At the Swiss Paul Scherrer Institute's Center for Proton Therapy, they treat cancer patients and do research for optimized radiotherapy.
Text: Paul Scherrer Institute/Brigitte Osterath
On 25 November 1996, the Center for Proton Therapy at the Paul Scherrer Institute treated a cancer patient using the spot-scanning technique for the very first time – a world premiere. This technique developed at PSI scans and irradiates deep-seated tumors with a pencil-thin beam of charged particles, killing cancer cells with extreme precision while preserving the surrounding healthy tissue. Meanwhile, this technique has become a standard procedure worldwide and since 1996 has been used to treat around 2000 cancer patients at PSI alone – over a third of them children and young people. The fact that the success story started at PSI was more than just a coincidence.
It was Monday, and the team was gathered in the control room at the Center for Proton Therapy. "We were huddled together, peering anxiously at the monitor relaying images from the treatment room," recalls Martin Grossmann, a physicist with the Center for Proton Therapy (CPT) at PSI. Back in the 1990s he was part of a team of 15 researchers led by Hans Blattmann, Eros Pedroni and Gudrun Goitein developing a new technology for treating cancer patients: spot scanning, also known as pencil beam scanning.
The moment of truth came on 25 November 1996: a human patient lay waiting in the treatment room. The 62-year old man from the Canton of Lucerne had malignant skin cancer that had already formed metastases in his brain. The purpose of the intervention was to irradiate these rogue metastases using the new technique.
Despite meticulous preparations, the team was nervous. "You can treat as many plastic dolls or models as much as you want, but when you have a live patient lying there, it’s a totally different experience," says the medical physicist Tony Lomax, one of the development team. That Monday he helped to place the patient in the exact position for the proton beams to precisely target the area of the body to be irradiated. The tolerance was a question of millimeters: "A proton beam is like an extremely sharp tool," Martin Grossmann stresses. "There is no room for error."
A huge success
The team of specialists ensured that the technology functioned smoothly and eventually everyone was able to breathe a sigh of relief: the treatment had gone exactly as planned – just as Martin Grossmann and Tony Lomax had expected. "We were all firmly convinced we had mastered the technology. We made a huge effort to ensure that everything was absolutely safe for the patient," Grossmann notes.
In the following year, CPT moved on to successfully treat several other cancer patients. The medical world was initially skeptical – the technology seemed too unmanageable at the time. During the ten years up to 2008, the Paul Scherrer Institute was the only facility in the world to use this technique. Since then, spot scanning has become established worldwide and now ranks as standard procedure for proton therapy.
Eradicating the tumor
"Proton therapy has completely revolutionized the battle against cancer," says Damien Weber, senior clinician and head of CPT. In proton therapy, a proton beam – a concentrated beam of rapidly moving, charged particles – kills cancer cells by destroying their DNA. Conventional radiation therapy works on the same principle, but uses X-rays rather than protons to destroy the malignant cells.
Protons have a big advantage over more energy-intense radiation, however, Weber goes on to explain. They can be precisely targeted to the specific area of the body, where they unleash their destructive effect. "Undesirable side-effects caused by radiation are therefore much less common, which makes the method especially suitable for children, but also for tumors in particularly sensitive or inaccessible areas of the body." Tumors in the region of the head, neck or spine are typical candidates for treatment.
For a long time the medical profession favored the scattering technique for proton therapy. With this method, the proton beam is spread out and, using an individually tailored metal aperture plate, filtered to match its shape to the size and contour of the tumor. Today this is still the preferred method for treating eye tumors. Not so for deeper-seated tumors.
"We already knew the spot scanning technique would offer a lot of advantages here," says Tony Lomax. The malignant tissue is scanned with the proton beam – "a bit like sketching its outline with a pencil," Lomax explains. Or rather rubbing it out with an eraser. The exact position of the tumor is determined beforehand with the help of imaging techniques such a CT or MRI scan, and the proton beam programmed so that precisely the right amount of charged particles is targeted at the areas to be treated.
PSI’s location advantage
Looking behind the scenes at the Center for Proton Therapy, it soon becomes clear why this technology could only have been developed at PSI rather than in a hospital, for example. The radiation unit (called a gantry) itself is the size of a large truck, and even bigger and more complex equipment is needed to generate the proton beams and deliver them to the gantry.
"Here we are actually working with applied accelerator physics," says Martin Grossmann. “We need measurement devices that control the path of the beam. We need ultrafast electronics to control the magnets used. And above all we need highly qualified people with the skills to build such a machine. These can’t be found in a hospital.”
The concept of spot scanning first arose in Japan. "But our team at CPT was brave enough to say at the time: let’s actually try using that technique," Grossmann. The resulting success story has been a blessing for cancer patients over the past 25 years – and beyond.
Click images to expand!
World’s first proton therapy facility to employ the spot scanning method
(Photo: Paul Scherrer Institute)
Gantry 3, the newest treatment station at PSI
(Photo: Paul Scherrer Institute)
Gantry 3 (close-up of the treatment station)
(Photo: Scanderbeg Sauer Photography)
How pencil beam scanning conquered the world
(Graphic: Paul Scherrer Institute/Mahir Dzambegovic)
About PSI
The Paul Scherrer Institute PSI develops, builds and operates large, complex research facilities and makes them available to the national and international research community. The institute's own key research priorities are in the fields of matter and materials, energy and environment and human health. PSI is committed to the training of future generations. Therefore about one quarter of our staff are post-docs, post-graduates or apprentices. Altogether PSI employs 2100 people, thus being the largest research institute in Switzerland. The annual budget amounts to approximately CHF 400 million. PSI is part of the ETH Domain, with the other members being the two Swiss Federal Institutes of Technology, ETH Zurich and EPFL Lausanne, as well as Eawag (Swiss Federal Institute of Aquatic Science and Technology), Empa (Swiss Federal Laboratories for Materials Science and Technology) and WSL (Swiss Federal Institute for Forest, Snow and Landscape Research).
