Your search keyword '"Hankenson, Kurt D."' showing total 22 results

1. Polylactide Degradation Activates Immune Cells by Metabolic Reprogramming.

Author

Maduka, Chima V., Alhaj, Mohammed, Ural, Evran, Habeeb, Oluwatosin M., Kuhnert, Maxwell M., Smith, Kylie, Makela, Ashley V., Pope, Hunter, Chen, Shoue, Hix, Jeremy M., Mallett, Christiane L., Chung, Seock‐Jin, Hakun, Maxwell, Tundo, Anthony, Zinn, Kurt R., Hankenson, Kurt D., Goodman, Stuart B., Narayan, Ramani, and Contag, Christopher H.

Subjects

NANOMEDICINE, POLYLACTIC acid, CELL metabolism, CLINICAL medicine, BIOMATERIALS, BIOPOLYMERS

Abstract

Polylactide (PLA) is the most widely utilized biopolymer in medicine. However, chronic inflammation and excessive fibrosis resulting from its degradation remain significant obstacles to extended clinical use. Immune cell activation has been correlated to the acidity of breakdown products, yet methods to neutralize the pH have not significantly reduced adverse responses. Using a bioenergetic model, delayed cellular changes were observed that are not apparent in the short‐term. Amorphous and semi‐crystalline PLA degradation products, including monomeric l‐lactic acid, mechanistically remodel metabolism in cells leading to a reactive immune microenvironment characterized by elevated proinflammatory cytokines. Selective inhibition of metabolic reprogramming and altered bioenergetics both reduce these undesirable high cytokine levels and stimulate anti‐inflammatory signals. The results present a new biocompatibility paradigm by identifying metabolism as a target for immunomodulation to increase tolerance to biomaterials, ensuring safe clinical application of PLA‐based implants for soft‐ and hard‐tissue regeneration, and advancing nanomedicine and drug delivery. [ABSTRACT FROM AUTHOR]

Published

2023

2. Thrombospondin‐2 spatiotemporal expression in skeletal fractures.

Author

Zondervan, Robert L., Jenkins, Daniel C., Reicha, John D., and Hankenson, Kurt D.

Subjects

FRACTURE healing, PROGENITOR cells, CELL populations, PROTEIN expression, BONES

Abstract

Fracture healing is a complex process that relies heavily on the carefully orchestrated expansion and differentiation of periosteal mesenchymal progenitor cells (MSC). Identification of new markers for periosteal MSCs is essential for the development of fracture therapeutics. Expression of the matricellular protein thrombospondin‐2 (TSP2) increases during early fracture healing; however, it is currently unknown what cell population expresses TSP2. Using a TSP2 GFP reporter mouse and a stabilized murine fracture model, we characterized the expression of TSP2 during the inflammatory, soft callus formation, and hard callus formation phases of fracture healing. In addition, using TSP2 GFP positive cells harvested from reporter mouse cells, we characterized the cell population using flow cytometry and colony formation assays. In uninjured diaphyseal bone, we observed TSP2 expression in the cells located along the inner periosteum. We also observed a population of TSP2 expressing cells in undifferentiated regions of early fracture callus and along the periphery of the callus. Later in callus development, TSP2 cells were broadly distributed in the undifferentiated callus, but GFP was not expressed by chondrocytes. Flow cytometry confirmed that the majority of TSP2 expressing cells were positive for traditional murine MSC markers. Our in vitro assays further supported these findings by demonstrating all adherent and colony‐forming cells expressed TSP2. Taken together, our results suggest that TSP2 is expressed by undifferentiated MSCs, but downregulated in chondrocytes. Clinical significance: expression of the matricellular protein TSP2 is a promising new marker to identify MSCs in early fracture healing. [ABSTRACT FROM AUTHOR]

Published

2021

3. Modulation of Notch1 signaling regulates bone fracture healing.

Author

Novak, Sanja, Roeder, Emilie, Sinder, Benjamin P., Adams, Douglas J., Siebel, Chris W., Grcevic, Danka, Hankenson, Kurt D., Matthews, Brya G., and Kalajzic, Ivo

Subjects

FRACTURE healing, BONE fractures, PROGENITOR cells, NOTCH effect, BONES, PERIOSTEUM, MYOFIBROBLASTS

