Arterial injury repair in nonhuman primates-the role of PDGF receptor-beta.

BACKGROUND: This study documents the time course of the response to injury of the saphenous artery in baboons and the role of the platelet-derived growth factor-beta. Fundamental differences with the well-characterized rat arterial injury model have been found. MATERIALS AND METHODS: Thirty-eight baboons received a unilateral balloon injury to the saphenous artery and were treated with a chimeric blocking antibody to PDGFR-beta or vehicle control for 7, 14, or 28 days. The arteries were evaluated morphologically and for cell proliferation. RESULTS: Both medial and intimal smooth muscle cell proliferation were elevated 7 days after injury and were back close to baseline at 14 days. Unlike the rat, blockade of PDGFR-beta inhibited medial proliferation over 80% at 7 and 14 days, while intimal proliferation was only inhibited at 14 days (>95%). Also, unlike the rat, the baboon arterial media, as well as the intima, increased in size by 14 days after injury. Blockade of PDGFR-beta completely inhibited both intimal and medial growth at 14 days, but there was less of an effect on intimal growth at 28 days. CONCLUSION: Blockade of PDGFR-beta may be a clinical approach to inhibit intimal hyperplasia in humans, but this study raises concerns about the long-term efficacy of this treatment.

Concomitant blockade of platelet-derived growth factor receptors alpha and beta induces intimal atrophy in baboon PTFE grafts.

OBJECTIVE: Although current treatments for restenosis attempt to prevent the development of intimal hyperplasia, an alternative strategy is to induce intimal atrophy after restenosis has developed. Because platelet-derived growth factor (PDGF) is a smooth muscle cell growth and survival factor, we tested the hypothesis that complete blockade of PDGF by using antibodies against PDGF receptors alpha and beta would cause intimal atrophy in a baboon vascular graft model. METHODS: We administered chimeric antibodies against PDGF receptor alpha or PDGF receptor beta, either separately or together, to baboons with bilateral prosthetic aortoiliac grafts, the intimas of which had reached maximal size before treatment was begun. High blood flow, which we have previously shown to cause intimal atrophy, was induced through one graft to serve as a positive control. After 2 weeks, the intima lining the grafts was assessed for cross-sectional area, cell proliferation, and apoptosis by standard morphologic and immunohistochemical techniques. RESULTS: Blocking both PDGF receptors simultaneously reduced the cross-sectional area of the normal-flow graft intima by 44% (P <.05 vs control), whereas treatment with the individual antibodies did not significantly alter intimal area. Blockade of both receptors also inhibited smooth muscle cell proliferation by 66% (P <.05 vs control), whereas neither antibody alone altered proliferation. In contrast, all treatments increased smooth muscle cell apoptosis threefold to fivefold. CONCLUSIONS: These data suggest that simultaneous inhibition of cell proliferation and stimulation of cell death by the administration of antibodies to both PDGF receptor alpha and receptor beta is required for intimal atrophy in this baboon graft model. In addition, these data provide an in vivo model for the pharmacologic induction of intimal atrophy and introduce a novel clinical approach to treat intimal hyperplasia. Clinical relevance This study introduces the concept of pharmacologic induction of intimal atrophy. Intimal hyperplasia plagues all forms of arterial reconstruction. Currently, the only effective treatment of these restenotic lesions is balloon angioplasty or operative revision. An alternative approach to patients with clinically significant intimal hyperplasia might be to stimulate intimal regression by modulating growth and survival factors required for intimal maintenance. Although PDGF is known to be critical in intimal formation, the results of this study suggest that PDGF is also critical for intimal maintenance. Inhibition of the PDGF system may prove to be a clinically applicable approach for inducing intimal atrophy.

Increased plasmin and serine proteinase activity during flow-induced intimal atrophy in baboon PTFE grafts.

High blood flow causes intimal atrophy and loss of extracellular matrix in PTFE aortoiliac grafts. We have investigated whether matrix-degrading proteinases are altered in this baboon model of atrophy using zymography, western analysis, and a versican degradation assay. After four days of high flow, urokinase was increased and plasminogen activator inhibitor-1 was decreased in the intima. Plasminogen was increased after seven days. Pro-matrix metalloproteinase (MMP)-2, activated MMP-2, and proMMP-9 levels were modestly increased by high flow at 7 days, whereas MMP-3 and tissue inhibitor of metalloproteinases-1 were not altered. Extracts of 4-day high-flow intimas degraded more 35S-methionine-labeled versican than low-flow intimal extracts, and this activity was inhibited by AEBSF, a serine proteinase inhibitor, and a plasmin antibody. In contrast, this activity was not inhibited by the MMP inhibitor, BB-94 (Batimastat). These data suggest that serine proteinases, including plasmin, may be largely responsible for extracellular matrix degradation in this primate model of flow-induced intimal atrophy.