Your search keyword '"Andersson, Sara B. E."' showing total 13 results

1. Controlled Suspensions Enable Rapid Determinations of Intrinsic Dissolution Rate and Apparent Solubility of Poorly Water-Soluble Compounds

Author

Andersson, Sara B. E., Alvebratt, Caroline, and Bergström, Christel A. S.

Published

2017

2. Effect of fluid velocity and particle size on the hydrodynamic diffusion layer thickness

Author

Andersson, Sara B. E., Frenning, Göran, Alderborn, Göran, and Gråsjö, Johan

Subjects

Stagnant layer, Single particle, Biophysics, Pharmaceutical Science, General Medicine, Computational fluid dynamics, Biofysik, Diffusion, Fluid flow, Solubility, Hydrodynamics, Computer Simulation, Hydrodynamic diffusion layer, Particle Size, Diffusion coefficient, Dissolution, Biotechnology

Abstract

The aim of this study was to determine the thickness of the hydrodynamic diffusion layer (h(HDL)) of three poor water-soluble compounds under laminar fluid flow using a single particle dissolution technique. The single particle dissolution experiments were performed in a flowing aqueous medium using four different fluid velocities (v), ranging from 46 to 103 mm/s. The particles used had an initial radius (r) of 18.8 to 52.3 mu m. The determined h(HDL) values were calculated from both dissolution experiments and computational fluid dynamics (CFD) simulation. In this study, single particle dissolution experiments gave, with one exception, h(HDL) values in the range of 2.09 to 8.85 mu m and corresponding simulations gave h(HDL) values in the range of 2.53 to 4.38 mu m. Hence, we found a semi-quantitative concordance between experimental and simulated determined h(HDL) values. Also, a theoretical relation between the dependence of hHDL on particle radius and flow velocity of the medium was established by a series of CFD simulations in a fluid velocity range of 10-100 mm/s and particle size (radius) range of 5-40 mu m. The outcome suggests a power law relation of the form h(HDL)alpha r(3/5)v(-2/5). In addition, the h(HDL) seems to be independent of the solubility, while it has a diffusion coefficient dependence. In conclusion, the hHDL values were determined under well-defined conditions; hence, this approach can be used to estimate the h(HDL) under different conditions to increase the understanding of the mass transfer mechanisms during the dissolution process.

Published

2022

3. Novel and refined small-scale approaches to determine the intrinsic dissolution rate of drugs

Author

Andersson, Sara B. E.

Subjects

Pharmaceutical Sciences, single particle dissolution, intrinsic dissolution rate, solubility, dissolution, poorly water-soluble compounds, Farmaceutiska vetenskaper

Abstract

Many drugs are administered as crystalline particles compressed into tablets and taken orally. When the tablet reaches the gastrointestinal tract, it disintegrates and the drug particles dissolve in the gastrointestinal fluid. The dissolved molecules are absorbed across the intestinal membranes into the bloodstream to reach their target sites. Only dissolved molecules can be absorbed, and if a drug has low solubility and/or dissolution rate in gastrointestinal fluid, the drug absorption might be insufficient. Hence, knowing the solubility and dissolution behaviour of a potential drug candidate is necessary early in the drug development process. The aim of this thesis was to evaluate and refine different approaches for measuring and determining dissolution rate, as well as to develop novel in vitro small-scale dissolution methods. First, interlaboratory variability in determination of intrinsic dissolution rate (IDR) and apparent solubility (Sapp) was investigated using a miniaturized dissolution instrument. To minimize the interlaboratory variability, standardized protocols for both the experimental design and the data analyses were required, and a flow chart for performing standardized powder and disc IDR measurements was established. Next, as an alternative to the powder and disc methods, carefully dispersed suspensions were used to determine the IDR, and rapid and more controlled IDR measurements were obtained using suspensions with dispersed primary particles. From the suspension measurements, an IDR/Sapp ratio of the compounds were determined. This ratio can potentially be used to identify whether a compound is likely to show dissolution rate-limited absorption and hence is sensitive to particle size reduction. The final experiments used a single particle dissolution approach to determine the IDR at four different fluid velocities. Computational fluid dynamics (CFD) simulations were used to theoretically investigate the flow conditions and dissolution rates. Single particle dissolution measurements under well-defined conditions gave high-quality dissolution data. An IDR was determined within 5-60 minutes using particles with initial diameters of 37.5-104.6 μm. The single particle dissolution experiments were used to determine the thickness of the effective hydrodynamic boundary layer (heff). The heff values were also assessed by CFD simulations, and a good concordance between experimental and simulated heff values was obtained. The approaches presented in this thesis can be used to derive qualified knowledge about the dissolution properties of drugs with several potential applications in drug development, such as profiling of solid drugs, informed formulation decisions, assisting the modelling of drug dissolution and providing improved understanding of the in vivo-dissolution behaviour

