Optomagnetic nanofluids for controlled brain hyperthermia: a critical study.

Optomagnetic nanofluids (OMNFs) are colloidal dispersions of nanoparticles (NPs) with combined magnetic and optical properties. They are especially appealing in biomedicine since they can be used as minimally invasive platforms for controlled hyperthermia treatment of otherwise difficultly accessible tumors such as intracranial ones. On the one hand, magnetic NPs act as heating mediators when subjected to alternating magnetic fields or light irradiation. On the other hand, suitably tailored luminescent NPs can provide a precise and remote thermal readout in real time. The combination of heating and thermometric properties allows, in principle, to precisely monitor the increase in the temperature of brain tumors up to the therapeutic level, without causing undesired collateral damage. In this work we demonstrate that this view is an oversimplification since it ignores the presence of relevant interactions between magnetic (γ-Fe2O3 nanoflowers) and luminescent nanoparticles (Ag2S NPs) that result in a detrimental alteration of their physicochemical properties. The magnitude of such interactions depends on the interparticle distance and on the surface properties of nanoparticles. Experiments performed in mouse brains (phantoms and ex vivo) revealed that OMNFs cannot induce relevant heating under alternating magnetic fields and fail to provide reliable temperature reading. In contrast, we demonstrate that the use of luminescent nanofluids (containing only Ag2S NPs acting as both photothermal agents and nanothermometers) stands out as a better alternative for thermally monitored hyperthermia treatment of brain tumors in small animal models.

Biological studies of an ICG-tagged aptamer as drug delivery system for malignant melanoma.

Malignant melanoma accounts for about 1% of all skin malignant tumors and represents the most aggressive and lethal form of skin cancer. Clinically, there exist different therapeutic options for melanoma treatment, such as surgery, chemotherapy, radiotherapy, photodynamic therapy and immunotherapy. However, serious adverse effects usually arise, and survival rates are still low because a high number of patients present relapses within 6-9 months after therapy. AS1411 is a G-quadruplex (G4) aptamer capable of tumor-specific recognition, since it binds to nucleolin, a multi-functional protein expressed in many different types of cancer cells. In this work, we present a novel drug delivery system composed of AS1411 and indocyanine green (ICG) to track its accumulation in tumoral cells in a melanoma mouse model. Using a simple supramolecular strategy, we conjugated the complex AS1411-ICG with C8 ligand, an acridine orange derivative with potential anticancer ligand. Then, we performed in vitro cytotoxicity experiments using the B16 mouse melanoma cell line, and in vivo experiments using a B16 mouse melanoma model to study biodistribution and histological changes. The circular dichroism (CD) data suggest that C8 does not affect the parallel G4 topology of AS1411-ICG, whereas it increases its thermal stability. Incubation of B16 melanoma cells with the AS1411-ICG complex associated with C8 increases the cytotoxicity compared with AS1411-ICG alone. From the in vivo studies, we conclude that both AS1411-ICG and AS1411-ICG-C8 presented the potential to accumulate preferentially in tumor tissues. Moreover, these compounds seem to be efficiently removed from the mice's bodies through kidney clearance. In summary, these results suggest that these complexes derived from AS1411 aptamer could act as a delivery system of ligands with antitumoral activity for in vivo melanoma therapy.

In Vivo Deep Tissue Fluorescence and Magnetic Imaging Employing Hybrid Nanostructures.

Breakthroughs in nanotechnology have made it possible to integrate different nanoparticles in one single hybrid nanostructure (HNS), constituting multifunctional nanosized sensors, carriers, and probes with great potential in the life sciences. In addition, such nanostructures could also offer therapeutic capabilities to achieve a wider variety of multifunctionalities. In this work, the encapsulation of both magnetic and infrared emitting nanoparticles into a polymeric matrix leads to a magnetic-fluorescent HNS with multimodal magnetic-fluorescent imaging abilities. The magnetic-fluorescent HNS are capable of simultaneous magnetic resonance imaging and deep tissue infrared fluorescence imaging, overcoming the tissue penetration limits of classical visible-light based optical imaging as reported here in living mice. Additionally, their applicability for magnetic heating in potential hyperthermia treatments is assessed.

Fluorescent nanothermometers provide controlled plasmonic-mediated intracellular hyperthermia.

AIM: This article demonstrates how controlled hyperthermia at the cellular level can be achieved. MATERIALS & METHODS: The method is based on the simultaneous intracellular incorporation of fluorescence nanothermometers (CdSe quantum dots) and metallic nanoheaters (gold nanorods). RESULTS: Real-time spectral analysis of the quantum dot emission provides a detailed feedback about the intracellular thermal loading caused by gold nanorods excited at the plasmon frequency. Based on this approach, thermal dosimetry is assessed in such a way that the infrared laser (heating) power required to achieve catastrophic intracellular temperature increments in cancer cells is identified. CONCLUSIONS: This pure optical method emerges as a new and promising guide for the development of infrared hyperthermia therapies with minimal invasiveness.

