ABSTRACT
Resumen El objetivo de esta investigación es la modelación del dominio de un marco técnico de compartición e interacción de un expediente clínico electrónico (ECE) entre diversas instituciones de salud, públicas o privadas, como primer paso para lograr un marco técnico de refererencia para la interoperabilidad de sistemas de ECE en México. Se ha utilizado el proceso sistemático KMOS-RE para obterner los diversos artefactos que conforman el modelo: el léxico extendido del conocimiento del domino, los modelos conceptuales del dominio de aplicación y del dominio de la solución y los modelos de estados. Debido a que el diseño e implementación de los sistemas de ECE de cada una de las instituciones de salud se generan de manera independiente, realizar un marco técnico de referencia representa un gran desafío y una gran oportunidad, ya que ofrecerá ventajas importantes, como el hecho de contar con la información clínica de manera oportuna en cualquier institución de salud, la posibilidad de que el propio paciente acceda a su información y la facilidad de realizar investigación clínica a partir de los datos compartidos. Aún cuando la modelación de un dominio es dinámica, el contar con un modelo del dominio lo más preciso posible en este punto, facilitará los siguientes pasos para lograr el marco técnico de referencia propuesto.
Abstract This paper presents the domain modeling of a technical framework of sharing and interaction of an electronic medical record among different healthcare institutions, both public or private, as a first step to establish a technical reference framework for the interoperability of electronic medical record systems in Mexico. The artefact that make up the domain model were carried out using the KMOS-RE systematic process. Through this process, the following components have been obtained: the knowledge domain extended lexicon, the conceptual models, one for the application domain and another for the solution domain, as well as the state models. Since the design and implementation of the electronic medical record systems of different healthcare institutions are generated independently, having a technical reference framework represents a great challenge but also a great opportunity, since it will offer important advantages, such as having the clinical information in a timely manner in any healthcare institution, the possibility of the patient accessing their own information and the ease of conducting clinical research from the shared data. Even when a domain modeling is a dynamic task, having a precise domain model at this point will facilitate the next steps to achieve the proposed technical reference framework.
ABSTRACT
In this study, ethylcellulose was evaluated as a carrier for the preparation of sustained release of acetaminophen via solid dispersion technique. Physical mixture at the same level of acetaminophen and ethylcellulose was prepared. Differential scanning calorimetry and scanning electron microscope were used to characterize the physical properties of the various systems and to determine if there is possible interaction between acetaminophen and ethylcellulose
Subject(s)
Acetaminophen/chemistry , Cellulose/analogs & derivatives , Acetaminophen/administration & dosage , Calorimetry, Differential Scanning , Cellulose/chemistry , Delayed-Action Preparations , Microscopy, Electron, ScanningABSTRACT
In this study ethylcellulose was evaluated as a carrier for preparation of prolonged release acetaminophen tablets. Solid dispersions containing three levels of ethylcellulose and acetaminophen (1:3; 1:1; 3:1) were prepared by the solvent method. Also physical mixtures at the same level of ethylcellulose and acetaminophen were prepared. Systems composed of solid dispersion or physical mixture containing the equivalent weight of 50 mg acetaminophen, Emcompress as diluent and 1 per cent magnesium stearate as lubricant were compressed into tablets and tested for dissolution. The dissolution data showed that the drug release decreased as the level of ethylcellulose increased in the solid dispersion formulations. The drug release from tablets prepared with solid dispersion followed the diffusion controlled model for inert porous matrix, while the drug release from tablets prepared with physical mixture followed the first-order kinetic model