Published

2021

4. Determination of Intrinsic Drug Dissolution and Solute Effective Transport Rate during Laminar Fluid Flow at Different Velocities

Author

Andersson, Sara B. E., primary, Frenning, Göran, additional, and Alderborn, Göran, additional

Published

2021

5. Determination of Intrinsic Drug Dissolution and Solute Effective Transport Rate during Laminar Fluid Flow at Different Velocities

Author

Andersson, Sara B. E., Frenning, Göran, Alderborn, Göran, Andersson, Sara B. E., Frenning, Göran, and Alderborn, Göran

Abstract

The objective of this study was to determine the intrinsic drug dissolution rate (IDR) and the solute effective transport rate of some drugs, using a single particle dissolution technique, satisfying qualified dissolution conditions. The IDR of three poorly water-soluble compounds was measured in milli-Q water using four different fluid velocities. The enveloped surface area of the particles was calculated from the projected area and the perimeter of the particle observed in the microscope. Furthermore, computational fluid dynamics (CFD) simulations were used to theoretically investigate the flow conditions and dissolution rate, comparing box shaped particles and spherical particles with similar dimensions and surface area as the particles used the experiments. In this study, the IDR measurement of the single particles was determined within 5-60 min using particles with an initial projected area diameter (Dp) between 37.5-104.6 mu m. The micropipette-assisted microscopy technique showed a good reproducibility between individual measurements, and the CFD simulations indicated a laminar flow around the particles at all flow velocities, even though there were evident differences in local particle dissolution rates. In conclusion, the IDR and solute effective transport rate were determined under well-defined fluid flow conditions. This type of approach can be used as a complementary approach to traditional dissolution studies to gain in-depth insights into the dissolution process of drug particles.

Published

2021

6. Interlaboratory validation of small-scale solubility and dissolution measurements of poorly water-soluble drugs

Author

Andersson, Sara B. E., Alvebratt, Caroline, Bevernage, Jan, Bonneau, Damien, Mathews, Claudia da Costa, Dattani, Rikesh, Edueng, Khadijah, He, Yan, Holm, René, Madsen, Cecilie Maria, Müller, Thomas, Muenster, Uwe, Müllertz, Anette, Ojala, Krista, Rades, Thomas, Sieger, Peter, Bergström, Christel A. S., Andersson, Sara B. E., Alvebratt, Caroline, Bevernage, Jan, Bonneau, Damien, Mathews, Claudia da Costa, Dattani, Rikesh, Edueng, Khadijah, He, Yan, Holm, René, Madsen, Cecilie Maria, Müller, Thomas, Muenster, Uwe, Müllertz, Anette, Ojala, Krista, Rades, Thomas, Sieger, Peter, and Bergström, Christel A. S.

Published

2016

7. Early pharmaceutical profiling to predict oral drug absorption : Current status and unmet needs

Author

Bergström, Christel A. S., Holm, Rene, Jorgensen, Soren Astrup, Andersson, Sara B. E., Artursson, Per, Beato, Stefania, Borde, Anders, Box, Karl, Brewster, Marcus, Dressman, Jennifer, Feng, Kung-I., Halbert, Gavin, Kostewicz, Edmund, McAllister, Mark, Muenster, Uwe, Thinnes, Julian, Taylor, Robert, Mullertz, Anette, Bergström, Christel A. S., Holm, Rene, Jorgensen, Soren Astrup, Andersson, Sara B. E., Artursson, Per, Beato, Stefania, Borde, Anders, Box, Karl, Brewster, Marcus, Dressman, Jennifer, Feng, Kung-I., Halbert, Gavin, Kostewicz, Edmund, McAllister, Mark, Muenster, Uwe, Thinnes, Julian, Taylor, Robert, and Mullertz, Anette

