STUDY DESIGN: An animal model of posterolateral intertransverse process lumbar spinal fusion compared fusion rates amongst autologous bone (group 1), a porous, bioabsorbable, scaffold based on the biopolymer, poly(propylene glycol-co-fumaric acid) (PPF) (group 2), and a combination of autograft and the bioabsorbable scaffold (group 3). OBJECTIVES: To evaluate the feasibility of augmenting spinal fusion with an osteoconductive and bioabsorbable scaffold as an alternative or as an adjunct, i.e., an extender, to autograft. SUMMARY OF BACKGROUND DATA: There is little preclinical data on applications of bioabsorable bone graft extenders in spinal fusion. METHODS: New Zealand White rabbits underwent single-level lumbar posterolateral intertransverse process fusion. Animals were treated with one of three materials: autologous bone (group 1), a bioabsorable material based on PPF (group 2), and the PPF biopolymer scaffold with autologous bone graft (group 3). Animals were evaluated at 6 weeks, and fusion was evaluated by manual palpation, and radiographic, histologic, and histomorphometric analyses. RESULTS: Radiographic and manual palpation showed evidence of fusion in all three groups. Histomorphometric measurement of bone ingrowth showed the highest quantity of new bone in group 3 (91%), followed by group 1 (72%) and group 2 (53%). CONCLUSIONS: Results of this study suggested that osteoconductive bioabsorbable scaffolds prepared from PPF might be used as an autograft extender when applied as an adjunct to spinal fusion.
STUDY DESIGN: An animal model of posterolateral intertransverse process lumbar spinal fusion compared fusion rates amongst autologous bone (group 1), a porous, bioabsorbable, scaffold based on the biopolymer, poly(propylene glycol-co-fumaric acid) (PPF) (group 2), and a combination of autograft and the bioabsorbable scaffold (group 3). OBJECTIVES: To evaluate the feasibility of augmenting spinal fusion with an osteoconductive and bioabsorbable scaffold as an alternative or as an adjunct, i.e., an extender, to autograft. SUMMARY OF BACKGROUND DATA: There is little preclinical data on applications of bioabsorable bone graft extenders in spinal fusion. METHODS: New Zealand White rabbits underwent single-level lumbar posterolateral intertransverse process fusion. Animals were treated with one of three materials: autologous bone (group 1), a bioabsorable material based on PPF (group 2), and the PPF biopolymer scaffold with autologous bone graft (group 3). Animals were evaluated at 6 weeks, and fusion was evaluated by manual palpation, and radiographic, histologic, and histomorphometric analyses. RESULTS: Radiographic and manual palpation showed evidence of fusion in all three groups. Histomorphometric measurement of bone ingrowth showed the highest quantity of new bone in group 3 (91%), followed by group 1 (72%) and group 2 (53%). CONCLUSIONS: Results of this study suggested that osteoconductive bioabsorbable scaffolds prepared from PPF might be used as an autograft extender when applied as an adjunct to spinal fusion.
Authors: Tomoyuki Akamaru; Dan Suh; Scott D Boden; Hak-Sun Kim; Akihito Minamide; John Louis-Ugbo Journal: Spine (Phila Pa 1976) Date: 2003-03-01 Impact factor: 3.468
Authors: David D Hile; Carl Kirker-Head; Stephen A Doherty; Michael P Kowaleski; John McCool; Donald L Wise; Debra J Trantolo Journal: J Biomed Mater Res B Appl Biomater Date: 2003-07-15 Impact factor: 3.368
Authors: Madison A P McGough; Stefanie M Shiels; Lauren A Boller; Katarzyna J Zienkiewicz; Craig L Duvall; Joseph C Wenke; Scott A Guelcher Journal: Tissue Eng Part A Date: 2019-01-09 Impact factor: 3.845
Authors: Lauren A Boller; Madison A P McGough; Stefanie M Shiels; Craig L Duvall; Joseph C Wenke; Scott A Guelcher Journal: Materials (Basel) Date: 2021-07-15 Impact factor: 3.623