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Press release of January 9, 2023

Radioactive substances fight cancer in the mini-lab

Two Dresden research institutes want to reduce the number of animal experiments in radiopharmaceutical research with a new Idea

Radioactivity can save lives. When neither chemotherapy or surgery nor radiation from the outside help against a tumor, modern medicine uses so-called radiopharmaceuticals. These radioactive drugs not only detect cancer cells, they also enable targeted radiation from the inside to destroy the tumor. However, before such substances become available for use in humans, extensive animal testing is currently required during their development. A joint project of the Fraunhofer Institute for Material and Beam Technology IWS in Dresden and the Helmholtz-Zentrum Dresden-Rossendorf (HZDR) is currently researching an alternative method to this. Artificial organ structures and tumors in chip format form the basis for this.

Foto: Ein Projektteam von HZDR und Fraunhofer IWS forscht daran, mithilfe von sogenannten mikrophysiologischen Systemen Tierversuche zu reduzieren, die aktuell vor der Anwendung am Menschen notwendig sind. ©Copyright: Amac Garbe//Fraunhofer IWS

An HZDR and Fraunhofer IWS project team is researching how to use so-called microphysiological systems to reduce animal testing, which is currently necessary before human application.

Source: Amac Garbe//Fraunhofer IWS | Download

In 2021, a total of 1.86 million vertebrates and cephalopods were used for research purposes in Germany, according to information from the Federal Ministry of Food and Agriculture. Although this is two percent less than in the previous year, it is still a very large number. The animals most commonly used in German laboratories are mice, fish and rats. “Currently, many research tasks require the help of such animal experiments to be solved,” Dr. Wiebke Sihver from the HZDR's Radionuclide Diagnostics Department points out. This is why searching for alternative options remains enormously important, she adds. “In addition, animal models often lack important references to the human organism.”

In their work, Wiebke Sihver and her HZDR colleagues are concerned with the development and application of radiolabeled substances for cancer diagnostics and in particular also therapy. These radioligands are labeled with a radioactive nuclide (radionuclide) and bind to a target molecule, in the case of cancer to specific target structures of the tumor. The radiopharmaceutical thus acts directly on the tumor. Surrounding healthy tissue is spared. To date, radiopharmaceuticals developed at the HZDR have to be tested in animal models such as mice and rats after in vitro characterization. Several years ago Wiebke Sihver was already seeking a replacement for the many animal experiments in radiopharmaceutical research. During her search for alternative systems she quickly came across Fraunhofer IWS. There, a team has been researching for several years on microphysiological systems that use cultivated mini-organisms to mimic the functioning of the human organism – thanks to the use of human cells, for example, closer to the human tumor than animal experiments could.  It was the starting point for a new idea.

Foto: Radiopharmaka kommen zum Einsatz, wenn gegen einen Tumor Chemotherapie, Operation oder Bestrahlung wirkungslos geblieben sind. In mikrophysiologischen Systemen lassen sich 3D-Tumormodelle in einer realistischen Mikroumgebung kultivieren, was die Testung exakter und gleichzeitig einfacher macht. ©Copyright: Amac Garbe//Fraunhofer IWS

Radiopharmaceuticals enter the picture when chemotherapy, surgery or radiation have proven ineffective against a tumor. Microphysiological systems emulate the micro environment of the body and are an easy to use platform for the cultivation of 3D tumor models. Source: Amac Garbe//Fraunhofer IWS | Download

Development with great potential

Researchers at Fraunhofer IWS have already been working on the mini-labs for more than ten years. With these microphysiological systems in the format of a tablet box, organ functions or even disease processes can be artificially represented with the help of cell cultures. Valves and channels simulate the vascular system, a small pump the heartbeat. The chips are made of plastic films layered on top of each other. Blood vessels and chambers are cut into these by laser. In special modules, users later grow cell cultures that can survive for up to a month in the microfluidic systems. Meanwhile, blood circulates in the mini-lab in the form of a nutrient medium that supplies the cells with oxygen and nutrients. A few years ago, this framework only enabled the representation of two organs. Today, as many as four can be simulated simultaneously on these novel multi-organ chips. 

When the HZDR team turned to Fraunhofer IWS, the experts there quickly recognized the potential for a new application. “Multi-organ chips have not yet been used in the development of radiopharmaceuticals, so there is a great need for them,” explains group leader Florian Schmieder, who has been involved in lab-on-chip research at Fraunhofer IWS for many years. Together, the two institutes successfully applied for a grant from the German Federal Ministry of Education and Research on “Alternative Methods to Animal Testing”. This will continue until 2024, and they have achieved the first promising results.

