Published on in Vol 4, No 1 (2020): Jan-Dec

Preprints (earlier versions) of this paper are available at https://preprints.jmir.org/preprint/20633, first published .
A Novel Virtual Reality Medical Image Display System for Group Discussions of Congenital Heart Disease: Development and Usability Testing

A Novel Virtual Reality Medical Image Display System for Group Discussions of Congenital Heart Disease: Development and Usability Testing

A Novel Virtual Reality Medical Image Display System for Group Discussions of Congenital Heart Disease: Development and Usability Testing

Journals

  1. Pushparajah K, Chu K, Deng S, Wheeler G, Gomez A, Kabir S, Schnabel J, Simpson J. Virtual reality three-dimensional echocardiographic imaging for planning surgical atrioventricular valve repair. JTCVS Techniques 2021;7:269 View
  2. Lau I, Gupta A, Sun Z. Clinical Value of Virtual Reality versus 3D Printing in Congenital Heart Disease. Biomolecules 2021;11(6):884 View
  3. Bindschadler M, Buddhe S, Ferguson M, Jones T, Friedman S, Otto R. HEARTBEAT4D: An Open-source Toolbox for Turning 4D Cardiac CT into VR/AR. Journal of Digital Imaging 2022;35(6):1759 View
  4. Pajaziti E, Schievano S, Sauvage E, Cook A, Capelli C. Investigating the Feasibility of Virtual Reality (VR) for Teaching Cardiac Morphology. Electronics 2021;10(16):1889 View
  5. Rother A, Spiliopoulou M. Virtual Reality for Medical Annotation Tasks: A Systematic Review. Frontiers in Virtual Reality 2022;3 View
  6. Wu Q, Wang Y, Lu L, Chen Y, Long H, Wang J. Virtual Simulation in Undergraduate Medical Education: A Scoping Review of Recent Practice. Frontiers in Medicine 2022;9 View
  7. Lai J, Cheong K. Adoption of Virtual and Augmented Reality for Mathematics Education: A Scoping Review. IEEE Access 2022;10:13693 View
  8. Awori J, Friedman S, Howard C, Kronmal R, Buddhe S. Comparative effectiveness of virtual reality (VR) vs 3D printed models of congenital heart disease in resident and nurse practitioner educational experience. 3D Printing in Medicine 2023;9(1) View
  9. Hellum O, Kersten-Oertel M, Xiao Y. Assessment of user-interaction strategies for neurosurgical data navigation and annotation in virtual reality. Virtual Reality 2023;27(2):1345 View
  10. Steele J, Moore R, Lang S. Use of advanced cardiac imaging in congenital heart disease: growth, indications and innovations. Current Opinion in Pediatrics 2021;33(5):495 View
  11. Jones E, Hultman G, Schmoke K, Ninkovic I, Dodge S, Bahr M, Melton G, Marquard J, Tignanelli C. Combined Expert and User-Driven Usability Assessment of Trauma Decision Support Systems Improves User-Centered Design. Surgery 2022;172(5):1537 View
  12. Brown E, Fujimoto K, Blumenkopf B, Kim A, Kontson K, Benz H. Usability Assessments for Augmented Reality Head-Mounted Displays in Open Surgery and Interventional Procedures: A Systematic Review. Multimodal Technologies and Interaction 2023;7(5):49 View
  13. Stephenson N, Pushparajah K, Wheeler G, Deng S, Schnabel J, Simpson J. Extended reality for procedural planning and guidance in structural heart disease – a review of the state-of-the-art. The International Journal of Cardiovascular Imaging 2023;39(7):1405 View
  14. Kieu V, Sumski C, Cohen S, Reinhardt E, Axelrod D, Handler S. The Use of Virtual Reality Learning on Transition Education in Adolescents with Congenital Heart Disease. Pediatric Cardiology 2023;44(8):1856 View
  15. Sun Z, Silberstein J, Vaccarezza M. Cardiovascular Computed Tomography in the Diagnosis of Cardiovascular Disease: Beyond Lumen Assessment. Journal of Cardiovascular Development and Disease 2024;11(1):22 View
  16. Minga I, Al-Ani M, Moharem-Elgamal S, MD A, MD A, Masoomi M, Mangi S. Use of Virtual Reality and 3D Models in Contemporary Practice of Cardiology. Current Cardiology Reports 2024;26(6):643 View
  17. Lee S, Squelch A, Sun Z. Investigation of the Clinical Value of Four Visualization Modalities for Congenital Heart Disease. Journal of Cardiovascular Development and Disease 2024;11(9):278 View
  18. Abasi A, Ayatollahi H. Computer-Based Simulation for Pediatric Cardiovascular Disease Management: A Policy Brief. Global Pediatric Health 2024;11 View
  19. Rashidova S, Bdoyan E, Timurzieva M, Lobanovskaya S, Naumenko V, Rakhmanova A, Timofeeva V, Gutsulyak A, Zainullin A, Uzbekova K, Kharitonova V, Akhmetova N. THE POSSIBILITIES OF USING VIRTUAL AND AUGMENTED REALITY TECHNOLOGIES IN MODERN CARDIOLOGY. Digital Diagnostics 2024 View
  20. Brun H, Lippert M, Langø T, Sanchez‐Margallo J, Sanchez‐Margallo F, Elle O. Comparing assisting technologies for proficiency in cardiac morphology: 3D printing and mixed reality versus CT slice images for morphological understanding of congenital heart defects by medical students. Anatomical Sciences Education 2024 View
  21. Kantor T, Mahajan P, Murthi S, Stegink C, Brawn B, Varshney A, Reddy R. Role of eXtended Reality use in medical imaging interpretation for pre-surgical planning and intraoperative augmentation. Journal of Medical Imaging 2024;11(06) View

Books/Policy Documents

  1. Szugye N, Moore R, Morales D. Advances in Cardiovascular Technology. View
  2. Tandon A. Intelligence-Based Cardiology and Cardiac Surgery. View
  3. Wong B, Vengusamy S, Chua C. Digital Healthcare in Asia and Gulf Region for Healthy Aging and More Inclusive Societies. View