Purpose of the study: Authors performed experimental PLIF operations on cadavers to verify appropriate shape and size of cage made from bioactive titan material. The approach for application into intervertebral space of the lumbar spine and appearance on X-ray and CT scans was also investigated.
Material: In experiment on cadavers five implantations of interbody cages were performed, two of them in interbody space L3/L4 and three of them in L4/L5. Subtotal discectomy and end platec preparation was done before cage insertion. Our type of cage is made from bioactive titan material and fastened in the application instrument that we developed for this purpose.
Method: To verify operational approach we used midline incision and opened spinal canal through laminectomy, partial hemilaminectomy or partial medial facetectomy. This phase was followed by discectomy and end plates preparation. Stability of inserted cages in intervertebral space is ensured by rotation and anchorage of cage wings in end plates. Operated motion segment was taken out and evaluated by X-rays and CT scans.
Results: The operational approach through partial hemilaminectomy and partial medial facetectomy was fully sufficient for cage application with respect to operated segment. All implantations were successful and position of cages satisfactory. Thanks to less robust gripping instrument the approach was more thrifty compared to glass-ceramic cage and comparable with commercially produced cages that we have experience with (Spine Tech, Stryker, Comesa). Due to cage radio opaque, proper position of cages is easy to control on X-ray and CT scans and allows good peroperative monitoring by X-ray magnifier.
Discussion: Usage of bioactive materials in spinal surgery started by introduction of glass ceramics. Based on our experience we determined suitable indications. To eliminate some of te disadvantages of glass ceramics (mainly mechanical properties), a cage made from bioactive material was developed. This type of cage does not require bone harvesting to fill the cage. This fact results in better comfort for patient in postoperative period and eliminates complications from bone graft harvesting. Bioactive surface of the cage with osseo conductive and osseo integrative features creates prerequisites for solid fusion without bone grafts. Titanium material guarantees mechanical strength and makes possible to produce a wide range of shapes and sizes. Strength of the material enables more advantageous gripping of cage in application instrument. The cage is well visible on X-ray and in MRI scans artifacts are considerably reduced. Operational approach and technique are similar to other commercially produced cages and the extent of destabilization is limited to minimum.
Conclusion: Experimentally we repeatedly verified operational approach, suitable shape and applicability of bioactive titanium cage into intervertebral space. For clinical use bioactive titanium could be a possible way how to replace bone grafts. For spinal surgeons it represents a chemically and mechanically stable material capable of interaction in an environment where it is implanted. Even in difficult conditions the level of osseo integration is high.