Premium
Adaptation of Resistance Arteries to Increases in Pressure
Author(s) -
Prewitt Russell L.,
Rice Darian C.,
Dobrian Anca D.
Publication year - 2002
Publication title -
microcirculation
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.793
H-Index - 83
eISSN - 1549-8719
pISSN - 1073-9688
DOI - 10.1038/sj.mn.7800143
Subject(s) - muscle hypertrophy , vasoconstriction , lumen (anatomy) , mesenteric arteries , mechanotransduction , myogenic contraction , medicine , anatomy , vascular smooth muscle , artery , extracellular , chemistry , endocrinology , cardiology , microbiology and biotechnology , biology , smooth muscle
During the development of hypertension, hypertrophy of smooth muscle cells and deposition of extracellular matrix thicken the walls of large arteries without reducing the size of the lumen. The small arteries and arterioles remodel inwardly through a eutrophic process of rearrangement of the same smooth muscle cells around a smaller lumen. Pressure, through an increase in circumferential wall stress, can account for both hypertrophy and inward, eutrophic remodeling. The small arteries constrict during an elevation of pressure, thus restoring wall stress toward control levels. The large arteries have little vasoactivity and respond to the increase in wall stress by initiating a growth process. Mechanotransduction of the pressure stimulus to a growth response is being studied in small mesenteric arteries. Raising the pressure from 90 to 140 mmHg initiates a signaling process starting with phosphorylation of Src within 1 minute. This is followed by phosphorylation of Erk 1/2 peaking at 5 minutes and expression of c‐fos mRNA within 30 minutes. Gene expression correlates with wall stress and is thus inhibited by a myogenic response. Maintained vasoconstriction in an isolated arteriole results in inward, eutrophic remodeling within 4 days. Thus, the current data support the hypothesis that wall thickness is determined by circumferential wall stress, and lumen size is determined by vascular tone.