Production of platelet-rich plasma gel from elderly patients under antithrombotic drugs: Perspectives in chronic wounds care.

Platelet-Rich Plasma (PRP) is an autologous biological therapy obtained by centrifuging the patient's own blood to concentrate platelets. The addition of autologous thrombin and calcium chloride to PRP allows the production of a semi-solid form called PRP gel. PRP gel is increasingly used in a variety of tissue defects and predominantly in the management of non-healing chronic wounds. The topical application of PRP gel seems promising due to the capability of platelets to store and secrete growth factors (GF), fibrin and cytokines, which are essentials for wound healing. Most patients who suffered from chronic wounds are elderly patients with co-morbidities and polypharmacy including antithrombotic drugs such as antiplatelet agents (AP) or anticoagulants (AC), which could hamper the feasibility of this autologous platelet-derived therapy. To date, no study has investigated PRP gel formation in patients with AP or AC. The aim of this study was to evaluate the influence of AP or AC drugs on the production of PRP gel formation from elderly patients. Different biological characteristics were determined to qualify the production of PRP gel from such patients (Interquartile range (IQR) = 75-92 years) compared to healthy volunteers (IQR = 23-37 years). No significant difference was observed in the volume, composition (quantity of platelets, leukocytes and red blood cells) and functionality of platelets from PRP except a higher ADP-induced P-selectin expression in healthy donors compared with elderly patients. Autologous thrombin characteristics were similar in the two groups. Gel time formation (IQR: 120-195 seconds for controls and 135-210 seconds for elderly patients) and final composition of PRP gel were not significantly modified. Concentrations of theoretical thrombin generated in the serum and in the gel were inversely correlated with the time of formation of PRP gel (r2 = 0.57, p = 0.012). Altogether these data indicate that PRP gel preparation is not impacted by the use of antithrombotic drugs. Such results support the feasibility of using this innovative autologous biotherapy in the management of elderly patients with non-healing chronic wounds.

CD28 deletion improves obesity-induced liver steatosis but increases adiposity in mice.

BACKGROUND/OBJECTIVES: Lymphocytes have a critical role in visceral adipose tissue (AT) inflammation. The CD28 costimulatory molecule is required for lymphocyte activation and for the development of a functional regulatory T cells (Tregs) compartment; however, its role during obesity is unknown. METHODS: During diet-induced obesity, we investigated the effects of selective interference with CD28 signaling using knockout mice (Cd28KO) and a CTLA4-Ig fusion protein inhibiting CD28-B7 interactions. RESULTS: Cd28 deficiency decreased pathogenic T cells and Treg content within AT without changing the macrophages number. Cd28KO epididymal but not subcutaneous fat was characterized by enlarged adipocytes, reduced levels of inflammatory cytokines and increased Glut4, adiponectin and lipogenic enzyme mRNA levels. This was associated with reduced inflammation, fat accumulation and enhanced glucose metabolism in liver. Weight gain and fasting glucose tolerance were not affected. CTLA4-Ig injections reduced the number of T cells in epididymal AT (epiAT) but not the inflammatory cytokines levels and failed to improve liver fat accumulation. CONCLUSIONS: Deletion of CD28 creates a new pro/anti-inflammatory balance in epiAT and liver and exerts a protective effect against hepatic steatosis.

Statins: maid-of-all-work in cardiovascular diseases!

Inhibitors of HMG-CoA reductase (statins) lower the level of circulating LDL-C by blocking the activity of HMG-CoA reductase. Their efficiency to prevent cardiovascular events was demonstrated in several clinical trials for primary and secondary prevention. However, subgroups analysis of trials together with experimental studies have increasingly documented that the beneficial effects of statins extend beyond the sole reduction in LDL-C. These effects include improvements of vasoreactivity, haemostasis and plaque stability, reduction of pro-inflammatory events such as a decrease in monocyte adhesion and infiltration, oxidation level and pericellular proteolysis. Possible repair of ischemic tissues through enhancement of mobilization of endothelial progenitor cells are also described, although more investigation are needed to clearly identify the role and safety of statins in angiogenesis. These pleiotropic effects are generally explained by the fact that statins inhibit the intracellular production of metabolites located downstream of mevalonate in the cholesterol pathway, such as isoprenoids (farnesyl pyrophosphate and geranylgeranylpyrophosphate). These hydrophobic metabolites allow the membrane anchorage of small G proteins (Ras and Rho) as well as the Gy subunit of heterotrimeric G proteins, a post-translational step that is critical in the regulation of G protein signaling activity. These drugs are therefore a valuable tool not only for the clinician but also for the biologist, allowing to investigate the regulation of gene expression that is controlled by the intracellular activity of membrane-anchored prenylated signaling proteins.