Experimental blunt chest trauma impairs fracture healing in rats

Recknagel, Stefan; Bindl, Ronny; Kurz, Julian; Wehner, Tim; Ehrnthaller, Christian; Knöferl, Markus W.; Gebhard, Florian; Huber‐Lang, Markus; Claes, Lutz; Ignatius, Anita

doi:10.1002/jor.21299

Cited by 68 publications

(131 citation statements)

References 38 publications

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“…We did not expect to detect an alteration in the serum cytokine levels, because our previous and on-going studies show that an isolated femur osteotomy is unable to induce any considerable systemic inflammatory response even 6 h after osteotomy and that the initial post-traumatic systemic inflammatory response is down-regulated to physiological levels within 24 h of osteotomy in rodents. To achieve a considerable systemic inflammation, a second trauma is necessary (Recknagel et al, 2011). However, whether the applied MSC have an immunomodulatory effect cannot be fully answered by the present study, earlier time-points after fracture would be necessary to investigate this.…”

Section: Discussionmentioning

confidence: 93%

Systemic mesenchymal stem cell administration enhances bone formation in fracture repair but not load-induced bone formation

Rapp

Bindl²,

Heilmann³

et al. 2015

eCM

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Mesenchymal stem cells (MSC) were shown to support bone regeneration, when they were locally transplanted into poorly healing fractures. The benefit of systemic MSC transplantation is currently less evident. There is consensus that systemically applied MSC are recruited to the site of injury, but it is debated whether they actually support bone formation. Furthermore, the question arises as to whether circulating MSC are recruited only in case of injury or whether they also participate in mechanically induced bone formation.To answer these questions we injected green fluorescent protein (GFP)-labelled MSC into C57BL/6J mice, which were subjected either to a femur osteotomy or to noninvasive mechanical ulna loading to induce bone formation. We detected GFP-labelled MSC in the early (day 10) and late fracture callus (day 21) by immunohistochemistry. Stromal cell-derived factor 1 (SDF-1 or CXCL-12), a key chemokine for stem cell attraction, was strongly expressed by virtually all cells near the osteotomy -indicating that SDF-1 may mediate cell migration to the site of injury. We found no differences in SDF-1 expression between the groups. Micro-computed tomography (µCT) revealed significantly more bone in the callus of the MSC treated mice compared to untreated controls. The bending stiffness of callus was not significantly altered after MSCapplication. In contrast, we failed to detect GFP-labelled MSC in the ulna after non-invasive mechanical loading. Histomorphometry and µCT revealed a significant loadinduced increase in bone formation; however, no further increase was found after MSC administration. Concluding, our results suggest that systemically administered MSC are recruited and support bone formation only in case of injury but not in mechanically induced bone formation.

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Section: Discussionmentioning

confidence: 93%

Systemic mesenchymal stem cell administration enhances bone formation in fracture repair but not load-induced bone formation

Rapp

Bindl²,

Heilmann³

et al. 2015

eCM

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“…However, most of these studies were performed under optimized surgical conditions with minimal tissue inflammation. In the realm of therapeutic bone regeneration, the defective or injured tissues are frequently inflamed with an abnormal expression of inflammatory mediators (14)(15)(16)(17). Growing evidence suggests that proinflammatory cytokines inhibit osteogenic differentiation and bone formation (18)(19)(20)(21)(22)(23)(24).…”

mentioning

confidence: 99%

NF-κB inhibits osteogenic differentiation of mesenchymal stem cells by promoting β-catenin degradation

Chang

Liu

Lee³

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

263

237

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Mesenchymal stem cell (MSC)-based transplantation is a promising therapeutic approach for bone regeneration and repair. In the realm of therapeutic bone regeneration, the defect or injured tissues are frequently inflamed with an abnormal expression of inflammatory mediators. Growing evidence suggests that proinflammatory cytokines inhibit osteogenic differentiation and bone formation. Thus, for successful MSC-mediated repair, it is important to overcome the inflammation-mediated inhibition of tissue regeneration. In this study, using genetic and chemical approaches, we found that proinflammatory cytokines TNF and IL-17 stimulated IκB kinase (IKK)–NF-κB and impaired osteogenic differentiation of MSCs. In contrast, the inhibition of IKK–NF-κB significantly enhanced MSC-mediated bone formation. Mechanistically, we found that IKK–NF-κB activation promoted β-catenin ubiquitination and degradation through induction of Smurf1 and Smurf2. To translate our basic findings to potential clinic applications, we showed that the IKK small molecule inhibitor, IKKVI, enhanced osteogenic differentiation of MSCs. More importantly, the delivery of IKKVI promoted MSC-mediated craniofacial bone regeneration and repair in vivo. Considering the well established role of NF-κB in inflammation and infection, our results suggest that targeting IKK–NF-κB may have dual benefits in enhancing bone regeneration and repair and inhibiting inflammation, and this concept may also have applicability in many other tissue regeneration situations.

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“…41 It is possible that one of the mechanisms underlying increased rates of delayed or failed fracture healing in compound fractures is the increased pathogen load in these open wounds resulting in inappropriate or extreme polarization of macrophages. Experimentally, elevated systemic inflammation due to additional soft-tissue trauma injuries impairs fracture healing, 42,43 confirming that persistence of a proinflammatory environment is one mechanism responsible for detrimental fracture healing. 44 Interestingly, low-dose TNF administered to the fracture site at the time of surgery and 1 day post surgery improved fracture healing in mice, 45 suggesting that TNF, and potentially macrophage activation, has complex dose-and time-dependent outcomes on bone healing.…”

Section: Macrophage Contributions To Inflammation During Fracture Repairmentioning

confidence: 96%

Unraveling macrophage contributions to bone repair

et al. 2013

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Macrophages have reemerged to prominence with widened understanding of their pleiotropic contributions to many biologies and pathologies. This includes clear advances in revealing their importance in wound healing. Here we have focused on the current state of knowledge with respect to bone repair, which has received relatively little scientific attention compared with its soft-tissue counterparts. Our detailed characterization of resident tissue macrophages residing in bone-lining tissues (osteomacs), including their pro-anabolic function, exposed a more prominent role for these cells in bone biology than previously anticipated. Recent studies have confirmed the importance of macrophages in early inflammatory processes that establish the healing cascade after bone fracture. Emerging data support that macrophage influence extends into both anabolic and catabolic phases of repair, suggesting that these cells have prolonged and diverse functions during fracture healing. More research is needed to clarify macrophage phase-specific contributions, temporospatial subpopulation variance and macrophage specific-molecular mediators. There is also clear motivation for determining whether macrophage alterations underlie compromised fracture healing. Overall, there is strong justification to pursue strategies targeting macrophages and/or their products for improving normal bone healing and overcoming failed repair.

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Experimental blunt chest trauma impairs fracture healing in rats

Cited by 68 publications

References 38 publications

Systemic mesenchymal stem cell administration enhances bone formation in fracture repair but not load-induced bone formation

Systemic mesenchymal stem cell administration enhances bone formation in fracture repair but not load-induced bone formation

NF-κB inhibits osteogenic differentiation of mesenchymal stem cells by promoting β-catenin degradation

Unraveling macrophage contributions to bone repair

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