Equivalencia terapéutica in vitro de tabletas de enalapril maleato 20 mg de producción nacional / In vitro therapeutic equivalence of 20 mg enalapril maleate tablets of national production

Los ensayos de equivalencia terapéutica tienen como objetivo demostrar que los medicamentos genéricos aportan la misma cantidad de principio activo en comparación con el medicamento innovador. El objetivo de la investigación fue evaluar la equivalencia terapéutica del medicamento enalapril maleato en tabletas de 20 mg, según la clasificación biofarmacéutica que le corresponde, ya que este es un medicamento representativo de la clase III, para demostrar que tienen un perfil de tolerabilidad adecuado y que son eficaces para su prescripción médica. Por otro lado, al demostrarse la equivalencia terapéutica se puede recurrir con toda seguridad al medicamento genérico y reducir los costos de los tratamientos, con lo cual la población tendrá una oferta de medicamentos confiables, seguros y a precios económicos. Se utilizó un medicamento innovador y tres de los ocho medicamentos genéricos de fabricación y comercialización nacional, a los cuales se les determinó perfiles de disolución (F2: 45.41, 92.42, 71.04), uniformidad de contenido (AV: 7.37, 2.97, 2.50) y valoración de principio activo (%: 107.14, 98.89, 101.71) para determinar la cantidad de principio activo en las muestras. Los análisis se realizaron con base en los criterios establecidos en la Farmacopea de los Estados Unidos. Se aplicó un modelo estadístico independiente, y se estableció que dos de los tres lotes analizados de los medicamentos genéricos son equivalentes terapéuticos con el lote del medicamento innovador. Con las pruebas de disolución in vitro realizadas a lo largo de este estudio, se puede concluir que los tres lotes analizados de dos medicamentos genéricos pueden ser considerados intercambiables con respecto al lote del medicamento innovador.

The therapeutic equivalence essays to demonstrate that generic medicine can provide the same amount of active ingredient compared to the innovative medicine. The objective of this research was to evaluate the therapeutic equivalence of enalapril maleate 20 mg, according to the biopharmaceutical classification, given that this is a representative class III drug. This to demonstrate that it has an acceptable tolerability profile and that it is effective for medical prescription. Once the therapeutic equivalence is stablished, the use of therapeutic bioequivalence products can reduce treatment costs, so that the general public can have access to reliable, safe and affordable medicines. For this study an innovative medicine and three of the eight generic medicines of national manufacture and commercialization were used for each medicine, the dissolucion profiles (F2: 45.41, 92.42, 71.04), the uniformity of content (AV: 7.37, 2.97, 2.50) and percentage of active ingredient (%: 107.14, 98.89, 101.71) were determined. The essays were performed based on the criteria established in The United States Pharmacopeia and were satisfactory in all the analyzed batches. An independent statistical model was carried out it was established, that two of the three analyzed batches for generic medicine are therapeutic equivalents with the batch of the innovative drug. In vitro dissolution tests obtained throughout this study, concluded that the three analyzed batches of two generic medicines can be considered interchangeable in respect to the batch of the innovative medicine.

Al2O3:Yb3+ integrated microdisk laser label-free biosensor.

Whispering gallery mode resonator lasers hold the promise of an ultralow intrinsic limit of detection. However, the widespread use of these devices for biosensing applications has been hindered by the complexity and lack of robustness of the proposed configurations. In this work, we demonstrate biosensing with an integrated microdisk laser. Al2O3doped with Yb3+ was utilized because of its low optical losses as well as its emission in the range 1020-1050 nm, outside the absorption band of water. Single-mode laser emission was obtained at a wavelength of 1024 nm with a linewidth of 250 kHz while the microdisk cavity was submerged in water. A limit of detection of 300 pM (3.6 ng/ml) of the protein rhS100A4 in urine was experimentally demonstrated, showing the potential of the proposed devices for biosensing.

Engineered Muscle Tissues for Disease Modeling and Drug Screening Applications.

