Bone adaptation under mechanical influence: regional differences in bone mineral density, degree of mineralisation, mirco-arhitecture evaluated by pQCT, BSE imaging and microCT. / CUHK electronic theses & dissertations collection

January 2006

Lai Yau Ming. / "August 2006." / Thesis (Ph.D.)--Chinese University of Hong Kong, 2006. / Includes bibliographical references (p. 260-290). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstracts in English and Chinese.

Bone densitometry

Bones--Adaptation

Bones--Mechanical properties

Adaptation, Physiological--physiology

Biomechanical Phenomena

Bone and Bones--physiology

Bone Density

Kalirin : novel role in osteocyte function

Wayakanon, Kornchanok

January 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Communication between bone cells is important for the maintenance of bone mass. Although osteocytes are deeply embedded within the mineralized matrix, they are essential for the regulation of osteoblast and osteoclast functions. However, the intracellular proteins that control the morphology and function of osteocytes, and their ability to communicate with other bone cells are still unknown. Kalirin is a novel multi-domain GTP exchange factor (GEF) protein that activates the RhoGTPases. Recently, we found that 14 week old female Kalirin knockout (Kal-KO) mice exhibit a 45% decrease in trabecular bone density and have significantly lower cortical area, perimeter, thickness and polar cross-sectional moment of inertia (-12.6%, -7.2%, -7.6% and -21.9%, respectively) than WT mice. Kalirin was found to be expressed in osteoclasts and osteoblasts but its expression and function in osteocytes is currently unclear. We examined the role of Kalirin on the morphology and function of osteocytes. Primary osteocytes were isolated by sequential collagenase digestions from long bones (femurs and tibias) of 10-week old WT and Kal-KO mice. Immunofluorescent staining revealed Kalirin was localized to the perinuclear region of primary osteocytes and MLO-Y4 cells, and was detected along the cytoplasmic processes of primary osteocytes. We also examined primary osteocytes isolated from the long bones of Kal-KO and WT mice for changes in the length and number of cytoplasmic processes. Kal-KO osteocytes were found to express significantly fewer cytoplasmic processes per cell (3.3±0.21) than WT osteocytes (4.7±0.3). In addition, the cytoplasmic processes of Kal-KO osteocytes were shorter (79.5±4.6 µm) than those observed for WT osteocytes (85.4±3.6 µm) (p <0.01). Quantitative PCR revealed the expression of mRNA for the three major Kalirin isoforms (Kal-7, Kal-9, Kal-12) in primary osteocytes and in MLO-Y4 cells. Moreover, the mRNA levels of osteoprotegerin (OPG) and SOST, which are important for controlling osteoclast differentiation and Wnt signaling leading to bone formation, respectively, were reduced in Kal-KO osteocytes. Next, the role of Kalirin in osteocyte morphology and function was further examined. Treatment of MLO-Y4 cells for 5 days with nerve growth factor, which is known to activate Kalirin in neurons, or over-expression of the Ser-Thr kinase domain of Kal-12, promoted cytoplasmic process elongation and upregulated phosphorylated ERK and RhoA levels. Together, these results suggest that Kalirin controls osteocyte morphology and function in part by regulating cytoskeletal remodeling and the activity of ERK and RhoA. Furthermore, Kalirin may control the bone remodeling cycle by regulating osteocyte signaling to osteoclasts and osteoblasts.

