Biomedical Engineering Reference
In-Depth Information
88. A. Shahsavari and R. C. Picu, “Model selection for athermal cross-linked fiber networks,” Phys.
Rev. E
86
, 011923 (2012).
89. M. Bai, A. R. Missel, A. J. Levine, and W. S. Klug, “On the role of the filament length
distribution in the mechanics of semi exible networks,” Acta Biomaterialia
7
, 2109-2118
(2011).
90. D. A. Head, A. J. Levine, and F. C. MacKintosh, “Mechanical response of semi exible networks
to localized perturbations,” Phys. Rev. E
72
, 061914 (2005).
91. R. C. Picu, “Mechanics of random fiber networks - a review,” Soft Matter
7
, 6768-6785 (2012).
92. A. K. T.Wann, C. Thompson, and M. K. Knight, “The role of the primary cilium in chondrocyte
response to mechanical loading,” Mechanosensitivity in Cells and Tisseus
6
, 405-426 (2013).
93. S. R. McGlashan, M. M. Knight, T. T. Chowdhury, P. Joshi, C. G. Jensen, S. Kennedy, and
C. A. Poole, “Mechanical loading modulates chondrocyte primary cilia incidence and length,”
Cell Biology International
34
, 441-446 (2010).
94. K. Gardner, S. P. Arnoczky, and M. Lavagnino, “Effect of in vitro stress-deprivation and cyclic
loading on the length of tendon cell cilia in situ,” Journal of Orthopaedic Research
29
, 582-587
(2011).
95. P. C. Bressloff, “Stochastic model of intra agellar transport,” Phys. Rev. E
73
, 061916 (2006).
96. D. L. Odor and R. J. Blandau, “Observation on the solitary cilium of rabbit oviductal epithelium:
its motility and ultrastructure,” American Journal of Anatomy
174
, 437-453 (1985).
97. M. Yamamoto and K. Kataoka, “Electron microscopic observation of the primary cilium in the
pancreatic islets,” Archivum Hisologicum Japonicum
49
, 449-457 (1986).
Search WWH ::
Custom Search