Your search keyword '"Kyung Shin Kang"' showing total 4 results

1. Loss of mechanosensitive sclerostin may accelerate cranial bone growth and regeneration

Author

Kyung Shin Kang, Alexander G. Robling, Jeff Lastfogel, Andrew Jea, Laurie L. Ackerman, and Sunil S. Tholpady

Subjects

Male, 0301 basic medicine, Bone Regeneration, medicine.medical_treatment, Down-Regulation, 030209 endocrinology & metabolism, Bone healing, Mechanotransduction, Cellular, Osteocytes, Mice, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Vascularity, Animals, Medicine, Bone regeneration, Adaptor Proteins, Signal Transducing, Glycoproteins, Mice, Knockout, Bone growth, Bone Development, business.industry, Regeneration (biology), Skull, X-Ray Microtomography, General Medicine, Anatomy, Cranioplasty, Disease Models, Animal, 030104 developmental biology, medicine.anatomical_structure, chemistry, Intercellular Signaling Peptides and Proteins, Sclerostin, Chromosome Deletion, medicine.symptom, business, Parietal bone

Abstract

OBJECTIVECranial defects can result from trauma, infection, congenital malformations, and iatrogenic causes and represent a surgical challenge. The current standard of care is cranioplasty, with either autologous or allogeneic material. In either case, the intrinsic vascularity of the surrounding tissues allows for bone healing. The objective of this study was to determine if mechanotransductive gene manipulation would yield non–weight-bearing bone regeneration in a critical size calvarial defect in mice.METHODSA mouse model of Sost deletion in Sost knockout (KO) mice was created in which the osteocytes do not express sclerostin. A critical size calvarial defect (4 mm in diameter) was surgically created in the parietal bone in 8-week-old wild-type (n = 8) and Sost KO (n = 8) male mice. The defects were left undisturbed (no implant or scaffold) to simulate a traumatic calvariectomy model. Eight weeks later, the animals were examined at necropsy by planimetry, histological analysis of new bone growth, and micro-CT scanning of bone thickness.RESULTSDefects created in wild-type mice did not fill with bone over the study period of 2 months. Genetic downregulation of sclerostin yielded animals that were able to regenerate 40% of the initial critical size defect area 8 weeks after surgery. A thin layer of bone covered a significant portion of the original defect in all Sost KO animals. A statistically significant increase in bone volume (p < 0.05) was measured in Sost KO mice using radiodensitometric analysis. Immunohistochemical analysis also confirmed that this bone regeneration occurred through the Wnt pathway and originated from the edge of the defect; BMP signaling did not appear to be affected by sclerostin.CONCLUSIONSMechanical loading is an important mechanism of bone formation in the cranial skeleton and is poorly understood. This is partially due to the fact that it is difficult to load bone in the craniomaxillofacial skeleton. This study suggests that modulation of the Wnt pathway, as is able to be done with monoclonal antibodies, is a potentially efficacious method for bone regeneration that requires further study.

Published

2018

2. Clcn7F318L/+ as a new mouse model of Albers-Schönberg disease

Author

Samantha Lessard, H. R. Noonan, Dorothy Hu, Joana Caetano-Lopes, Matthew L. Warman, Daniel J. Horan, Kyung Eun Lim, Alexander G. Robling, K. Espinoza, Roland Baron, Steven Hann, and Kyung Shin Kang

Subjects

0301 basic medicine, Histology, biology, Physiology, Endocrinology, Diabetes and Metabolism, 030209 endocrinology & metabolism, Osteopetrosis, Dominant-Negative Mutation, medicine.disease, Molecular biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Mutant protein, Osteoclast, Immunology, Knockout mouse, medicine, biology.protein, Autosomal dominant osteopetrosis type 2, Interferon gamma, CLCN7, medicine.drug

Abstract

Dominant negative mutations in CLCN7, which encodes a homodimeric chloride channel needed for matrix acidification by osteoclasts, cause Albers-Schonberg disease (also known as autosomal dominant osteopetrosis type 2). More than 25 different CLCN7 mutations have been identified in patients affected with Albers-Schonberg disease, but only one mutation (Clcn7G213R) has been introduced in mice to create an animal model of this disease. Here we describe a mouse with a different osteopetrosis-causing mutation (Clcn7F318L). Compared to Clcn7+/+ mice, 12-week-old Clcn7F318L/+ mice have significantly increased trabecular bone volume, consistent with Clcn7F318L acting as a dominant negative mutation. Clcn7F318L/F318L and Clcn7F318L/G213R mice die by 1month of age and resemble Clcn7 knockout mice, which indicate that p.F318L mutant protein is non-functional and p.F318L and p.G213R mutant proteins do not complement one another. Since it has been reported that treatment with interferon gamma (IFN-G) improves bone properties in Clcn7G213R/+ mice, we treated Clcn7F318L/+ mice with IFN-G and observed a decrease in osteoclast number and mineral apposition rate, but no overall improvement in bone properties. Our results suggest that the benefits of IFN-G therapy in patients with Albers-Schonberg disease may be mutation-specific.

