Autograft

Autogenous iliac crest bone in the past has been considered the “gold standard” of graft material. Historically, it has been the most successful graft source in spine fusion. Cancellous autograft has the requisite matrix proteins, mineral, and collagen for the ideals of osteoinductivity, osteogenicity, and osteoconductivity. Its large trabecular surface makes it highly connective as well. Donor site complication rates as high as 25% to 30% have been reported, although a rate of 8% seems more realistic and is more commonly cited.^7,8 Morbidity may be associated with an increased incidence of blood loss, chronic donor site pain, increased operative time, infection, and nerve injury. Furthermore, the quantity of bone available is limited, and may be insufficient for long-segment fusions, or in patients who have had previous graft harvests.

Autogenous cortical bone is useful when structural support is needed at the graft site. Otherwise, it is less desirable than cancellous bone because of the absence of robust bone marrow and, as a result, fewer osteoprogenitor cells. Additionally, these cells are less likely to survive, because they are embedded in a compact matrix where the diffusion of nutrients essential for cell proliferation is impeded compared with the cancellous environment. Cortical bone also has less surface area per unit weight with matrix proteins exposed, and, therefore, connectivity is marginal. Vascular ingrowth into cortical bone is slow. Mechanical strength lags because incorporation takes longer. Although cancellous bone is incorporated fairly rapidly and remodeled, portions of cortical graft may remain necrotic for extended periods. When the likelihood of avascular graft healing is low, as in previously irradiated tissue beds, vascularized grafts may be more desirable due to the presence of greater numbers of osteogenic cells.

Demineralized Bone Matrix

Demineralized bone matrix (DBM) is present in a variety of forms, each of which has a variable degree of osteoinductivity.⁴ Current data support its use as a bone graft extender but not as a pure substitute or enhancer.⁹ Autogenous and allograft DBMs are osteoinductive due to the presence of low doses of BMPs (~0.1% by weight).¹⁰ Collagenous and noncollagenous proteins serve as osteoconductive material that is left after the demineralization process. Preliminary animal studies have shown efficacy of DBM as a carrier molecule for recombinant human bone morphogenetic protein (rhBMP-2) in ectopic bone formation or as a graft alternative in experimental posterolateral arthrodesis.^11,12 A study by Louis-Ugbo et al. used a non-human primate posterolateral fusion model to test a specific formulation of DBM, which was more porous than its predecessor. With this new formulation they found robust fusions and suggested that it exhibited properties of both a graft enhancer and extender.¹³ A recent prospective randomized study by Cammisa et al. looked at 2-year fusion rates in the posterolateral environment in 120 human patients. They concluded that DBM could function as an adequate graft extender and promote adequate fusions when mixed with a small amount of autogenous bone graft.¹⁴

Allograft

The desire to avoid donor site morbidity led to increased use of allograft bone in spine surgery. This was made practical by advances in procurement, sterilization, preparation, and storage.¹⁵ Although allograft bone is widely used in spine surgery, concerns regarding fusion rates and disease transmission remain. Allograft is not osteogenic, because there are no surviving cells in the graft. Because of the processing and storage requirements of allograft, some of the osteoinductive potential is lost. It also carries a small but real risk of disease transmission and may elicit an immune response from the recipient.^16–21

Sterilization, donor screening, and sterile harvesting of donor bone help to keep the risks just cited to a minimum. Bone must be harvested in a sterile fashion within 24 hours of death, cultured, and processed for storage. Large tissue banks are available at most academic institutions.

Immunogenicity and maintenance of osteoinductive and osteoconductive properties are affected by these processing and preservation techniques. Bone usually is frozen or freeze-dried as soon as possible after harvest. Both methods decrease immunogenicity and allow for extended storage. Freezing does not diminish the mechanical properties of the bone, and it may be stored at −70°C for 5 years. Freeze-drying further reduces immunogenicity and inactivates viral agents, but it reduces the mechanical strength of the graft.^22–24 Freeze-dried bone may be stored under vacuum, at room temperature, for an indefinite period.

