> Detailanzeige

Kosterhon, Michael; Gutenberg, Angelika; Kantelhardt, Sven R.; Conrad, Jens; Nimer Amr, Amr; Gawehn, Joachim; Giese, Alf

Three-dimensional Cross-Platform Planning for Complex Spinal Procedures : A New Method Adaptive to Different Navigation Systems

Literatur-
verwaltung

Zur
Merkliste

Lösche von
Merkliste

Per Whatsapp teilen

Schließen

Merkliste



Sie können Bookmarks mittels Listen verwalten, loggen Sie sich dafür bitte in Ihr SLUB Benutzerkonto ein.
  • Medientyp: E-Artikel
  • Titel: Three-dimensional Cross-Platform Planning for Complex Spinal Procedures : A New Method Adaptive to Different Navigation Systems : A New Method Adaptive to Different Navigation Systems
  • Beteiligte: Kosterhon, Michael; Gutenberg, Angelika; Kantelhardt, Sven R.; Conrad, Jens; Nimer Amr, Amr; Gawehn, Joachim; Giese, Alf
  • Erschienen: Ovid Technologies (Wolters Kluwer Health), 2017
  • Erschienen in: Clinical Spine Surgery: A Spine Publication, 30 (2017) 7, Seite E1000-E1009
  • Sprache: Englisch
  • DOI: 10.1097/bsd.0000000000000477
  • ISSN: 2380-0186
  • Schlagwörter: Neurology (clinical) ; Orthopedics and Sports Medicine ; Surgery
  • Entstehung:
  • Anmerkungen:
  • Beschreibung: Study Design: A feasibility study. Objective: To develop a method based on the DICOM standard which transfers complex 3-dimensional (3D) trajectories and objects from external planning software to any navigation system for planning and intraoperative guidance of complex spinal procedures. Summary of Background Data: There have been many reports about navigation systems with embedded planning solutions but only few on how to transfer planning data generated in external software. Materials and Methods: Patients computerized tomography and/or magnetic resonance volume data sets of the affected spinal segments were imported to Amira software, reconstructed to 3D images and fused with magnetic resonance data for soft-tissue visualization, resulting in a virtual patient model. Objects needed for surgical plans or surgical procedures such as trajectories, implants or surgical instruments were either digitally constructed or computerized tomography scanned and virtually positioned within the 3D model as required. As crucial step of this method these objects were fused with the patient’s original diagnostic image data, resulting in a single DICOM sequence, containing all preplanned information necessary for the operation. By this step it was possible to import complex surgical plans into any navigation system. Results: We applied this method not only to intraoperatively adjustable implants and objects under experimental settings, but also planned and successfully performed surgical procedures, such as the percutaneous lateral approach to the lumbar spine following preplanned trajectories and a thoracic tumor resection including intervertebral body replacement using an optical navigation system. To demonstrate the versatility and compatibility of the method with an entirely different navigation system, virtually preplanned lumbar transpedicular screw placement was performed with a robotic guidance system. Conclusions: The presented method not only allows virtual planning of complex surgical procedures, but to export objects and surgical plans to any navigation or guidance system able to read DICOM data sets, expanding the possibilities of embedded planning software.