constant temperature

  12. Klystron • Klystron: A linear beam microwave amplifier requiring an external oscillator or radiofrequency (RF) source driver • A form of radiowave amplifier, multiplies the amount of introduced radiowaves greatly. • Electron tube that is used to provide microwave power to accelerate electrons • Microwave frequencies needed for linear accelerator operation are about three billion cycles per second

  13. Magnetron • Magnetron: device that provides high-frequency microwave power that is used to accelerate the electrons in the accelerating waveguide. • Electrons are emitted from the cathode and spiral in the perpendicular magnetic field. The interaction of the spiraling electrons with the cavities in the anode creates the high-frequency EM waves. • oscillator and amplifier used in low-energy

  14. Gantry • Gantry: responsible for directing the photon (x-ray) energy or electron beam at a patients tumor. • Electron gun: produce electrons and injects them into the accelerator structure • Accelerator structure: a special type of wave guide in which electrons are accelerated. • Treatment head: components designed to shape and monitor the treatment beam

  15. Accelerator Structure • Microwave power (produced in the klyston) is transported to the accelerator stricture in which corrugations are used to slow up the waves synchronous with the flowing electrons. After the flowing electrons leave the accelerator structure, they are directed toward the target (for photon production) or scattering foil (for electron production) located in the treatment head. • Amplification that occurs in the accelerator structure is in the closed ended, precision crafted copper cavities where the electrical power provides momentum to the low-level electron stream mixed with the microwaves. Alternating positive and negative electric charge accelerates the electrons toward the treatment head, the negative voltage repels electrons while the positive voltage attracts then, thereby pushing and pulling the electrons along. • Charged particles experience the equivalent of a small voltage multiple times, ending up with a large amount of kinetic energy

  16. Accelerator Structure • Length varies depending on the beam energy of the linac, as more cavities are used, higher energy is derived • Traveling wave: an electromagnetic wave travels to the right along with the electron, the electron is continuously accelerated as it moves • Limitation: the electron and the electric field must move at the same velocity • Irises: washer shaped metal discs that provide resistance to the travel of the electromagnetic waves. • As the electron increases in energy and velocity, the need for irises is reduced, so irises are increasingly far apart and have increasingly wider openings. • Standing wave: microwave power is joined into the structure by side-coupling cavities, rather than through the beam aperture, provides a shorter accelerating tube • Makes use of the concept if interference • More efficient, more costly

  17. Treatment head • Treatment head: components designed to shape and monitor the treatment beam • Bending magnet: direct the electrons vertically toward the patient • X-ray target: • Primary collimator: designed to limit the maximum field size • Beam flattening filter: shaped the x-ray beam in its cross sectional dimension • Ion chamber: monitors the beam for its symmetry in the right-left and inferior-superior direction • Secondary collimators: upper and lower collimator jaws • Field light: outlines the dimensions of the radiation field as it appears on the patient, allows accurate positioning of the radiation field in relationship to skim marks or other reference points

  18. Bending Magnet • Bending magnet: bends the electron beam through a right angle, so it ends up pointed at the patient • 90 degree magnets (chromatic) have the property that any energy spread results in spatial dispersion of the beam. • Electrons are bent in proportion with their energy, the lower energy electrons are bent more, the higher energy electrons less • Results in a beam that is spread from side to side according to energy • Energy sensitive, act as energy differentiators • 270 degree magnets (achromatic) designed to eliminate spatial dispersion • So not significantly disperse the different electron energies in the beam.

  19. Flattening Filter • Flattening filter: (lead, steel, copper etc.) • Modifies the narrow, non-uniform photon beam at the isocenter into a clinically useful beam through a combination of attenuation of the center of the beam and scatter into the periphery of the beam • Measured in percent at a particular depth in a phantom (10 cm) • Must be carefully positioned in the beam or the beam hitting the patient will be non-uniform, resulting in hot and cold spots • Flatness: a wide beam that is nearly uniform in intensity from one side to the other (+/- 6%) • Symmetry: the measure of intensity difference between its opposite sides (+/- 4%) • Causes include the use of a wedge, misalignment of the flattening filter, and misdirection of the electron beam before hitting the target.

  20. Scattering foil • Scattering foil: thin metal sheets provide electrons with which they can scatter, expanding the useful size of the beam • Other accessories

  21. Monitor Chambers • Electron and photon beams must first be measured or monitored in order to allow delivery of the prescribed amount of radiation.

  22. Treatment Couch • Treatment couch: mounted on a rotational axis around the isocenter • Also called patient support assembly (PSA) • Move mechanically in a horizontal and lengthwise direction- must be smooth and accurate allowing for precise and exact positioning of the isocenter during treatment positioning • Support up to 450 lbs • Range in width from 45-50 cm • Racket-like frame should be periodically tightened to provide more patient support and reduce the amount of sag during treatment positioning.

  23. Multimodality Treatment • Multimodality treatment units offer several advantages: • Dual photon energies- they can provide backup for other treatment units that may experience down-time • Patients can be treated with multiple beam energies on the same treatment unit

  24. New Technologies • Three-dimensional conformal therapy (3D-CRT): the field shape and beam angle change as the gantry moves around the patient • Images from CT scanners are transferred to treatment planning computers, where normal tissues and tumor volumes are defined • “forward planning” process: beam arrangement are tested by trial and error • Intensity Modulated radiation therapy (IMRT): beneficial in escalating the dose to the tumor volume and reducing the dose to normal tissue • “inverse treatment planning”: the radiation oncologist selects dose parameters for normal tissues and the target volume and the computer back calculates the desired dose distribution and beam arrangements • Adjusts the intensity of radiation beam across the field with the aid of MLC moving in and out of the beam portal under precise computer guidance.

  25. Additional Advances • Independent collimators (dual asymmetrical jaws): provide increased flexibility in treatment planning • MLCs allow an increased number of treatment fields without the use of heavy Cerrobend blocking • Dynamic wedge: computerized shaping of the treatment field • Electronic portal imaging: provides feedback on single-event setup accuracy or observation of treatment in near real-time

  26. Additional Advances • Verification and record devices: • Allow incorrect setup parameters to be corrected before the machine is turned on • Provide data in computer assisted setup • Recording of patient data • Allowing for data transfer from the simulator or treatment planning computer • Assisting with quality control • Stereotactic radiation therapy: involves the aiming and delivery of a well defined narrow beam to extremely hard to reach places

  27. Interlocks • Designed to protect the patient, staff members and equipment from hazards • Patient protection interlocks, including beam energy, beam symmetry, dose, and dose-rate monitoring, prevent radiation and mechanical hazards to the patient • Emergency off buttons terminate irradiation and machine functions require a complete warm-up procedure before the treatment machine can produce an electron or photon beam

  28. High-energy Machines • High-energy machines • Van de Graaff generator • Betatron: particles travel in a circular pattern • Cyclotron: the particles travel in a spiral pattern • Linear accelerator • Cobalt unit

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