Abstract

Preformulation measurements are used to estimate the fraction absorbed in vivo for orally administered compounds and thereby allow an early evaluation of the need for enabling formulations. As part of the Oral Biopharmaceutical Tools (OrBiTo) project, this review provides a summary of the pharmaceutical profiling methods available, with focus on in silica and in vitro models typically used to forecast active pharmaceutical ingredient's (APIs) in vivo performance after oral administration. An overview of the composition of human, animal and simulated gastrointestinal (GI) fluids is provided and state-of-the art methodologies to study API properties impacting on oral absorption are reviewed. Assays performed during early development, i.e. physicochemical characterization, dissolution profiles under physiological conditions, permeability assays and the impact of excipients on these properties are discussed in detail and future demands on pharmaceutical profiling are identified. It is expected that innovative computational and experimental methods that better describe molecular processes involved in vivo during dissolution and absorption of APIs will be developed in the OrBiTo. These methods will provide early insights into successful pathways (medicinal chemistry or formulation strategy) and are anticipated to increase the number of new APIs with good oral absorption being discovered. (C) 2013 Elsevier B.V. All rights reserved.

Published

2014

8. Is the full potential of the biopharmaceutics classification system reached?

Author

Bergström, Christel A. S., Andersson, Sara B. E., Fagerberg, Jonas H., Ragnarsson, Gert, Lindahl, Anders, Bergström, Christel A. S., Andersson, Sara B. E., Fagerberg, Jonas H., Ragnarsson, Gert, and Lindahl, Anders

Abstract

In this paper we analyse how the biopharmaceutics classification system (BCS) has been used to date. A survey of the literature resulted in a compilation of 242 compounds for which BCS classes were reported. Of these, 183 compounds had been reported to belong to one specific BCS class whereas 59 compounds had been assigned to multiple BCS classes in different papers. Interestingly, a majority of the BCS class 2 compounds had fraction absorbed (FA) values >85%, indicating that they were completely absorbed after oral administration. Solubility was computationally predicted at pH 6.8 for BCS class 2 compounds to explore the impact of the pH of the small intestine, where most of the absorption occurs, on the solubility. In addition, the solubilization capacity of lipid aggregates naturally present in the intestine was studied computationally and experimentally for a subset of 12 compounds. It was found that all acidic compounds with FA > 85% were completely dissolved in the pH of the small intestine. Further, lipids at the concentration used in fasted state simulated intestinal fluid (FaSSIF) dissolved the complete dose given of the most lipophilic (logD(6.5) >3) compounds studied. Overall, biorelevant dissolution media (pure buffer of intestinal pH or FaSSIF) identified that for 20 of the 29 BCS class 2 compounds with FA > 85% the complete dose given orally would be dissolved. These results indicate that a more relevant pH restriction for acids and/or dissolution medium with lipids present better forecast solubility-limited absorption in vivo than the presently used BCS solubility criterion. The analysis presented herein further strengthens the discussion on the requirement of more physiologically relevant dissolution media for the in vitro solubility classification performed to reach the full potential of the BCS. (C) 2013 Elsevier B.V. All rights reserved.

Published

2014

9. Formulation of the Microbicide INP0341 for In Vivo Protection against a Vaginal Challenge by Chlamydia trachomatis

Author

Pedersen, Christian, Slepenkin, Anatoly, Andersson, Sara B. E., Fagerberg, Jonas H., Bergström, Christel A. S., Peterson, Ellena M., Pedersen, Christian, Slepenkin, Anatoly, Andersson, Sara B. E., Fagerberg, Jonas H., Bergström, Christel A. S., and Peterson, Ellena M.