Animal models have been the main resources for drug discovery and prediction of drugs' pharmacokinetic responses in the body. However, noticeable drawbacks associated with animal models include high cost, low reproducibility, low physiological similarity to humans, and ethical problems. Engineered tissue models have recently emerged as an alternative or substitute for animal models in drug discovery and testing and disease modeling. In this review, we focus on skeletal muscle and cardiac muscle tissues by first describing their characterization and physiology. Major fabrication technologies (i.e., electrospinning, bioprinting, dielectrophoresis, textile technology, and microfluidics) to make functional muscle tissues are then described. Finally, currently used muscle tissue models in drug screening are reviewed and discussed.

The use of microtechnology and nanotechnology in fabricating vascularized tissues.

Tissue engineering (TE) is a multidisciplinary research area that combines medicine, biology, and material science. In recent decades, microtechnology and nanotechnology have also been gradually integrated into this field and have become essential components of TE research. Tissues and complex organs in the body depend on a branched blood vessel system. One of the main objectives for TE researchers is to replicate this vessel system and obtain functional vascularized structures within engineered tissues or organs. With the help of new nanotechnology and microtechnology, significant progress has been made. Achievements include the design of nanoscale-level scaffolds with new functionalities, development of integrated and rapid nanotechnology methods for biofabrication of vascular tissues, discovery of new composite materials to direct differentiation of stem and inducible pluripotent stem cells into the vascular phenotype. Although numerous challenges to replicating vascularized tissue for clinical uses remain, the combination of these new advances has yielded new tools for producing functional vascular tissues in the near future.

Facile and rapid generation of 3D chemical gradients within hydrogels for high-throughput drug screening applications.

We propose a novel application of dielectrophoresis (DEP) to make three-dimensional (3D) methacrylated gelatin (GelMA) hydrogels with gradients of micro- and nanoparticles. DEP forces were able to manipulate micro- and nanoparticles of different sizes and materials (i.e., C2C12 myoblasts, polystyrene beads, gold microparticles, and carbon nanotubes) within GelMA hydrogels in a rapid and facile way and create 3D gradients of these particles in a microchamber. Immobilization of drugs, such as fluorescein isothiocyanate-dextran (FITC-dextran) and 6-hydroxydopamine (6-OHDA), on gold microparticles allowed us to investigate the high-throughput release of these drugs from GelMA-gold microparticle gradient systems. The latter gradient constructs were incubated with C2C12 myoblasts for 24h to examine the cell viability through the release of 6-OHDA. The drug was released from the microparticles in a gradient manner, inducing a cell viability gradient. This novel approach to create 3D chemical gradients within hydrogels is scalable to any arbitrary length scale. It is useful for making anisotropic biomimetic materials and high-throughput platforms to investigate cell-microenvironment interactions in a rapid, simple, cost-effective, and reproducible manner.

Applications of carbon nanotubes in stem cell research.

Stem cells are a key element in tissue engineering and regenerative medicine. However, they require a suitable microenvironment to grow and regenerate. Carbon nanotubes (CNTs) have attracted much attention as promising materials for stem cell research due to their extraordinary properties, such as their extracellular matrix-like structure, high mechanical strength, optical properties, and high electrical conductivity. Of particular interest is the use of CNTs as biomimetic substrates to control the differentiation of stem cells. CNTs have also been combined with commonly used scaffolds to fabricate functional scaffolds to direct stem cell fate. CNTs can also be used for stem cell labeling due to their high optical absorbance in the near-infrared regime. In this paper, we review and discuss the applications of CNTs in stem cell research along with CNT toxicity issues.

Non-invasive measurement of glucose uptake of skeletal muscle tissue models using a glucose nanobiosensor.

Skeletal muscle tissues play a significant role to maintain the glucose level of whole body and any dysfunction of this tissue leads to the diabetes disease. A culture medium was created in which the muscle cells could survive for a long time and meanwhile it did not interfere with the glucose sensing. We fabricated a model of skeletal muscle tissues in vitro to monitor its glucose uptake. A nanoporous gold as a high sensitive nanobiosensor was then successfully developed and employed to detect the glucose uptake of the tissue models in this medium upon applying the electrical stimulation in a rapid, and non-invasive approach. The response of the glucose sensor was linear in a wide concentration range of 1-50 mM, with a detection limit of 3 µM at a signal-to-noise ratio of 3.0. The skeletal muscle tissue was electrically stimulated during 24 h and glucose uptake was monitored during this period. During the first 3 h of stimulation, electrically stimulated muscle tissue consumed almost twice the amount of glucose than counterpart non-stimulated sample. In total, the glucose consumption of muscle tissues was higher for the electrically stimulated tissues compared to those without applying the electrical field.

