Your search keyword '"Jonas Widmer"' showing total 3 results

1. Vertebropexy as a semi-rigid ligamentous alternative to lumbar spinal fusion

Author

Mazda Farshad, Christos Tsagkaris, Jonas Widmer, Marie-Rosa Fasser, Frédéric Cornaz, and Anna-Katharina Calek

Subjects

Ligamentous stabilization, Lumbar spine, Vertebropexy, Spinal stabilization, Orthopedics and Sports Medicine, Surgery, Semi-rigid, Lumbar fusion

Abstract

Purpose To develop ligamentous vertebral stabilization techniques (“vertebropexy”) that can be used after microsurgical decompression (intact posterior structures) and midline decompression (removed posterior structures) and to elaborate their biomechanical characteristics. Methods Fifteen spinal segments were biomechanically tested in a stepwise surgical decompression and ligamentous stabilization study. Stabilization was achieved with a gracilis or semitendinosus tendon allograft, which was attached to the spinous process (interspinous vertebropexy) or the laminae (interlaminar vertebropexy) in form of a loop. The specimens were tested (1) in the native state, after (2) microsurgical decompression, (3) interspinous vertebropexy, (4) midline decompression, and (5) interlaminar vertebropexy. In the intact state and after every surgical step, the segments were loaded in flexion–extension (FE), lateral shear (LS), lateral bending (LB), anterior shear (AS) and axial rotation (AR). Results Interspinous vertebropexy significantly reduced the range of motion (ROM) in all loading scenarios compared to microsurgical decompression: in FE by 70% (p, European Spine Journal, 32 (5), ISSN:0940-6719, ISSN:1432-0932, ISSN:001991155

Published

2023

2. Residual motion of different posterior instrumentation and interbody fusion constructs

Author

Marco D. Burkhard, José M. Spirig, Florian Wanivenhaus, Frédéric Cornaz, Marie-Rosa Fasser, Jonas Widmer, and Mazda Farshad

Subjects

Interbody fusion, PLIF, TLIF, Unilateral, Facet-sparing, Orthopedics and Sports Medicine, Surgery

Abstract

Purpose To elucidate residual motion of cortical screw (CS) and pedicle screw (PS) constructs with unilateral posterior lumbar interbody fusion (ul-PLIF), bilateral PLIF (bl-PLIF), facet-sparing transforaminal lumbar interbody fusion (fs-TLIF), and facet-resecting TLIF (fr-TLIF). Methods A total of 35 human cadaver lumbar segments were instrumented with PS (n = 18) and CS (n = 17). Range of motion (ROM) and relative ROM changes were recorded in flexion/extension (FE), lateral bending (LB), axial rotation (AR), lateral shear (LS), anterior shear (AS), and axial compression (AC) in five instrumentational states: without interbody fusion (wo-IF), ul-PLIF, bl-PLIF, fs-TLIF, and fr-TLIF. Results Whereas FE, LB, AR, and AC noticeably differed between the instrumentational states, AS and LS were less prominently affected. Compared to wo-IF, ul-PLIF caused a significant increase in ROM with PS (FE + 42%, LB + 24%, AR + 34%, and AC + 77%), however, such changes were non-significant with CS. ROM was similar between wo-IF and all other interbody fusion techniques. Insertion of a second PLIF (bl-PLIF) significantly decreased ROM with CS (FE -17%, LB -26%, AR -20%, AC -51%) and PS (FE − 23%, LB − 14%, AR − 20%, AC − 45%,). Facet removal in TLIF significantly increased ROM with CS (FE + 6%, LB + 9%, AR + 17%, AC of + 23%) and PS (FE + 7%, AR + 12%, AC + 13%). Conclusion bl-PLIF and TLIF show similarly low residual motion in both PS and CS constructs, but ul-PLIF results in increased motion. The fs-TLIF technique is able to further decrease motion compared to fr-TLIF in both the CS and PS constructs., European Spine Journal, 32 (4), ISSN:0940-6719, ISSN:1432-0932, ISSN:001991155

Published

2023

3. Real-time assessment of anteroposterior stability of spinal segments

Author

Frédéric Cornaz, Samuel Haupt, Mazda Farshad, Jonas Widmer, University of Zurich, and Widmer, Jonas

Subjects

2732 Orthopedics and Sports Medicine, Lumbar Vertebrae, Spinal Fusion, Cadaver, Humans, Reproducibility of Results, 610 Medicine & health, 10046 Balgrist University Hospital, Swiss Spinal Cord Injury Center, Orthopedics and Sports Medicine, Surgery, Range of Motion, Articular, 2746 Surgery, Biomechanical Phenomena

Abstract

Purpose While anteroposterior instability of spinal segments is regarded as an important biomechanical aspect in the clinical evaluation of lumbar pathologies, the reliability of the available diagnostic tools is limited and an intraoperative method to quantify stability is lacking. The aim of this study was to develop and validate an instrument to measure the anteroposterior stability of a spinal segments in real-time. Methods Torsi of five fresh-frozen human cadavers were used for this study. After pedicle screw insertion, a specifically modified reposition tool composed with load and linear sensors was used to measure the segmental anteroposterior motion caused by 100 N anterior and posterior force during 5 loading cycles on either side of the instrumentation by two different operators. The spinal segments were then resected from the torsi and anteroposterior loading with ± 100 N was repeated in an advanced biomechanical spine testing setup as a reference measurement. The Inter-correlation coefficient (ICC) was used for validation of the “intraoperative” device. Results Inter-operator repeatability of the measurements showed an ICC of 0.93 (p p p p Conclusion An accurate and reliable measurement tool is developed and validated for real-time quantification of anteroposterior stability of spinal segments and serves as a basis for future intraoperative use.

Published

2022