Glycophthalocyanines as photosensitizers for triggering mitotic catastrophe and apoptosis in cancer cells.

Photodynamic therapy (PDT) is a treatment modality for different forms of cancer based on the combination of light, molecular oxygen, and a photosensitizer (PS) compound. When activated by light, the PS generates reactive oxygen species leading to tumor destruction. Phthalocyanines are compounds that have already shown to be efficient PSs for PDT. Several examples of carbohydrate substituted phthalocyanines have been reported, assuming that the presence of carbohydrate moieties could improve their tumor selectivity. This work describes the photoeffects of symmetric and asymmetric phthalocyanines with D-galactose (so-called GPh1, GPh2, and GPh3) on HeLa carcinoma cells and their involvement in cell death. Photophysical properties and in vitro photodynamic activities for the compounds considered revealed that the asymmetric glycophthalocyanine GPh3 is very efficient and selective, producing higher photocytotoxicity on cancer cells than in nonmalignat HaCaT. The cell toxiticy after PDT treatment was dependent upon light exposure level and GPh3 concentration. GPh3 causes cell cycle arrest at the metaphase stage leading to multiple spindle poles, mitotic catastrophe, followed by apoptosis in cancer cells. These effects were partially negated by the pancaspase inhibitor Z-VAD-FMK. Together, these results indicate that GPh3 is an excellent candidate drug for PDT, able to induce selective tumor cell death.

Reversibility of established diabetic glomerulopathy by anti-TGF-beta antibodies in db/db mice.

Treatment with a neutralizing anti-transforming growth factor-beta (TGF-beta) antibody can prevent the development of diabetic nephropathy in the db/db mouse, a model of type 2 diabetes. However, it is unknown whether anti-TGF-beta therapy can reverse the histological lesions of diabetic glomerulopathy once they are established. Diabetic db/db mice and their non-diabetic db/m littermates were allowed to grow until 16 weeks of age, by which time the db/db mice had developed glomerular basement membrane (GBM) thickening and mesangial matrix expansion. The mice were then treated with an irrelevant control IgG or a panselective, neutralizing anti-TGF-beta antibody for eight more weeks. Compared with control db/m mice, the db/db mice treated with IgG had developed increased GBM width (16.64+/-0.80 nm vs. 21.55+/-0.78 nm, P<0.05) and increased mesangial matrix fraction (4.01+/-0.81% of total glomerular area vs. 9.55+/-1.04%, P<0.05). However, the db/db mice treated with anti-TGF-beta antibody showed amelioration of GBM thickening (18.40+/-0.72 nm, P<0.05 vs. db/db-IgG) and mesangial matrix accumulation (6.32+/-1.79%, P<0.05 vs. db/db-IgG). Our results demonstrate that inhibiting renal TGF-beta activity can partially reverse the GBM thickening and mesangial matrix expansion in this mouse model of type 2 diabetes. Anti-TGF-beta regimens would be useful in the treatment of diabetic nephropathy.

Smad pathway is activated in the diabetic mouse kidney and Smad3 mediates TGF-beta-induced fibronectin in mesangial cells.

Activation of the transforming growth factor-beta (TGF-beta) system has been implicated in the pathological changes of diabetic nephropathy such as renal hypertrophy and accumulation of extracellular matrix. Streptozotocin-induced diabetic mice were used to examine whether the Smad pathway, which transduces the TGF-beta signal, is activated in the diabetic kidney, employing Southwestern histochemistry with labeled Smad-binding element (SBE) oligonucleotides and immunoblotting of nuclear protein extracts for Smad3. Mouse mesangial cells were used to study the role of Smads in mediating the effects of high glucose and TGF-beta on fibronectin expression, using transient transfections of Smad expression vectors and TGF-beta-responsive reporter assays. By Southwestern histochemistry, the binding of nuclear proteins to labeled SBE increased in both glomeruli and tubules at 1, 3, and 6 weeks of diabetes. Likewise, immunoblotting demonstrated that nuclear accumulation of Smad3 was increased in the kidney of diabetic mice. Both increases were prevented by insulin treatment. In mesangial cells, high glucose potentiated the effect of low-dose TGF-beta1 (0.2ng/ml) on the following TGF-beta-responsive constructs: 3TP-Lux (containing AP-1 sites and PAI-1 promoter), SBE4-Luc (containing four tandem repeats of SBE sequence), and the fibronectin promoter. Additionally, Smad3 overexpression increased fibronectin promoter activity, an effect that was enhanced by high ambient glucose or treatment with TGF-beta1 (2ng/ml). The TGF-beta-stimulated activity of the fibronectin promoter was prevented by transfection with either a dominant-negative Smad3 or the inhibitory Smad7. We conclude that hyperglycemia activates the intrarenal TGF-beta/Smad signaling pathway, which then promotes mesangial matrix gene expression in diabetic nephropathy.

Effects of high glucose and TGF-beta1 on the expression of collagen IV and vascular endothelial growth factor in mouse podocytes.

