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The Innovative Prone: Excelsius® Prone Lateral Surgical Solution
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Excelsius® Prone Lateral is a comprehensive, robotic navigation assisted lateral lumbar interbody surgical solution that enables a single-position, single-stage approach for both direct and indirect decompression. This solution is designed to maximize operational efficiencies, increase implant placement accuracy, and minimize surgeon fatigue.
The system offers:
SIMULTANEOUS ACCESS TO DIRECT AND INDIRECT DECOMPRESSION
Excelsius® Prone Lateral offers robotic-assisted navigation and enables streamlined access for direct and indirect decompression of neural elements through an anterior-to-psoas, transpsoas, or posterior approach without the need to reposition the patient.
ERGONOMIC APPROACH TO LATERAL SURGERY
Excelsius® Prone Lateral offers a dynamic patient positioner with a contralateral bolster that enables ideal patient positioning with coronal bend and tilt control, which may help reduce the surgeon’s physical strain and cognitive load.
MAXIMUM STABILITY
Excelsius® Prone Lateral offers radiolucent contralateral bolsters, a rigid lateral access system, and expandable interbody technology, all designed to reduce impaction forces during interbody insertion.
The system offers:
SIMULTANEOUS ACCESS TO DIRECT AND INDIRECT DECOMPRESSION
Excelsius® Prone Lateral offers robotic-assisted navigation and enables streamlined access for direct and indirect decompression of neural elements through an anterior-to-psoas, transpsoas, or posterior approach without the need to reposition the patient.
ERGONOMIC APPROACH TO LATERAL SURGERY
Excelsius® Prone Lateral offers a dynamic patient positioner with a contralateral bolster that enables ideal patient positioning with coronal bend and tilt control, which may help reduce the surgeon’s physical strain and cognitive load.
MAXIMUM STABILITY
Excelsius® Prone Lateral offers radiolucent contralateral bolsters, a rigid lateral access system, and expandable interbody technology, all designed to reduce impaction forces during interbody insertion.