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55. Structural features of colloidal species in the human fasted upper small intestine

Author

Mullertz, Anette, Reppas, Christos, Psachoulias, Dimitrios, Vertzoni, Maria, Fatouros, Dimitrios G., Mullertz, Anette, Reppas, Christos, Psachoulias, Dimitrios, Vertzoni, Maria, and Fatouros, Dimitrios G.

Abstract

Objectives This paper aims to study the features of colloidal species in the lumen of the upper small intestine of two healthy adults at fasted state by means of electron microscopy. Methods Samples were aspirated from a location near the ligament of Treitz 30 min (volunteer no. 1, Aspirate30min sample) and 60 min (volunteer no. 2, Aspirate60min sample), after administration of 240 ml of an aqueous solution in the fasted state. Key findings In the Aspirate30min sample micelles coexist with multi-, oligo- and unilamellar vesicles. Tubular structures and long structures were frequently visualised. In the Aspirate60min sample micelles, few unilamellar vesicles, long structures and tubular structures were the dominating structural features. In both samples, multivesicular structures and faceted vesicles (previously visualised at fed state) were absent. Structural features of both samples bear similarities with previously studied samples from the lower intestine in the fasted state. Micelles and unilamellar vesicles observed in both samples closely resemble morphological characteristics of those found in fluids simulating the colloidal species in fasted upper intestinal environment. Conclusions Features of colloidal species in contents of fasted small intestine have similarities with fluids simulating the contents in fasted upper small intestine and with contents of lower intestine in the fasted state.

Published
2015

56. 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
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57. Combining in vitro and in silico methods for better prediction of surfactant effects on the absorption of poorly water soluble drugs-a fenofibrate case example

Author

Berthelsen, Ragna, Sjögren, Erik, Jacobsen, Jette, Kristensen, Jakob, Holm, Rene, Abrahamsson, Bertil, Mullertz, Anette, Berthelsen, Ragna, Sjögren, Erik, Jacobsen, Jette, Kristensen, Jakob, Holm, Rene, Abrahamsson, Bertil, and Mullertz, Anette

Abstract

The aim of this study was to develop a sensitive and discriminative in vitro-in silico model able to simulate the in vivo performance of three fenofibrate immediate release formulations containing different surfactants. In addition, the study was designed to investigate the effect of dissolution volume when predicting the oral bioavailability of the formulations. In vitro dissolution studies were carried out using the USP apparatus 2 or a mini paddle assembly, containing 1000 mL or 100 mL fasted state biorelevant medium, respectively. In silico simulations of small intestinal absorption were performed using the GI-Sim absorption model. All simulation runs were performed twice adopting either a total small intestinal volume of 533 mL or 105 mL, in order to examine the implication of free luminal water volumes for the in silico predictions. For the tested formulations, the use of a small biorelevant dissolution volume was critical for in vitro-in silico prediction of drug absorption. Good predictions, demonstrating rank order in vivo-in vitro-in silico correlations for C-max, were obtained with in silico predictions utilizing a 105 mL estimate for the human intestinal water content combined with solubility and dissolution data performed in a mini paddle apparatus with 100 mL fasted state simulated media.

Published
2014
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58. The Biopharmaceutics Risk Assessment Roadmap for Optimizing Clinical Drug Product Performance

Author

Selen, Arzu, Dickinson, Paul A., Mullertz, Anette, Crison, John R., Mistry, Hitesh B., Cruanes, Maria T., Martinez, Marilyn N., Lennernäs, Hans, Wigal, Tim L., Swinney, David C., Polli, James E., Serajuddin, Abu T. M., Cook, Jack A., Dressman, Jennifer B., Selen, Arzu, Dickinson, Paul A., Mullertz, Anette, Crison, John R., Mistry, Hitesh B., Cruanes, Maria T., Martinez, Marilyn N., Lennernäs, Hans, Wigal, Tim L., Swinney, David C., Polli, James E., Serajuddin, Abu T. M., Cook, Jack A., and Dressman, Jennifer B.

