Bone marrow cells secrete angiogenic factors that induce endothelial cell proliferation and, when injected transendocardially, augment collateral perfusion and myocardial function in ischemic myocardium.
The purpose of this study was to evaluate the effects of exogenous recombinant basic fibroblast growth factor (bFGF) on angiogenesis in severely ischemic tissue beds. We used a two-stage procedure to produce severe ischemia of the hindlimb of 34 New Zealand rabbits. The ischemic hindlimb received intramuscular injection of saline (group A), 1 microgram bFGF (group B), or 3 micrograms bFGF (group C), daily for 2 weeks. Tissue perfusion, skeletal muscle infarction, angiogenesis, and collateral growth were assessed by angiography, transcutaneous oximetry (TcPO2), quantitative spectrophotometric assay of triphenyltetrazolium chloride reduction in muscle, capillary density (capillaries per square millimeter), and capillary per muscle fiber ratio. There were no significant differences in baseline TcPO2 among the three groups for both thigh and calf measurements. Angiography revealed extensive perfusion of the left hindlimb in all the assessed bFGF treated animals. Both thigh and calf TcPO2 values showed a significant increase in all groups over the 14 days ischemia was induced (p less than 0.0001), but the two treatment groups exhibited a much more rapid rise in TcPO2 than the control group (p less than 0.0001). The capillaries per square millimeter and capillaries per muscle fiber ratios were significantly increased in all posttreatment measurements for all animals that received bFGF. The treatment groups with bFGF had a significant (p = 0.025) increase in thigh muscle viability compared with controls based on triphenyltetrazolium chloride reduction. Whereas there was evidence of muscle infarction in both the thighs of groups A and B, there was none in group C.(ABSTRACT TRUNCATED AT 250 WORDS)
The importance of spontaneously developing collateral vessels to supplement perfusion of tissue rendered ischemic by vascular obstruction was recognized many years ago. However, it was not until potent angiogenesis factors were identified, purified, and produced in sufficient quantities, that the field began its rapid development. In the early 1990s it was first shown that basic fibroblast growth factor (bFGF) and vascular endothelial growth factor (VEGF) proteins could actually stimulate collateral flow. However, additional studies also demonstrated that the duration of exposure of the vessels to angiogenesis factors was critical, and that the administration of proteins, with their relatively brief half-lives, may pose important practical limitations. The demonstration that gene therapy can improve collateral function presents one of the solutions to the conundrum, since gene therapy can be considered a sophisticated form of a sustained delivery system. The results of several clinical trials have been reported. All involve administration of single angiogenesis agents, and most are Phase I trials. The two studies rising to Phase II status demonstrated no treatment effect on the primary end-point. It may therefore be relevant to consider that the molecular mechanisms responsible for angiogenesis are extraordinarily complex, and an optimal angiogenesis intervention may require a 'multiple factor' strategy. It is important to note that no serious side-effects ascribable to an angiogenesis agent were recognized in these trials. However, angiogenesis agents are potent molecules with multiple activities. It is therefore possible that they might occasionally cause side-effects, some serious. Among these, based on their biologic activities, are neovascularization of non-targeted tissues, expansion and induction of instability of atherogenic plaque, and growth of tumors. In summary, there is ample experimental evidence justifying an optimistic outlook relating to our eventually being successful in enhancing collateral flow to ischemic tissue in a clinical setting. However, we are not there yet, and identification of the optimal angiogenesis strategy is still unclear. Additional experimental work, in parallel with large, carefully controlled clinical trials are needed to continue the exciting advances of the last decade, and to achieve the goal of providing patients with alternative potent therapies to improve collateral flow, and thereby to alleviate their symptoms and perhaps to prolong their lives.
The current study demonstrates that stents made of biocorrodible iron are safe. In some of the measured parameters, such as intimal thickness, intimal area, and percentage occlusion, there was a trend in favor of the iron stents.
Abstract-Constitutive activation of serine/threonine kinase Akt causes uncontrolled cell-cycle progression in different cell types and in malignancy. To investigate how Akt activation modulates cell-cycle progression in vascular smooth muscle cells (SMCs) in vitro and in the intact animal, we inhibited Akt-dependent signaling by adenovirus-mediated transfection of a dominant-negative Akt mutant (AA-Akt). We observed reduced proliferation rate (PϽ0.01), DNA synthesis (PϽ0.01), and a significant arrest in G1/S exit (PϽ0.01) both in vitro in response to serum stimulation and in vivo after vascular injury. In vivo transfection of the balloon-injured vessel with AA-Akt reduced SMC proliferation, resulting in decreased neointima compared with control virus (PϽ0.01). These effects were at least in part modulated, both in vitro and in vivo, by increased p21 Cip1 expression, as demonstrated by lack of effect of AA-Akt on cell proliferation in p21 Ϫ/Ϫ mouse SMCs. In conclusion, this study demonstrates that Akt-dependent signaling enhances cell-cycle progression of nontransformed SMCs in vitro and in response to vascular injury in the intact animal. These results suggest a role for Akt signaling in modulating the response of normal tissues to stress and the response of the arterial wall to acute and possibly repetitive injuries that ultimately contribute to restenosis and atherosclerosis.
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