A predictive integrated framework based on the radial basis function for the modelling of the flow of pharmaceutical powders

Alshafiee, Maen and AlAlaween, Wafa' H. and Markl, Daniel and Soundaranathan, Mithushan and Almajaan, Ammar and Walton, Karl and Blunt, Liam and Asare-Addo, Kofi (2019) A predictive integrated framework based on the radial basis function for the modelling of the flow of pharmaceutical powders. International Journal of Pharmaceutics, 568. 118542. ISSN 0378-5173

[img]
Preview
Text (Alshafiee-etal-IJP-2019-framework-based-on-the-radial-basis-function-for-the-modelling-of-the-flow-of-pharmaceutical-powders)
Alshafiee_etal_IJP_2019_framework_based_on_the_radial_basis_function_for_the_modelling_of_the_flow_of_pharmaceutical_powders.pdf
Accepted Author Manuscript
License: Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 logo

Download (415kB)| Preview

    Abstract

    This study presents a modelling framework to predict the flowability of various commonly used pharmaceutical powders and their blends. The flowability models were trained and validated on 86 samples including single components and binary mixtures. Two modelling paradigms based on artificial intelligence (AI) namely, a radial basis function (RBF) and an integrated network were employed to model the flowability represented by the flow function coefficient (FFC) and the bulk density (RHOB). Both approaches were utilized to map the input parameters (i.e. particle size, shape descriptors and material type) to the flow properties. The input parameters of the blends were determined from the particle size, shape and material type properties of the single components. The results clearly indicated that the integrated network outperformed the single RBF network in terms of the predictive performance and the generalization capabilities. For the integrated network, the coefficient of determination of the testing data set (not used for training the model) for FFC was R2=0.93, reflecting an acceptable predictive power of this model. Since the flowability of the blends can be predicted from single component size and shape descriptors, the integrated network can assist formulators in selecting excipients and their blend concentrations to improve flowability with minimal experimental effort and material resulting in the (i) minimization of the time required, (ii) exploration and examination of the design space, and (iii) minimization of material waste.