Abstract

The biopharmaceutics risk assessment roadmap (BioRAM) optimizes drug product development and performance by using therapy-driven target drug delivery profiles as a framework to achieve the desired therapeutic outcome. Hence, clinical relevance is directly built into early formulation development. Biopharmaceutics tools are used to identify and address potential challenges to optimize the drug product for patient benefit. For illustration, BioRAM is applied to four relatively common therapy-driven drug delivery scenarios: rapid therapeutic onset, multiphasic delivery, delayed therapeutic onset, and maintenance of target exposure. BioRAM considers the therapeutic target with the drug substance characteristics and enables collection of critical knowledge for development of a dosage form that can perform consistently for meeting the patient's needs. Accordingly, the key factors are identified and in vitro, in vivo, and in silico modeling and simulation techniques are used to elucidate the optimal drug delivery rate and pattern. BioRAM enables (1) feasibility assessment for the dosage form, (2) development and conduct of appropriate learning and confirming studies, (3) transparency in decision-making, (4) assurance of drug product quality during lifecycle management, and (5) development of robust linkages between the desired clinical outcome and the necessary product quality attributes for inclusion in the quality target product profile.

Published
2014
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59. Refining stability and dissolution rate of amorphous drug formulations

Author

Grohganz, Holger, Priemel, Petra A, Löbmann, Korbinian, Nielsen, Line Hagner, Laitinen, Riikka, Mullertz, Anette, Van den Mooter, Guy, Rades, Thomas, Grohganz, Holger, Priemel, Petra A, Löbmann, Korbinian, Nielsen, Line Hagner, Laitinen, Riikka, Mullertz, Anette, Van den Mooter, Guy, and Rades, Thomas

Abstract

Introduction: Poor aqueous solubility of active pharmaceutical ingredients (APIs) is one of the main challenges in the development of new small molecular drugs. Additionally, the proportion of poorly soluble drugs among new chemical entities is increasing. The transfer of a crystalline drug to its amorphous counterpart is often seen as a potential solution to increase the solubility. However, amorphous systems are physically unstable. Therefore, pharmaceutical formulations scientists need to find ways to stabilise amorphous forms. Areas covered: The use of polymer-based solid dispersions is the most established technique for the stabilisation of amorphous forms, and this review will initially focus on new developments in this field. Additionally, newly discovered formulation approaches will be investigated, including approaches based on the physical restriction of crystallisation and crystal growth and on the interaction of APIs with small molecular compounds rather than polymers. Finally, in situ formation of an amorphous form might be an option to avoid storage problems altogether. Expert opinion: The diversity of poorly soluble APIs formulated in an amorphous drug delivery system will require different approaches for their stabilisation. Thus, increased focus on emerging techniques can be expected and a rational approach to decide the correct formulation is needed.

Published
2014

60. 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

62. In vitro digestion testing of lipid-based delivery systems:calcium ions combine with fatty acids liberated from triglyceride rich lipid solutions to form soaps and reduce the solubilization capacity of colloidal digestion products

Author

Devraj, Ravi, Williams, Hywel D, Warren, Dallas B, Mullertz, Anette, Porter, Christopher J H, Pouton, Colin W, Devraj, Ravi, Williams, Hywel D, Warren, Dallas B, Mullertz, Anette, Porter, Christopher J H, and Pouton, Colin W

Abstract

In vitro digestion testing is of practical importance to predict the fate of drugs administered in lipid-based delivery systems. Calcium ions are often added to digestion media to increase the extent of digestion of long-chain triglycerides (LCTs), but the effects they have on phase behaviour of the products of digestion, and consequent drug solubilization, are not well understood. This study investigates the effect of calcium and bile salt concentrations on the rate and extent of in vitro digestion of soybean oil, as well as the solubilizing capacity of the digestion products for two poorly water-soluble drugs, fenofibrate and danazol. In the presence of higher concentrations of calcium ions, the solubilization capacities of the digests were reduced for both drugs. This effect is attributed to the formation of insoluble calcium soaps, visible as precipitates during the digestions. This reduces the availability of liberated fatty acids to form mixed micelles and vesicles, thereby reducing drug solubilization. The use of high calcium concentrations does indeed force in vitro digestion of LCTs but may overestimate the extent of drug precipitation that occurs within the intestinal lumen.