Published

2017

3. Postnatal β-catenin deletion from Dmp1-expressing osteocytes/osteoblasts reduces structural adaptation to loading, but not periosteal load-induced bone formation

Author

Jung Min Hong, Kyung Shin Kang, and Alexander G. Robling

Subjects

0301 basic medicine, medicine.medical_specialty, Histology, Beta-catenin, Physiology, Endocrinology, Diabetes and Metabolism, Population, 030209 endocrinology & metabolism, Bone tissue, Osteocytes, Article, Weight-Bearing, Mice, 03 medical and health sciences, Absorptiometry, Photon, 0302 clinical medicine, Bone Density, Osteogenesis, Periosteum, Internal medicine, Cortical Bone, medicine, Animals, Transgenes, Mechanotransduction, education, Alleles, beta Catenin, Extracellular Matrix Proteins, education.field_of_study, Osteoblasts, biology, Chemistry, Muscles, Wnt signaling pathway, LRP5, Adaptation, Physiological, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Endocrinology, Animals, Newborn, Osteocyte, Catenin, biology.protein, Gene Deletion

Abstract

Mechanical signal transduction in bone tissue begins with load-induced activation of several cellular pathways in the osteocyte population. A key pathway that participates in mechanotransduction is Wnt/Lrp5 signaling. A putative downstream mediator of activated Lrp5 is the nucleocytoplasmic shuttling protein β-catenin (βcat), which migrates to the nucleus where it functions as a transcriptional co-activator. We investigated whether osteocytic βcat participates in Wnt/Lrp5-mediated mechanotransduction by conducting ulnar loading experiments in mice with or without chemically induced βcat deletion in osteocytes. Mice harboring βcat floxed loss-of-function alleles (βcat(f/f)) were bred to the inducible osteocyte Cre transgenic (10)(kb)Dmp1-CreERt2. Adult male mice were induced to recombine the βcat alleles using tamoxifen, and intermittent ulnar loading sessions were applied over the following week. Although adult-onset deletion of βcat from Dmp1-expressing cells reduced skeletal mass, the bone tissue was responsive to mechanical stimulation as indicated by increased relative periosteal bone formation rates in recombined mice. However, load-induced improvements in cross sectional geometric properties were compromised in recombined mice. The collective results indicate that the osteoanabolic response to loading can occur on the periosteal surface when β-cat levels are significantly reduced in Dmp1-expressing cells, suggesting that either (i) only low levels of β-cat are required for mechanically induced bone formation on the periosteal surface, or (ii) other additional downstream mediators of Lrp5 might participate in transducing load-induced Wnt signaling.

Published

2016

4. Effects of electromagnetic field frequencies on chondrocytes in 3D cell-printed composite constructs

Author

Jinah Jang, Jung Min Hong, Young Hun Jeong, Kyung Shin Kang, Moon Nyeo Park, Dong-Woo Cho, and Hee-Gyeong Yi

Subjects

0301 basic medicine, Scaffold, animal structures, Materials science, Cartilage, 0206 medical engineering, Metals and Alloys, Biomedical Engineering, 02 engineering and technology, Chondrogenesis, 020601 biomedical engineering, In vitro, Biomaterials, Glycosaminoglycan, Extracellular matrix, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, Cell culture, In vivo, Ceramics and Composites, medicine, Biomedical engineering

Abstract

In cartilage tissue engineering, electromagnetic field (EMF) therapy has been reported to have a modest effect on promoting cartilage regeneration. However, these studies were conducted using different frequencies of EMF to stimulate chondrocytes. Thus, it is necessary to investigate the effect of EMF frequency on cartilage formation. In addition to the stimulation, a scaffold is required to satisfy the characteristics of cartilage such as its hydrated and dense extracellular matrix, and a mechanical resilience to applied loads. Therefore, we 3D-printed a composite construct composed of a polymeric framework and a chondrocyte-laden hydrogel. Here, we observed frequency-dependent positive and negative effects on chondrogenesis using a 3D cell-printed cartilage tissue. We found that a frequency of 45 Hz promoted gene expression and secretion of extracellular matrix molecules of chondrocytes. In contrast, a frequency of 7.5 Hz suppressed chondrogenic differentiation in vitro. Additionally, the EMF-treated composite constructs prior to implantation showed consistent results with those of in vitro, suggesting that in vitro pre-treatment with different EMF frequencies provides different capabilities for the enhancement of cartilage formation in vivo. This correlation between EMF frequency and 3D-printed chondrocytes suggests the necessity for optimization of EMF parameters when this physical stimulus is applied to engineered cartilage. © 2016 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 104A: 1797-1804, 2016.

Published

2016