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Biophys J, June 2001, p. 2968-2975, Vol. 80, No. 6
*Department of Mechanical Engineering and Center for
Biomedical Engineering, Massachusetts Institute of Technology,
Cambridge; and Department of Radiology, Beth
Israel Deaconess Medical Center and Harvard Medical School, Boston,
Massachusetts
The determination of principal fiber directions in
structurally heterogeneous biological tissue substantially contributes to an understanding of its mechanical function in vivo. In this study
we have depicted structural heterogeneity through the model of the
mammalian tongue, a tissue comprised of a network of highly interwoven
fibers responsible for producing numerous variations of shape and
position. In order to characterize the three-dimensional-resolved microscopic myoarchitecture of the intrinsic musculature of the tongue,
we viewed its fiber orientation at microscopic and macroscopic length
scales using NMR (diffusion tensor MRI) and optical (two-photon microscopy) imaging methods. Diffusion tensor imaging (DTI) of the
excised core region of the porcine tongue resulted in an array of 3D
diffusion tensors, in which the leading eigenvector corresponded to the
principal fiber orientation at each location in the tissue. Excised
axially oriented lingual core tissues (fresh or paraffin-embedded) were
also imaged with a mode-locked Ti-Sapphire laser, (76 MHz repetition
rate, 150 femtosecond pulse width), allowing for the visualization of
individual myofibers at in situ orientation. Fiber orientation was
assessed by computing the 3D autocorrelation of discrete image volumes,
and deriving the minimal eigenvector of the center voxel Hessian
matrix. DTI of the fibers, comprising the intrinsic core of the tongue,
demonstrated directional heterogeneity, with two distinct populations
of fibers oriented orthogonal to each other and in-plane to the axial
perspective. Microscopic analysis defined this structural heterogeneity
as discrete regions of in-plane parallel fibers, with an angular
separation of ~80°, thereby recapitulating the macroscopic angular
relationship. This analysis, conceived at two different length scales,
demonstrates that the lingual core is a spatially complex tissue,
composed of repeating orthogonally oriented and in-plane fiber patches, which are capable of jointly producing hydrostatic elongation and displacement.
Biophys J, June 2001, p. 2968-2975, Vol. 80, No. 6
© 2001 by the Biophysical Society 0006-3495/01/06/2968/08 $2.00
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