Published
2012

63. Characterization and physical stability of spray dried solid dispersions of probucol and PVP-K30

Author

Thybo, Pia, Pedersen, Betty L, Hovgaard, Lars, Holm, Rene, Mullertz, Anette, Thybo, Pia, Pedersen, Betty L, Hovgaard, Lars, Holm, Rene, and Mullertz, Anette

Abstract

The main purpose of this study was to obtain stable, well-characterized solid dispersions (SDs) of amorphous probucol and polyvinylpyrrolidone K-30 (PVP-K30) with improved dissolution rates. A secondary aim was to investigate the flow-through dissolution method for in-vitro dissolution measurements of small-sized amorphous powders dispersed in a hydrophilic polymer. SDs were prepared by spray drying solutions of probucol and different amounts of PVP-K30. The obtained SDs were characterized by dissolution rate measurements in a flow-through apparatus, X-ray Powder Diffraction (XRPD), Differential Scanning Calorimetry (DSC), Scanning Electron Microscopy (SEM), particle sizing (laser diffraction) and Brunauer-Emmett-Teller Method (BET) and results were compared with starting material and a physical mixture. The physical stability was monitored after storage at 25 degrees C and 60% RH for up to 12 weeks. The flow-through method was found suitable as dissolution method. All SDs showed improved in-vitro dissolution rates when compared to starting material and physical mixtures. The greatest improvement in the in-vitro dissolution rate was observed for the highest polymer to drug ratio. By means of the results from XRPD and DSC, it was argued that the presence of amorphous probucol improved the dissolution rate, but the amorphous state could not fully account for the difference in dissolution profiles between the SDs. It was suggested that the increase in surface area due to the reduction in particle size contributed to an increased dissolution rate as well as the presence of PVP-K30 by preventing aggregation and drug re-crystallization and by improving wettability during dissolution. The stabilizing effect of the polymer was verified in the solid state, as all the SDs retained probucol in the amorphous state throughout the entire length of the stability study.

Published
2008

64. Clinical studies with oral lipid based formulations of poorly soluble compounds

Author

Fatouros, Dimitrios, Karpf, Ditte M, Nielsen, Flemming S, Mullertz, Anette, Fatouros, Dimitrios, Karpf, Ditte M, Nielsen, Flemming S, and Mullertz, Anette

Abstract

Udgivelsesdato: 2007-Aug, This work is an attempt to give an overview of the clinical data available on lipid based formulations. Lipid and surfactant based formulations are recognized as a feasible approach to improve bioavailability of poorly soluble compounds. However not many clinical studies have been published so far. Several drug products intended for oral administration have been marketed utilizing lipid and surfactant based formulations. Sandimmune((R)) and Sandimmune Neoral((R)) (cyclosporin A, Novartis), Norvir((R)) (ritonavir), and Fortovase((R)) (saquinavir) have been formulated in self-emulsifying drug delivery systems (SEDDS). This review summarizes published pharmacokinetic studies of orally administered lipid based formulations of poorly aqueous soluble drugs in human subjects. Special attention has been paid to the physicochemical characteristics of the formulations, when available and the impact of these properties on the in vivo performance of the formulation. Equally important is the effect of concurrent food intake on the bioavailability of poorly soluble compounds. The effect of food on the bioavailability of compounds formulated in lipid and surfactant based formulations is also reviewed.

