Irregularly shaped lesions with awkward configurations near critical structures are well suited for proton beam therapy. Protons have a physical advantage over gamma rays and x-rays when it comes to sparing normal tissues. Protons deposit most of their radiation energy in what is known as the Bragg peak, which occurs at the point of greatest penetration of the protons in tissue. The exact depth to which protons penetrate, and at which the Bragg peak occurs, is dependent on the energy of the proton beam. This energy can be very precisely controlled to place the Bragg peak within a tumor or other tissues that are targeted to receive the radiation dose. Because the protons are absorbed at this point, normal tissues beyond the target receive very little or no radiation.

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Radiation levels from a conventional x-ray therapy unit (Linac) and protons of various energies as they penetrate in tissue or water. X-rays have a maximum dose near the surface followed by a continuously reducing dose with depth. Proton energy can be adjusted to match the depth of the target with a sharp drop in dose beyond the Bragg peak.

The figure on the right shows a widened proton beam as well as an x-ray beam adjusted to treat an 8 cm thick target with a maximum depth of 23 cm. The x-ray beam “spills” unnecessary dose beyond the target compared to protons.

The proton Bragg peak is generally narrower than most lesions therefore special equipment is used to combine protons of various energies to broaden the Bragg peak to match the thickness of individual targets. Properly selecting the thickness of the broadened Bragg peak ensures uniform dose coverage of a target with optimal reduction of dose at the entry surface of the beam.

Tumors can have very irregular shapes and can be located close to critical organs. Every patient’s tumor shape, size and location are unique. Patient specific hardware, which helps sculpt the proton beam, is customized to maximize the dose to the tumor while minimizing the dose to normal structures. Aiming proton beams, each with customized hardware, from various directions further ensures that the dose to normal tissues is reduced as much as possible therefore reducing the risk of treatment related complications.

Pictured Above: Customized dose-shaping devices used for proton beam therapy. A brass aperture shaped to the outline of a target blocks the proton beam outside a specified safety margin. The penetration depth of the protons that pass through the aperture opening is adjusted to match the shape of the target with a Lucite range compensator. A target is depicted in red on the rightmost figure with the proton radiation dose conforming to its shape and avoiding a critical structure shown in green.