Abstract

Fracture healing involves interactions of different cell types, driven by various growth factors, and signaling cascades. Periosteal mesenchymal progenitor cells give rise to the majority of osteoblasts and chondrocytes in a fracture callus. Notch signaling has emerged as an important regulator of skeletal cell proliferation and differentiation. We investigated the effects of Notch signaling during the fracture healing process. Increased Notch signaling in osteochondroprogenitor cells driven by overexpression of Notch1 intracellular domain (NICD1) (αSMACreERT2 mice crossed with Rosa‐NICD1) during fracture resulted in less cartilage, more mineralized callus tissue, and stronger and stiffer bones after 3 weeks. Periosteal cells overexpressing NICD1 showed increased proliferation and migration in vitro. In vivo data confirmed that increased Notch1 signaling caused expansion of alpha‐smooth muscle actin (αSMA)‐positive cells and their progeny including αSMA‐derived osteoblasts in the callus without affecting osteoclast numbers. In contrast, anti‐NRR1 antibody treatment to inhibit Notch1 signaling resulted in increased callus cartilage area, reduced callus bone mass, and reduced biomechanical strength. Our study shows a positive effect of induced Notch1 signaling on the fracture healing process, suggesting that stimulating the Notch pathway could be beneficial for fracture repair. [ABSTRACT FROM AUTHOR]

Published

2020

4. Evaluation of global gene expression in regenerate tissues during Masquelet treatment.

Author

Gohel, Nishant, Senos, Rafael, Goldstein, Steven A., Hankenson, Kurt D., Hake, Mark E., and Alford, Andrea I.

Subjects

GENE expression, FOREIGN body reaction, GENE expression profiling, BONES, INFLAMMATION, OSTEOBLASTS

Abstract

The Masquelet induced‐membrane (IM) technique is indicated for large segmental bone defects. Attributes of the IM and local milieu that contribute to graft‐to‐bone union are unknown. Using a rat model, we compared global gene expression profiles in critically sized femoral osteotomies managed using a cement spacer as per Masquelet to those left empty. At the end of the experiment, IM and bone adjacent to the spacer were collected from the Masquelet side. Nonunion tissue in the defect and bone next to the empty defect were collected from the contralateral side. Tissues were subjected to RNA isolation, sequencing, and differential expression analysis. Cell type enrichment analysis suggested the IM and the bone next to the polymethylmethacrylate (PMMA) spacer were comparatively enriched for osteoblastic genes. The nonunion environment was comparatively enriched for innate and adaptive immune cell markers, but only macrophages were evident in the Masquelet context. iPathwayGuide was utilized to identify cell signaling pathways and protein interaction networks enriched in the Masquelet environment. For IM vs nonunion false‐discovery rate correction of P values rendered overall pathway differences nonsignificant, and so only protein interaction networks are presented. For the bone comparison, substantial enrichment of pathways and networks known to contribute to osteogenic mechanisms was revealed. Our results suggest that the PMMA spacer affects the cut bone ends that are in contact with it and at the same time induces the foreign body reaction and formation of the IM. B cells in the empty defect suggest a chronic inflammatory response to a large segmental osteotomy. [ABSTRACT FROM AUTHOR]

Published

2020

5. CTRP3 Regulates Endochondral Ossification and Bone Remodeling During Fracture Healing.

Author

Youngstrom, Daniel W., Zondervan, Robert L., Doucet, Nicole R., Acevedo, Parker K., Sexton, Hannah E., Gardner, Emily A., Anderson, JonCarlos S., Kushwaha, Priyanka, Little, Hannah C., Rodriguez, Susana, Riddle, Ryan C., Kalajzic, Ivo, Wong, G. William, and Hankenson, Kurt D.