The most common sterilization methods are high-dose gamma irradiation and ethylene oxide gas sterilization.¹⁸ Both alter the structure of matrix proteins, decreasing the osteoinductive capacity and mechanical strength of the bone.²³ Other sterilization methods such as autoclaving are even more destructive, and generally are not used.

Although allograft usually has performed well in both cervical and lumbar interbody fusions, in which the graft is subject to compression, the results in the posterolateral lumbar environment, in which primary tensile forces exist, have not been as favorable.^25–33 This result has led many surgeons to use allograft as an autograft expander rather than a pure substitute for posterolateral arthrodeses.

Xenograft

The use of bone graft taken from other species has been reported in the orthopaedic literature, but these alternatives to autograft never were incorporated into widespread use. Despite processing, xenografts remain immunogenic and provoke a host response. The graft may become encapsulated from the host’s response, with resultant blockade to revascularization. Ivory and cow horn resist incorporation into host bone and are no longer used. Bovine bone, both freeze-dried and deproteinized, remains weakly antigenic. Both of these types of xenografts have been used in spine surgery with limited success, and therefore they are not recommended as a graft material.^34–37

Ceramics

Calcium phosphate (CaPO₄) ceramics, including hydroxyapatite (HA) and tricalcium phosphate (TCP), have been widely used in orthopaedic and spine surgery.³⁸ These osteoconductive, biodegradable materials are compatible with the remodeling of bone necessary to achieve optimal strength of a construct. Other, nonresorbable materials remain in the fusion mass, leaving permanent stress risers and prolonging strength deficiencies.

To be useful as a graft material, synthetic materials must have several properties. They must be compatible with local tissues, remain chemically stable in body fluids, and be able to withstand sterilization. Furthermore, they must be available in useful shapes and sizes, be cost-effective, and have reliable quality control. CaPO₄ ceramics qualify, and have been widely used in dentistry and maxillofacial surgery, as well as in animal models for experimental spinal research.^21,39–47 A wide body of literature exists discussing the use of these materials in human spine surgery.^{38,46,48–51}

Both HA and TCP ceramics are inherently brittle. They may be prepared as either a compact or a porous material. The greater crystallinity and density of the compact form results in greater strength and resistance to dissolution in vivo, whereas porous versions more closely approximate cancellous bone and enhance bony ingrowth (at the expense of more rapid degradation). Under physiologic conditions, HA is resorbed very slowly, whereas TCP generally is resorbed within 6 weeks of implantation.²⁵

Natural coral has been used to augment or even replace autograft, with some success.^52–55 The calcium carbonate (CaCO₃) in coral is hydrothermally converted to CaPO₄. The structural geometry of coral is similar to that of cancellous bone, making it highly osteoconductive and connective.

Animal Studies: Spinal Instrumentation

The effects of spinal instrumentation and stability have been investigated in various animal models.^77–81 Although this approach can tell us much about short-term effects of instrumentation failure, caution must be exercised in extrapolating this information to the long-term effects in the human body at the bone/instrumentation interface. McAfee et al. created a canine instability model to study both the effect of spinal instrumentation on fusion success and the radiographic incidence of fusion with respect to spinal stability.^66–68 At 6 months, radiographs revealed a greater probability of fusion in the instrumented animals than in the noninstrumented animals. The instrumented fusions also were more rigid. Likewise, Zdeblick et al. demonstrated both an increased rate of fusion and a more rigid fusion when anterior instrumentation was used in a canine model of an unstable burst fracture at L5.⁷⁰ These results also were replicated by Shirado.⁸² Kotani et al. showed that after solid posterolateral arthrodesis was achieved in a sheep model, transpedicular fixation continued to provide mechanical support.⁸³

The biologic activity of the graft material may partly determine the need for internal fixation. Fuller et al. showed that rigid fixation improved bone ingrowth into a calcium carbonate block in a canine anterior thoracic interbody fusion model.^84,85 Because ceramics are not osteoinductive, a mechanically stable environment is crucial for ingrowth. Osteoinductive graft substitutes, on the other hand, may not be as reliant on construct rigidity.

