On bone adaptation due to venous stasis

This paper addresses the question of whether or not interstitial fluid flow due to the blood circulation accounts for the observed periosteal bone formation associated with comprised venous return (venous stasis). Increased interstitial fluid flow induced by increased intramedullary pressure has been proposed to account for the periosteal response in venous stasis. To investigate the shear stresses acting on bone cell processes due to the blood circulation-driven interstitial fluid flow, a poroelastic model is extended to the situation in which the interstitial fluid flow in an osteon is driven by the pulsatile extravascular pressure in the osteonal canal as well as by the applied cyclic mechanical loading. Our results show that under normal conditions, the pulsatile extravascular pressure in the osteonal canal due to cardiac contraction (10mm Hg at 2Hz) and skeletal muscle contraction (30mm Hg at 1Hz) induce peak shear stresses on the osteocyte cell processes that are two orders of magnitude lower than those induced by physiological mechanical loading (100 microstrain at 1Hz). In venous stasis the induced peak shear stress is reduced further compared to the normal conditions because, although the mean intramedullary pressure is increased, the amplitude of its pulsatile component is decreased. These results suggest that the interstitial fluid flow is unlikely to cause the periosteal bone formation in venous stasis. However, the mean interstitial fluid pressure is found to increase in venous stasis, which may pressurize the periosteum and thus play a role in periosteal bone formation.     

Formation of human prostate tissue from embryonic stem cells

Rodent models and immortalized or genetically modified cell lines are frequently used-but have limited utility-for studying human prostate development and maturation. Using rodent mesenchyme to establish reciprocal mesenchymal-epithelial cell interactions with human embryonic stem cells (hESCs), we generated human prostate tissue expressing prostate-specific antigen (PSA) within 8-12 weeks. This human prostate model shows species-conserved signalling mechanisms that could extend to integumental, gastrointestinal and genital tissues.     

Non-interacting modes for stress, strain and energy in anisotropic hard tissue.

The six non-interacting modes for stress, strain and energy in an orthotropic elastic model of human femoral cortical bone tissue are discussed and illustrated. The stress and strain modes are illustrated using the representation of the stress and strain fields around a circular hole in a flat plate of cortical bone subjected to a uniaxial field of tension as the example. The six modes play a role in the stress analysis of orthotropic elastic materials similar to the roles played by the hydrostatic and deviatoric non-interacting stress, strain and energy modes in isotropic elasticity. The biomechanical significance of the six non-interacting modes for stress, strain and energy in hard tissue is both practical and suggestive. The modes suggest a practical scheme for the representation of stress and strain fields in hard tissue. The existence of the modes suggests physical insights, for example, possible failure mechanisms or adaptation strategies possessed by the hard tissues.     

Fluid shear stress remodels expression and function of junctional proteins in cultured bone cells

We tested the hypothesis that fluidshear stress () modifies the expression, function, and distributionof junctional proteins [connexin (Cx)43, Cx45, and zona occludens(ZO)-1] in cultured bone cells. Cell lines with osteoblastic (MC3T3-E1cells) and osteocytic (MLO-Y4 cells) phenotypes were exposed to-values of 5 or 20 dyn/cm² for 1-3 h.Immunostaining indicated that at 5 dyn/cm², thedistribution of Cx43, Cx45, and ZO-1 was moderately disrupted at cellmembranes; at 20 dyn/cm², disruption was more severe.Intercellular coupling was significantly decreased at both shear stresslevels. Western blots showed the downregulation of membrane-bound Cx43and ZO-1 and the upregulation of cytosolic Cx43 and Cx45 at differentlevels of shear stress. Similarly, Northern blots revealed thatexpression of Cx43, Cx45, and ZO-1 was selectively up- anddownregulated in response to different shear stress levels. Theseresults indicate that in cultured bone cells, fluid shear stressdisrupts junctional communication, rearranges junctional proteins, anddetermines de novo synthesis of specific connexins to an extent thatdepends on the magnitude of the shear stress. Such disconnection fromthe bone cell network may provide part of the signal whereby thedisconnected cells or the remaining network initiate focal bone remodeling.

     

Analysis of avian bone response to mechanical loading, Part Two: Development of a computational connected cellular network to study bone intercellular communication

Mechanical loading-induced signals are hypothesized to be transmitted and integrated by connected bone cells before reaching the bone surfaces where adaptation occurs. A computational connected cellular network (CCCN) model is developed to explore how bone cells perceive and transmit the signals through intercellular communication. This is part two of a two-part study in which a CCCN is developed to study the intercellular communication within a grid of bone cells. The excitation signal was computed as the loading-induced bone fluid shear stress in part one. Experimentally determined bone adaptation responses (Gross et al. in J Bone Miner Res 12:982-988, 1997 and Judex et al. in J Bone Miner Res 12:1737-1745, 1997) are correlated with the fluid shear stress by the CCCN, which adjusts cell sensitivities (loading and signal thresholds) and connection weights. Intercellular communication patterns extracted by the CCCN indicate the cell population responsible for perceiving the loading-induced signal, and loading threshold is shown to play an important role in regulating the bone response.     

