UCL INSTITUTE OF BIOMEDICAL ENGINEERING

Developments in 3D x-ray imaging: enhancing detail visibility while reducing the dose

Researchers at UCL Medical Physics & Biomedical Engineering and the University of Western Australia have developed a novel method to obtain highly detailed 3D x-ray images with low doses of radiation. The results, published in the July edition of Medical Physics (“Low-dose phase contrast tomography with conventional x-ray sources” by Charlotte Hagen and co-workers), were selected to feature on the front cover of the journal.

The novel method is based on a new contrast mechanism in x-ray imaging, known as phase contrast (PC). Conventional radiographic methods measure the absorption of x-rays while they travel through a sample, which can lead to poor contrast for weakly absorbing materials (for example, biological soft tissue). PC imaging, on the contrary, exploits the minimal (micro-radian) directional changes that x-rays suffer while they travel through matter, a phenomenon known as refraction. For biological soft tissues, x-ray refraction can be much stronger than absorption; therefore, PC imaging can overcome the problem of poor image quality and reveal more detailed information on the inside of a sample.

Slices through phase (a) and absorption (b) contrast tomographs of a wasp. The phase contrast image shows an enhanced detail visibility.

Slices through phase (a) and absorption (b) contrast tomographs of a wasp. The phase contrast image shows an enhanced detail visibility.

PC imaging has been investigated at UCL for almost a decade by the UCL Phase Contrast Group, currently nine-strong, led by Prof. Alessandro Olivo. The group’s main activity is the development of Edge Illumination PC, an approach compatible with x-ray sources ranging from highly specialised to commercially available.

Charlotte Hagen, first author on the Medical Physics paper, said: “It is very important to make sure that PC imaging can also be carried out with commercial x-ray equipment, which can already be found in many standard research labs, as this makes the benefits of PC imaging available to researchers from a various disciplines.”

Highly detailed 3D rendering of a beetle, acquired with Edge Illumination phase contrast imaging.

Highly detailed 3D rendering of a beetle, acquired with Edge Illumination phase contrast imaging.

In the future, the Edge Illumination PC could be applied to a wide range of biological and medical applications; current areas of investigation by the UCL Phase Contrast group include mammography, atherosclerosis and osteoarthritis research, and regenerative medicine. “By developing a new imaging modality, we aim at providing a tool for other scientists to push the limits of their own research. Often, visualisation is key to gaining new insight”, Charlotte Hagen said.

The publication in Medical Physics describes how Charlotte Hagen and co-workers have combined Edge Illumination PC with the principles of computed tomography. In this way, highly detailed 3D images of the inside of the sample can be reconstructed, revealing structures on the micrometre scale. Most importantly, these images can be obtained with commercially available x-ray sources and require a low radiation exposure.

The UCL Phase Contrast group welcomes collaborations, especially across biomedical disciplines where non-destructive imaging using conventional radiographic techniques is considered challenging.

 

3D rendering of a wasp, acquired with Edge Illumination phase contrast imaging.

3D rendering of a wasp, acquired with Edge Illumination phase contrast imaging.

Author

Charlotte Hagen, Research Associate
Department of Medical Physics & Biomedical Engineering

 

Read full paper

Click here for the cover of Medical Physics Journal – July issue: Medical Physics 41 (7) July 2014

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