Gelatin methacrylate as a promising hydrogel for 3D microscale organization and proliferation of dielectrophoretically patterned cells.

Establishing the 3D microscale organization of cells has numerous practical applications, such as in determining cell fate (e.g., proliferation, migration, differentiation, and apoptosis) and in making functional tissue constructs. One approach to spatially pattern cells is by dielectrophoresis (DEP). DEP has characteristics that are important for cell manipulation, such as high accuracy, speed, scalability, and the ability to handle both adherent and non-adherent cells. However, widespread application of this method is largely restricted because there is a limited number of suitable hydrogels for cell encapsulation. To date, polyethylene glycol-diacrylate (PEG-DA) and agarose have been used extensively for dielectric patterning of cells. In this study, we propose gelatin methacrylate (GelMA) as a promising hydrogel for use in cell dielectropatterning because of its biocompatibility and low viscosity. Compared to PEG hydrogels, GelMA hydrogels showed superior performance when making cell patterns for myoblast (C2C12) and endothelial (HUVEC) cells as well as in maintaining cell viability and growth. We also developed a simple and robust protocol for co-culture of these cells. Combined application of the GelMA hydrogels and the DEP technique is suitable for creating highly complex microscale tissues with important applications in fundamental cell biology and regenerative medicine in a rapid, accurate, and scalable manner.

A Pt layer/Pt disk electrode configuration to evaluate respiration and alkaline phosphatase activities of mouse embryoid bodies.

A Pt layer/Pt disk electrode configuration was used as a scanning electrochemical microscopy (SECM) probe. The glass seal part of the insulator was covered with a Pt layer to form an exposed pseudo reference electrode. In a HEPES-based medium at pH 7.5, the half-wave potential (E(1/2)) for [Fe(CN)(6)](4-) oxidation and O(2) reduction measured versus the internal Pt pseudo reference was shifted by about -0.2V, compared with the E(1/2) measured versus the external Ag/AgCl reference electrode. The shape and the current of the cyclic voltammograms (CVs) did not change notably over time, indicating that the Pt layer is sufficiently stable to be used as an integrated pseudo reference for voltammetric measurements. To demonstrate the suitability for SECM applications, the Pt/Pt probe configuration was used for measuring the oxygen consumption and the alkaline phosphatase (ALP) activity of a single mouse embryoid body (mEB). Ten individual mEB samples were characterized to monitor the oxygen concentration profile. Oxygen reduction currents were monitored at -0.7 V versus the Pt pseudo reference and compared with those monitored at -0.5 V versus Ag/AgCl. The respiration rate of mEBs becomes greater with increasing cultivation dates. We have plotted the oxygen consumption rate (F(O(2))) of each mEB sample, measured versus the Pt layer and versus Ag/AgCl. The linearity of the plot was excellent (coefficient of determination R(2)=0.90). The slope of the least squares method was 1. In a 1.0mM p-aminophenylphospate (PAPP) HEPES buffer (pH 9.5) solution, APL activity of mEBs can be characterized, to monitor the p-aminophenol (PAP) oxidation current. ALP catalyzes the hydrolysis of PAPP to PAP. The E(1/2) for PAP oxidation measured versus the Pt layer was not shifted, compared with the E(1/2) versus Ag/AgCl. The mEB samples were characterized to monitor the PAP concentration profile. PAP oxidation currents were monitored at +0.3 V versus the Pt layer and compared with those monitored at +0.3 V versus Ag/AgCl. We have plotted the PAP production rate (F(PAP)) of each mEB sample, measured versus the Pt layer and versus Ag/AgCl. In this case, the linearity of the plot became slightly scattered, but it was found to be possible to evaluate ALP activities of mEB samples utilizing the Pt/Pt probe configuration. This type of probe is very useful because it is not necessary to insert a reference electrode into the measuring solution to obtain an electrical connection, and thus electrochemical measurement in a small volume becomes much easier.