Utilizing micro-CT imaging to define collagen modeling in murine aorta.

Abstract

We aim to demonstrate local aortic tissue biodynamics via collagen and elastin fiber remodeling in murine aorta at varying distension using microcomputed tomography (microCT). Ten week-old C57BL/6 mice were injected via tail vein with in-vivo collagen hybridizing peptide, which reforms the triple-helix structure of denatured collagen, and is visualized via fluorescein tag. Careful dissection and removal of the thoracoabdominal aorta was performed, which was pressurized with formalin at varying distensions. Samples were then prepared via heavy-metal staining, and fixed in epoxy resin. These were subsequently imaged at the microCT scanner at University of Chicago, as well as at the 2-BM-B beamline using the Advanced Photon Source at Argonne National Laboratory to obtain micron and sub-micron resolution images and thus provide multi-level views of the tissue. Clear visualization of distinct collagen and elastin layers was observed with microCT. The images also clearly illustrate the effect on individual collagen and elastin fiber organization created by overdistension and shear-stress on the aorta. Clear demonstration of the geometric structure of aortic elastin fibers was seen upon initial segmentation. Preliminary experiments demonstrate that microCT provides an excellent visualization of murine aorta at micron and submicron levels. Next steps will be to segment and mesh this data in order to simulate local tissue responses to stress via finite element analysis. This method will produce a multi-scale imaging model of aortic failure.