Subjects

FRACTURE healing, ENDOCHONDRAL ossification, BONE remodeling, GENE expression profiling, BONE regeneration, PERIOSTEUM

Abstract

C1q/TNF‐related protein 3 (CTRP3) is a cytokine known to regulate a variety of metabolic processes. Though previously undescribed in the context of bone regeneration, high throughput gene expression experiments in mice identified CTRP3 as one of the most highly upregulated genes in fracture callus tissue. Hypothesizing a positive regulatory role for CTRP3 in bone regeneration, we phenotyped skeletal development and fracture healing in CTRP3 knockout (KO) and CTRP3 overexpressing transgenic (TG) mice relative to wild‐type (WT) control animals. CTRP3 KO mice experienced delayed endochondral fracture healing, resulting in abnormal mineral distribution, the presence of periosteal marrow compartments, and a nonunion‐like state. Decreased osteoclast number was also observed in CTRP3 KO mice, whereas CTRP3 TG mice underwent accelerated callus remodeling. Gene expression profiling revealed a broad impact on osteoblast/osteoclast lineage commitment and metabolism, including arrested progression toward mature skeletal lineages in the KO group. A single systemic injection of CTRP3 protein at the time of fracture was insufficient to phenocopy the chronic TG healing response in WT mice. By associating CTRP3 levels with fracture healing progression, these data identify a novel protein family with potential therapeutic and diagnostic value. © 2019 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 38:00‐19966, 2020 [ABSTRACT FROM AUTHOR]

Published

2020

6. Review of Animal Models of Comorbidities in Fracture‐Healing Research.

Author

Haffner‐Luntzer, Melanie, Hankenson, Kurt D., Ignatius, Anita, Pfeifer, Roman, Khader, Basel A., Hildebrand, Frank, Griensven, Martijn, Pape, Hans‐Christoph, and Lehmicke, Michael

Subjects

*FRACTURE healing, *ANIMAL models in research, *BONE regeneration, *OSTEOPOROSIS, *COMORBIDITY, *MOLECULAR models, *PERIODICAL publishing

Abstract

There is clinical evidence that patient‐specific comorbidities like osteoporosis, concomitant tissue injury, and ischemia may strongly interfere with bone regeneration. However, underlying mechanisms are still unclear. To study these mechanisms in detail, appropriate animal models are needed. For decades, bone healing has been studied in large animals, including dogs, rabbits, pigs, or sheep. However, large animal models display a limited ability to study molecular pathways and cellular functions. Therefore in recent years, mice and rats have become increasingly popular as a model organism for fracture healing research due to the availability of molecular analysis tools and transgenic models. Both large and small animals can be used to study comorbidities and risk factors, modelling the human clinical situation. However, attention has to be paid when choosing an appropriate model due to species differences between large animals, rodents, and humans. This review focuses on large and small animal models for the common comorbidities ischemic injury/reduced vascularization, osteoporosis, and polytrauma, and critically discusses the translational and molecular aspects of these models. Here, we review material which was presented at the workshop "Animal Models of Comorbidities in Fracture Healing Research" at the 2019 ORS Annual Meeting in Austin Texas. © 2019 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 37:2491–2498, 2019 [ABSTRACT FROM AUTHOR]

Published

2019

7. Suppression of Notch Signaling in Osteoclasts Improves Bone Regeneration and Healing.

Author

Goel, Peeyush N., Moharrer, Yasaman, Hebb, John H., Egol, Alexander J., Kaur, Gurpreet, Hankenson, Kurt D., Ahn, Jaimo, and Ashley, Jason W.

Subjects

BONE regeneration, OSTEOCLASTS, NOTCH signaling pathway, BONE growth, FRACTURE healing

Abstract

Owing to the central role of osteoclasts in bone physiology and remodeling, manipulation of their maturation process provides a potential therapeutic strategy for treating bone diseases. To investigate this, we genetically inhibited the Notch signaling pathway in the myeloid lineage, which includes osteoclast precursors, using a dominant negative form of MAML (dnMAML) that inhibits the transcriptional complex required for downstream Notch signaling. Osteoclasts derived from dnMAML mice showed no significant differences in early osteoclastic gene expression compared to the wild type. Further, these demonstrated significantly lowered resorption activity using bone surfaces while retaining their osteoblast stimulating ability using ex vivo techniques. Using in vivo approaches, we detected significantly higher bone formation rates and osteoblast gene expression in dnMAML cohorts. Further, these mice exhibited increased bone/tissue mineral density compared to wild type and larger bony calluses in later stages of fracture healing. These observations suggest that therapeutic suppression of osteoclast Notch signaling could reduce, but not eliminate, osteoclastic resorption without suppression of restorative bone remodeling and, therefore, presents a balanced paradigm for increasing bone formation, regeneration, and healing. © 2019 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 37:2089–2103, 2019 [ABSTRACT FROM AUTHOR]

