Dynamic Stabilization with Active Locking Plates Delivers Faster, Stronger, and More Symmetric Fracture-Healing

Bottlang, Michael; Tsai, Stanley; Bliven, Emily; Rechenberg, Brigitte von; Klein, Karina; Augat, Peter; Henschel, Julia; Fitzpatrick, Daniel; Madey, Steven M.

doi:10.2106/jbjs.o.00705

Cited by 66 publications

(70 citation statements)

References 43 publications

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“…However, in some circumstances the constructs are considered too rigid and fracture healing can be delayed, resulting in implant failure and subsequent non-union (Figure 4; Gautier and Sommer, 2003; Lujan et al, 2010). Further research to address this issue has led to the development of modified designs that limit the stiffness of the implant-fracture construct, including far-cortical locking screws (Bottlang et al, 2009) and the recently proposed “active” plate (Bottlang et al, 2016). It is far too soon to know whether either of these developments will demonstrate sufficient advantages clinically, or will instead lead to further modifications to internal fixation.…”

Section: How This Knowledge Has Influenced Clinical Practicementioning

confidence: 99%

A Concert between Biology and Biomechanics: The Influence of the Mechanical Environment on Bone Healing

2017

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In order to achieve consistent and predictable fracture healing, a broad spectrum of growth factors are required to interact with one another in a highly organized response. Critically important, the mechanical environment around the fracture site will significantly influence the way bone heals, or if it heals at all. The role of the various biological factors, the timing, and spatial relationship of their introduction, and how the mechanical environment orchestrates this activity, are all crucial aspects to consider. This review will synthesize decades of work and the acquired knowledge that has been used to develop new treatments and technologies for the regeneration and healing of bone. Moreover, it will discuss the current state of the art in experimental and clinical studies concerning the application of these mechano-biological principles to enhance bone healing, by controlling the mechanical environment under which bone regeneration takes place. This includes everything from the basic principles of fracture healing, to the influence of mechanical forces on bone regeneration, and how this knowledge has influenced current clinical practice. Finally, it will examine the efforts now being made for the integration of this research together with the findings of complementary studies in biology, tissue engineering, and regenerative medicine. By bringing together these diverse disciplines in a cohesive manner, the potential exists to enhance fracture healing and ultimately improve clinical outcomes.

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Section: How This Knowledge Has Influenced Clinical Practicementioning

confidence: 99%

A Concert between Biology and Biomechanics: The Influence of the Mechanical Environment on Bone Healing

2017

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“…Indeed, in all treated bone where spiral fracture occurred, the fracture passed through, or more likely originated from, a “cortical defect” (screw hole). Otherwise, the torsion will have determine an horizontal fracture through the callus, as already described in previous reports (Bottlang et al, ; Lu et al, ). Therefore, it is interesting to note that the spiral fracture occurred only in one case in the DBM + MSC group against the two cases observed in the DBM group, where a hybrid fracture took place in other two cases.…”

Section: Discussionmentioning

confidence: 63%

“…Indeed, the spiral fracture, which occurred in all intact tibiae tested in the present study, is typical of an intact bone segment subjected to torsion (Johner, Stäubli, Gunst, & Cordey, ; Paavolainen, ; Robinson, McLauchlan, McLean, & Court‐Brown, ; Strömberg & Dalén, ). In a treated bone, this mode of failure can occur only in presence of a hard callus: The fracture can propagate along the shaft only when the mechanical competence of the callus is at least comparable with the one of bone stumps (Bottlang et al, ), taking into account the stress concentration effect of screw holes (Brooks, Burstein, & Frankel, ). Indeed, in all treated bone where spiral fracture occurred, the fracture passed through, or more likely originated from, a “cortical defect” (screw hole).…”

Section: Discussionmentioning

confidence: 99%

Nonunion fracture healing: Evaluation of effectiveness of demineralized bone matrix and mesenchymal stem cells in a novel sheep bone nonunion model

