Ms. Penn et al., RELATIVE SIGNIFICANCE OF ENDOTHELIUM AND INTERNAL ELASTIC LAMINA IN REGULATING THE ENTRY OF MACROMOLECULES INTO ARTERIES IN-VIVO, Circulation research, 74(1), 1994, pp. 74-82
A role for the internal elastic lamina (IEL), which separates the inti
ma and media of an artery wall, as a restrictive barrier to macromolec
ular movement has been suggested in atherosclerotic lesion development
or restenosis during angioplasty. The permeability coefficient of the
IEL, however, has never been quantified in unperturbed vessels in viv
o. Using a newly developed technique, we measured the concentration di
stributions in both intima and media of cationic (pI approximate to 8.
5) and anionic (pI approximate to 6.3) isozymes of the 44-kD macromole
cule horseradish peroxidase (HRP). Two mathematical models of arterial
wall transport differing in their resolution of the intima were requi
red to simulate the concentration distribution data and to estimate th
e parameters of interest. Optimal estimates of the permeability coeffi
cients of the endothelium (P-E) and IEL (P-IEL) to HRP were determined
by the best least-squares fit of the two models to experimental data.
These estimates (anionic: P-E = 0.050 +/- 0.021 mu m/min, P-IEL = 0.1
46 +/- 0.082 mu m/min, n=8; cationic: P-E = 0.034 +/- 0.018 mu m/min,
P-IEL = 0.110 +/- 0.047 mu m/min, n = 8) indicate that the IEL is resp
onsible far approximate to 25% (anionic, 26 +/- 9%; cationic, 25 +/- 1
3%) of the resistance to WRP transport from the blood into the arteria
l media. Although both parameters were less for the cationic preparati
on, the differences were not significant, and the relative role of the
IEL was similar for both molecules. These data demonstrate the import
ance of the IEL in controlling the intimal accumulations of plasma-bor
ne macromolecules, and they imply a role for the IEL in influencing pa
racrine communication between cells of the intima and media.