Cationic poly-L-lysine dendrimer complexes doxorubicin and delays tumor growth in vitro and in vivo.

We report in this study the complexation of the chemotherapeutic drug doxorubicin (DOX) with the novel sixth-generation cationic poly-l-lysine dendrimer (DM) (MW 8149 kDa), which we previously reported to exhibit systemic antiangiogenic activity in tumor-bearing mice. DOX-DM complexation was confirmed by florescence polarization measurement, proton nuclear magnetic resonance spectroscopy, and molecular modeling. Enhanced penetration of DOX-DM (at 1:10 molar ratio), compared to the free DOX, into prostate 3D multicellular tumor spheroids (MTS) was confirmed by confocal laser scanning microscopy. Furthermore, DOX-DM complexes achieved a significantly higher cytotoxicity in DU145 MTS system compared to the free drug, as shown by growth delay curves. Incubation of MTS with low DOX concentration (1 µM) complexed with DM led to a significant delay in MTS growth compared to untreated MTS or MTS treated with free DOX. DOX-DM complex retention was also achieved in a Calu-6 lung cancer xenograft model in tumor-bearing mice, as shown by live whole animal fluorescence imaging. Therapeutic experiments in B16F10 tumor bearing mice have shown enhanced therapeutic efficacy of DOX when complexed to DM. This study suggests that the cationic poly-l-lysine DM molecules studied here could, in addition to their systemic antiangiogenic property, complex chemotherapeutic drugs such as DOX and improve their accumulation and cytotoxicity into MTS and solid tumors in vivo. Such an approach offers new capabilities for the design of combinatory antiangiogenic/anticancer therapeutics.

Reduced glucose transporter GLUT4 in skeletal muscle predicts insulin resistance in non-diabetic chronic heart failure patients independently of body composition.

BACKGROUND: In chronic heart failure (CHF) skeletal muscle insulin resistance occurs independently of etiology and contributes to impaired energy metabolism. GLUT4, the predominant glucose transporter in the skeletal muscle promotes the rate-limiting step of glucose utilization in skeletal muscle. The significance of skeletal muscle GLUT4 in patients with CHF has not been studied in detail. METHODS: In patients with CHF and free of diabetes mellitus (n=29; mean NYHA class 2.3+/-0.1, peak VO(2) 18.8+/-1.1 mL/kg/min) and healthy control subjects of similar age (n=7), GLUT4 protein was assessed from percutaneous skeletal muscle biopsies. Skeletal muscle insulin sensitivity was assessed by intravenous glucose tolerance testing using a minimal modeling technique. Body composition was analyzed by dual energy X-ray absorptiometry (DEXA) scanning. RESULTS: Skeletal muscle GLUT4 was lower in CHF patients than in controls (0.75+/-0.07 vs 1.24+/-0.19 density units, P<0.01) and decreased in parallel to severity of CHF, being lowest in NYHA III/IV (0.596+/-0.08, ANOVA P<0.01 vs controls). GLUT4 was lower in patients with an ischemic etiology compared to dilated cardiomyopathy and controls (ANOVA P<0.01). Patients and controls were similar for global parameters of body composition (weight: 78+/-4 vs 76+/-4 kg, BMI 25.5+/-0.8 vs 25.8+/-1.5 kg/m(2)), and total tissue amount and regional distribution of fat and lean tissue (all P>0.2). Low GLUT4 predicted impaired insulin sensitivity, i.e. insulin resistance (r=0.55, P<0.01). In multivariate analysis, GLUT4 levels predicted insulin sensitivity independently of age and parameters of body composition (including weight, BMI, and total and regional fat and lean tissue distribution). CONCLUSION: In non-diabetic patients with CHF, skeletal muscle GLUT4 transport protein is reduced in parallel to disease severity, independently of body composition. Low skeletal muscle GLUT4 contributes to insulin resistance in CHF.

Myocardial glucose transport and utilization in patients with type 2 diabetes mellitus, left ventricular dysfunction, and coronary artery disease.

OBJECTIVES: This research was designed to assess the effect of type 2 diabetes mellitus (T2DM) on myocardial glucose utilization in patients with heart failure secondary to coronary artery disease. BACKGROUND: Patients with T2DM and coronary artery disease have an increased morbidity and mortality compared with patients with coronary artery disease without diabetes that may relate to a reduction in the ability of the myocardium to utilize glucose. METHODS: Myocardial blood flow and glucose utilization were assessed during a hyperinsulinemic clamp by 18F-flurodeoxyglucose and positron emission tomography in 54 patients (19 with T2DM) with multivessel coronary artery disease and heart failure. In a subgroup of 18 patients, myocardial biopsies were obtained during coronary bypass surgery to assess glucose transporter (GLUT4) distribution and protein concentration, and compared with myocardium from transplant donor hearts. RESULTS: Myocardial blood flow was similar in patients without diabetes and those with T2DM. Myocardial glucose utilization was lower in patients with T2DM (0.34 +/- 0.16 vs. 0.47 +/- 0.24 micromol x min(-1) x g(-1), p = 0.0002) despite comparable plasma insulin concentrations and a higher blood glucose concentration. Extraction of glucose by the myocardium was reduced in patients with T2DM (7.1 +/- 3.1% vs. 13.5 +/- 5.2%, p < 0.01). Myocardial GLUT4 protein was similar in patients with and without T2DM (p = 0.75). CONCLUSIONS: Patients with coronary artery disease and heart failure exhibit myocardial insulin resistance, and this is greater in those with T2DM. This may limit the ability of the myocardium in patients with T2DM to withstand ischemia and may contribute to the increased cardiovascular morbidity and mortality in such patients.