STUDY DESIGN: : Different biologic strategies exist to treat degenerative disc disease. Tissue engineering approaches favor autologous chondrocyte transplantation. In our one-step-approach, a resorbable cell-free polyglycolic acid (PGA)-based implant is immersed in serum from whole blood and implanted into the disc defect directly after discectomy. OBJECTIVES: : The aim of our study was to investigate the capacity of a cell-free implant composed of a PGA felt, hyaluronic acid, and serum to recruit disc cells and stimulate repair tissue formation in vivo after microdiscectomy in a rabbit model. SUMMARY OF THE BACKGROUND DATA: : Disc tissue has a limited ability to regenerate after the degeneration process was once initiated. Therefore, we developed a cell-free resorbable implant that is able to attract local cells into the defect and induce proper repair tissue formation. METHODS: : The cell-free implant consisting of PGA and hyaluronic acid was immersed in allogenic serum and implanted into the disc defect after discectomy in New Zealand white rabbits. One week and 6 months after the operation, the disc height index and the T2-weighted signal intensity index were determined using plane radiographs and magnetic resonance imaging. Finally, discs were explanted and investigated histologically. Animals with discectomy only served as controls. RESULTS: : In our animal studies, we could demonstrate that the T2-weighted signal intensity of the operated discs decreased in both groups 1 week after surgery. However, after 6 months, the T2-weighted signal intensity index increased by 45% in the implanted group whereas the index decreased further by 11% in the sham group. This corresponded to changes in the disc height index. Furthermore, the histologic examinations indicated cell migration into the defect and showed tissue regeneration. CONCLUSION: : The implantation of a cell-free PGA-hyaluronic acid implant immersed in serum after discectomy induces regeneration, resulting in improvement of the disc water content and preservation of the disc height 6 months after surgery.
STUDY DESIGN: : Different biologic strategies exist to treat degenerative disc disease. Tissue engineering approaches favor autologous chondrocyte transplantation. In our one-step-approach, a resorbable cell-free polyglycolic acid (PGA)-based implant is immersed in serum from whole blood and implanted into the disc defect directly after discectomy. OBJECTIVES: : The aim of our study was to investigate the capacity of a cell-free implant composed of a PGA felt, hyaluronic acid, and serum to recruit disc cells and stimulate repair tissue formation in vivo after microdiscectomy in a rabbit model. SUMMARY OF THE BACKGROUND DATA: : Disc tissue has a limited ability to regenerate after the degeneration process was once initiated. Therefore, we developed a cell-free resorbable implant that is able to attract local cells into the defect and induce proper repair tissue formation. METHODS: : The cell-free implant consisting of PGA and hyaluronic acid was immersed in allogenic serum and implanted into the disc defect after discectomy in New Zealand white rabbits. One week and 6 months after the operation, the disc height index and the T2-weighted signal intensity index were determined using plane radiographs and magnetic resonance imaging. Finally, discs were explanted and investigated histologically. Animals with discectomy only served as controls. RESULTS: : In our animal studies, we could demonstrate that the T2-weighted signal intensity of the operated discs decreased in both groups 1 week after surgery. However, after 6 months, the T2-weighted signal intensity index increased by 45% in the implanted group whereas the index decreased further by 11% in the sham group. This corresponded to changes in the disc height index. Furthermore, the histologic examinations indicated cell migration into the defect and showed tissue regeneration. CONCLUSION: : The implantation of a cell-free PGA-hyaluronic acid implant immersed in serum after discectomy induces regeneration, resulting in improvement of the disc water content and preservation of the disc height 6 months after surgery.
Authors: Johannes L Bron; Harriet W Mulder; Lucienne A Vonk; Bherouz Zandieh Doulabi; M J Oudhoff; Theodoor H Smit Journal: J Mater Sci Mater Med Date: 2012-01-05 Impact factor: 3.896
Authors: Nicholas Vaudreuil; Tiffany Kadow; Takashi Yurube; Robert Hartman; Kevin Ngo; Qing Dong; Pedro Pohl; J Paulo Coelho; James Kang; Nam Vo; Gwendolyn Sowa Journal: Spine J Date: 2017-04-14 Impact factor: 4.166
Authors: Steven K Leckie; Gwendolyn A Sowa; Bernard P Bechara; Robert A Hartman; Joao Paulo Coelho; William T Witt; Qing D Dong; Brent W Bowman; Kevin M Bell; Nam V Vo; Brian C Kramer; James D Kang Journal: Spine J Date: 2013-02-04 Impact factor: 4.166
Authors: Aldemar A Hegewald; Sven Knecht; Daniel Baumgartner; Hans Gerber; Michaela Endres; Christian Kaps; Edgar Stüssi; Claudius Thomé Journal: J Orthop Surg Res Date: 2009-07-15 Impact factor: 2.359