Holoxica creates world’s first 3D holographic atlas of the human body

Breakthrough offers a better way of understanding health and the human body 
Edinburgh-based Holoxica, a specialist holographic 3D visualisation company, has created the world’s first ever holographic 3D digital Human Anatomy ‘Atlas’ prototype, which will give teaching hospitals, medical schools, colleges and research centres a more detailed interpretation and perspective of intricate anatomical structures.
The firm has teamed up with Professor Gordon Findlater, a Professor of Translation Anatomy at The School of Biomedical Sciences at the University of Edinburgh, to develop the Holographic 3D Anatomy Atlas, which is a joint collaboration.
It says the Atlas looks like a book, with physical pages that you can turn, and an integrated light. The light is used to bring out the holographic images which look spectacular as they pop right out of the page in full colour 3D. The hologram is explained on the opposite page using conventional 2D illustrations.
The image data used to create the Atlas has been sourced from CT, MRI, Ultrasound scans and specially created 3D models to replicate a true three-dimensional understanding of the underlying anatomy.
Holoxica says biomedical science now has access to a tool which gives trainee surgeons and clinicians a fresh perspective into identifying, diagnosing and treating a wide range of conditions like never before.
CEO Dr Javid Khan explained: “Medical students have often struggled with a deeper understanding of the relative positioning of complex anatomical structures, for example, the location of a vein in front of a nerve, which might be located behind a tendon.
“This is the level of pinpoint accuracy and detailed precision which the 3D digital Atlas offers. And since human visual perception is inherently 3D, viewing this information this way aids a better understanding of the underlying anatomy, as well as helping recollection and recall.
“Digital holograms contain a vast amount of information – a square millimetre holds around 24 Mbytes of data, which corresponds to all of the rays of light emitting from every direction to form a 3D image. By comparison, a typical smartphone has less than a thousand bytes of information in the same area.
The holograms are manufactured using a special holographic printing machine, which is used to make a master hologram. The master is then replicated with no loss of resolution or quality and the 3D Atlas takes shape from there.”
Holoxica hopes the 3D Anatomy Atlas will be used by universities around the world as a teaching aid for first and second year medical and anatomy students. For them, the challenge is understanding the true 3D nature of the underlying anatomy, so solving this issue will save considerable time and effort.
The feedback from students and teachers so far has been positive, with one professor of Anatomy saying that the technology would have saved him months of study as an undergraduate.
Over the past five years, Holoxica has pioneered techniques for image processing 3D medical data from CT, MRI and Ultrasound scanners into full colour digital 3D Holograms. The company has made significant breakthroughs by creating a number of ‘world first’ digital hologram designs – among them –  a liver from Ultrasound Scan, brain fibres from MRI and lungs from CT scanning.
Dr Khan added: “Collating all this incredible data and developing the 3D Atlas is a natural progression for us.
“Every hologram image is illustrated and annotated on the opposite page of the atlas which contains 11 pages and 13 holograms. All but one of these pages contains a ‘channelling’ feature which enables the viewer to move around the hologram and see directly ‘inside’ organs where different layers are stripped away.”
Holoxica is teaming up with Scion Publishing, a renowned medical publisher, and Zebra Imaging, the leading manufacturer of digital holograms, to transform the 3D Anatomy Atlas prototype into a commercial product.
It’s also conducting research into a holographic 3D VIDEO display, which is being designed to view images in real-time as they are produced by medical scanners. This project has support from the EU Horizon2020 SME Instrument Programme.