The Biological Enhancement of Spinal Fusion for Spinal Degenerative Disease

Makino, Takahiro; Tsukazaki, Hiroyuki; Ukon, Yuichiro; Tateiwa, Daisuke; Yoshikawa, Hideki; Kaito, Takashi

doi:10.3390/ijms19082430

Cited by 38 publications

(31 citation statements)

References 147 publications

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“…Several biological enhancement strategies to promote successful spinal fusion have been proposed in animal and human clinical studies. These include use of bisphosphonates, teriparatide (recombinant deoxyribonucleic acid form of parathyroid hormone [PTH1-34]), prostaglandin agonists, bone morphogenic proteins (BMPs), and stem cells [ 25 ]. Among these, bone marrow stromal (a.k.a.…”

Section: Introductionmentioning

confidence: 99%

Role of oxidative metabolism in osseointegration during spinal fusion

et al. 2020

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Spinal fusion is a commonly performed orthopedic surgery. Autologous bone graft obtained from the iliac crest is frequently employed to perform spinal fusion. Osteogenic bone marrow stromal (a.k.a. mesenchymal stem) cells (BMSCs) are believed to be responsible for new bone formation and development of the bridging bone during spinal fusion, as these cells are located in both the graft and at the site of fusion. Our previous work revealed the importance of mitochondrial oxidative metabolism in osteogenic differentiation of BMSCs. Our objective here was to determine the impact of BMSC oxidative metabolism on osseointegration of the graft during spinal fusion. The first part of the study was focused on correlating oxidative metabolism in bone graft BMSCs to radiographic outcomes of spinal fusion in human patients. The second part of the study was focused on mechanistically proving the role of BMSC oxidative metabolism in osseointegration during spinal fusion using a genetic mouse model. Patients’ iliac crest-derived graft BMSCs were identified by surface markers. Mitochondrial oxidative function was detected in BMSCs with the potentiometric probe, CMXRos. Spinal fusion radiographic outcomes, determined by the Lenke grade, were correlated to CMXRos signal in BMSCs. A genetic model of high oxidative metabolism, cyclophilin D knockout (CypD KO), was used to perform spinal fusion in mice. Graft osseointegration in mice was assessed with micro-computed tomography. Our study revealed that higher CMXRos signal in patients’ BMSCs correlated with a higher Lenke grade. Mice with higher oxidative metabolism (CypD KO) had greater mineralization of the spinal fusion bridge, as compared to the control mice. We therefore conclude that higher oxidative metabolism in BMSCs correlates with better spinal fusion outcomes in both human patients and in a mouse model. Altogether, our study suggests that promoting oxidative metabolism in osteogenic cells could improve spinal fusion outcomes for patients.

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Section: Introductionmentioning

confidence: 99%

Role of oxidative metabolism in osseointegration during spinal fusion

et al. 2020

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“…5 However, the effects of bisphosphonates on fusion success in these animal models are inconsistent, with some showing a negative effect and others no effect. 6,11 Unfortunately, this basic science work, along with the theoretical potential that uncoupling balanced osteoclastic and osteoblastic activity could adversely impact fusion, has caused some spine surgeons to be concerned about the perioperative use of this medication. Given the results of the current study by Guppy et al and the meta-analysis by Liu et al, 7 the concerns of a negative effect of bisphosphonate should be tempered.…”

Section: Bisphosphonates Do Not Impair Spinal Fusionmentioning

confidence: 99%

Editorial. Bisphosphonates do not impair spinal fusion

Anderson

Freedman

2020

Neurosurgical Focus

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O steOpOrOsis is defined as diminished bone mineral density and bone quality resulting in increased risk of fracture. This is a chronic condition that is underappreciated and undertreated, even after the occurrence of fragility fractures. 1,2 Osteoporosis is also very common in patients undergoing elective spine surgery, occurring in 20% or more of patients, and rates are often higher in patients undergoing revision or deformity surgery. 3 Two classes of medications are used to treat osteoporosis: antiresorptive and anabolic. Antiresorptive medications include bisphosphonates, denosumab, calcitonin, and estrogens and selective estrogen receptor modulators. Bisphosphonates are the most commonly used drugs for treating osteoporosis because they are inexpensive (generic options are available), usually well tolerated, and can be given orally. However, their mechanism of action (inhibition of osteoclasts) and their theoretical negative effect on bone healing, which may follow an uncoupling of balanced osteoclastic and osteoblastic activities, has caused concern among spine surgeons that bisphosphonates will interfere with bone healing after fusion. Bisphosphonates inhibit a key enzyme of the mevalonate pathway that reduces osteoclastic bone resorption ability and induces osteoclastic apoptosis. 4 These mechanisms of action result in a rapid decrease in bone turnover along with increased bone mineral density and lower fracture risk. In fracture models in animals treated with bisphosphonates, bone remodeling of the callus is slowed but mechanical strength is maintained as a larger callus is formed in treated than control animals. A similar phenomenon likely occurs during spine fusion. Although results in animal studies are conflicting with regard to whether spine fusion is affected by bisphosphonates, 5,6 bone healing after fractures in humans, including spinal fractures, does not appear to be affected by the use of bisphosphonates either before or after fracture. 7,8 Bisphosphonates are analogs of pyrophosphate and Disclosures Dr. Anderson reports direct stock ownership in Titan Spine; being a consultant for Medtronic, Amgen, and Radius Medical; and receiving royalties from Regeneration Technologies.

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“…High doses of rhBMP-2 have also been loosely correlated with increased rates of deep infections (2.4%), arrhythmias (2.4%), cancer (3.4%), and pseudarthrosis (5%) in certain studies [48,60]. In an attempt to better alleviate risk of these complications, some studies with animal models suggest using parathyroid hormone (1-34) in addition to BMP to lessen the amount of BMP dosage required [61][62][63]. Finally, the cost of BMP is high according to one economic evaluation, and it may not be cost-effective for use in the majority of patients [64].…”

Section: Bone Morphogenetic Proteinsmentioning

confidence: 99%

Graft Materials and Biologics for Spinal Interbody Fusion

et al. 2019

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Spinal fusion is the most widely performed procedure in spine surgery. It is the preferred treatment for a wide variety of pathologies including degenerative disc disease, spondylolisthesis, segmental instability, and deformity. Surgeons have the choice of fusing vertebrae by utilizing cages containing autografts, allografts, demineralized bone matrices (DBMs), or graft substitutes such as ceramic scaffolds. Autografts from the iliac spine are the most commonly used as they offer osteogenic, osteoinductive, and osteoconductive capabilities, all while avoiding immune system rejection. Allografts obtained from cadavers and living donors can also be advantageous as they lack the need for graft extraction from the patient. DBMs are acid-extracted organic allografts with osteoinductive properties. Ceramic grafts containing hydroxyapatite can be readily manufactured and are able to provide osteoinductive support while having a long shelf life. Further, bone-morphogenetic proteins (BMPs), mesenchymal stem cells (MSCs), synthetic peptides, and autologous growth factors are currently being optimized to assist in improving vertebral fusion. Genetic therapies utilizing viral transduction are also currently being devised. This review provides an overview of the advantages, disadvantages, and future directions of currently available graft materials. The current literature on growth factors, stem cells, and genetic therapy is also discussed.

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The Biological Enhancement of Spinal Fusion for Spinal Degenerative Disease

Cited by 38 publications

References 147 publications

Role of oxidative metabolism in osseointegration during spinal fusion

Role of oxidative metabolism in osseointegration during spinal fusion

Editorial. Bisphosphonates do not impair spinal fusion

Graft Materials and Biologics for Spinal Interbody Fusion

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