Fracture healing: mechanisms and interventions

Einhorn, Thomas A.; Gerstenfeld, Louis C.

doi:10.1038/nrrheum.2014.164

Cited by 1,299 publications

(1,236 citation statements)

References 94 publications

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“…Manipulating the surface Ce 4+ /Ce 3+ ratio of CeONPs can modulate macrophage polarization and cytokine secretion, and facilitate appropriate immune reactions that balance antiinflammation and pro‐inflammation, which lead to the satisfactory outcomes of new bone formation and bone–biomaterial integration. The introduction of a biomaterial into the body initiates an inflammatory cascade due to cell and tissue damage, and this cascade persists for roughly 4 d 13. This early inflammatory response is highly beneficial to the host, it must subsequently be terminated to avoid tissue damage and to promote tissue regeneration 14.…”

Section: Discussionmentioning

confidence: 99%

“…[[qv: 11f,12]] Introduction of an implant into the body initiates an inflammatory cascade due to cell and tissue damage, and this cascade persists for roughly 4 d 13. This early inflammatory response is beneficial to the host, but termination of subsequent inflammation is critical for blocking tissue damage and promoting tissue regeneration 14.…”

Section: Introductionmentioning

confidence: 99%

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Valence State Manipulation of Cerium Oxide Nanoparticles on a Titanium Surface for Modulating Cell Fate and Bone Formation

Wen

et al. 2017

Advanced Science

124

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Understanding cell–biomaterial interactions is critical for the control of cell fate for tissue engineering and regenerative medicine. Here, cerium oxide nanoparticles (CeONPs) are applied at different Ce4+/Ce3+ ratios (i.e., 0.46, 1.23, and 3.23) to titanium substrate surfaces by magnetron sputtering and vacuum annealing. Evaluation of the cytotoxicity of the modified surface to cultured rat bone marrow mesenchymal stem cells (BMSCs) reveals that the cytocompatibility and cell proliferation are proportional to the increases in Ce4+/Ce3+ ratio on titanium surface. The bone formation capability induced by these surface modified titanium alloys is evaluated by implanting various CeONP samples into the intramedullary cavity of rat femur for 8 weeks. New bone formation adjacent to the implant shows a close relationship to the surface Ce4+/Ce3+ ratio; higher Ce4+/Ce3+ ratio achieves better osseointegration. The mechanism of this in vivo outcome is explored by culturing rat BMSCs and RAW264.7 murine macrophages on CeONP samples for different durations. The improvement in osteogenic differentiation capability of BMSCs is directly proportional to the increased Ce4+/Ce3+ ratio on the titanium surface. Increases in the Ce4+/Ce3+ ratio also elevate the polarization of the M2 phenotype of RAW264.7 murine macrophages, particularly with respect to the healing‐associated M2 percentage and anti‐inflammatory cytokine secretion. The manipulation of valence states of CeONPs appears to provide an effective modulation of the osteogenic capability of stem cells and the M2 polarization of macrophages, resulting in favorable outcomes of new bone formation and osseointegration.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Valence State Manipulation of Cerium Oxide Nanoparticles on a Titanium Surface for Modulating Cell Fate and Bone Formation

Wen

et al. 2017

Advanced Science

124

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“…Fractures of the femoral and tibia shaft often occur in response to high energy trauma and are preferentially treated by an intramedullary nail that supports the fracture zone and facilitates bone healing [1][2][3]. The intramedullary stabilization usually remains since implant removal in general and extraction of a nail in particular can be very time-consuming, cumbersome and may cause further tissue damage, refracture and other subsequent problems [4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Intramedullary Mg2Ag nails augment callus formation during fracture healing in mice

Jähn¹,

Saito

Taipaleenmäki

et al. 2016

Acta Biomaterialia

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Intramedullary stabilization is frequently used to treat long bone fractures. Implants usually remain unless complications arise. Since implant removal can become technically very challenging with the potential to cause further tissue damage, biodegradable materials are emerging as alternative options. Magnesium (Mg)-based biodegradable implants have a controllable degradation rate and good tissue compatibility, which makes them attractive for musculoskeletal research. Here we report for the first time the implantation of intramedullary nails made of an Mg alloy containing 2% silver (Mg2Ag) into intact and fractured femora of mice. Prior in vitro analyses revealed an inhibitory effect of Mg2Ag degradation products on osteoclast differentiation and function with no impair of osteoblast function. In vivo, Mg2Ag implants degraded under non-fracture and fracture conditions within 210 days and 133 days, respectively. During fracture repair, osteoblast function and subsequent bone formation were enhanced, while osteoclast activity and bone resorption were decreased, leading to an augmented callus formation. We observed a widening of the femoral shaft under steady state and regenerating conditions, which was at least in part due to an uncoupled bone remodeling. However, Mg2Ag implants did not cause any systemic adverse effects. These data suggest that Mg2Ag implants might be promising for intramedullary fixation of long bone fractures, a novel concept that has to be further investigated in future studies.

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“…These two stages occur within the first 21 days after the trauma [3]. The acute inflammatory expressions are usually observed in the first 4 to 24 hours and callus production occurs in the first 3 days [13].…”

Section: Biological Background and Model Assumptionsmentioning

confidence: 99%

“…The simulation time is set to 21 days after the trauma which is the approximate time for the inflammation and repairing steps of fracture healing both in humans and animals [3]. During this time, the cartilage density is being replaced by woven bone which eventually fills completely the fracture gap [1].…”

Section: Delay Fracture Healingmentioning

confidence: 99%

Modeling the effects of inflammation in bone fracture healing

Kojouharov¹,

Trejo²,

Chen-Charpentier³

2017

AIP Conference Proceedings

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Abstract.A new mathematical model is presented to study the early inflammatory effects in bone healing. It consists of a system of nonlinear ordinary differential equations that represents the interactions among macrophages, mesenchymal stem cells, and osteoblasts. A qualitative analysis of the model is performed to determine the equilibria and their corresponding stability properties. A set of numerical simulations is performed to support the theoretical results. The model is also used to numerically monitor the evolution of a broken bone for different types of fractures and to explore possible treatments to accelerate bone healing by administrating anti-inflammatory drugs.

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Fracture healing: mechanisms and interventions

Cited by 1,299 publications

References 94 publications

Valence State Manipulation of Cerium Oxide Nanoparticles on a Titanium Surface for Modulating Cell Fate and Bone Formation

Valence State Manipulation of Cerium Oxide Nanoparticles on a Titanium Surface for Modulating Cell Fate and Bone Formation

Intramedullary Mg2Ag nails augment callus formation during fracture healing in mice

Modeling the effects of inflammation in bone fracture healing

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