Researchers devise new scanning technique to produce high-resolution 3D images of bone without radiation

155

cervical-spine-model

Chemists from Trinity College Dublin, (Dublin, Ireland) in collaboration with the Royal College of Surgeons in Ireland (RSCI), have devised a new scanning technique that can produce extremely high-resolution 3D images of bones without exposing patients to X-ray radiation.

The chemists attach luminescent compounds to tiny gold structures to form biologically safe ‘nanoagents’ that are attracted to calcium-rich surfaces, which appear when bones crack—even at a micro level. These nanoagents target and highlight the cracks formed in bones, allowing researchers to produce a complete 3D image of the damaged regions.

According to a press release, the technique could have major implications for the health sector as it can be used to diagnose bone strength and provide a detailed blueprint of the extent and precise positioning of any weakness or injury. Additionally, this knowledge could help prevent the need for bone implants in many cases, and act as an early-warning system for people at a high risk of degenerative bone diseases, such as osteoporosis.

The research, led by the Trinity College Dublin team of professor of Chemistry, Thorri Gunnlaugsson, and postdoctoral researcher, Esther Surender, has been published in Chem, a sister journal to Cell.

Gunnlaugsson says, “This work is the outcome of many years of successful collaboration between chemists from Trinity and medical and engineering experts from RCSI. We have demonstrated that we can achieve a three-dimensional map of bone damage, showing the so-called microcracks, using non-invasive luminescence imaging. The nanoagent we have developed allows us to visualise the nature and the extent of the damage in a manner that was not previously possible. This is a major step forward in our endeavour to develop targeted contrast agents for bone diagnostics for use in clinical applications.”

Lee says, “By using our new nanoagent to label microcracks and detecting them with magnetic resonance imaging (MRI), we hope to measure both bone quantity and quality and identify those at greatest risk of fracture and institute appropriate therapy. Diagnosing weak bones before they break should therefore reduce the need for operations and implants—prevention is better than cure.”

In addition to the unprecedented resolution of this imaging technique, another major step forward lies in it not exposing X-rays to patients. X-rays emit radiation and have, in some cases, been associated with an increased risk of cancer. The red emitting gold-based nanoagents used in this alternative technique are biologically safe – gold has been used safely by medics in a variety of ways in the body for some time.

Surender says, “These nanoagents have great potential for clinical application. Firstly, by using gold nanoparticles, we were able to lower the overall concentration of the agent that would have to be administered within the body, which is ideal from a clinical perspective. Secondly, by using what is called ‘two-photon excitation’ we were able to image bone structure using long wavelength excitation, which is not harmful or damaging to biological tissues.”

She adds, “These nanoagents are similar to the contrast agents that are currently being utilised for MRI within the clinic, and hence have the potential to provide a novel means of medical bone diagnosis in the future. Specifically, by replacing the Europium with its sister ion Gadolinium, we can tune into the MRI activity of these nanoagents for future use alongside X-ray and computed tomography (CT) scans.”

LEAVE A REPLY