Published
2007

68. The influence of solidification on the in vitro solubilisation of blonanserin loaded supersaturated lipid-based oral formulations

Author

Anette Müllertz, Hayley B. Schultz, Clive A. Prestidge, Amalie Møller, Tahlia R. Meola, Moller, Amalie, Schultz, Hayley B, Meola, Tahlia R, Mullertz, Anette, and Prestidge, Clive A

Subjects
oral drug delivery, supersaturation, Pharmaceutical Science, Administration, Oral, Biological Availability, lipid-based formulation, 02 engineering and technology, 030226 pharmacology & pharmacy, Piperazines, 03 medical and health sciences, 0302 clinical medicine, Drug Delivery Systems, Piperidines, medicine, Solubility, Supersaturation, Drug Carriers, Chromatography, Chemistry, blonanserin, Blonanserin, 021001 nanoscience & nanotechnology, Lipids, In vitro, Bioavailability, lipolysis, Emulsions, porous silica, 0210 nano-technology, Weak base, medicine.drug
Abstract

Supersaturated silica-lipid hybrids have previously demonstrated improved in vitro solubilisation and in vivo oral bioavailability of poorly water-soluble drugs, however were only fabricated using a single lipid (LFCS type I formulations) and were not compared to their liquid precursors. This study investigated the influence of lipid formulation classification (type I vs. type II vs. type IIIA/SNEDDS) and physical state (liquid LBF vs. solidified with silica) on the in vitro solubilisation of the poorly soluble, weak base, anti-psychotic drug, blonanserin (BLON), from a supersaturated lipid-based formulation (LBF).Stable liquid supersaturated LBF were fabricated using BLON (loaded at 150% of its equilibrium solubility), and solidified through encapsulation within porous silica microparticles at a 1:1 ratio. Their physicochemical properties and in vitro solubilisation during lipolysis were compared.Supersaturated BLON was encapsulated in the non-crystalline form. All supersaturated LBF improved the solubilisation of pure BLON during lipolysis regardless of their lipid formulation type or their physical state (1.7- to 13.4-fold). SNEDDS achieved greater solubilisation than the type II formulations (1.4- to 1.7-fold). Furthermore, the liquid precursors achieved greater solubilisation than the silica solidified formulations (4.5- to 5.7-fold). Additionally, in an attempt to increase BLON solubilisation, a spray-dried SNEDDS and dual-loaded solidified super-SNEDDS solidified with silica pre-loaded with BLON was developed, however did not significantly improve solubilisation.Liquid SNEDDS were identified as the optimal oral supersaturated LBF strategy for BLON based on in vitro lipolysis studies. Solidification of LBF using silica is a viable strategy for improving stability, however for drugs such as BLON, solidification may impede in vitro release and solubilisation. Refereed/Peer-reviewed

Published
2021

69. Self-nanoemulsifying drug delivery systems for oral insulin delivery: in vitro and in vivo evaluations of enteric coating and drug loading

Author

Angel Tan, Clive A. Prestidge, Ping Li, Anette Müllertz, Hanne Mørck Nielsen, Li, Ping, Tan, Angel, Prestidge, Clive Allan, Nielsen, Hanne Mørck, and Mullertz, Anette

Subjects
Drug, Blood Glucose, Male, insulin, oral drug delivery, media_common.quotation_subject, medicine.medical_treatment, Pharmaceutical Science, Administration, Oral, Biological Availability, Capsules, Absorption (skin), Pharmacology, Oral Mucosal Absorption, Rats, Sprague-Dawley, Drug Delivery Systems, Polymethacrylic Acids, In vivo, medicine, Animals, Humans, Hypoglycemic Agents, Insulin, enteric coating, pharmacokinetic, media_common, Drug Carriers, Chromatography, Chemistry, Biological Transport, Enteric coating, In vitro, Bioavailability, Drug Liberation, hypoglycemia, Delayed-Action Preparations, Drug delivery, SNEDDS, Nanoparticles, Emulsions, Caco-2 Cells, medicine.drug
Abstract

