Future paper. Since platelets are considered to be essential both in atherosclerosis and in vascular and tissue regeneration through paracrine mechanisms, we focused on their relationship with EPCs. Although the effect of platelets on EPCs homing and their differentiation to endothelial cells has been well-documented, the functional consequences of these interactions on EPCs and platelets have received less attention. Moreover, we evaluated the role of PMPs, alone and in correlation with EPCs on platelets in the original experimental models. We questioned the consequences of EPC, PMP administration (alone and in combination) on molecules involved in platelet activation (such as integrin b3), and on aIIbb3 signaling (such as FAK, PI3K and Src). Our results present a marked improvement of platelet function after EPC-based therapy in both situation (prevention and regression), compared to HH group. These findings are in concordance with the study of Abou-Saleh et al. [24] that demonstrated that in vitro and into mice with FeCl3induced carotid artery injury EPCs bind platelets via P-selectin and inhibit platelet activation, aggregation, adhesion to collagen, and thrombus formation. The platelet activation in hypertension associated with hypercholesterolemia was revealed also in our previous study performed on HH experimental model (Alexandru et al., 2011). PMP administration enhanced platelet activation, and in combination with EPCs induced a decreased of these molecule expression compared to HH-PMPs group, but without the same results as EPC therapy. The immediate 101043-37-2 presence of platelets at the atherosclerotic lesions renders them a potential checkpoint regulator of downstream events [40]. They can release a plethora of inflammatory mediators, enriching and boosting the inflammatory milieu. Moreover, upon activation, platelets released from the a-granules growth factors (e.g., PDGF, transforming growth factor-b, VEGF), and active metabolites that influence clinical situations requiring rapid healing and tissue regeneration [41]. Platelets chemokines (e.g. RANTES, PF4, SDF-1, MCP-1, CXCL5, CXCL7) and newly synthesized active cytokine-like factors [e.g. IL-1b, CD40 ligand (CD40L), b-thromboglobulin] are implicated in the development of atherosclerosis [41,42,43]. Recently, animal and (pre)clinical human studies have suggested that the two major platelet chemokines PF4 and RANTES, as well as CD40L, may be considered potential new candidates in the treatment of atherogenesis and inflammation [44]. Likewise, the SDF-1a/CXCR4 axis has been shown to be implicated in the mobilization and EPC homing [45]. Stellos et al. [23] reported that platelet-derived SDF1a enhanced the accumulation of CD34+ cells at sites of injury after intravenously injection of CD34+ cells. To elucidate the potential underlying mechanism involved in EPCs-platelets relationship, we compared the SDF-1a, RANTES, MCP-1 released levels, as well as their protein expression, in Hypericin manufacturer activated platelets isolated from hamster groups and we found an increased concentration in HH group, compared to C group and more elevated in HH-PMPs group compared to HH group. The finding of increased expression of SDF-1 in platelets from HH hamsters is consistent with the reports assessing SDF-1a in platelets from patients with cardiovascular risk factors [4] and in peripheral blood and hearts of patients with cardiovascular disease [46]. The higher values in platelets obtained from HH-PMPs group than in.Future paper. Since platelets are considered to be essential both in atherosclerosis and in vascular and tissue regeneration through paracrine mechanisms, we focused on their relationship with EPCs. Although the effect of platelets on EPCs homing and their differentiation to endothelial cells has been well-documented, the functional consequences of these interactions on EPCs and platelets have received less attention. Moreover, we evaluated the role of PMPs, alone and in correlation with EPCs on platelets in the original experimental models. We questioned the consequences of EPC, PMP administration (alone and in combination) on molecules involved in platelet activation (such as integrin b3), and on aIIbb3 signaling (such as FAK, PI3K and Src). Our results present a marked improvement of platelet function after EPC-based therapy in both situation (prevention and regression), compared to HH group. These findings are in concordance with the study of Abou-Saleh et al. [24] that demonstrated that in vitro and into mice with FeCl3induced carotid artery injury EPCs bind platelets via P-selectin and inhibit platelet activation, aggregation, adhesion to collagen, and thrombus formation. The platelet activation in hypertension associated with hypercholesterolemia was revealed also in our previous study performed on HH experimental model (Alexandru et al., 2011). PMP administration enhanced platelet activation, and in combination with EPCs induced a decreased of these molecule expression compared to HH-PMPs group, but without the same results as EPC therapy. The immediate presence of platelets at the atherosclerotic lesions renders them a potential checkpoint regulator of downstream events [40]. They can release a plethora of inflammatory mediators, enriching and boosting the inflammatory milieu. Moreover, upon activation, platelets released from the a-granules growth factors (e.g., PDGF, transforming growth factor-b, VEGF), and active metabolites that influence clinical situations requiring rapid healing and tissue regeneration [41]. Platelets chemokines (e.g. RANTES, PF4, SDF-1, MCP-1, CXCL5, CXCL7) and newly synthesized active cytokine-like factors [e.g. IL-1b, CD40 ligand (CD40L), b-thromboglobulin] are implicated in the development of atherosclerosis [41,42,43]. Recently, animal and (pre)clinical human studies have suggested that the two major platelet chemokines PF4 and RANTES, as well as CD40L, may be considered potential new candidates in the treatment of atherogenesis and inflammation [44]. Likewise, the SDF-1a/CXCR4 axis has been shown to be implicated in the mobilization and EPC homing [45]. Stellos et al. [23] reported that platelet-derived SDF1a enhanced the accumulation of CD34+ cells at sites of injury after intravenously injection of CD34+ cells. To elucidate the potential underlying mechanism involved in EPCs-platelets relationship, we compared the SDF-1a, RANTES, MCP-1 released levels, as well as their protein expression, in activated platelets isolated from hamster groups and we found an increased concentration in HH group, compared to C group and more elevated in HH-PMPs group compared to HH group. The finding of increased expression of SDF-1 in platelets from HH hamsters is consistent with the reports assessing SDF-1a in platelets from patients with cardiovascular risk factors [4] and in peripheral blood and hearts of patients with cardiovascular disease [46]. The higher values in platelets obtained from HH-PMPs group than in.