Plakoglobin is a component of the filamentous subplasmalemmal coat of lens cells

The plasma membranes of the cells of the superficial layer of the eye lens and the lens fibres are in close intercellular contact, leaving an intermembrane space of approximately 20 nm or less throughout their entire length. This plasma membrane is underlaid by a filamentous, cytoplasmic web containing actin, proteins of the spectrin and band 4.1 families, alpha-actinin and vinculin. Using immunofluorescence microscopy and immunoblotting of gel electrophoretically separated proteins, we show that plakoglobin, the plaque protein common to desmosomal and nondesmosomal adhering junctions, is present in lens cells and is also a component of the subplasmalemmal coat of these cells. Plakoglobin also exists in the extended regions of intercellular contacts between cultured lenticular cells where it often colocalizes with vinculin but does not occur in other vinculin-rich plasma membrane regions such as the focal adhesions at the ventral cell surface. Plakoglobin associated with plasma membrane regions can also be identified in various other adhesive cultured cells, but it is not detected in cells and tissues that do not establish firm intercellular junctions such as erythrocytes, platelets, cultured myeloma cells and smooth muscle tissue. We conclude that plakoglobin occurs, at least in lens cells, throughout the entire subplasmalemmal coat, coexisting in this situation not only with vinculin but also with spectrin and 4.1 protein(s). This colocalization infers the presence of a distinct, complex type of membrane-skeleton assembly involving the actin filament-associated junctional plaque elements plakoglobin and vinculin together with actin-associated proteins of the spectrin and band 4.1 protein families.     

Functional adaptation in long bones: establishing in vivo values for surface remodeling rate coefficients

In this paper we describe a computational means, based on beam theory, for application of the theory of adaptive elasticity to examples of real bone geometries. The results of the animal experiments were taken from the literature, and each documented the temporal evolution of a change in bone shape after a significant change in the mechanical loading environment of the bone. For each of these studies, we establish preliminary estimates of the in vivo values of the surface remodeling rate coefficients--the key parameters in the theory of surface remodeling. Our preliminary parameter estimates are established by comparison of published animal experimental results with surface remodeling theory predictions generated by the computational method.     

Mechanosensation and fluid transport in living bone

The mechanosensory mechanisms in bone include (i) the cell system that is stimulated by external mechanical loading applied to the bone; (ii) the system that transduces that mechanical loading to a communicable signal; and (iii) the systems that transmit that signal to the effector cells for the maintenance of bone homeostasis and for strain adaptation of the bone structure. The effector cells are the osteoblasts and the osteoclasts. These systems and the mechanisms that they employ have not yet been unambiguously identified. The candidate systems will be reviewed. It will be argued that the current theoretical and experimental evidence suggests that osteocytes are the principal mechanosensory cells of bone, that they are activated by shear stress from fluid flowing through the osteocyte canaliculi, and that the electrically coupled three-dimensional network of osteocytes and lining cells is a communications system for the control of bone homeostasis and structural strain adaptation. The movement of bone fluid from the region of the bone vasculature through the canaliculi and the lacunae of the surrounding mineralized tissue accomplishes three important tasks. First, it transports nutrients to the osteocytes in the lacunae buried in the mineralized matrix. Second, it carries away the cell waste. Third, the bone fluid exerts a force on the cell process, a force that is large enough for the cell to sense. This is probably the basic mechanotransduction mechanism in bone, the way in which bone senses the mechanical load to which it is subjected. The mechanisms of bone fluid flow are described with particular emphasis on mechanotransduction. Also described is the cell to cell communication by which higher frequency signals might be transferred, a potential mechanism in bone by which the small whole tissue strain is amplified so the bone cells can respond to it. One of the conclusions is that higher frequency low amplitude strains can maintain bone as effectively as low frequency high amplitude strains. This conclusion leads to a paradigm shift in how to treat osteoporosis and how to cope with microgravity.     

Dynamic permeability of the lacunar–canalicular system in human cortical bone

A new method for the experimental determination of the permeability of a small sample of a fluid-saturated hierarchically structured porous material is described and applied to the determination of the lacunar–canalicular permeability \((K_\mathrm{LC})\) in bone. The interest in the permeability of the lacunar–canalicular pore system (LCS) is due to the fact that the LCS is considered to be the site of bone mechanotransduction due to the loading-driven fluid flow over cellular structures. The permeability of this space has been estimated to be anywhere from \(10^{-17}\;\) to \(10^{-25}\; \hbox {m}^{2}\) . However, the vascular pore system and LCS are intertwined, rendering the permeability of the much smaller-dimensioned LCS challenging to measure. In this study, we report a combined experimental and analytical approach that allowed the accurate determination of the \(K_\mathrm{LC}\) to be on the order of \(10^{-22}\; \hbox {m}^{2}\) for human osteonal bone. It was found that the \(K_\mathrm{LC}\) has a linear dependence on loading frequency, decreasing at a rate of \(2 \times 10^{-24}\; \hbox {m}^{2}\) /Hz from 1 to 100 Hz, and using the proposed model, the porosity alone was able to explain 86 % of the \(K_\mathrm{LC}\) variability.