Javad Fotouhi1,2, Mathias Unberath3,4, Tianyu Song3, Wenhao Gu3, Alex Johnson5, Greg Osgood5, Mehran Armand5,6,7, Nassir Navab3,4,8. 1. Computer Aided Medical Procedures, Johns Hopkins University, Baltimore, MD, USA. javad.fotouhi@jhu.edu. 2. Department of Computer Science, Johns Hopkins University, Baltimore, MD, USA. javad.fotouhi@jhu.edu. 3. Computer Aided Medical Procedures, Johns Hopkins University, Baltimore, MD, USA. 4. Department of Computer Science, Johns Hopkins University, Baltimore, MD, USA. 5. Department of Orthopaedic Surgery, Johns Hopkins Hospital, Baltimore, MD, USA. 6. Johns Hopkins University Applied Physics Laboratory, Laurel, MD, USA. 7. Department of Mechanical Engineering, Johns Hopkins University, Baltimore, MD, USA. 8. Computer Aided Medical Procedures, Technische Universität München, Munich, Germany.
Abstract
PURPOSE: As the trend toward minimally invasive and percutaneous interventions continues, the importance of appropriate surgical data visualization becomes more evident. Ineffective interventional data display techniques that yield poor ergonomics that hinder hand-eye coordination, and therefore promote frustration which can compromise on-task performance up to adverse outcome. A very common example of ineffective visualization is monitors attached to the base of mobile C-arm X-ray systems. METHODS: We present a spatially and imaging geometry-aware paradigm for visualization of fluoroscopic images using Interactive Flying Frustums (IFFs) in a mixed reality environment. We exploit the fact that the C-arm imaging geometry can be modeled as a pinhole camera giving rise to an 11-degree-of-freedom view frustum on which the X-ray image can be translated while remaining valid. Visualizing IFFs to the surgeon in an augmented reality environment intuitively unites the virtual 2D X-ray image plane and the real 3D patient anatomy. To achieve this visualization, the surgeon and C-arm are tracked relative to the same coordinate frame using image-based localization and mapping, with the augmented reality environment being delivered to the surgeon via a state-of-the-art optical see-through head-mounted display. RESULTS: The root-mean-squared error of C-arm source tracking after hand-eye calibration was determined as [Formula: see text] and [Formula: see text] in rotation and translation, respectively. Finally, we demonstrated the application of spatially aware data visualization for internal fixation of pelvic fractures and percutaneous vertebroplasty. CONCLUSION: Our spatially aware approach to transmission image visualization effectively unites patient anatomy with X-ray images by enabling spatial image manipulation that abides image formation. Our proof-of-principle findings indicate potential applications for surgical tasks that mostly rely on orientational information such as placing the acetabular component in total hip arthroplasty, making us confident that the proposed augmented reality concept can pave the way for improving surgical performance and visuo-motor coordination in fluoroscopy-guided surgery.
PURPOSE: As the trend toward minimally invasive and percutaneous interventions continues, the importance of appropriate surgical data visualization becomes more evident. Ineffective interventional data display techniques that yield poor ergonomics that hinder hand-eye coordination, and therefore promote frustration which can compromise on-task performance up to adverse outcome. A very common example of ineffective visualization is monitors attached to the base of mobile C-arm X-ray systems. METHODS: We present a spatially and imaging geometry-aware paradigm for visualization of fluoroscopic images using Interactive Flying Frustums (IFFs) in a mixed reality environment. We exploit the fact that the C-arm imaging geometry can be modeled as a pinhole camera giving rise to an 11-degree-of-freedom view frustum on which the X-ray image can be translated while remaining valid. Visualizing IFFs to the surgeon in an augmented reality environment intuitively unites the virtual 2D X-ray image plane and the real 3D patient anatomy. To achieve this visualization, the surgeon and C-arm are tracked relative to the same coordinate frame using image-based localization and mapping, with the augmented reality environment being delivered to the surgeon via a state-of-the-art optical see-through head-mounted display. RESULTS: The root-mean-squared error of C-arm source tracking after hand-eye calibration was determined as [Formula: see text] and [Formula: see text] in rotation and translation, respectively. Finally, we demonstrated the application of spatially aware data visualization for internal fixation of pelvic fractures and percutaneous vertebroplasty. CONCLUSION: Our spatially aware approach to transmission image visualization effectively unites patient anatomy with X-ray images by enabling spatial image manipulation that abides image formation. Our proof-of-principle findings indicate potential applications for surgical tasks that mostly rely on orientational information such as placing the acetabular component in total hip arthroplasty, making us confident that the proposed augmented reality concept can pave the way for improving surgical performance and visuo-motor coordination in fluoroscopy-guided surgery.
Entities:
Keywords:
Augmented reality; Fluoroscopy; Frustum; Surgical data visualization
Authors: Nicholas Theocharopoulos; Kostas Perisinakis; John Damilakis; George Papadokostakis; Alexander Hadjipavlou; Nicholas Gourtsoyiannis Journal: J Bone Joint Surg Am Date: 2003-09 Impact factor: 5.284
Authors: Jonathan S Hott; Vivek R Deshmukh; Jeffrey D Klopfenstein; Volker K H Sonntag; Curtis A Dickman; Robert F Spetzler; Stephen M Papadopoulos Journal: Neurosurgery Date: 2004-05 Impact factor: 4.654
Authors: Donald L Miller; Eliseo Vañó; Gabriel Bartal; Stephen Balter; Robert Dixon; Renato Padovani; Beth Schueler; John F Cardella; Thierry de Baère Journal: Cardiovasc Intervent Radiol Date: 2009-12-18 Impact factor: 2.740
Authors: Bronek M Boszczyk; Michael Bierschneider; Stephanie Panzer; Werner Panzer; Roger Harstall; Katharina Schmid; Hans Jaksche Journal: Eur Spine J Date: 2005-06-10 Impact factor: 3.134
Authors: Joon Ha; Priya Parekh; David Gamble; James Masters; Peter Jun; Thomas Hester; Timothy Daniels; Mansur Halai Journal: J Clin Orthop Trauma Date: 2021-05-05
Authors: Fabio A Casari; Nassir Navab; Laura A Hruby; Philipp Kriechling; Ricardo Nakamura; Romero Tori; Fátima de Lourdes Dos Santos Nunes; Marcelo C Queiroz; Philipp Fürnstahl; Mazda Farshad Journal: Curr Rev Musculoskelet Med Date: 2021-02-05