Published

2019

8. Cellular biology of fracture healing.

Author

Bahney, Chelsea S., Theologis, Alekos, Miclau, Theodore, Marcucio, Ralph S., Allison, Patrick, Zondervan, Robert L., Hankenson, Kurt D., Ashley, Jason W., and Ahn, Jaimo

Subjects

CYTOLOGY, FRACTURE healing

Abstract

The biology of bone healing is a rapidly developing science. Advances in transgenic and gene‐targeted mice have enabled tissue and cell‐specific investigations of skeletal regeneration. As an example, only recently has it been recognized that chondrocytes convert to osteoblasts during healing bone, and only several years prior, seminal publications reported definitively that the primary tissues contributing bone forming cells during regeneration were the periosteum and endosteum. While genetically modified animals offer incredible insights into the temporal and spatial importance of various gene products, the complexity and rapidity of healing—coupled with the heterogeneity of animal models—renders studies of regenerative biology challenging. Herein, cells that play a key role in bone healing will be reviewed and extracellular mediators regulating their behavior discussed. We will focus on recent studies that explore novel roles of inflammation in bone healing, and the origins and fates of various cells in the fracture environment. © 2018 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res Advances in transgenic and gene‐targeted mice have enabled tissue and cell‐specific investigation of skeletal regeneration. While genetically modified animals offer incredible insights into the temporal and spatial importance of various molecules, the complexity and rapidity of healing renders studies of regenerative biology challenging. Herein, cells and extracellular mediators that play a key role in bone healing are reviewed. We will focus on recent studies that explore the origins and fates of various cells in the fracture environment. [ABSTRACT FROM AUTHOR]

Published

2019

9. Bone healing in an aged murine fracture model is characterized by sustained callus inflammation and decreased cell proliferation.

Author

Hebb, John H., Ashley, Jason W., McDaniel, Lee, Lopas, Luke A., Tobias, John, Hankenson, Kurt D., and Ahn, Jaimo

Subjects

FRACTURE mechanics, CELL proliferation, GENE expression, LABORATORY mice, MULTIPLE correspondence analysis (Statistics)

Abstract

ABSTRACT: Geriatric fractures take longer to heal and heal with more complications than those of younger patients; however, the mechanistic basis for this difference in healing is not well understood. To improve this understanding, we investigated cell and molecular differences in fracture healing between 5‐month‐old (young adult) and 25‐month‐old (geriatric) mice healing utilizing high‐throughput analysis of gene expression. Mice underwent bilateral tibial fractures and fracture calluses were harvested at 5, 10, and 20 days post‐fracture (DPF) for analysis. Global gene expression analysis was performed using Affymetrix MoGene 1.0 ST microarrays. After normalization, data were compared using ANOVA and evaluated using Principal Component Analysis (PCA), CTen, heatmap, and Incromaps analysis. PCA and cross‐sectional heatmap analysis demonstrated that DPF followed by age had pronounced effects on changes in gene expression. Both un‐fractured and 20 DPF aged mice showed increased expression of immune‐associated genes (CXCL8, CCL8, and CCL5) and at 10 DPF, aged mice showed increased expression of matrix‐associated genes, (Matn1, Ucma, Scube1, Col9a1, and Col9a3). Cten analysis suggested an enrichment of CD8+ cells and macrophages in old mice relative to young adult mice and, conversely, a greater prevalence of mast cells in young adult mice relative to old. Finally, consistent with the PCA data, the classic bone healing pathways of BMP, Indian Hedgehog, Notch and Wnt clustered according to the time post‐fracture first and age second. Clinical Significance: Greater understanding of age‐dependent molecular changes with healing will help form a mechanistic basis for therapies to improve patient outcomes. © 2017 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 36:149–158, 2018. [ABSTRACT FROM AUTHOR]

Published

2018

10. Ethical use of animal models in musculoskeletal research.

Author

Allen, Matthew J., Hankenson, Kurt D., Goodrich, Laurie, Boivin, Gregory P., and von Rechenberg, Brigitte

