Biological cells are strongly influenced by the topography of the surface o
n which they live, both in cell culture and in an animal. They are guided a
long micron sized grooves and change their shape becoming more elongated. O
n the other hand, cells do not adhere to surfaces that are covered in small
nanometrically sized pillars. These effects can be used for cellular engin
eering purposes to determine the behavior of cells and in particular to mak
e prostheses for medical purposes. The differences in micro and nanofabrica
tion techniques necessary to adapt normal semiconductor technology for thes
e purposes are discussed. Patterning of plastics using mechanical methods (
embossing and molding) is shown to have excellent resolution, can be used o
n biodegradable material and a large enough area of patterned material can
be produced at a reasonable cost. An application of this technology to the
repair of broken tendons is discussed in some detail. It is shown that a bi
odegradable membrane patterned by embossing with a fused silica master can
be used to effect tendon repair. Not only does the tendon reheal, but the s
ynovial channel that should surround the tendon and provide lubrication to
the tendon, is reformed correctly. (C) 1998 American Vacuum Society. [S0734
-211X(98)14506-7].