Abstract

The salicylidene acylhydrazide (SA) compounds have exhibited promising microbicidal properties. Previous reports have shown the SA compounds, using cell cultures, to exhibit activity against Chlamydia trachomatis, herpes simplex virus and HIV-1. In addition, using an animal model of a vaginal infection the SA compound INP0341, when dissolved in a liquid, was able to significantly protect mice from a vaginal infection with C. trachomatis. To expand upon this finding, in this report INP0341 was formulated as a vaginal gel, suitable for use in humans. Gelling agents (polymers) with inherent antimicrobial properties were chosen to maximize the total antimicrobial effect of the gel. In vitro formulation work generated a gel with suitable rheology and sustained drug release. A formulation containing 1 mM INP0341, 1.6 wt% Cremophor ELP (solubility enhancer) and 1.5 wt% poly(acrylic acid) (gelling and antimicrobial agent), was chosen for studies of efficacy and toxicity using a mouse model of a vaginal infection. The gel formulation was able to attenuate a vaginal challenge with C. trachomatis, serovar D. Formulations with and without INP0341 afforded protection, but the inclusion of INP0341 increased the protection. Mouse vaginal tissue treated with the formulation showed no indication of gel toxicity. The lack of toxicity was confirmed by in vitro assays using EpiVaginal tissues, which showed that a 24 h exposure to the gel formulation did not decrease the cell viability or the barrier function of the tissue. Therefore, the gel formulation described here appears to be a promising vaginal microbicide to prevent a C. trachomatis infection with the potential to be expanded to other sexually transmitted diseases.

Published

2014

10. Early pharmaceutical profiling to predict oral drug absorption:current status and unmet needs

Author

Bergström, Christel A S, Holm, René, Jørgensen, Søren Astrup, Andersson, Sara B E, Artursson, Per, Beato, Stefania, Borde, Anders, Box, Karl, Brewster, Marcus, Dressman, Jennifer, Feng, Kung-I, Halbert, Gavin, Kostewicz, Edmund, McAllister, Mark, Muenster, Uwe, Thinnes, Julian, Taylor, Robert, Mullertz, Anette, Bergström, Christel A S, Holm, René, Jørgensen, Søren Astrup, Andersson, Sara B E, Artursson, Per, Beato, Stefania, Borde, Anders, Box, Karl, Brewster, Marcus, Dressman, Jennifer, Feng, Kung-I, Halbert, Gavin, Kostewicz, Edmund, McAllister, Mark, Muenster, Uwe, Thinnes, Julian, Taylor, Robert, and Mullertz, Anette

Abstract

Preformulation measurements are used to estimate the fraction absorbed in vivo for orally administered compounds and thereby allow an early evaluation of the need for enabling formulations. As part of the Oral Biopharmaceutical Tools (OrBiTo) project, this review provides a summary of the pharmaceutical profiling methods available, with focus on in silico and in vitro models typically used to forecast active pharmaceutical ingredient's (APIs) in vivo performance after oral administration. An overview of the composition of human, animal and simulated gastrointestinal (GI) fluids is provided and state-of-the art methodologies to study API properties impacting on oral absorption are reviewed. Assays performed during early development, i.e. physicochemical characterization, dissolution profiles under physiological conditions, permeability assays and the impact of excipients on these properties are discussed in detail and future demands on pharmaceutical profiling are identified. It is expected that innovative computational and experimental methods that better describe molecular processes involved in vivo during dissolution and absorption of APIs will be developed in the OrBiTo. These methods will provide early insights into successful pathways (medicinal chemistry or formulation strategy) and are anticipated to increase the number of new APIs with good oral absorption being discovered.

Published

2014

11. Formulation of the Microbicide INP0341 for In Vivo Protection against a Vaginal Challenge by Chlamydia trachomatis

Author

Pedersen, Christian, primary, Slepenkin, Anatoly, additional, Andersson, Sara B. E., additional, Fagerberg, Jonas H., additional, Bergström, Christel A. S., additional, and Peterson, Ellena M., additional

