Author: donnellyeve

DOI

Abstract

Transcriptional regulation of the postnatal skeleton is incompletely understood. Here, we determined the consequence of loss of early growth response gene 1 (EGR-1) on bone properties. Analyses were performed on both the microscopic and molecular levels utilizing micro-computed tomography (micro-CT) and Fourier transform infrared imaging (FTIRI), respectively. Mice deficient in EGR-1 (Egr-1 ^−/−) were studied and compared to sex- and age-matched wild-type (wt) control animals. Femoral trabecular bone in male Egr-1 ^−/− mice demonstrated osteopenic characteristics marked by reductions in both bone volume fraction (BV/TV) and bone mineral density (BMD). Morphological analysis revealed fewer trabeculae in these animals. In contrast, female Egr-1 ^−/− animals had thinner trabeculae, but BV/TV and BMD were not significantly reduced. Analysis of femoral cortical bone at the mid-diaphysis did not show significant osteopenic characteristics but detected changes in cross-sectional geometry in both male and female Egr-1 ^−/− animals. Functionally, this resulted in decreased resistance to three-point bending as indicated by a reduction in maximum load, failure load, and stiffness. Assessment of compositional bone properties, including mineral-to-matrix ratio, carbonate-to-phosphate ratio, crystallinity, and cross-linking, in femurs by FTIRI did not show any significant differences or an appreciable trend between Egr-1 ^−/− and wt mice of either sex. Unexpectedly, rib bone from Egr-1 ^−/− animals displayed distinct osteopenic traits that were particularly pronounced in female mice. This study provides genetic evidence that both sex and skeletal site are critical determinants of EGR-1 activity in vivo and that its site-specific action may contribute to the mechanical properties of bone.

Keywords

Transcription factor; Early growth response gene 1; Mice; Micro-computed tomography; Biomechanics

DOI

Abstract

Bone geometry and tissue material properties jointly govern whole-bone structural behavior. While the role of geometry in structural behavior is well characterized, the contribution of the tissue material properties is less clear, partially due to the multiple tissue constituents and hierarchical levels at which these properties can be characterized. Our objective was to elucidate the contribution of the mineral phase to bone mechanical properties across multiple length scales, from the tissue material level to the structural level. Vitamin D and calcium deficiency in 6-week-old male rats was employed as a model of reduced mineral content with minimal collagen changes. The structural properties of the humeri were measured in three-point bending and related to the mineral content and geometry from microcomputed tomography. Whole-cortex and local bone tissue properties were examined with infrared (IR) spectroscopy, Raman spectroscopy, and nanoindentation to understand the role of altered mineral content on the constituent material behavior. Structural stiffness (−47%) and strength (−50%) were reduced in vitamin D-deficient (−D) humeri relative to controls. Moment of inertia (−38%), tissue mineral density (TMD, −9%), periosteal mineralization (−28%), and IR mineral:matrix ratio (−19%) were reduced in −D cortices. Thus, both decreased tissue mineral content and changes in cortical geometry contributed to impaired skeletal load-bearing function. In fact, 97% of the variability in humeral strength was explained by moment of inertia, TMD, and IR mineral:matrix ratio. The strong relationships between structural properties and cortical material composition demonstrate a critical role of the microscale material behavior in skeletal load-bearing performance.

Keywords

Bone strength; Material property; Mineral; Rat; Fourier transform infrared spectroscopy

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Abstract

Keywords

fracture ; osteoporosis ; bone resorption ; bone mineral density ; hip fractures ; osteogenesis ; women

DOI

Abstract

In this chapter, a technique is outlined for the use of immunohistochemistry (IHC) followed by multiphoton microscopy (MPM) for the analysis of incidence, length, and 3D orientation of the axoneme of the primary cilium. Although the application presented specifically emphasizes localizations in tenocytes and chondrocytes, the technique is applicable to cells in a wide range of connective tissues. The primary advantages of utilizing MPM as opposed to TEM for these kinds of ciliary analyses are the rapidity of the technique for preparation of the samples and the ability to collect data from multiple cells simultaneously. Using MPM, the axoneme, basal body, and associated centriole can be visualized by specific IHC with localizing antibodies. However, the resolution achieved through TEM analyses allows the complex morphology of the primary cilium to be visualized, and this remains the primary advantage of TEM versus MPM. SHG, which occurs only with MPM, allows visualization of collagen fibrils and is particularly advantageous for localizing primary cilia associated with cells in connective tissues. This, and the deep penetration with less photobleaching, are the primary advantages of MPM compared to confocal microscopy. As with any microscopical technique, the protocol needs to be optimized for any given tissue. In particular, additional antigen retrieval techniques to enhance the unmasking of specific epitopes for antibody binding may be required for adaptation of this approach to other dense connective tissues with complex spatial organizations such as intervertebral disc or meniscus.

