RAD 561 RADIOTHERAPY Chapter5.pdf

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Chapter 5

TREATMENT MACHINES FOR EXTERNAL BEAM
RADIOTHERAPY

E.B. PODGORSAK
Department of Medical Physics,
McGill University Health Centre,
Montreal, Quebec, Canada

5.1. INTRODUCTION

Since the inception of radiotherapy soon after the discovery of X rays by
Roentgen in 1895, the technology of X ray production has first been aimed
towards ever higher photon and electron beam energies and intensities, and
more recently towards computerization and intensity modulated beam
delivery. During the first 50 years of radiotherapy the technological progress
was relatively slow and mainly based on X ray tubes, van de Graaff generators
and betatrons.
The invention of the 60Co teletherapy unit by H.E. Johns in Canada in the
early 1950s provided a tremendous boost in the quest for higher photon
energies and placed the cobalt unit at the forefront of radiotherapy for a
number of years. The concurrently developed medical linacs, however, soon
eclipsed cobalt units, moved through five increasingly sophisticated
generations and became the most widely used radiation source in modern
radiotherapy. With its compact and efficient design, the linac offers excellent
versatility for use in radiotherapy through isocentric mounting and provides
either electron or megavoltage X ray therapy with a wide range of energies.
In addition to linacs, electron and X ray radiotherapy is also carried out
with other types of accelerator, such as betatrons and microtrons. More exotic
particles, such as protons, neutrons, heavy ions and negative p mesons, all
produced by special accelerators, are also sometimes used for radiotherapy;
however, most contemporary radiotherapy is carried out with linacs or
teletherapy cobalt units.

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5.2. X RAY BEAMS AND X RAY UNITS

Clinical X ray beams typically range in energy between 10 kVp and
50 MV and are produced when electrons with kinetic energies between 10 keV
and 50 MeV are decelerated in special metallic targets.
Most of the electron’s kinetic energy is transformed in the target into
heat, and a small fraction of the energy is emitted in the form of X ray photons,
which are divided into two groups: characteristic X rays and bremsstrahlung X
rays.

5.2.1. Characteristic X rays

Characteristic X rays result from Coulomb interactions between the
incident electrons and atomic orbital electrons of the target material (collision
loss).
In a given Coulomb interaction between the incident electron and an
orbital electron, the orbital electron is ejected from its shell and an electron
from a higher level shell fills the resulting orbital vacancy. The energy
difference between the two shells may either be emitted from the atom in the
form of a characteristic photon (characteristic X ray) or transferred to an
orbital electron that is ejected from the atom as an Auger electron.

The fluorescent yield w gives the number of fluorescent (characteristic)
photons emitted per vacancy in a shell (0 < _ w