STUDY DESIGN: Prospective animal and human clinical pilot trial. OBJECTIVES: The purpose of this study was to determine and test the dose of Ne-Osteo growth factor extract and carrier required for consistent radiographic bone induction in humans. SUMMARY OF BACKGROUND DATA: Preclinical studies have demonstrated that Ne-Osteo, an extract-containing bone morphogenetic proteins, was successful at generating spine fusion in rabbits and rhesus monkeys. Consistent fusions have yet to be achieved in nonhuman primates and humans. METHODS: Adult rhesus monkeys underwent single-level posterolateral intertransverse lumbar arthrodesis with either 3.0 mg (N = 4), 5.0 mg (N = 4), 12.5 mg (N = 4), or 25 mg (N = 4) of Ne-Osteo per side. Animals were killed after 24 weeks. In the human clinical trial, 22 patients (18 females, 4 males) had lumbar spinal stenosis and/or spondylolisthesis requiring spine arthrodesis. To minimize patient risk of nonunion, patients received autogenous bone graft from the posterior iliac crest on one side and Ne-Osteo growth factor on the other. The dose was 12.5 mg, 25 or 50 mg, or 25 mg Ne-Osteo per side performed in the three phases, respectively. RESULTS: Three of four monkeys that received 12.5 mg Ne-Osteo per side and four of four that received 25 mg per side achieved solid fusions. In phase I of the human clinical trial, two of six patients showed radiographic bone induction (plain radiograph, CT scans-blindly evaluated) on the Ne-Osteo side (12.5-mg dose). In phase II, both sides were graded as fused in five of six patients. Although graded as fused, the 6-month scans demonstrated a ring of new bone with the center filling in slower (12-24 mo) than was predicted by nonhuman primate studies. As a result, phase III carrier was designed to have a more porous/open early fusion mass than with the dense DBM paste (used in phase I and II) by mixing in local bone or cancellous allograft chips. Results using the 25- and 50-mg doses were the same, so 25 mg was used in phase III. In phase III, 9 of 10 autograft were fused by 12 months. Five of five patients with Ne-Osteo plus local bone and four of five with allograft chips were fused by 6 months. The one patient in this group that did not heal on either the autograft or the Ne-Osteo side was a smoker. CONCLUSIONS: A graft composite of Ne-Osteo bone growth factor with human DBM with or without cancellous allograft or local bone autograft was capable of achieving a contiguous spine fusion mass in 15 of 16 patients at a dose of at least 25 mg per side. This result was comparable with the results using iliac crest autograft (94%) in this side-by-side model. These results warrant confirmation in a definitive trial using Ne-Osteo on both sides of the spine and thus avoiding the need for iliac crest bone graft harvest.
STUDY DESIGN: Prospective animal and human clinical pilot trial. OBJECTIVES: The purpose of this study was to determine and test the dose of Ne-Osteo growth factor extract and carrier required for consistent radiographic bone induction in humans. SUMMARY OF BACKGROUND DATA: Preclinical studies have demonstrated that Ne-Osteo, an extract-containing bone morphogenetic proteins, was successful at generating spine fusion in rabbits and rhesus monkeys. Consistent fusions have yet to be achieved in nonhuman primates and humans. METHODS: Adult rhesus monkeys underwent single-level posterolateral intertransverse lumbar arthrodesis with either 3.0 mg (N = 4), 5.0 mg (N = 4), 12.5 mg (N = 4), or 25 mg (N = 4) of Ne-Osteo per side. Animals were killed after 24 weeks. In the human clinical trial, 22 patients (18 females, 4 males) had lumbar spinal stenosis and/or spondylolisthesis requiring spine arthrodesis. To minimize patient risk of nonunion, patients received autogenous bone graft from the posterior iliac crest on one side and Ne-Osteo growth factor on the other. The dose was 12.5 mg, 25 or 50 mg, or 25 mg Ne-Osteo per side performed in the three phases, respectively. RESULTS: Three of four monkeys that received 12.5 mg Ne-Osteo per side and four of four that received 25 mg per side achieved solid fusions. In phase I of the human clinical trial, two of six patients showed radiographic bone induction (plain radiograph, CT scans-blindly evaluated) on the Ne-Osteo side (12.5-mg dose). In phase II, both sides were graded as fused in five of six patients. Although graded as fused, the 6-month scans demonstrated a ring of new bone with the center filling in slower (12-24 mo) than was predicted by nonhuman primate studies. As a result, phase III carrier was designed to have a more porous/open early fusion mass than with the dense DBM paste (used in phase I and II) by mixing in local bone or cancellous allograft chips. Results using the 25- and 50-mg doses were the same, so 25 mg was used in phase III. In phase III, 9 of 10 autograft were fused by 12 months. Five of five patients with Ne-Osteo plus local bone and four of five with allograft chips were fused by 6 months. The one patient in this group that did not heal on either the autograft or the Ne-Osteo side was a smoker. CONCLUSIONS: A graft composite of Ne-Osteo bone growth factor with human DBM with or without cancellous allograft or local bone autograft was capable of achieving a contiguous spine fusion mass in 15 of 16 patients at a dose of at least 25 mg per side. This result was comparable with the results using iliac crest autograft (94%) in this side-by-side model. These results warrant confirmation in a definitive trial using Ne-Osteo on both sides of the spine and thus avoiding the need for iliac crest bone graft harvest.
Authors: Fabiano R T Canto; Sergio B Garcia; João P M Issa; Anderson Marin; Elaine A Del Bel; Helton L A Defino Journal: Eur Spine J Date: 2008-02-27 Impact factor: 3.134