Subjects

*MUSCULOSKELETAL system, *ANIMAL models in research, *EXPERIMENTAL design, *ORTHOPEDICS, *ANIMAL welfare

Abstract

ABSTRACT The use of animals in research is under increasing scrutiny from the general public, funding agencies, and regulatory authorities. Our ability to continue to perform in-vivo studies in laboratory animals will be critically determined by how researchers respond to this new reality. This Perspectives article summarizes recent and ongoing initiatives within ORS and allied organizations to ensure that musculoskeletal research is performed to the highest ethical standards. It goes on to present an overview of the practical application of the 3Rs (reduction, refinement, and replacement) into experimental design and execution, and discusses recent guidance with regard to improvements in the way in which animal data are reported in publications. The overarching goal of this review is to challenge the status quo, to highlight the absolute interdependence between animal welfare and rigorous science, and to provide practical recommendations and resources to allow clinicians and scientists to optimize the ways in which they undertake preclinical studies involving animals. © 2016 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 35:740-751, 2017. [ABSTRACT FROM AUTHOR]

Published

2017

11. Notch Signaling Promotes Osteoclast Maturation and Resorptive Activity.

Author

Ashley, Jason W., Ahn, Jaimo, and Hankenson, Kurt D.

Published

2015

12. Synergistic Effects of SDF-1α and BMP-2 Delivery from Proteolytically Degradable Hyaluronic Acid Hydrogels for Bone Repair.

Author

Holloway, Julianne L., Ma, Henry, Rai, Reena, Hankenson, Kurt D., and Burdick, Jason A.

Published

2015

13. Type III collagen modulates fracture callus bone formation and early remodeling.

Author

Miedel, Emily L., Brisson, Becky K., Hamilton, Todd, Gleason, Hadley, Swain, Gary P., Lopas, Luke, Dopkin, Derek, Perosky, Joseph E., Kozloff, KENneth M., HankENson, Kurt D., and Volk, Susan W.

Subjects

COLLAGEN, FRACTURE fixation, BONE growth, BONE grafting, BONE remodeling

Abstract

ABSTRACT Type III collagen (Col3) has been proposed to play a key role in tissue repair based upon its temporospatial expression during the healing process of many tissues, including bone. Given our previous finding that Col3 regulates the quality of cutaneous repair, as well as our recent data supporting its role in regulating osteoblast differentiation and trabecular bone quantity, we hypothesized that mice with diminished Col3 expression would exhibit altered long-bone fracture healing. To determine the role of Col3 in bone repair, young adult wild-type (Col3+/+) and haploinsufficent (Col3+/−) mice underwent bilateral tibial fractures. Healing was assessed 7, 14, 21, and 28 days following fracture utilizing microcomputed tomography (microCT), immunohistochemistry, and histomorphometry. MicroCT analysis revealed a small but significant increase in bone volume fraction in Col3+/− mice at day 21. However, histological analysis revealed that Col3+/− mice have less bone within the callus at days 21 and 28, which is consistent with the established role for Col3 in osteogenesis. Finally, a reduction in fracture callus osteoclastic activity in Col3+/− mice suggests Col3 also modulates callus remodeling. Although Col3 haploinsufficiency affected biological aspects of bone repair, it did not affect the regain of mechanical function in the young mice that were evaluated in this study. These findings provide evidence for a modulatory role for Col3 in fracture repair and support further investigations into its role in impaired bone healing. © 2015 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 33:675-684, 2015. [ABSTRACT FROM AUTHOR]

Published

2015

14. Jagged1 immobilization to an osteoconductive polymer activates the Notch signaling pathway and induces osteogenesis.

Author

Dishowitz, Michael I., Zhu, Fengchang, Sundararaghavan, Harini G., Ifkovits, Jamie L., Burdick, Jason A., and Hankenson, Kurt D.