Nagel et al. developed a sheep model of delayed union and nonunion.⁶⁹ Posterior lumbar laminar and facet fusions with iliac crest graft were performed on seven sheep. Six of the seven sheep developed nonunions at the L6-S1 interspace; all cephalad interspaces fused (21 of 21). Eight normal sheep underwent in vivo flexion-extension radiographs. Five normal sheep spines were studied ex vivo, using displacement transducers to test stiffness, displacement, and strain in flexion-extension. The lumbosacral level demonstrated significantly more motion than the other levels, suggesting that motion was a major factor in determining the success of fusion in this sheep model. Similar observations have been made in dogs.⁸⁶ The increased stability and decreased motion that instrumentation provides would seem valuable in such instances.

Human Studies: Spinal Instrumentation

Contradictory human studies of the effects of spinal instrumentation have been widely reported. Zdeblick discussed 124 patients undergoing fusion for different conditions.⁷² Patients were randomized into three groups, all having dorsolateral autograft fusions. Patients in group 1 were not instrumented, those in group 2 were instrumented with a semirigid pedicle screw system, and individuals in group 3 had rigid pedicle screw instrumentation implanted. The rigid group had a significantly higher fusion rate (95%) than the noninstrumented group (65%). The instrumented groups together had 95% excellent or good results, whereas the noninstrumented patients had only 71% good or excellent outcomes (a statistically significant result).

Bridwell et al. described 44 patients with degenerative spondylolisthesis.⁷¹ Patients were individualized into three groups: no fusion; noninstrumented posterolateral fusion; and pedicle screw instrumented posterolateral fusion. Patients with more than 10 degrees or 3 mm of motion were automatically assigned to the instrumentation group. There was an 87% fusion rate in the instrumented group versus a 30% rate in noninstrumented patients, yet there was no significant clinical difference in successful outcomes between the noninstrumented and unfused groups (30% vs. 33%). Successful outcomes in the instrumented group (83%) were significantly greater than in the nonfusion group. Fischgrund et al. also demonstrated a markedly increased rate of fusion in their patients with instrumentation (83% vs. 45%), yet found no difference in clinical outcome.

In their meta-analysis, Mardjetko et al. reviewed 25 papers describing 889 patients with degenerative spondylolisthesis.⁸⁷ Five of the included studies described patients undergoing decompression and posterolateral arthrodesis with pedicle screw instrumentation. Although there was a trend toward an increased rate of fusion in the instrumented versus noninstrumented patients (93% vs. 86%), it did not reach significance (P = .08). The clinical outcome was better in the uninstrumented group: 90% versus 86%. However, the authors acknowledged several limitations of their review: data from different treatments over 20 years; variable study designs and quality; and possible dilution of data from the stronger, better-designed studies that suggested an advantage to instrumentation.

Fusion success is also affected by the physical stresses placed on the graft.⁸⁸ In human beings, 80% of the load at a motion segment is transmitted through the intervertebral disc. Graft placed ventrally, in the interbody region, is thus primarily subjected to compression. This compressive force promotes fusion, presumably by stimulating vascular ingrowth and the proliferation of mesenchymal cells. Dorsally placed graft experiences tensile forces, as does graft placed in the intertransverse process region. Under these less favorable mechanical conditions, fusion is more dependent on biologic factors.

Facet preparation for fusion has been shown to increase motion of the involved segment. Although many surgeons routinely include facet fusion in posterolateral intertransverse process arthrodeses, biomechanical studies have demonstrated a resultant decrease in stability.^89,90 The developing fusion preparation decreases the surface area incorporated into the fusion mass, and may result in a less rigid fusion. Rigid instrumentation allows the facets to be prepared and incorporated without sacrificing stability. However, in the osteoporotic patient, the screw-bone interface often is weak. Even with instrumentation, facet preparation may not be appropriate in these individuals.

Overall, it is generally agreed that spinal instrumentation decreases the rate of pseudarthrosis. However, in some situations, especially with single-level fusions, no significant clinical benefit may be obtained. Additionally, although a positive relation exists between radiographic fusion and clinical outcome, no absolute convincing correlation has been demonstrated.⁹¹ Currently, prospective randomized blinded clinical trials examining the effects of instrumentation have not yet been completed.