Jun-Cheng Weng1
1Department of Medical Imaging and
Radiological Sciences,
Fundamental
relationships between diffusion tensor imaging (DTI) and q-space imaging can
be derived which establish conditions when these two complementary MR methods
are equivalent. When the 3D displacement distribution is measured by q-space
imaging with large displacement and small q vector, the result is similar to
3D Gaussian assumed in DTI. Combing displacement information from q-space
imaging and fiber direction from DTI, distribution of axonal diameters and
directions could be derived at the same time. The study proposed a novel
technique, q-space diffusion tensor imaging (qDTI), combined with two image
reconstruction methods based on the assumption to simultaneously map axonal
diameter distribution and direction of rat brain. One was tensor-based method.
The 3D Gaussian displacement distribution could be obtained directly by the
displacement tensor. The other was displacement projection method. The
effective axonal diameter was defined as the average of several displacements
projected to the direction of the fiber section. They provided MR images in
which physical parameters of water diffusion such as the mean displacement
and maximum diffusivity of water molecules were used as image contrast. Our
results demonstrated that two qDTI methods both produced reasonable
distribution of effective axonal diameters and directions in rat brain.