A large European research consortium headed by the University of Twente (UT) is to receive grants of more than 5 million euros, predominantly from the EU, to develop a new imaging device for the diagnosis of breast cancer. A prototype of the device will be ready for large scale testing and production in four years.
Not only will it provide improved photoacoustic and ultrasound imaging, it will also be able to combine the images generated by both techniques. The expectation is that the new imager will improve and accelerate the diagnosis of breast cancer, and also be applicable for younger women.Worldwide, every year more than 1.5 million women are diagnosed with breast cancer; half a million women die from the disease. Current techniques for detecting breast cancer—X-ray mammography, ultrasound and magnetic resonance imaging (MRI)—have shortcomings. The most significant disadvantage of these techniques is that they cannot always clearly distinguish a tumor from healthy tissue or a benign abnormality, so that tumors are missed, and often unnecessary—and stressful—biopsies have to be carried out.
A large European research consortium, will therefore develop a completely new device for the diagnosis of breast cancer. The proposed device is expected to shorten the time to accurate diagnosis substantially. It will also be suitable for younger women, where X-ray mammography usually does not perform well. The device does not use radiation or contrast media which are potentially harmful, and does not cause any pain to the woman being examined.
The consortium is to receive a grant of 4.35 million euros from the European Union and the rest from the Swiss government, for the development of the device. Project leader Srirang Manohar calls the proposed device, which has been dubbed ‘PAMMOTH,’ a ‘dream imager.’ “We will be working on this prototype with the best partners in Europe and actively involving doctors and patient associations for their inputs and advice in the design and testing processes.”
PAMMOTH will combine existing photoacoustic and ultrasound imaging techniques, and elevate both to a higher level at the same time. Manohar: “The images from the two systems will be combined together. This will result in simultaneous three-dimensional information about disease specific optical contrast, as well as about the ultrasound properties which provide anatomic information within the breast. Further we wish to do this combined imaging in real time.”
The improvement of both systems will, incidentally, not only be useful for the final clinical prototype on which the researchers will be working. Manohar expects the project to lead to various improved subsystems for data acquisition, ultrasound detection and a new powerful laser.
Although photoacoustics is a relatively new imaging technique in the medical world, the UT has been conducting research in its application in breast imaging, which is called photoacoustic mammography or PAMmography, for some time now. In PAMmography, the breast is illuminated with laser light. This laser light is converted into ultrasound in regions where higher concentrations of blood are present, such as the areas around malignant tumors.
The ultrasound produced travels from the tumor to the surface of the skin, where it can be detected. The partners participating in the PAMMOTH project will improve the technique and introduce various novel functionalities. For example, various colors of laser light will be used to improve visualization of the tumor, as well as, to yield information about the oxygen saturation of the blood in tumors, which can indicate whether they are malignant or benign.
The researchers are also hoping to take significant steps in the field of ultrasound. They will develop technology which will yield a three-dimensional image, with the ultrasound waves being generated in an unconventional manner. Contrary to regular ultrasound imaging, hand-held scanners will not be used in this project so as to images from being affected by the operator of the device.
The research consortium will be coordinated by Srirang Manohar from the Biomedical Photonic Imaging group part of the UT research institute MIRA. Besides coordination, the UT will focus on the photoacoustic imaging part, and will conduct research for generating ultrasound for the ultrasound subsystem. PA Imaging, a UT spin-off company, will develop rapid, low-noise electronics for the detectors and will ensure that the various partners’ components are integrated into the functioning clinical prototype.
At the end of the project, Medical Spectrum Twente (MST) will, together with the University of Twente, conduct a pilot study to test, the performance of the system in imaging the most common breast tumors. Researchers from University College London will work on image reconstruction methods, and will be responsible for the mathematics and calculations required to compute the images.
One of the proposed methods, will make possible quantitative image reconstruction. The developed mathematics will be converted into usable and rapid algorithms to enable real-time imaging at the Brno University of Technology. Scientists from the University of Bern will have a role in the analysis of ultrasound images, and will develop specialized breast phantoms from materials having the correct acoustic and photoacoustic properties for testing the system. The French company Imasonic will design highly sensitive multi-element detectors for detecting the ultrasound, the Lithuanian company Ekspla will develop the lasers needed for the system, and the German company TP21 will be responsible for the management of the project, and the requisite internal information infrastructure.
The project will be financed by the European Union’s Horizon 2020 program which has reserved a total of 80 billion euros for research and innovation between 2014 and 2020. Essential criteria for eligibility for funding by the program are excellent scientific research, cooperation between different scientific disciplines and with industry, and whether the research addresses large social problems.