Quasi-3D Cytoskeletal Dynamics of Osteocytes under Fluid Flow

Osteocytes respond to dynamic fluid shear loading by activating various biochemical pathways, mediating a dynamic process of bone formation and resorption. Whole-cell deformation and regional deformation of the cytoskeleton may be able to directly regulate this process. Attempts to image cellular de...

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Bibliographic Details
Published in:Biophysical journal 2010-11, Vol.99 (9), p.2812-2820
Main Authors: Baik, Andrew D., Lu, X. Lucas, Qiu, Jun, Huo, Bo, Hillman, Elizabeth M.C., Dong, Cheng, Guo, X. Edward
Format: Article
Language:English
Subjects:
Actins - physiology
Animals
Biochemistry
Biocompatibility
Biomedical materials
Biophysical Phenomena
Biophysics
Cell Line
Cell Membrane - physiology
Cells
Cellular Biophysics and Electrophysiology
Colchicine - pharmacology
Cytoskeleton
Cytoskeleton - physiology
Deformation
Dynamics
Green Fluorescent Proteins - genetics
Green Fluorescent Proteins - metabolism
Imaging, Three-Dimensional
Loads (forces)
Membranes
Mice
Microscopy
Microscopy, Confocal - instrumentation
Microscopy, Confocal - methods
Microscopy, Video - instrumentation
Microscopy, Video - methods
Microtubules - drug effects
Microtubules - physiology
Networks
Osteocytes - cytology
Osteocytes - drug effects
Osteocytes - physiology
Rheology
Strain
Stress, Mechanical
Studies
Tensile Strength
Three dimensional imaging
Transfection
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Summary:Osteocytes respond to dynamic fluid shear loading by activating various biochemical pathways, mediating a dynamic process of bone formation and resorption. Whole-cell deformation and regional deformation of the cytoskeleton may be able to directly regulate this process. Attempts to image cellular deformation by conventional microscopy techniques have been hindered by low temporal or spatial resolution. In this study, we developed a quasi-three-dimensional microscopy technique that enabled us to simultaneously visualize an osteocyte's traditional bottom-view profile and a side-view profile at high temporal resolution. Quantitative analysis of the plasma membrane and either the intracellular actin or microtubule (MT) cytoskeletal networks provided characterization of their deformations over time. Although no volumetric dilatation of the whole cell was observed under flow, both the actin and MT networks experienced primarily tensile strains in all measured strain components. Regional heterogeneity in the strain field of normal strains was observed in the actin networks, especially in the leading edge to flow, but not in the MT networks. In contrast, side-view shear strains exhibited similar subcellular distribution patterns in both networks. Disruption of MT networks caused actin normal strains to decrease, whereas actin disruption had little effect on the MT network strains, highlighting the networks' mechanical interactions in osteocytes.
ISSN:0006-3495
1542-0086
DOI:10.1016/j.bpj.2010.08.064