Dozza

Salamanna

Baleani

et al. 2018

J Tissue Eng Regen Med

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Nonunion treatment has a high rate of success, although recalcitrant nonunion may determine the need for amputation. Therefore, new treatment options are continuously investigated in order to further reduce the risk of nonunion recurrence. This study aimed to (a) develop a new large animal model for bone atrophic nonunion and (b) compare the efficacy of demineralized bone matrix (DBM) and DBM in combination with mesenchymal stem cells (MSC) in the new nonunion model. The new model consists of a noncritical, full-thickness segmental defect created in the sheep tibia, stabilized by an intramedullary nail, and involves the creation of a locally impaired blood supply achieved through periosteum excision and electrocauterization of the stump ends. Six weeks after defect creation, lack of hard tissue callus and established nonunion was observed in all operated tibiae both by radiographic and clinical evaluation. Nonunion was treated with allogeneic DBM or autologous MSC cultivated on DBM particles (DBM + MSC) for 1 day before implantation. Twelve weeks after treatment, radiographic, microtomographic, histologic, and histomorphometric analysis showed the formation of bone callus in DBM group, whereas the fracture healing appeared at an early stage in DBM + MSC group. Torsional strength and stiffness of the DBM group appeared higher than those of DBM + MSC group, although the differences were not statistically significant. In conclusion, a new sheep bone nonunion model resembling the complexity of the clinical condition was developed. DBM is an effective option for nonunion treatment, whereas MSC do not improve the healing process when cultivated on DBM particles before implantation.

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“…18 A virtual torsion test was chosen as the summary measure of mechanical integrity in each model. Torsional stiffness relative to intact paired controls is often used as a summary indicator of healing in preclinical models, [19][20][21][22][23] because it is direction independent. 24…”

Section: Ct Scan Processing and Injured Limb Reconstructionmentioning

confidence: 99%

Virtual Mechanical Testing from Low-Dose CT Scans Predicts Tibial Fracture Time to Union and Outperforms Subjective Outcomes Scoring

Schwarzenberg¹,

Dailey²

2018

Preprint

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Background: Quantitative outcomes assessment remains a persistent challenge in orthopaedic trauma. Although patient-reported outcomes measures (PROMs) and radiographic assessments such as RUST scores are frequently used, very little evidence has been presented to support their validity for measuring structural bone formation or biomechanical integrity.Methods: A sequential cohort of tibial shaft fracture patients was prospectively recruited for observation following standard reamed intramedullary nailing in a Level I trauma center. Follow-ups at 6, 12, 18, and 24 weeks included X-rays and completion of PROMs (EQ-5D and pain scores). Low-dose computed-tomography (CT) scans were also completed at 12 weeks. Scans were reconstructed in 3D and subjected to virtual mechanical testing via the finite element method to assess fracture limb torsional rigidity relative to intact bone.Results: Patients reported progressive longitudinal improvement in mobility, self-care, activity, and health over time, but the PROMs were not correlated with structural bone healing. RUST scoring showed moderate intra-rater agreement (ICC = 0.727), but the scores at 12 weeks were not correlated with time to union (R2 = 0.103, p = 0.193) and were only moderately correlated with callus structural integrity (R2 = 0.346, p = 0.010). In contrast, patient-specific virtual torsional rigidity (VTR) was significantly correlated with time to union (R2 = 0.383, p = 0.005) and clearly differentiated one case of delayed union (VTR = 10%, union at 8 months) from the rest of the normally healing cohort (VTR > 60%, median union time 19 weeks) using CT data alone.Conclusions: PROMs provide insight into the natural history of the patient experience after tibial fracture, but have limited utility as a measure of structural bone healing. RUST scoring, although repeatable, is not a valid longitudinal predictor of time to union. In contrast, virtual mechanical testing from low-dose CT scans provides a quantitative and objective structural callus assessment that reliably predicts time to union and may enable early diagnosis of compromised healing.Level of Evidence: Diagnostic Level II.

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Dynamic Stabilization with Active Locking Plates Delivers Faster, Stronger, and More Symmetric Fracture-Healing

Cited by 66 publications

References 43 publications

A Concert between Biology and Biomechanics: The Influence of the Mechanical Environment on Bone Healing

A Concert between Biology and Biomechanics: The Influence of the Mechanical Environment on Bone Healing

Nonunion fracture healing: Evaluation of effectiveness of demineralized bone matrix and mesenchymal stem cells in a novel sheep bone nonunion model

Virtual Mechanical Testing from Low-Dose CT Scans Predicts Tibial Fracture Time to Union and Outperforms Subjective Outcomes Scoring

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