Your search keyword '"Sbaraglini, María Laura"' showing total 4 results

1. Saxagliptin affects long-bone microarchitecture and decreases the osteogenic potential of bone marrow stromal cells.

Author

Sbaraglini, María Laura, Molinuevo, María Silvina, Sedlinsky, Claudia, Schurman, León, and McCarthy, Antonio Desmond

Subjects

*DIPEPTIDES, *MESENCHYMAL stem cells, *DIABETES, *BONE fractures, *HYPOGLYCEMIC agents, *BONE metabolism, *THERAPEUTICS

Abstract

Abstract: Diabetes mellitus is associated with a decrease in bone quality and an increase in fracture incidence. Additionally, treatment with anti-diabetic drugs can either adversely or positively affect bone metabolism. In this study we evaluated: the effect of a 3-week oral treatment with saxagliptin on femoral microarchitecture in young male non-type-2-diabetic Sprague Dawley rats; and the in vitro effect of saxagliptin and/or fetal bovine serum (FBS), insulin or insulin-like growth factor-1 (IGF1), on the proliferation, differentiation (Runx2 and PPAR-gamma expression, type-1 collagen production, osteocalcin expression, mineralization) and extracellular-regulated kinase (ERK) activation, in bone marrow stromal cells (MSC) obtained from control (untreated) rats and in MC3T3E1 osteoblast-like cells. In vivo, oral saxagliptin treatment induced a significant decrease in the femoral osteocytic and osteoblastic density of metaphyseal trabecular bone and in the average height of the proximal cartilage growth plate; and an increase in osteoclastic tartrate-resistant acid phosphatase (TRAP) activity of the primary spongiosa. In vitro, saxagliptin inhibited FBS-, insulin- and IGF1-induced ERK phosphorylation and cell proliferation, in both MSC and MC3T3E1 preosteoblasts. In the absence of growth factors, saxagliptin had no effect on ERK activation or cell proliferation. In both MSC and MC3T3E1 cells, saxagliptin in the presence of FBS inhibited Runx2 and osteocalcin expression, type-1 collagen production and mineralization, while increasing PPAR-gamma expression. In conclusion, orally administered saxagliptin induced alterations in long-bone microarchitecture that could be related to its in vitro down-regulation of the ERK signaling pathway for insulin and IGF1 in MSC, thus decreasing the osteogenic potential of these cells. [Copyright &y& Elsevier]

Published

2014

2. Nebulization of a polyelectrolyte-drug system for systemic hypertension treatment.

Author

Ceschan, Nazareth E., Scioli-Montoto, Sebastián, Sbaraglini, María Laura, Ruiz, María Esperanza, Smyth, Hugh D.C., Bucalá, Verónica, and Ramírez-Rigo, María V.

Subjects

*ALGINIC acid, *PULMONARY circulation, *DISEASE risk factors, *SALINE solutions, *BLOOD pressure

Abstract

• Around 40% of the formulation would be deposited in the alveolar membrane. • Inclusion of alginic acid confers mucoadhesive properties to the inhalatory system. • Plasmatic area under the curve is higher when the drug is combined with the polymer. • The developed material is not cytotoxic in the A-549 cell line even at high doses. • The interaction between the drug and polymer is reversible by ionic exchange. Hypertension is a chronic pathology where blood pressure levels are continuously high, causing cardiac, renal, cerebral, and vascular damage leading to early morbi-mortality. This illness is the main risk factor for cardiovascular diseases and the main cause of atrial fibrillation. Atenolol (AT) is a β-1 blocker drug useful for antihypertension and antiarrhythmic treatments. However, this drug possesses low oral bioavailability associated to its low permeability and extensive hepatic first-pass metabolism. To solve the conventional AT-administration problems, oral controlled-release and transdermal delivery have been reported. In this work, an alternative AT inhalatory system administered by nebulization is presented. This system is based on an ionic complex between acidic groups of alginic acid and cationic groups of AT (AA-AT), which was obtained by spray-drying. Pharmaceutical and biopharmaceutical properties for AA-AT inhalatory administration using a jet nebulizer were investigated. The aerodynamic performance (assayed at different cup-nebulizer loadings) of the nebulized system demonstrated that around 40% of the formulation would deposit in the respiratory membrane, with mass median aerodynamic diameters of 3.4–3.6 µm. The AT carried in the AA-AT system was released adequately by ionic exchange in saline solution by permeation through a cellulose membrane. The presence of AA as polyelectrolyte conferred mucoadhesive properties to the ionic complex. Even at high relative AA-AT concentrations, no cytotoxic effect was detected in A-549 cell line. Finally, the preliminary pharmacokinetic assay in the in vivo model confirmed that AT was absorbed from the lung to the systemic circulation, with a greater plasmatic AUC compared to the pure drug (around 50% higher). Then, the system and the nebulization administration demonstrated potential for drug cardiac targeting. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

