Your search keyword '"Ramírez-Rigo, María V."' showing total 4 results

1. Very fast dissolving acid carboxymethylcellulose-rifampicin matrix: Development and solid-state characterization.

Author

Luciani-Giacobbe, Laura C., Ramírez-Rigo, María V., Garro-Linck, Yamila, Monti, Gustavo A., Manzo, Ruben H., and Olivera, María E.

Subjects

*DRUG bioavailability, *ORAL medication, *SOLID dosage forms, *RIFAMPIN, *CARBOXYMETHYLCELLULOSE, *TUBERCULOSIS treatment, *THERAPEUTICS

Abstract

One of the main obstacles to the successful treatment of tuberculosis is the poor and variable oral bioavailability of rifampicin (RIF), which is mainly due to its low hydrophilicity and dissolution rate. The aim of this work was to obtain a hydrophilic new material that allows a very fast dissolution rate of RIF and therefore is potentially useful in the development of oral solid dosage forms. The acid form of carboxymethylcellulose (CMC) was co-processed with RIF by solvent impregnation to obtain CMC-RIF powder, which was characterized by polarized optical microscopy, powder x-ray diffraction, DSC-TGA, hot stage microscopy, 13 C and 15 N solid-state NMR and FT-IR spectroscopy. In addition, the CMC-RIF matrices were subjected to water uptake and dissolution studies to assess hydrophilicity and release kinetics. CMC-RIF is a crystalline solid dispersion. Solid-state characterization indicated that no ionic interaction occurred between the components, but RIF crystallized as a zwitterion over the surface of CMC, which drastically increased the hydrophilicity of the solid. The CMC-RIF matrices significantly improved the water uptake of RIF and disintegrated in a very short period immediately releasing RIF. As CMC improves the hydrophilicity and delivery properties of RIF, CMC-RIF is very useful in the design of oral solid dosage forms with very fast dissolution of RIF, either alone or in combination with other antitubercular drugs. [ABSTRACT FROM AUTHOR]

Published

2017

2. Enhanced intestinal permeability and oral bioavailability of enalapril maleate upon complexation with the cationic polymethacrylate Eudragit E100.

Author

Ramírez-Rigo, María V., Olivera, María E., Rubio, Modesto, and Manzo, Ruben H.

Subjects

*BIOAVAILABILITY, *PERMEABILITY, *INTESTINAL physiology, *ENALAPRIL, *MALEIC acid, *POLYMETHACRYLATES

Abstract

Abstract: The low bioavailability of enalapril maleate associated to its instability in solid state motivated the development of a polyelectrolyte-drug complex between enalapril maleate and the cationic polymethacrylate Eudragit E100. The solid complexes were characterized by DSC–TG, FT-IR and X-ray diffraction. Their aqueous dispersions were evaluated for drug delivery in bicompartimental Franz cells and electrokinetic potentials. Stability in solid state was also evaluated using an HPLC–UV stability indicating method. Absorption of enalapril maleate was assessed thorough the rat everted gut sac model. In addition, urinary recovery after oral administration in rats was used as an indicator of systemic exposition. The solid materials are stable amorphous solids in which both moieties of enalapril maleate are ionically bonded to the polymer. Their aqueous dispersions exhibited controlled release over more than 7h in physiologic saline solution, being ionic exchange the fundamental mechanism that modified the extent and rate of drug release. Intestinal permeation of enalapril maleate was 1.7 times higher in the presence of the cationic polymer. This increase can be related with the capacity to adhere the mucosa due to the positive zeta potential of the complexes. As a consequence bioavailability was significantly improved (1.39 times) after oral administration of the complexes. In addition, no signs of chemical decomposition were observed after a 14months period. The results indicated that the products are new chemical entities that improve unfavorable properties of a useful drug. [Copyright &y& Elsevier]

Published

2014

3. Swellable drug-polyelectrolyte matrices of drug-carboxymethylcellulose complexes. Characterization and delivery properties.

Author

Ramírez Rigo, María V., Allemandi, Daniel A., and Manzo, Ruben H.

Subjects

*POLYELECTROLYTES, *NEUTRALIZATION (Chemistry), *FOURIER transform infrared spectroscopy, *X-ray diffraction, *ATENOLOL, *HYDROGELS, *DRUG delivery systems

Abstract

This article reports the development and delivery properties of swellable drug-polyelectrolyte matrices prepared with complexes of the acid form of carboxymethylcellulose (HCMC). Drug-polyelelectrolyte complexes (HCMC-D) were obtained by neutralization of HCMC with two model basic drugs (atenolol and metoclopramide). Characterization through FT-infrared spectroscopy, power X-ray diffraction, and DSC indicates the ionic nature of the interaction between the carboxylic groups of HCMC and the basic group of D. Matrices prepared by compacting (HCMC-D) alone or in a mixture with sodium carboxymethylcellulose were subjected to measurements of solvent up-take, dynamics of swelling, and release kinetics. Delivery rate of mixed matrices is a function of its composition and may be widely modulated. They exhibited anomalous delivery kinetics with Korsmeyer exponent n in the range 0.67-0.87. Experimental results indicate that the erosion of the hydrogel layer is the main delivery process. [ABSTRACT FROM AUTHOR]

Published

2009

4. 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