A novel biomechanical testing methodology was developed to obtain the intri
nsic material properties of an individual cell attached to a rigid substrat
e, With use of a newly designed cell-indentation apparatus (cytoindenter),
displacement-controlled indentation tests were conducted on the surface of
individual MG63 cells and the corresponding surface reaction force of each
cell was measured. The cells were modeled with a linear elasticity solution
of half-space indentation and the linear biphasic theory on the assumption
that the viscoelastic behavior of each cell was due to the interaction bet
ween the solid cytoskeletal matrix and the cytoplasmic fluid. To obtain the
intrinsic material properties (aggregate modulus, Poisson's ratio, and per
meability), the data for experimental surface reaction force and deformatio
n were curve-fitted with use of solutions predicted with a linear biphasic
finite element code in conjunction with optimization routines. The MG63 ost
eoblast-like cells had a compressive aggregate modulus of 2.05 +/- 0.89 kPa
, which is two to three orders of magnitude smaller than that of articular
cartilage, six to seven orders smaller than that of compact bone, and quite
similar to that of leukocytes. The permeability was 1.18 +/- 0.65 (x10(-10
)) m(4)/N-s, which is four to six orders of magnitude larger than that of c
artilage. The Poisson's ratio was 0.37 +/- 0.03. The intrinsic material pro
perties of the individual cell in this study can be useful in precisely qua
ntifying mechanical stimuli acting on cells. This information is also neede
d for theories attempting to establish mechanotransductional relationships.