Applied quantum mechanics in medicine
Quantum technology for cancer imaging
Quantum mechanics describes physical phenomena at the smallest of scales – in the domain of molecules, atoms, atomic nuclei, and even smaller units. The drive to revolutionize diverse domains of our daily lives using quantum technology like quantum computing or quantum sensors surfaced well before this year's Nobel Prize in Physics was awarded to three scientists for their work in this field. How can these new technologies be deployed in the field of medicine?
Detecting cancer cells in early stages, assessing them with greater precision and evaluating the effectiveness of treatments faster is facilitated by the visualization of metabolic processes in both diseased and healthy cells. This is known as metabolic imaging. To this end, diagnostically relevant molecules are injected into the body and their metabolism is monitored.
One approach is to use positron emission tomography (PET). However, this method requires radioactive substances and cannot distinguish between the initial and end products in metabolic processes. Magnetic resonance imaging (MRI), on the other hand, allows metabolic imaging of various metabolites without using radioactive substances. Albeit only if the MRI signal of the injected molecules is amplified sufficiently to make it detectable. Although initial patient studies show great potential of metabolic imaging with MRI, the signal amplification technologies deployed up to now are prohibitively expensive, insufficiently robust, or slow. This has prevented routine deployment of these technologies in clinical settings up to now.
The interdisciplinary research team of the "Revolutionizing Cancer Imaging with Quantum Technologies" project (QuE-MRI) is now developing a new solution: A so-called quantum hyperpolarizer uses quantum physical laws to amplify the signal of metabolic molecules in the MRI up to 100,000-fold.
The technology of common MRI machines takes advantage of quantum mechanical properties of atomic nuclei associated with the so-called spin, or angular momentum. Each nuclear spin generates a magnetic moment, not unlike the dipole magnet of a compass needle.
The alignment of the nuclear spins determines the strength of the overall magnetic moment of the atomic nuclei. This in turn determines the signal strength, which is used for magnetic resonance imaging. When the directional distribution of the magnetic moments is random, they cancel each other out and the MRI machine detects no signal. The strongest signal is achieved when the magnetic moments of the nuclear spins point in the same direction, resulting in the maximum effective magnetization.
MRI uses very strong magnetic fields to make this possible. Nonetheless, the magnetic moments of the nuclear spins are nearly randomly distributed and thus have only low effective magnetization. The technique of hyperpolarization boosts the effective magnetization of the nuclear spins by factor of 10,000 to 100,000, thereby significantly increasing the sensitivity of MRI.
However, in practice enticing the atomic nuclei of the metabolic molecules into a hyperpolarized state is difficult. The researchers therefore use an intermediate step based on a special magnetic state of hydrogen, called parahydrogen. This can be produced at low temperatures using known methods with liquid nitrogen and stored in gas cylinders.
The properties of parahydrogen also build on the laws of quantum mechanics. While parahydrogen itself is magnetically shielded and not measurable using magnetic resonance methods, its spin configuration can hyperpolarize other atomic nuclei, increasing their visibility in MRI.
Using this approach, the researchers hyperpolarize molecules important for studying metabolic processes. Pyruvate, for example, a metabolic product that is processed into lactic acid by tumors, is particularly suitable for diagnostic purposes. The researchers dock para-hydrogen onto pyruvate in the hyperpolarizer and use its spin configuration to hyperpolarize a carbon atom of pyruvate in a magnetic field using radio waves. The signal from pyruvate is thereby enhanced in MRI, allowing the corresponding metabolic process to be visualized with temporal resolution.
Project partners have already developed functional prototypes of the hyperpolarizer. In the QuE-MRI project, researchers, physicians, industrial partners, and developers in the fields of medicine, physics, chemistry and engineering are now collaborating closely to optimize these prototypes so that the hyperpolarizer can be deployed clinically on a large scale. In addition, the project team plans to validate the non-invasive and non-radioactive technology in initial clinical trials for the diagnosis of cancer.
- From TUM, the Department of Chemistry and the TUM University Hospital Klinikum rechts der Isar are involved in the project, including the following units: Department of Nuclear Medicine, Institute for Diagnostic and Interventional Radiology, Department of Internal Medicine II, Department of Urology.
- Prof. Franz Schilling, subproject leader at QuE-MRI, and Principal Investigator Prof. Wolfgang Weber are researchers at the Munich Institute of Biomedical Engineering (MIBE). MIBE is an Integrative Research Institute (IRI) within TUM that fosters interdisciplinary cooperation and synergies between researchers from the broad field of Biomedical Engineering. At MIBE, researchers specializing in medicine, the natural sciences, and engineering join forces to develop new methods for preventing, diagnosing or treating diseases. The activities cover the entire development process – from the study of basic scientific principles through to their application in new medical devices, medicines and software. https://www.bioengineering.tum.de/en/
- Project partners: NVision Imaging Technologies GmbH, Ulm; Universitätsklinikum Ulm, Klinik für Innere Medizin II, Ulm; Universität Ulm, Institut für Organische Chemie I, Ulm; Albert-Ludwigs-Universität Freiburg, Universitätsklinikum, Klinik für diagnostische und interventionelle Radiologie, Freiburg im Breisgau; Technische Universität München, Faculty of Chemistry, Garching; Klinikum rechts der Isar der Technischen Universität München, Klinik und Poliklinik für Nuklearmedizin, München
- Associated partners: RAPID Biomedical GmbH, Rimpar; Siemens Healthcare GmbH, Erlangen; Qruise GmbH, Saarbrücken
- QuE-MRI is one of four new projects funded by the German Federal Ministry of Education and Research (BMBF) under the framework program "Quantum Technologies – From Fundamentals to Market."
- QuE-MRI project description and project profile