OBJECTIVE:
To investigate scleroderma fibroblast behavior, and the effect of different human sera on fibroblast behavior, we established a model using the newly developed electrical biosensor, electrical cell-substrate impedance sensing (ECIS).
METHODS:
Cellular locomotion, defined as cellular micromotion, measured by ECIS indicates the dynamic vertical motion of a given group of cells. The junctional resistance (Rb) between adjacent cells and the average height (h) between basal cell surface and substratum derived from ECIS were quantified for dermal fibroblasts obtained from patients with scleroderma and normal controls. The cellular micromotions of both scleroderma and normal control fibroblasts were compared in the presence of different human sera, including those from patients with scleroderma, systemic lupus erythematosus (SLE), and Sjögren's syndrome (SS) and from normal individuals.
RESULTS:
The Rb and h levels for scleroderma and normal fibroblasts were 2.7 omega.cm2, 150 nm and 0.8 omega.cm2, 303 nm respectively. The micromotions of scleroderma fibroblasts were more active than those of normal fibroblasts. Sera from patients with scleroderma can inhibit the micromotions of normal fibroblasts but not those of scleroderma fibroblasts, while sera from patients with SLE and SS have no inhibitory effect on either normal or scleroderma fibroblast micromotions.
CONCLUSION:
We have demonstrated the previously unrecognized characteristics of dermal fibroblasts and sera derived from patients with scleroderma. It is possible that in vivo activities cause scleroderma fibroblasts to display active cellular micromotions, while sera from patients with scleroderma inhibit the micromotions of normal fibroblasts. The use of ECIS technology has also provided a new approach to the study of scleroderma.