Abstract

Treatment of nonunion fractures is a significant problem. Common therapeutics, including autologous bone grafts and bone morphogenetic proteins, show well-established limitations. Therefore, a need persists for the identification of novel clinical therapies to promote healing. The Notch signaling pathway regulates bone development. Clinically, loss-of-function mutations to the Notch ligand Jagged1 decrease bone mass and increase fracture risk. Jagged1 is also the most highly upregulated ligand during fracture repair, identifying it as a potential target to promote bone formation. Therefore, the objective of this study was to develop a clinically translatable construct comprised of Jagged1 and an osteoconductive scaffold, and characterize its activity in human mesenchymal stem cells (hMSC). We first evaluated the effects of Jagged1 directly immobilized to a novel poly(β-amino ester) relative to indirect coupling via antibody. Direct was more effective at activating hMSC Notch target gene expression and osteogenic activity. We then found that directly immobilized Jagged1 constructs induced osteoblast differentiation. This is the first study to demonstrate that Jagged1 delivery transiently activates Notch signaling and increases osteogenesis. A positive correlation was found between Jagged1-induced Notch and osteogenic expression. Collectively, these results indicate that Jagged1 coupled to an osteogenic biomaterial could promote bone tissue formation during fracture healing. © 2013 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 102A: 1558-1567, 2014. [ABSTRACT FROM AUTHOR]

Published

2014

15. The role of oxygen as a regulator of stem cell fate during fracture repair in TSP2-null mice.

Author

Burke, Darren, Dishowitz, Michael, Sweetwyne, Mariya, Miedel, Emily, Hankenson, Kurt D., and Kelly, Daniel J.

Subjects

TREATMENT of fractures, PHYSIOLOGICAL effects of oxygen, STEM cells, CELL differentiation, CELL determination, THROMBOSPONDINS, LABORATORY mice

Abstract

ABSTRACT It is often difficult to decouple the relative importance of different factors in regulating MSC differentiation. Genetically modified mice provide model systems whereby some variables can be manipulated while others are kept constant. Fracture repair in thrombospondin-2 (TSP2)-null mice is characterized by reduced endochondral ossification and enhanced intramembranous bone formation. The proposed mechanism for this shift in MSC fate is that increased vascular density and hence oxygen availability in TSP2-null mice regulates differentiation. However, TSP2 is multifunctional and regulates other aspects of the regenerative cascade, such as MSC proliferation. The objective of this study is to use a previously developed computational model of tissue differentiation, in which substrate stiffness and oxygen tension regulate stem cell differentiation, to simulate potential mechanisms which may drive alterations in MSC fate in TSP2-null mice. Four models (increased cell proliferation, increased numbers of MSCs in the marrow decreased cellular oxygen consumption, and an initially stiffer callus) were not predictive of experimental observations in TSP2-null mice. In contrast, increasing the rate of angiogenic progression led to a prediction of greater intramembranous ossification, diminished endochondral ossification, and a reduced region of hypoxia in the fracture callus similar to that quantified experimentally by the immunohistochemical detection of pimonidazole adducts that develop with hypoxia. This study therefore provides further support for the hypothesis that oxygen availability during early fracture healing is a key regulator of MSC bipotential differentiation, and furthermore, it highlights the advantages of integrating computational models with genetically modified mouse studies for further elucidating mechanisms regulating stem cell fate. © 2013 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 31:1585-1596, 2013. [ABSTRACT FROM AUTHOR]

Published

2013

16. Disruption of thrombospondin-2 accelerates ischemic fracture healing.

Author

Miedel, Emily, Dishowitz, Michael I., Myers, Marc H., Dopkin, Derek, Yu, Yan‐Yiu, Miclau, Ted S., Marcucio, Ralph, Ahn, Jaimo, and Hankenson, Kurt D.

Subjects

TREATMENT of fractures, THROMBOSPONDINS, REPERFUSION, BONE growth, CELL proliferation, PROGENITOR cells