Kalirin

Osteocytes

Cytoplasmic processes

Bone and Bones -- physiology

Osteocytes -- cytology

Osteoblasts -- cytology

Guanine Nucleotide Exchange Factors

Protein Isoforms

Carrier Proteins

Experimental and Computational Analysis of Dynamic Loading for Bone Formation

Dodge, Todd Randall

12 November 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Bone is a dynamic tissue that is constantly remodeling to repair damage and strengthen regions exposed to loads during everyday activities. However, certain conditions, including long-term unloading of the skeleton, hormonal imbalances, and aging can disrupt the normal bone remodeling cycle and lead to low bone mass and osteoporosis, increasing risk of fracture. While numerous treatments for low bone mass have been devised, dynamic mechanical loading modalities, such as axial loading of long bones and lateral loading of joints, have recently been examined as potential methods of stimulating bone formation. The effectiveness of mechanical loading in strengthening bone is dependent both on the structural and geometric characteristics of the bone and the properties of the applied load. For instance, curvature in the structure of a bone causes bending and increased strain in response to an axial load, which may contribute to increased bone formation. In addition, frequency of the applied load has been determined to impact the degree of new bone formation; however, the mechanism behind this relationship remains unknown. In this thesis, the application of mechanical loading to treat osteoporotic conditions is examined and two questions are addressed: What role does the structural geometry of bone play in the mechanical damping of forces applied during loading? Does mechanical resonance enhance geometric effects, leading to localized areas of elevated bone formation dependent on loading frequency? Curvature in the structure of bone was hypothesized to enhance its damping ability and lead to increased bone formation through bending. In addition, loading at frequencies near the resonant frequencies of bone was predicted to cause increased bone formation, specifically in areas that experienced high principal strains due to localized displacements during resonant vibration. To test the hypothesis, mechanical loading experiments and simulations using finite element (FE) analysis were conducted to characterize the dynamic properties of bone. Results demonstrate that while surrounding joints contribute to the greatest portion of the damping capacity of the lower limb, bone absorbs a significant amount of energy through curvature-driven bending. In addition, results show that enhanced mechanical responses at loading frequencies near the resonant frequencies of bone may lead to increased bone formation in areas that experience the greatest principal strain during vibration. These findings demonstrate the potential therapeutic effects of mechanical loading in preventing costly osteoporotic fractures, and explore characteristics of bone that may lead to optimization of mechanical loading techniques. Further investigation of biomechanical properties of bone may lead to the prescribing of personalized mechanical loading treatments to treat osteoporotic diseases.

Biomechanics

Mechanical Loading

Bone Formation

Resonance

Biomechanics

Human mechanics

Bones -- Mechanical properties

Osteoporosis -- Pathophysiology

Bones -- Physiology

Bones -- Growth

Resonance

Resonant vibration

Bone remodeling

The essential role of Stat3 in bone homeostasis and mechanotransduction

Zhou, Hongkang

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Signal Transducer and Activator of Transcription 3 (Stat3) is a transcription factor expressed in bone and joint cells that include osteoblasts, osteocytes, osteoclasts, and chondrocytes. Stat3 is activated by a variety of cytokines and growth factors, including IL-6/gp130 family cytokines. These cytokines not only regulate the differentiation of osteoblasts and osteoclasts, but also regulate proliferation of chondrocytes through Stat3 activation. In 2007, mutations of Stat3 have been confirmed to cause a rare human immunodeficiency disease – Job syndrome which presents skeletal abnormalities like: reduced bone density (osteopenia), scoliosis, hyperextensibility of joints, and recurrent pathological bone fractures. Changes in the Stat3 gene alter the structure and function of the Stat3 proteins, impairing its ability to control the activity of other genes. However, little is known about the effects of Stat3 mutations on bone cells and tissues. To investigate the in vivo physiological role of Stat3 in bone homeostasis, osteoblast/osteocyte-specific Stat3 knockout (KO) mice were generated via the Cre-LoxP recombination system. The osteoblast/osteocyte-specific Stat3 KO mice showed bone abnormalities and an osteoporotic phenotype because of a reduced bone formation rate. Furthermore, inactivation of Stat3 decreased load-driven bone formation, and the disruption of Stat3 in osteoblasts suppressed load-driven mitochondrial activity, which led to an elevated level of reactive oxygen species (ROS) in cultured primary osteoblasts. Stat3 has been found to be responsive to mechanical stimulation, and might play an important role in mechanical signal transduction in osteocytes. To investigate the role Stat3 plays in mechanical signaling transduction, osteocyte-specific Stat3 knockout (KO) mice were created. Inactivation of Stat3 in osteocytes presented a significantly reduced load-driven bone formation. Decreased osteoblast activity indicated by reduced osteoid surface was also found in osteocyte-specific Stat3 KO mice. Moreover, sclerostin (SOST) protein which is a critical osteocyte-specific inhibitor of bone formation, its encoded gene SOST expression has been found to be enhanced in osteocyte-specific Stat3 KO mice. Thus, these results clearly demonstrated that Stat3 plays an important role in bone homeostasis and mechanotransduction, and Stat3 is not only involved in bone-formation-important genes regulation in the nucleus but also in mediation of ROS and oxidative stress in mitochondria.

Bone formation

Osteoblast

Osteocyte

Mechanotransduction

Bones -- Growth -- Molecular aspects

Human mechanics

Bones -- Physiology

Biomechanics -- Research

Bones -- Metabolism -- Disorders

Osteocytes -- Research

Osteoblasts -- Research

Osteoclasts -- Research

Bone cells -- Research

Cellular signal transduction -- Research

Transcription factors -- Research

Bone remodeling