Reducing the number of animal experiments

Foto: Die ersten Tests mit den Multiorgan-Chips zeigten positive Ergebnisse. Die Bindung bekannter Substanzen an den Tumorsphäroiden funktionierte bereits. Geplant ist, die mikrophysiologischen Systemen um ein Nierenmodell und ein Leberorganoid zu erweitern. ©Copyright: Amac Garbe//Fraunhofer IWS

First tests with the multi-organ chips already showed positive results. The binding of known substances to the tumor spheroids already worked. It is planned to further extend the microphysiological system by adding a kidney model and a liver organoid. Source: Amac Garbe//Fraunhofer IWS | Download

The joint research work aims to place 3D tumor models on a chip that will subsequently make testing radiopharmaceuticals simpler and less expensive. Producing a three-dimensional cell aggregate – a spheroid that can mimic tumor tissue – from a two-dimensional cell culture therefore posed the first challenge. “This allows us to integrate the characteristics of the micro-tumor into our system,” explains development engineer Stephan Behrens, Fraunhofer IWS. In perspective, this representation on the chip should become increasingly detailed, for example by using patient-specific cells or to determine newly discovered, characteristic proteins on different tumor cell types that can be detected radiopharmacologically.

The first tests of Wiebke Sihver and her team with the multi-organ chips already showed positive results. First, they used known substances whose properties can be easily observed on the chip. “We saw that the binding to the tumor spheroids already works,” she describes. They also plan to display a kidney model and a liver organoid on the chips. The kidneys in particular are considered dose-limiting and thus play an important role in radiopharmaceutical research. “In colloquial terms, this means that if the radioligand gets stuck, this can lead to damage in the kidney, but also in the liver cells,” the scientist explains. Testing such substances using cell cultures on a chip therefore offers a promising alternative, she says. If the tests in the project continue to be positive, unknown radioligands will also be tested in the systems at a later stage. “This saves a large number of animal experiments,” says Sihver. Although their research cannot yet completely eliminate animal experiments, the researchers are working to reduce their number.

As a result of the new development, Florian Schmieder sees many advantages for future patients. “We could place patient-specific cells on a chip and thus simulate how a cancer develops.” Individual therapies tailored to the patient's needs would be possible in this way “Cancer also forms tumor-specific antigens that are not so representable in animal models.” This should be feasible on the chips, too.

The close cooperation between the two research institutes constitutes a striking example illustrating the added value of the DRESDEN-concept science alliance, in which 36 partners have joined forces to promote Dresden as a research location and to create as well as exploit synergies in research and teaching as well as infrastructure and administration.

Publication: A binding study with radiolabeled cetuximab
Even before potentially toxic side effects of a new drug are of interest, the binding characteristics matter most. They tell scientists whether the new drug can interact with its target cancer cell and how robust the interaction is. Therefore binding studies are conducted in order to measure the binding strength and the amount of the drug that is bond to the target cell. In a first publication, researchers of Fraunhofer IWS and HZDR show in detail how this works: Wiebke Sihver, Anne-Kathrin Nitt-Weber, Stephan Behrens, Martin Ullrich, Hans-Juergen Pietzsch, Negin Namazian Jam, Florian Schmieder*, Frank Sonntag: Introducing micro physiological systems to evaluate new radiopharmaceuticals: A binding study with radiolabeled cetuximab https://doi.org/10.1515/cdbme-2022-1136

Foto: Bindung von [68Ga]Ga-C225 (2 nM) in MPS-Modulen an A431 (1, 2) und MDA-MB435S (3, 4); (2) zeigt die unspezifische Bindung an A431, (4) an MDA-MB435S (0,8 μM C225); unten: Diagramme von Sättigungsassays auf A431-Monolayer in MPS-Chips mit [64Cu]Cu-C225 (5) und [68Ga]Ga-C225 (6) (dunkelblaue, graue, grüne Symbole: gesamte, unspezifische, spezifische Bindung). ©Copyright: HZDR/Fraunhofer IWS

Binding of [68Ga]Ga-C225 (2 nM) in MPS-modules on A431 (A) and MDA-MB435S (C); (B) shows the nonspecific binding on A431, (D) on MDA-MB435S (0.8 μM C225); below: graphs of saturation assays on A431 monolayer in MPS chips with [64Cu]Cu-C225 (E) and [68Ga]Ga-C225 (F) (black, gray, red symbols: total, nonspecific, specific binding).

Source: HZDR/Fraunhofer IWS | Download


Additional information:
Dr. Wiebke Sihver I HZDR
Institute of Radiopharmaceutical Cancer Research | Department of Radionuclide Theragnostics
Phone: +49 351 260 2423 I Email: w.sihver@hzdr.de   

Dipl.-Ing. Florian Schmieder | Fraunhofer Institute for Material and Beam Technology IWS Dresden
Phone +49 351 83391-3520 | Email:  florian.schmieder@iws.fraunhofer.de

Media contact:
Simon Schmitt | HZDR
Head of Communications and Media Relations
Phone: +49 351 260 3400 | Email: s.schmitt@hzdr.de

Markus Forytta | Fraunhofer Institute for Material and Beam Technology IWS 
Head of Corporate Communications
Phone: +49 351 83391-3614 | Email: markus.forytta@iws.fraunhofer.de