Research & Development

World's smallest imaging device has heart disease in focus

3D micro-printing was applied to develop the world's smallest, flexible scope for looking inside blood vessels.

The camera-like imaging device can be inserted into blood vessels to provide high quality 3D images to help scientists better understand the causes of heart attack and heart disease progression, and could lead to improved treatment and prevention. In this study a multidisciplinary team of researchers and clinicians led by the University of Adelaide and University of Stuttgart was able to 3D print a tiny lens onto the end of an optical fibre.

The imaging device is so small that researchers were able to scan inside the blood vessels of mice. Dr Jiawen Li, Heart Foundation Postdoctoral Fellow at the Institute for Photonics and Advanced Sensing, University of Adelaide, says that in Australia cardiovascular disease kills one person every 19 minutes. "A major factor in heart disease is the plaques, made up of fats, cholesterol and other substances that build up in the vessel walls," Li said. "Preclinical and clinical diagnostics increasingly rely on visualising the structure of the blood vessels to better understand the disease. "Miniaturised endoscopes, which act like tiny cameras, allow doctors to see how these plaques form and explore new ways to treat them," she said.

Dr Simon Thiele, Group Leader, Optical Design and Simulation at the University of Stuttgart, was responsible for fabricating the tiny lens. "Until now, we couldn't make high quality endoscopes this small," Thiele said. "Using 3D micro-printing, we are able to print complicated lenses that are too small to see with the naked eye. "The entire endoscope, with a protective plastic casing, is less than half a millimetre across," he said. Li adds: "It's exciting to work on a project where we take these innovations and build them into something so useful.

The research collaboration also included researchers from The South Australian Health and Medical Research Institute, The Royal Adelaide Hospital and Monash University.


Original publication:
[Li, J., Thiele, S., Quirk, B.C. et al. Ultrathin monolithic 3D printed optical coherence tomography endoscopy for preclinical and clinical use. Light Sci Appl 9, 124 (2020),]

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