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Abstract

Skeletal tissues adapt to their mechanical environments by modulating gene expression, cell metabolism, and extracellular matrix (ECM) architecture; however, the mechanosensory mechanisms for these processes are incompletely understood. Primary cilia have emerged as critical components of the cellular mechanosensory apparatus and have been hypothesized to participate in establishment of cellular and ECM orientation, but their function in skeletal tissues is just beginning to be examined. Here we focused on tendon, a tissue with an oriented matrix that is ideal for analysis of spatial relationships between primary cilia and the ECM. The objective of this study was to characterize the incidence and orientation of tenocyte primary cilia in their native ECM. Primary cilia, nuclei, and collagen were analyzed three-dimensionally in immunofluorescently labeled rat extensor tendon using multiphoton microscopy and semiautomated morphometry. Primary cilia were observed in 64% of tenocytes. The cilia were highly oriented with respect to the ECM: cilia were aligned parallel to the collagen fibers and the long axis of the tendon. This study represents the first quantification of the in situ incidence and orientation of primary cilia in tendon. © 2009 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 28:77–82, 2010

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Abstract

Although osteoporosis is known to alter bone tissue composition, the effects of such compositional changes on tissue material properties have not yet been examined. The natural gradient in tissue mineral content arising from skeletal appositional growth provides a basic model for investigation of relationships between tissue composition and mechanical properties. The purpose of this study was to examine the effects of tissue age on bone tissue composition and nanomechanical properties. The nanomechanical properties and composition of regions of differing tissue age were characterized in the femoral cortices of growing rats using nanoindentation and Raman spectroscopy. In addition, spatial maps of the properties of periosteal tissue were examined to investigate in detail the spatial gradients in the properties of newly formed tissue. Newly formed tissue (0–4 days) was 84% less stiff and had 79% lower mineral:matrix ratio than older intracortical (15–70 days) tissue. Tissue modulus, hardness, mineral:matrix ratio, and carbonate:phosphate ratio increased sharply with distance from the periosteum and attained the properties of intracortical tissue within 4 days of formation. The mineral: matrix ratio explained 54% and 62% of the variation in tissue indentation modulus and hardness, respectively. Our data demonstrate significant variations in tissue mechanical properties with tissue age and relate mechanical properties to composition at the microscale. © 2009 Wiley Periodicals, Inc. J Biomed Mater Res, 2010

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DOI

Abstract

Although the role of the primary cilium as a sensory organelle in epithelial cells has been elucidated significantly over the past decade, the function of primary cilia in connective tissue cells has been studied less extensively. Primary cilia have been implicated as mechanotransducers in connective tissues, but the mechanisms by which the cells sense loads and convert them to biochemical signals for tissue formation and adaptation are poorly understood. Before hypotheses regarding the function of the primary cilium in connective tissue cells can be tested, methods for quantitation of incidence as well as three-dimensional visualization of primary cilia with respect to the extracellular matrix (ECM) are needed. The objective of this study was to develop a rapid method for visualizing primary cilia in their native ECM in a wide range of connective tissues. Whole-mount immunohistochemical and multiphoton microscopy techniques were developed to simultaneously image primary cilia, cell nuclei, and collagen and their relationships to each other in situ. Axonemes of primary cilia projecting into the ECM were successfully visualized in thick sections of growth plate cartilage, tendon, ligament, meniscus, intervertebral disc, and perichondrium. These methodologies will allow analysis of the incidence and three-dimensional orientation of primary cilia and enable investigation of the role of primary cilia in normal and pathological growth and adaptation in a variety of musculoskeletal tissues. Anat Rec, 291:1062–1073, 2008. © 2008 Wiley-Liss, Inc.

Keywords

Small cracks; Biaxial stress; Fatigue crack growth

Fig 7 from The Anatomical Record: Advances in Integrative Anatomy and Evolutionary Biology
Volume 291, Issue 9, pages 1062-1073, 25 AUG 2008 DOI: 10.1002/ar.20665
http://onlinelibrary.wiley.com/doi/10.1002/ar.20665/full#fig7

DOI

Abstract

Cancellous bone plays a crucial structural role in the skeleton, yet little is known about the microstructure-mechanical property relationships of the tissue at the microscale. Cancellous tissue is characterized by a microstructure consisting of layers interspaced with transition zones with different proportions of collagen and mineral. In this study, the quasistatic and dynamic mechanical properties of lamellar and interlamellar tissue in human vertebrae were assessed with nanoindentation, and the collagen content and organization were characterized with second harmonic generation microscopy. Lamellar tissue was 35% stiffer, 25% harder, and had a 13% lower loss tangent relative to interlamellar tissue. The stiff, hard lamellae corresponded to areas of highly ordered, collagen-rich material, with a relatively low loss tangent, whereas the compliant, soft interlamellar regions corresponded to areas of disordered or collagen-poor material. These data suggest an important role for collagen in the tissue-level mechanical properties of bone.

Keywords

Bone; Hardness; Microstructure

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Abstract

The effects of two key experimental parameters on the measured nanomechanical properties of lamellar and interlamellar tissue were examined in dehydrated rabbit cancellous bone. An anhydrous sample preparation protocol was developed to maintain surface integrity and produce RMS surface roughnesses ∼10 nm (5 × 5-μm² area). The effects of surface roughness and maximum nanoindentation load on the measured mechanical properties were examined in two samples of differing surface roughness using maximum loads ranging from 250 to 3000 μN. As the ratio of indentation depth to surface roughness decreased below ∼3:1, the variability in material properties increased substantially. At low loads, the indentation modulus of the lamellar bone was ∼20% greater than that of the interlamellar bone, while at high loads the measured properties of both layers converged to an intermediate value. Relatively shallow indentations made on smooth surfaces revealed significant differences in the properties of lamellar and interlamellar bone that support microstructural observations that lamellar bone is more mineralized than interlamellar bone. © 2005 Wiley Periodicals, Inc. J Biomed Mater Res, 2006.

Keywords

cancellous bone; nanoindentation; mechanical properties; surface roughness; sample preparation