Published

2014

12. Is the full potential of the biopharmaceutics classification system reached?

Author

Bergström CA, Andersson SB, Fagerberg JH, Ragnarsson G, and Lindahl A

Subjects

Administration, Oral, Animals, Computer Simulation, Humans, Hydrogen-Ion Concentration, Intestinal Absorption, Intestinal Mucosa metabolism, Permeability, Pharmaceutical Preparations administration & dosage, Pharmaceutical Preparations chemistry, Reproducibility of Results, Solubility, Biopharmaceutics methods, Models, Biological, Pharmaceutical Preparations classification, Pharmaceutical Preparations metabolism, Pharmacokinetics, Terminology as Topic

Abstract

In this paper we analyse how the biopharmaceutics classification system (BCS) has been used to date. A survey of the literature resulted in a compilation of 242 compounds for which BCS classes were reported. Of these, 183 compounds had been reported to belong to one specific BCS class whereas 59 compounds had been assigned to multiple BCS classes in different papers. Interestingly, a majority of the BCS class 2 compounds had fraction absorbed (FA) values >85%, indicating that they were completely absorbed after oral administration. Solubility was computationally predicted at pH 6.8 for BCS class 2 compounds to explore the impact of the pH of the small intestine, where most of the absorption occurs, on the solubility. In addition, the solubilization capacity of lipid aggregates naturally present in the intestine was studied computationally and experimentally for a subset of 12 compounds. It was found that all acidic compounds with FA>85% were completely dissolved in the pH of the small intestine. Further, lipids at the concentration used in fasted state simulated intestinal fluid (FaSSIF) dissolved the complete dose given of the most lipophilic (logD6.5>3) compounds studied. Overall, biorelevant dissolution media (pure buffer of intestinal pH or FaSSIF) identified that for 20 of the 29 BCS class 2 compounds with FA>85% the complete dose given orally would be dissolved. These results indicate that a more relevant pH restriction for acids and/or dissolution medium with lipids present better forecast solubility-limited absorption in vivo than the presently used BCS solubility criterion. The analysis presented herein further strengthens the discussion on the requirement of more physiologically relevant dissolution media for the in vitro solubility classification performed to reach the full potential of the BCS., (Copyright © 2013 Elsevier B.V. All rights reserved.)

Published

2014

13. Early pharmaceutical profiling to predict oral drug absorption: current status and unmet needs.

Author

Bergström CA, Holm R, Jørgensen SA, Andersson SB, Artursson P, Beato S, Borde A, Box K, Brewster M, Dressman J, Feng KI, Halbert G, Kostewicz E, McAllister M, Muenster U, Thinnes J, Taylor R, and Mullertz A

Subjects

Administration, Oral, Animals, Chemistry, Pharmaceutical, Computer Simulation, Excipients chemistry, Gastric Juice chemistry, Gastric Juice metabolism, Humans, Hydrogen-Ion Concentration, Intestinal Secretions chemistry, Intestinal Secretions metabolism, Models, Biological, Pharmaceutical Preparations chemistry, Solubility, Biopharmaceutics methods, Gastrointestinal Tract physiology, Intestinal Absorption, Pharmaceutical Preparations administration & dosage, Pharmaceutical Preparations metabolism, Pharmacokinetics, Technology, Pharmaceutical methods

Abstract

Preformulation measurements are used to estimate the fraction absorbed in vivo for orally administered compounds and thereby allow an early evaluation of the need for enabling formulations. As part of the Oral Biopharmaceutical Tools (OrBiTo) project, this review provides a summary of the pharmaceutical profiling methods available, with focus on in silico and in vitro models typically used to forecast active pharmaceutical ingredient's (APIs) in vivo performance after oral administration. An overview of the composition of human, animal and simulated gastrointestinal (GI) fluids is provided and state-of-the art methodologies to study API properties impacting on oral absorption are reviewed. Assays performed during early development, i.e. physicochemical characterization, dissolution profiles under physiological conditions, permeability assays and the impact of excipients on these properties are discussed in detail and future demands on pharmaceutical profiling are identified. It is expected that innovative computational and experimental methods that better describe molecular processes involved in vivo during dissolution and absorption of APIs will be developed in the OrBiTo. These methods will provide early insights into successful pathways (medicinal chemistry or formulation strategy) and are anticipated to increase the number of new APIs with good oral absorption being discovered., (Copyright © 2013 Elsevier B.V. All rights reserved.)

Published

2014