UNLABELLED: Effects of high glucose and TGF-beta1 on the expression of collagen IV and vascular endothelial growth factor in mouse podocytes. BACKGROUND: The podocyte takes center stage in the pathogenesis of glomerular basement membrane (GBM) thickening and proteinuria in diabetic glomerulopathy. In part, GBM thickening may occur when the podocyte synthesizes increased amounts of collagen IV. Proteinuria may develop if the podocyte secretes excessive amounts of vascular endothelial growth factor (VEGF), which may increase the glomerular permeability to macromolecules. The augmented production of collagen IV and VEGF may be caused by metabolic mediators of diabetes such as hyperglycemia and transforming growth factor-beta (TGF-beta). METHODS: The effects of high glucose and exogenous TGF-beta1 were examined on a mouse podocyte cell line that retains its differentiated phenotype. The gene expression and protein production of certain alpha chains of collagen IV, the major isoforms of VEGF, and components of the TGF-beta system were assayed. An inhibitor of TGF-beta signaling was used to determine whether some of the high glucose effects might be mediated by the TGF-beta system. RESULTS: Compared with normal glucose (5.5 mmol/L), high glucose (HG, 25 mmol/L) for 14 days stimulated [3H]-proline incorporation, a measure of collagen production, by 1.8-fold, and exogenous TGF-beta1 (2 ng/mL) for 24 hours stimulated proline incorporation by 2.4-fold. Northern analysis showed that exposure to HG for 14 days increased the mRNA level of alpha1(IV) collagen by 51% and alpha5(IV) by 90%, whereas treatment with TGF-beta1 (2 ng/mL) for 24 hours decreased the mRNA level of alpha1(IV) by 36% and alpha5(IV) by 40%. Consistent with these effects on mRNA expression, Western blotting showed that HG increased alpha1(IV) protein by 44% and alpha5(IV) by 28%, while TGF-beta1 decreased alpha1(IV) protein by 29% and alpha5(IV) by 7%. In contrast to their opposing actions on alpha1 and alpha5(IV), both HG and exogenous TGF-beta1 increased alpha3(IV) collagen and VEGF, with TGF-beta1 having the greater effect. An inhibitor of the TGF-beta type I receptor (ALK5) was able to prevent the stimulation of alpha3(IV) and VEGF proteins by HG. Unlike in other renal cell types, HG did not increase TGF-beta1 mRNA or protein in the podocyte, but HG did induce the expression of the ligand-binding TGF-beta type II receptor (TbetaRII). Because HG had up-regulated TbetaRII after two weeks, the addition of physiological-dose TGF-beta1 (0.010 ng/mL) for 24 hours stimulated the production of alpha3(IV) and VEGF proteins to a greater extent in high than in normal glucose. Up-regulation of TbetaRII in the podocyte was corroborated by immunohistochemistry of the kidney cortex in the db/db mouse, a model of type 2 diabetes. CONCLUSIONS: High glucose and exogenous TGF-beta1 exert disparate effects on the expression of alpha1 and alpha5(IV) collagen. However, high glucose and TGF-beta1 coordinately induce the production of alpha3(IV) collagen and VEGF in the podocyte. The HG-induced increases in alpha3(IV) collagen and VEGF proteins are mediated by the TGF-beta system. By increasing the expression of TbetaRII, high glucose may augment the response of the podocyte to ambient levels of TGF-beta1.

Inhibiting albumin glycation in vivo ameliorates glomerular overexpression of TGF-beta1.

BACKGROUND: Glycated albumin has been causally linked to the pathobiology of diabetic renal disease through its ability to stimulate the expression of transforming growth factor-beta1 (TGF-beta1), activate protein kinase C (PKC) and extracellular signal-regulated kinase (ERK), and promote production of extracellular matrix proteins in cultured glomerular cells. Whether glycated albumin modulates glomerular TGF-beta1 expression in vivo is not known. To address this issue, we assessed glomerular TGF-beta1 expression and pathology in response to reducing the burden of glycated albumin in vivo. METHODS: We measured serum glycated albumin, urine protein, glomerular TGF-beta1 expression and morphometry, and collagen IV and fibronectin mRNA in db/m and db/db controls and in db/db mice treated for eight weeks with a synthetic compound that inhibits the condensation of glucose with albumin. RESULTS: In situ hybridization studies showed markedly increased glomerular TGF-beta1 mRNA in control db/db mice, which was significantly reduced in db/db mice treated for eight weeks with test compound. The treatment protocol, which normalized serum glycated albumin, concomitantly reduced the elevated protein excretion and the renal overexpression of mRNAs encoding fibronectin and collagen IV, and significantly decreased the mesangial matrix expansion, observed in db/db control animals. CONCLUSIONS: These findings, to our knowledge, provide the first evidence that glomerular overexpression of TGF-beta1 in diabetes derives at least in part from elevated glycated albumin concentrations, and can be partially suppressed by inhibiting the formation of this glycated protein. The results further suggest that glycated albumin has an important nephropathogenic role in diabetes that is operative, and can be therapeutically addressed, independent of glycemic status.