Barrier Forming Tissue

In multicellular organisms epithelial and endothelial cell layers serve as functional barriers and perform very complex and vital activities. While comprising various tissues of the body, these cell layers form selectively permeable interfaces between compartments of different chemical composition. They not only control diffusive permeation of solutes along intercellular clefts between adjacent cells but can also actively transport substances along transcellular paths. Key components of epithelial and endothelial cell barriers are the connecting points between adjacent cells. These tight junctions are of particular relevance for the active barrier functionality of the cell layer. They regulate the passage of molecules across the barrier as they selectively open and close in response to various signals from the inside and outside of the cells.

While the barrier function is responsible for a multitude of physiological activities and is thereby of vital importance for the correct functioning of the organism, it is at the same time also a severe obstacle for specific types of medical treatment, in particular for targeted drug delivery: in order to get a drug to the intended site of action it has somehow to pass through these tissue barriers.

Consequently, in the field of fundamental research, pharmaceutical research, and drug development there is great interest in understanding and controlling the barrier function of epithelial and endothelial tissue. Finding methods to overcome this hurdle is of particular relevance to medication by drug delivery across the blood-brain barrier, blood vessels, nasal tissue, or gastrointestinal tissue. Therefore adequate in vitro cell models and assays are required - for instance for identifying compounds that reversibly increase drug permeation through tissue barriers.

A direct correlation between the permeability of a cell layer and its electric resistance, i.e. the so called transepithelial / -endothelial electric resistance TER, exists. This fact can be utilized to form the basis for an assay: tight cell layers exhibit high electric resistance and - vice versa - high permeability correlates with low electric resistance. Therefore, the electric resistance measured across a cell layer is a highly qualified parameter for quantifying leak tightness of barrier forming tissue. Consequently, it can be recorded to compare and monitor the establishment or modulation of barrier-forming cell-to-cell contacts.

Analyzing the properties of a cell layer by means of electrical measurements is not limited to measuring the electric resistance, but can be complemented by recording the electric capacitance C_cl as well. This parameter provides additional information about the cell layer properties: in particular it is indicative of the expression of microvilli and other membrane extrusions.

The two quantities, resistance TER and capacitance C_cl, combine for the complex impedance Z of the cell layer, which can be measured electronically. In contrast to other assay techniques electrical measurements require neither a fluorescent or radioactive marker nor any other type of physiologic modification of the cell system. While providing a wealth of information on the barrier properties electrical measurements can be performed without affecting the native cell culture under investigation.