Abstract

Thrombospondin-2 (TSP2) is a matricellular protein that is highly up-regulated during fracture healing. TSP2 negatively regulates vascularity, vascular reperfusion following ischemia, and cutaneous wound healing. As well, TSP2-null mice show increased endocortical bone formation due to an enhanced number of mesenchymal progenitor cells and show increased cortical thickness. Mice deficient in TSP2 (TSP2-null) show an alteration in fracture healing, that is unrelated to their cortical bone phenotype, which is characterized by enhanced vascularization with a shift towards an intramembranous healing phenotype; thus, we hypothesized that there would be enhanced ischemic fracture healing in the absence of TSP2. We investigated whether an absence of TSP2 would enhance ischemic fracture healing utilizing Laser doppler, µCT and histological analysis. Ischemic tibial fractures were created in wildtype (WT) and TSP2-null mice and harvested 10, 20, or 40 days post-fracture. TSP2-null mice show enhanced vascular perfusion following ischemic fracture. At day 10 post-fracture, TSP2-null mice have 115% greater bone volume than WT mice. This is associated with a 122% increase in vessel density, 20% increase in cell proliferation, and 15% decrease in apoptosis compared to WT. At day 20, TSP2-null mice have 34% more bone volume, 51% greater bone volume fraction, and 37% more bone tissue mineral density than WT. By 40 days after fracture the TSP2-null mice have a 24% increase in bone volume fraction, but other parameters show no significant differences. These findings indicate TSP2 is a negative regulator of ischemic fracture healing and that in the absence of TSP2 bone regeneration is enhanced. © 2012 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 31: 935-943, 2013 [ABSTRACT FROM AUTHOR]

Published

2013

17. The transcription factor osterix (SP7) regulates BMP6-induced human osteoblast differentiation.

Author

Zhu, Fengchang, Friedman, Michael S., Luo, Weijun, Woolf, Peter, and Hankenson, Kurt D.

Subjects

TRANSCRIPTION factors, BONE morphogenetic proteins, PROTEOGLYCANS, OSTEOBLASTS, CELL differentiation, EXTRACELLULAR matrix, GENE expression

Abstract

The transcription factor Osterix (Sp7) is essential for osteoblastogenesis and bone formation in mice. Genome wide association studies have demonstrated that Osterix is associated with bone mineral density in humans; however, the molecular significance of Osterix in human osteoblast differentiation is poorly described. In this study we have characterized the role of Osterix in human mesenchymal progenitor cell (hMSC) differentiation. We first analyzed temporal microarray data of primary hMSC treated with bone morphogenetic protein-6 (BMP6) using clustering to identify genes that are associated with Osterix expression. Osterix clusters with a set of osteoblast-associated extracellular matrix (ECM) genes, including bone sialoprotein (BSP) and a novel set of proteoglycans, osteomodulin (OMD), osteoglycin, and asporin. Maximum expression of these genes is dependent upon both the concentration and duration of BMP6 exposure. Next we overexpressed and repressed Osterix in primary hMSC using retrovirus. The enforced expression of Osterix had relatively minor effects on osteoblastic gene expression independent of exogenous BMP6. However, in the presence of BMP6, Osterix overexpression enhanced expression of the aforementioned ECM genes. Additionally, Osterix overexpression enhanced BMP6 induced osteoblast mineralization, while inhibiting hMSC proliferation. Conversely, Osterix knockdown maintained hMSC in an immature state by decreasing expression of these ECM genes and decreasing mineralization and hMSC proliferation. Overexpression of the Osterix regulated gene OMD with retrovirus promoted mineralization of hMSC. These results suggest that Osterix is necessary, but not sufficient for hMSC osteoblast differentiation. Osterix regulates the expression of a set of ECM proteins which are involved in terminal osteoblast differentiation. J. Cell. Physiol. 227: 2677-2685, 2012. © 2011 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2012

18. Notch signaling components are upregulated during both endochondral and intramembranous bone regeneration.

Author

Dishowitz, Michael I., Terkhorn, Shawn P., Bostic, Sandra A., and Hankenson, Kurt D.

Subjects

ENDOCHONDRAL ossification, BONE regeneration, TREATMENT of fractures, TIBIA injuries, CHONDROGENESIS

