Obid, PeterPeterObidDanyali, RezaRezaDanyaliKueny, RebeccaRebeccaKuenyHuber, GerdGerdHuberReichl, MichaelMichaelReichlRichter, AlexanderAlexanderRichterNiemeyer, ThomasThomasNiemeyerMorlock, MichaelMichaelMorlockPüschel, KlausKlausPüschelÜbeyli, HüseyinHüseyinÜbeyli2019-03-012019-03-012017-04-03Global spine journal 1 (7): 47-53 (2017)http://hdl.handle.net/11420/2051Study Design Ex vivo human cadaveric study. Objective The development or progression of adjacent segment disease (ASD) after spine stabilization and fusion is a major problem in spine surgery. Apart from optimal balancing of the sagittal profile, dynamic instrumentation is often suggested to prevent or impede ASD. Hybrid instrumentation is used to gain stabilization while allowing motion to avoid hypermobility in the adjacent segment. In this biomechanical study, the effects of two different hybrid instrumentations on human cadaver spines were evaluated and compared with a rigid instrumentation. Methods Eighteen human cadaver spines (T11-L5) were subdivided into three groups: rigid, dynamic, and hook comprising six spines each. Clinical parameters and initial mechanical characteristics were consistent among groups. All specimens received rigid fixation from L3-L5 followed by application of a free bending load of extension and flexion. The range of motion (ROM) for every segment was evaluated. For the rigid group, further rigid fixation from L1-L5 was applied. A dynamic Elaspine system (Spinelab AG, Winterthur, Switzerland) was applied from L1 to L3 for the dynamic group, and the hook group was instrumented with additional laminar hooks at L1-L3. ROM was then evaluated again. Results There was no significant difference in ROM among the three instrumentation techniques. Conclusion Based on this data, the intended advantage of a hybrid or dynamic instrumentation might not be achieveden2192-5682201714753Sage Publications : formerly Georg Thieme Verlaghttps://creativecommons.org/licenses/by-nc-nd/3.0/de/degenerative lumbar spinelumbar fusionadjacent segment diseasedynamic stabilizationhybrid instrumentationElaspinelaminar hooksMedizinJournal Articleurn:nbn:de:gbv:830-882.02702310.15480/882.204710.1055/s-0036-158394510.15480/882.2047Journal Article