3. Parabens inhibit hNaV 1.2 channels.

Author

Enrique, Andrea, Martín, Pedro, Sbaraglini, María Laura, Talevi, Alan, and Milesi, Verónica

Subjects

*PARABENS, *DRUG design, *SODIUM channels, *ANTIMICROBIAL preservatives, *BIOCHEMICAL mechanism of action

Abstract

• Propylparaben, butylparaben and benzylparaben inhibit hNa V 1.2 channel mediated currents through a voltage- and frequency-dependent mechanism. • The state-dependent inhibitory effect increases with the size of the lipophilic alcoholic residue of the ester group. • Benzylparaben is a new promising compound among the assayed parabens series, presenting a similar mechanism of action, but a higher potency than PPB. Propylparaben, a commonly used antimicrobial preservative, has been reported as an anticonvulsant agent targeting neuronal Na+ channels (Na V). However, the specific features of the Na V channel inhibition by this agent have so far not been extensively studied. Moreover, it is still unclear if it shares this pharmacological activity with other parabens. Here, we fully characterized the mechanism of action of the inhibitory effect that propylparaben and benzylparaben induce on human Na V 1.2 channel isoform (hNa V 1.2). We established a first approach to know the parabens structural determinants for this channel inhibition. The parabens effects on hNa V 1.2 channel mediated currents were recorded using the patch-clamp whole-cell configuration on hNa V 1.2 stably transfected HEK293 cells. Propylparaben induced a typical state-dependent inhibition on hNa V 1.2 channel carried current, characterized by a left-shift in the steady-state inactivation curve, a prolongation in the time needed for recovery from fast inactivation and a frequency-dependent blocking behavior. The state-dependent inhibition is increased for butylparaben and benzylparaben and diminished for methylparaben, ethylparaben and p-hydroxybenzoic acid (the major metabolite of parabens hydrolysis). Particularly, butylparaben and benzylparaben shift the steady-state inactivation curve 2- and 3-times more than propylparaben, respectively. Parabens are blockers of hNa V 1.2 channels, sharing the mechanism of action of most of sodium channel blocking antiseizure drugs. The potency of this inhibition increases with the size of the lipophilic alcoholic residue of the ester group. These results provide a basis for rational drug design directed to generate new potential anticonvulsant agents. [ABSTRACT FROM AUTHOR]

Published

2020

4. Metformin prevents anti-osteogenic in vivo and ex vivo effects of rosiglitazone in rats

Author

Sedlinsky, Claudia, Molinuevo, María Silvina, Cortizo, Ana María, Tolosa, María José, Felice, Juan Ignacio, Sbaraglini, María Laura, Schurman, Leon, and McCarthy, Antonio Desmond

Subjects

*METFORMIN, *ROSIGLITAZONE, *BONE growth, *LABORATORY rats, *OSSIFICATION, *PHOSPHORYLATION, *GENE expression

Abstract

Abstract: Long-term treatment with the insulin-sensitizer rosiglitazone reduces bone mass and increases fracture risk. We have recently shown that orally administered metformin stimulates bone reossification and increases the osteogenic potential of bone marrow progenitor cells (BMPC). In the present study we investigated the effect of a 2-week metformin and/or rosiglitazone treatment on bone repair, trabecular bone microarchitecture and BMPC osteogenic potential, in young male Sprague–Dawley rats. Compared to untreated controls, rosiglitazone monotherapy decreased bone regeneration, femoral metaphysis trabecular area, osteoblastic and osteocytic density, and TRAP activity associated with epiphyseal growth plates. It also decreased the ex vivo osteogenic commitment of BMPC, inducing an increase in PPARγ expression, and a decrease in Runx2/Cbfa1 expression, in AMP-kinase phosphorylation, and in osteoblastic differentiation and mineralization. After monotherapy with metformin, with the exception of PPARγ expression which was blunted, all of the above parameters were significantly increased (compared to untreated controls). Metformin/rosiglitazone co-treatment prevented all the in vivo and ex vivo anti-osteogenic effects of rosiglitazone monotherapy, with a reversion back to control levels of PPARγ, Runx2/Cbfa1 and AMP-kinase phosphorylation of BMPC. In vitro co-incubation of BMPC with metformin and compound C—an inhibitor of AMPK phosphorylation—abrogated the metformin-induced increase in type-1 collagen production, a marker of osteoblastic differentiation. In conclusion, in rodent models metformin not only induces direct osteogenic in vivo and ex vivo actions, but when it is administered orally in combination with rosiglitazone it can prevent several of the adverse effects that this thiazolidenedione shows on bone tissue. [Copyright &y& Elsevier]

Published

2011