Abstract

Previous studies have demonstrated that Notch signaling regulates endochondral and intramembranous bone formation by controlling cell proliferation and differentiation. Notch signaling has also been shown to regulate healing in a variety of tissues. The objective of this study was to characterize and compare activation of the Notch signaling pathway during endochondral and intramembranous bone healing using tibial fracture and calvarial defect injury models, respectively. Bilateral tibial fractures or bilateral 1.5 mm diameter calvarial defects were created in mice, and tissues were harvested at 0, 5, 10, and 20 days post-fracture. Gene expression of Notch signaling components was upregulated during both tibial fracture and calvarial defect healing, with expression generally higher during tibial fracture healing. The most highly expressed ligand and receptor during healing, Jag1 and Notch2 (specifically the activated receptor, known as NICD2), were similarly localized in mesenchymal cells during both modes of healing, with expression decreasing during chondrogenesis, but remaining present in osteoblasts at all stages of maturity. Results suggest that in addition to embryological bone development, Notch signaling regulates both endochondral and intramembranous bone healing. © 2011 Orthopaedic Research Society Published by Wiley Periodicals, Inc. J Orthop Res 30:296-303, 2012 [ABSTRACT FROM AUTHOR]

Published

2012

19. Integration of BMP, Wnt, and notch signaling pathways in osteoblast differentiation.

Author

Lin, Grace L. and Hankenson, Kurt D.

Published

2011

20. Zoledronic acid inhibits macrophage SOCS3 expression and enhances cytokine production.

Author

Scheller, Erica L., Hankenson, Kurt D., Reuben, Jayne S., and Krebsbach, Paul H.

Published

2011

21. The Muenke syndrome mutation ( FgfR3P244R) causes cranial base shortening associated with growth plate dysfunction and premature perichondrial ossification in murine basicranial synchondroses.

Author

Laurita, Jason, Koyama, Eiki, Chin, Bianca, Taylor, Jesse A., Lakin, Gregory E., Hankenson, Kurt D., Bartlett, Scott P., and Nah, Hyun-Duck

Abstract

Muenke syndrome caused by the FGFR3 P250R mutation is an autosomal dominant disorder mostly identified with coronal suture synostosis, but it also presents with other craniofacial phenotypes that include mild to moderate midface hypoplasia. The Muenke syndrome mutation is thought to dysregulate intramembranous ossification at the cranial suture without disturbing endochondral bone formation in the skull. We show in this study that knock-in mice harboring the mutation responsible for the Muenke syndrome ( FgfR3 P244R) display postnatal shortening of the cranial base along with synchondrosis growth plate dysfunction characterized by loss of resting, proliferating and hypertrophic chondrocyte zones and decreased Ihh expression. Furthermore, premature conversion of resting chondrocytes along the perichondrium into prehypertrophic chondrocytes leads to perichondrial bony bridge formation, effectively terminating the postnatal growth of the cranial base. Thus, we conclude that the Muenke syndrome mutation disturbs endochondral and perichondrial ossification in the cranial base, explaining the midface hypoplasia in patients. Developmental Dynamics 240:2584-2596, 2011. © 2011 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2011

22. Novel explant model to study mechanotransduction and cell-cell communication.

Author

Hoffler, C. Edward, Hankenson, Kurt D., Miller, Joshua D., Bilkhu, Sukhinderdeep K., and Goldstein, Steven A.

Subjects

*BONE cells, *OSTEOCYTES, *LACTATE dehydrogenase, *BIOMECHANICS, *BONE mechanics, *ARTIFICIAL implants

Abstract

To understand in situ behavior of osteocytes, we characterized a model of osteocytes in their native bone matrix and demonstrated real-time biologic activity of osteocytes while bending the bone matrix. Using 43 male Sprague-Dawley rats, dumbbell-shaped explants were harvested from stainless steel femoral implants after 6-12 weeks and incubated in culture medium or fixed. Sixteen specimens were used to determine bone volume density (BV/TV), volumetric bone mineral density (BMD) and histology for different implantation periods. Osteocyte viability was evaluated by L-lactate dehydrogenase (LDH) activity in 12 cultured explants. Confocal microscopy was used to assess tracer diffusion in three explants and changes in osteocyte pH of a mechanically loaded explant. From 6 to 12 weeks, explant BV/TV and volumetric BMD trended up 92.5% and 101%, respectively. They were significantly and highly correlated. Tissues were uniformly intramembranous and all bone cell types were present. Explants maintained LDH activity through culture day 8. Diffusion at 200 µM was limited to 1,209 Da. Explants appeared capable of reproducing complex bone biology. This model may be useful in understanding osteocyte mechanotransduction in the context of a physiologically relevant bone matrix. © 2006 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 24:1687-1698, 2006 [ABSTRACT FROM AUTHOR]

Published

2006