We developed an in vitro preparation to investigate shape and stress distri
bution in the intact rat diaphragm. Our hypothesis was that the diaphragm i
s anisotropic with smaller compliance in transverse fiber direction than al
ong fibers, and therefore shape change may be small. After the animals were
killed (8 rats), the entire diaphragm was excised and fixed into a mold at
the insertions. Oxygenated Krebs-Ringer solution was circulated under the
diaphragm and perfused over its surface. A total of 20-23 small markers wer
e sutured on the diaphragm surface. At transdiaphragmatic pressure (P-di) o
f 3-15 cmH(2)O, curvature was smaller in transverse direction than along fi
bers. Using finite element analysis we computed membrane tension. At P-di o
f 15 cmH(2)O, tension in central tendon was larger than muscle. In costal r
egion maximum principal tension (sigma (1)) is essentially along the fibers
and ranged from 6-10 g/cm. Minimum principal tension (sigma (2)) was 0.3-4
g/cm. In central tendon, sigma (1) was 10-15 g/cm, compared with 4-10 g/cm
for sigma (2). The diaphragm was considerably stiffer in transverse fiber
direction than along the fibers.