Immunogold labeling to enhance contrast in optical coherence microscopy of tissue engineered corneal constructs.

Our lab has used an optical coherence microscope (OCM) to assess both the structure of tissue-engineered corneal constructs and their transparency. Currently, we are not able to resolve cells versus collagen matrix material in the images produced. We would like to distinguish cells in order to determine if they are viable while growing in culture and also if they are significantly contributing to the light scattering in the tissue. In order to do this, we are currently investigating the use of immunogold labeling. Gold nanoparticles are high scatterers and can create contrast in images. We have conjugated gold nanoparticles to antibodies specific to the alpha/sub 5/beta/sub 1/ integrins expressed in some corneal cells. This choice of target should allow assessment of the phenotypic behavior of the cells in the tissue, as different integrins are expressed in different phenotypes. This study applies the immunogold technique to study cultured corneal cells using the OCM with the ultimate goal of monitoring cellular behavior in engineered tissue and corroborating results from standard histological methods.

Optical coherence microscopy for the evaluation of a tissue-engineered artificial cornea.

A transparent artificial cornea derived from biological material is the ultimate goal of corneal research. Attempts at artificial corneal constructs produced from synthetic polymers have proved unsuccessful due to lack of biocompatibility and ability to integrate into the tissue. We have designed a corneal model derived from collagenous biological materials that has several advantages: it has low antigenicity and therefore small chance of eliciting an immune reaction, it can be broken down by the body's own cells and gradually replaced over time by natural materials, and it may contain signaling information for native cells, thereby inducing normal phenotype and behavior. In addition, a transparent corneal model has the potential to be used for testing of novel ophthalmic drugs or gene therapy approaches, eliminating the need for animal testing. We have used an optical coherence microscope (OCM) to evaluate both the structure of our tissue constructs over time in culture and the optical properties of the tissue itself. This imaging technique promises to be an important diagnostic tool in our efforts to understand the influence of mechanical forces, cell phenotype, and soluble factors on the transparency of corneal tissue.

In vitro culture characteristics of corneal epithelial, endothelial, and keratocyte cells in a native collagen matrix.

The objective of this investigation was to demonstrate the effectiveness of a tissue-engineered collagen sponge as a substrate for the culture of human corneal cells. To that end, human kerotocyte, epithelial, and endothelial cells were cultured separately on collagen sponges composed of native fibrillar collagen with a pore size of approximately 0.1 mm. Co-culture experiments were also performed (epithelial/endothelial and epithelial/keratocyte cultures). Proliferation of keratocytes and matrix production was assessed. The morphology of the epithelial and endothelial cell cultures was characterized by histology and scanning electron microscopy. Keratocytes cultured on collagen sponges exhibited increased matrix synthesis over time as well as proliferation and repopulation of the matrix. Epithelial and endothelial cells showed the ability to migrate over the collagen sponge. The thickness of the epithelial layer was influenced by soluble factors produced by endothelial cells. The morphology of the bottom layer of epithelial cells was influenced by the presence of keratocytes in the culture. These studies indicate that human corneal cells exhibit normal cell phenotype when cultured individually on an engineered collagen sponge matrix and co-culture of different cell types in the cornea can influence cell behavior.