Mixed Reality Intraoperative Navigation in Craniomaxillofacial Surgery

Purpose Communication between allied health professionals, teachers, and family members is a critical skill when addressing and providing for the individual needs of patients. Graduate students in speech-language pathology programs often have limited opportunities to practice these skills prior to or during externship placements. The purpose of this study was to research a mixed reality simulator as a viable option for speech-language pathology graduate students to practice interprofessional communication (IPC) skills delivering diagnostic information to different stakeholders compared to traditional role-play scenarios. Method Eighty graduate students ( N = 80) completing their third semester in one speech-language pathology program were randomly assigned to one of four conditions: mixed-reality simulation with and without coaching or role play with and without coaching. Data were collected on students' self-efficacy, IPC skills pre- and postintervention, and perceptions of the intervention. Results The students in the two coaching groups scored significantly higher than the students in the noncoaching groups on observed IPC skills. There were no significant differences in students' self-efficacy. Students' responses on social validity measures showed both interventions, including coaching, were acceptable and feasible. Conclusions Findings indicated that coaching paired with either mixed-reality simulation or role play are viable methods to target improvement of IPC skills for graduate students in speech-language pathology. These findings are particularly relevant given the recent approval for students to obtain clinical hours in simulated environments.

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Aktueller Stellenwert der minimal-invasiven Chirurgie bei der Frakturversorgung

Therapeutische Umschau ◽

10.1024/0040-5930.62.2.145 ◽

2005 ◽

Vol 62 (2) ◽

pp. 145-151 ◽

Cited By ~ 3

Author(s):

Sommer ◽

Bereiter

Keyword(s):

Fixateur Externe ◽

Minimal Invasive ◽

Intraoperative Navigation ◽

Neue Technologien

Minimal-invasive Osteosynthesen (MIO) sollten heutzutage ins Repertoire jedes unfallchirurgisch tätigen Operateurs gehören. Entsprechend dem Bestreben jedes Chirurgen, dem Patienten durch den Eingriff selbst möglichst wenig Zusatzschaden beizufügen, stellt die Reduktion des Ausmaßes der Invasivität eine logische Entwicklung dar. Der Begriff «MIO» umfasst folgende Kriterien: Frakturzone nicht freigelegt, Reposition durch indirekte Manöver oder perkutan via Joysticks, kleine Zugänge zur Applikation der Implantate, intraoperative Überprüfung der Reposition und Implantatlage mittels Bildgebung (Röntgen-Bildverstärker, Arthroskopie, Endoskopie, etc.). Schon lange vor der Definition der sogenannt «minimal-invasiven Chirurgie» wurden Frakturen mit gewissen Techniken versorgt, die eigentlich dem Begriff der «Minimal-Invasivität» vollumfänglich gerecht werden, wie z.B. Stabilisierungen mittels Fixateur externe oder geschlossenem Marknagel. In den 90er Jahren des 20. Jahrhunderts erfolgten dann erste Operationen mit «eingeschobenen Platten», einer Technik, die sich in den letzten fünf Jahren unter dem Begriff MIPO (minimal-invasive Plattenosteosynthese), insbesondere dank der neuen winkelstabilen Schrauben-Plattensysteme LISS und LCP, weiter verbreitet hat. Klares Hauptproblem der MIO ist und bleibt die Frakturreposition (kein direktes offenes Manipulieren möglich) mit ihrer intraoperativen Überprüfung (keine direkte Visualisierung). Die Balance zwischen Ausmaß der Invasivität und erreichter Qualität der Reposition und Stabilität ist oft schwierig zu finden und muss von multiplen Faktoren (Frakturlokalisation und -typ, lokale Weichteilsituation, Knochenqualität, Patientenalter und -ansprüche, vorhandene Implantate, Erfahrung des Chirurgen, etc.) abhängig gemacht werden. Neue Technologien wie verbesserte Bildgebung, intraoperative Navigation und perkutane Repositionshilfen werden dazu beitragen, die Invasivität eines operativen Eingriffes auch in der Frakturversorgung weiter reduzieren zu können.

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Quantifying the benefit of facility-based mixed reality training in support of the FITE JCTD business case analysis

PsycEXTRA Dataset ◽

10.1037/e661082010-001 ◽

2009 ◽

Author(s):

Chez Yee Ang

Keyword(s):

Mixed Reality ◽

Case Analysis ◽

Business Case

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Advanced Craniomaxillofacial Surgery

10.1055/b-000-000139 ◽

2020 ◽

Keyword(s):

Craniomaxillofacial Surgery

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Use of Intraoperative Navigation Update to Improve Accuracy during Skull Base Surgery

10.1055/s-0039-1679589 ◽

2019 ◽

Author(s):

Holly Oemke ◽

Margaret Pain ◽

Daniel Charytonowicz ◽

Leslie Schlachter ◽

Anthony Costa ◽

...

Keyword(s):

Skull Base ◽

Skull Base Surgery ◽

Intraoperative Navigation ◽

Improve Accuracy

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Stellenwert der Navigation

Die Wirbelsäule ◽

10.1055/s-0043-112422 ◽

2017 ◽

Vol 01 (04) ◽

pp. 317-334

Author(s):

Jan-Sven Jarvers ◽

Ulrich Spiegl ◽

Stefan Glasmacher ◽

Christoph Heyde ◽

Christoph Josten

Keyword(s):

Patient Safety ◽

Radiation Exposure ◽

Pedicle Screw ◽

Spinal Surgery ◽

Intraoperative Imaging ◽

Intraoperative Navigation ◽

Advantages And Disadvantages ◽

Tumor Diseases ◽

Intraoperative Control ◽

Improved Technology

Abstract Importance of Navigation Navigation and intraoperative imaging have undergone an enormous development in recent years. By using intraoperative navigation, the precision of pedicle screw implantation can be increased in the sense of patient safety. Especially in the case of complex defects or tumor diseases, navigation is a decisive aid. As a result of the constantly improved technology, the requirements for reduced radiation exposure and intraoperative control can also be met. The high costs of the devices can be amortized, for example by a reduced number of revisions. This overview presents the principles of navigation in spinal surgery and the advantages and disadvantages of the different navigation procedures.

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