Scientists have unveiled a new technique using a super-resolution ultrasound method that improves resolution by 5 to 10 times compared to standard ultrasound images.
The procedure, which allows whole organs to be scanned in super-resolution for the first time, is expected to lead to earlier cancer diagnoses and allow medical staff to more effectively target treatments to any malignant tissue. In fact, it could eventually replace the need for biopsy altogether.
Writing in the Journal of Investigative Radiology, the team demonstrated for the first time the detection of prostate cancer by mapping the blood vessels that surround it and showing a different pattern to that of normal tissue.
The enhanced images utilize existing clinical two-dimensional (2D) ultrasound equipment and standard Contrast Enhanced Ultrasound (CEUS) modes. This means hospitals won’t be required to invest in new equipment and no new hardware technology needs to be developed.
Having demonstrated that it works with live animals, the researchers from Heriot-Watt University aim to start human trials using the new technique by December 2019. Prostate patients will be the first to benefit from the enhanced imaging.
The approach is based on CEUS, an ultrasound examination mode that is set to visualize the blood circulation of organs such as the prostate, pancreas or liver with millimeter accuracy, which is typical for most medical imaging.
CEUS imaging assesses vascular flow using the intravenous injection of the gas-filled microbubbles, which can efficiently scatter ultrasound. Their diameter, typically around 2 to 3 μm, allows them to pass through the entire vascular bed. The CEUS mode relies specifically on processing within the ultrasound equipment that enhances their scatter while also suppressing tissue signals. However, after more than 20 years of research in this area, there are currently very few CEUS applications in a clinical setting globally.
The breakthrough, developed by Heriot-Watt University, is an image analysis methodology, translated from algorithms used in astronomy and light microscopy, that employs a bolus or infusion injection of microbubble suspensions at the start of the examination. New features that are tailored for CEUS data and the blood circulation dynamics have been developed for microbubble scatter detection and segmentation, allowing the algorithm to localize them and track them as they cross the blood stream, thus delineating the vascular tree in view.
“Ultrasound imaging is an indispensable tool in medical diagnosis, primarily due to its cost-effectiveness and unique real-time capability,” said Dr Vassilis Sboros who led the research. “Scotland has pioneered medical ultrasound starting with its invention over 60 years ago. However, the limitations of current ultrasound images mean more expensive techniques like MRI are often employed for diagnosis and treatment.
“MRI doesn’t provide clinicians with more detail but it has generally provided better results than other methods. However, in the prostate for example, biopsy has to be performed as a separate procedure which is more expensive for the hospital and can be both disruptive and distressing for the patient.
“Our new technique has the advantage that it can be done as an adjunct to the ultrasound examination which allows the biopsy to be integrated into it. Due to the super-resolution capability of the image created, we anticipate that the ability of the medical staff to pinpoint, diagnose and treat a range of cancers will be greatly enhanced. We will work to establish the usefulness of our method in the upcoming clinical study. We hope that further research will help expand this method to other applications in cardiovascular disease, diabetes, liver disease and transplant rejection and one day biopsies may not be necessary.
“Until now, CEUS’ use has been limited due to its high inter- and intra-observer variability compared to other imaging techniques like MRI or CT. While existing ultrasound imaging provides comparable resolution to MRI or CT, a number of factors including the equipment type and settings, the patient variability and contrast material has affected its performance. We believe our technique overcomes a large part of these challenges.
“Another key limitation of super-resolution imaging can be the unrealistic amount of time a patient is expected to remain still in a clinical setting. We have overcome this, ensuring the imaging is achievable in a realistic examination period of a few minutes, comparable to existing times.”
The morbidity and mortality associated with a large number of tumors is due to the development of a vascular network that supports them and is responsible for secondary malignant growths at a distance from the primary site of cancerous cells. Mapping the development of such networks will provide a new tool to clinicians in an effort to better understand and harness the progression of cancer.
Initial images of prostate cancer have been included in the initial study with promising results. Both the density and velocity maps generated show strong correlation with the histological evaluation after surgery. The research team hope their method will be a significant advance in the fight against cancer.
Professor Alan McNeill, Consultant Urological Surgeon at the Western General Hospital in Edinburgh said: “Prostate cancer is an increasing problem for our society. Whilst we have a number of methods for detecting it, these don’t always provide us with the important information that we need regarding who has cancer that needs to be treated and who doesn’t.
“A method that maps the blood flow of the tumor accurately could well provide new information about the disease state that allows us to better identify those men who need urgent treatment and those who don’t. It is exciting that we will be the first hospital in the world that will assess this method with patients.”
Reprinted from Heriot-Watt University
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