Abstract
The oral administration of solid dosage forms is the commonest method to achieve systemic therapy and relies on the drug’s solubility in human intestinal fluid (HIF), a key factor that influences bioavailability and biopharmaceutical classification. However, HIF is difficult to obtain and is known to be variable, which has led to the development of a range of simulated intestinal fluid (SIF) systems to determine drug solubility in vitro. In this study we have applied a novel multidimensional approach to analyse and characterise HIF composition using a published data set in both fasted and fed states with a view to refining the existing SIF approaches. The data set provided 152 and 172 measurements of five variables (total bile salt, phospholipid, total free fatty acid, cholesterol and pH) in time-dependent HIF samples from 20 volunteers in the fasted and fed state, respectively. The variable data sets for both fasted state and fed state are complex, do not follow normal distributions but the amphiphilic variable concentrations are correlated. When plotted 2-dimensionally a generally ellipsoid shaped data cloud with a positive slope is revealed with boundaries that enclose published fasted or fed HIF compositions. The data cloud also encloses the majority of fasted state and fed state SIF recipes and illustrates that the structured nature of design of experiment (DoE) approaches does not optimally cover the variable space and may examine media compositions that are not biorelevant. A principal component analysis in either fasted or fed state in combination with fitting an ellipsoid shape to enclose the data results in 8 points that capture over 95% of the compositional variability of HIF. The variable’s average rate of concentration change in both fasted state and fed state over a short time scale (10 min) is zero and a Euclidean analysis highlights differences between the fasted and fed states and among individual volunteers. The results indicate that a 9-point DoE (8 + 1 central point) could be applied to investigate drug solubility in vitro and provide statistical solubility limits. In addition, a single point could provide a worst-case solubility measurement to define the lowest biopharmaceutical classification boundary or for use during drug development. This study has provided a novel description of HIF composition. The approach could be expanded in multiple ways by incorporation of further data sets to improve the statistical coverage or to cover specific patient groups (e.g., paediatric). Further development might also be possible to analyse information on the time dependent behaviour of HIF and to guide HIF sampling and analysis protocols.
Highlights
Oral drug administration is the favoured route based around patient preference and compliance with solid oral dosage forms the most common pharmaceutical product type
A principal component analysis in either fasted or fed state in combination with fitting an ellipsoid shape to enclose the data results in 8 points that capture over 95% of the compositional variability of human intestinal fluid (HIF)
Initial Data Analysis Based on the sampling protocol, the maximum number of HIF samples in the study in either fasted or fed state is 180, which would provide a total of 900 individual variable measurements
Summary
Oral drug administration is the favoured route based around patient preference and compliance with solid oral dosage forms the most common pharmaceutical product type. Drug solubility in the gastrointestinal environment is a key factor controlling bioavailability and has been incorporated into theoretical and practical biopharmaceutical concepts for example the Absorption Potential (AP) [2], Maximum Absorbable Dose (MAD) [3], Biopharmaceutical Classification System (BCS) [4] and Developability Classification System (DCS) [5, 6]. This has led to a focus on gastrointestinal drug solubility during development [7,8,9] and a recognition that determination of the value either by computation or experimentation is a key stage. The current experimental methods available to determine solubility are not adequate [10] to permit in vivo prediction of average solubility and its variability from in vitro measurement and further development is warranted
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More From: European Journal of Pharmaceutics and Biopharmaceutics
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