Insights from imaging the implanting embryo and the uterine environment in three dimensions.

Although much is known about the embryo during implantation, the architecture of the uterine environment in which the early embryo develops is not well understood. We employed confocal imaging in combination with 3D analysis to identify and quantify dynamic changes to the luminal structure of murine uterus in preparation for implantation. When applied to mouse mutants with known implantation defects, this method detected striking peri-implantation abnormalities in uterine morphology that cannot be visualized by histology. We revealed 3D organization of uterine glands and found that they undergo a stereotypical reorientation concurrent with implantation. Furthermore, we extended this technique to generate a 3D rendering of the cycling human endometrium. Analyzing the uterine and embryo structure in 3D for different genetic mutants and pathological conditions will help uncover novel molecular pathways and global structural changes that contribute to successful implantation of an embryo

The cellular networks of normal ovine medial collateral and anterior cruciate ligaments are not accurately recapitulated in scar tissue

The purpose of this study was to characterize the cellular organization of the ovine medial collateral ligament (MCL) and anterior cruciate ligament (ACL) and compare this organization with that found in ligaments undergoing healing. Indirect immunofluorescence microscopy, used in combination with antibodies to cytoskeletal proteins, was employed to visualize individual ligament cells. Normal ligaments contained fusiform cells arranged in rows, which were stacked at regular intervals across the body of the ligament forming a three-dimensional cellular lattice. Each cell exhibited prominent cytoplasmic processes that extended for long distances through the extracellular matrix to adjacent cells, and these processes contained gap junctions. Thus the cells in rows and between rows were interconnected. The cells of the MCL and ACL scars were also arranged in rows, but these rows were shorter, irregularly arranged and closely packed into bundles resulting in tissue with a higher cellular density. In addition, cells transiting the cell cycle were detected in the scar but not in normal ligament. While the rows of cells in the normal ligament extended along the long axis of the ligament, the bundles of rows of ligament scar cells had a random orientation with respect to one another and to the region outside the scar. Over time both the ACL and the MCL scars displayed discontinuities in their cellular rows. In contrast to the scars of the MCL, which contained discontinuities filled with cellular projections and gap junctions, ACL scars contained discontinuities that were devoid of cells and gap junctions. These discontinuities as well as the differences between normal and scar cytoarchitecture may represent features of an inadequate healing response and/or may provide the structural basis for the altered biomechanics of healing ligaments