Inhibiting advanced-glycation end products (AGEs) formation or downstream signaling reduced medial calcification in diabetic rats.
Does inhibition of AGEs formation, elimination of AGEs, or inhibition of RAGE signaling reduce vascular calcification in diabetic rats?
Inhibiting AGE formation, eliminating AGEs, or blocking downstream RAGE signaling with antioxidants reduces medial vascular calcification in a diabetic rat model.
Advanced-glycation end products (AGEs) were recently implicated in vascular calcification, through a process mediated by RAGE (receptor for AGEs). Although a correlation between AGEs levels and vascular calcification was established, there is no evidence that reducing in vivo AGEs deposition or inhibiting AGEs-RAGE signaling pathways can decrease medial calcification. We evaluated the impact of inhibiting AGEs formation by pyridoxamine or elimination of AGEs by alagebrium on diabetic medial calcification. We also evaluated if the inhibition of AGEs-RAGE signaling pathways can prevent calcification. Rats were fed a high fat diet during 2 months before receiving a low dose of streptozotocin. Then, calcification was induced with warfarin. Pyridoxamine was administered at the beginning of warfarin treatment while alagebrium was administered 3 weeks after the beginning of warfarin treatment. Results demonstrate that AGEs inhibitors prevent the time-dependent accumulation of AGEs in femoral arteries of diabetic rats. This effect was accompanied by a reduced diabetes-accelerated calcification. Ex vivo experiments showed that N-methylpyridinium, an agonist of RAGE, induced calcification of diabetic femoral arteries, a process inhibited by antioxidants and different inhibitors of signaling pathways associated to RAGE activation. The physiological importance of oxidative stress was demonstrated by the reduction of femoral artery calcification in diabetic rats treated with apocynin, an inhibitor of reactive oxygen species production. We demonstrated that AGE inhibitors prevent or limit medial calcification. We also showed that diabetes-accelerated calcification is prevented by antioxidants. Thus, inhibiting the association of AGE-RAGE or the downstream signaling reduced medial calcification in diabetes.
Brodeur et al. (Tue,) conducted a other in Diabetic vascular calcification. Pyridoxamine, alagebrium, or apocynin was evaluated on Medial calcification. Inhibiting advanced-glycation end products (AGEs) formation or downstream signaling reduced medial calcification in diabetic rats.
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