This study aims at evaluating the combination of self-nanoemulsifying drug delivery systems (SNEDDS) and enteric-coated capsules as a potential delivery strategy for oral delivery of insulin. The SNEDDS preconcentrates, loaded with insulin–phospholipid complex at different levels (0, 2.5 and 10% w/w), were readily dispersed in water to form nanoemulsions of 35 nm and vesicles of 300 nm. The association efficiency of non-complexed insulin in the dispersed SNEDDS was 18.6%, and was increased to 73.1% for insulin–phospholipid complex (at 10% loading level). The morphology of the dispersed SNEDDS changed from nanoemulsion droplets to vesicular structures with increasing complex loading levels. A pHdependent insulin release profile was observed for SNEDDS filled into capsules coated with the enteric polymer, Eudragit1 L100. Using a Caco-2 cell model, it was observed that the transport of insulin was enhanced by factors of 7.7- and 9.3- for SNEDDS loaded with 2.5 and 10% complex, respectively. In healthy fasted rats, administration of SNEDDS (10% complex) filled in enteric-coated capsules produced a 2.7-fold and 3.4-fold enhancement in the relative bioavailability and glucose reduction, respectively. This study shows the effectiveness of combining SNEDDS (loaded with insulin–phospholipid complex) with entericcoated capsules for enhancing the oral absorption and efficacy of insulin. Refereed/Peer-reviewed

Published
2014

70. Recent developments in oral lipid-based drug delivery

Author

Thomas, Nicky Dieter, Rades, Thomas, and Mullertz, Anette

Subjects
lipids, super SNEDDS, absorption, in vitro lipolysis
Abstract

The increasing number of poorly water-soluble drugs in development in the pharmaceutical industry has sparked interest in novel drug delivery options such as lipid-based drug delivery systems (LbDDS). Several LbDDS have been marketed successfully and have shown superior and more reliable bioavailability compared to conventional formulations. However, some reluctance in the broader application of LbDDS still appears, despite the growing commercial interest in lipids as a drug delivery platform. This reluctance might at least in part be related to the complexity associated with the development and characterization of LbDDS. In particular, the lack of standardized test protocols can be identified as the major obstacles for the broader application of LbDDS. This review seeks to summarize recent approaches in the field of lipid-based drug delivery that try to elucidate some critical steps in their development and characterization. Refereed/Peer-reviewed

Published
2013

71. Exploring the fate of liposomes in the intestine by dynamic in vitro lipolysis

Author

Anette Müllertz, Gert Fricker, Nicky Thomas, Johannes Parmentier, Thomas Rades, Parmentier, Johannes, Thomas, Nicky, Mullertz, Anette, Fricker, G, and Rades, Thomas

Subjects
Liposome, Chromatography, Vesicle, Danazol, Lipolysis, Phospholipid, Pharmaceutical Science, dynamic light scattering, Intestines, chemistry.chemical_compound, chemistry, Oral administration, Phosphatidylcholine, scanning ion occlusion sensing, Drug delivery, Liposomes, Phosphatidylcholines, liposome stability, bile salts, Particle Size, Digestion, in vitro lipolysis
Abstract

Liposomes are generally well tolerated drug delivery systems with a potential use for the oral route. However, little is known about the fate of liposomes during exposure to the conditions in the gastro-intestinal tract (GIT). To gain a better understanding of liposome stability in the intestine, a dynamic in vitro lipolysis model, which so far has only been used for the in vitro characterisation of other lipid-based drug delivery systems, was applied to different liposomal formulations. Liposome size and phospholipid (PL) digestion were determined as two markers for liposome stability. In addition, the effect of PL degradation on the ability to maintain liposomally incorporated danazol in solution during lipolysis was evaluated in order to address the feasibility of liposomes designed for oral administration. Rate and extend of hydrolysis of PLs mediated by pancreatic enzymes was determined by titration and HPLC. Size of liposomes was determined by dynamic light scattering during incubation in lipolysis medium (LM) and during lipolysis. SPC-based (soy phosphatidylcholine) liposomes were stable in LM, whereas for EPC-3-based (hydrated egg phosphatidylcholine) formulations the formation of aggregates of around 1 J.m in diameter was observed over time. After 60 min lipolysis more than 80% of PLs of the SPC-liposomes were digested, but dependent on the liposome concentration only a slight change in size and size distribution could be observed. Although EPC-3 formulations did form aggregates during lipolysis, the lipids exhibited a higher stability compared to SPC and only 30% of the PLs were digested. No direct correlation between liposome integrity assessed by vesicle size and PL digestion was observed. Danazol content in the liposomes was around 5% (mol/mol danazol/total lipid) and hardly any precipitation was detected during the lipolysis assay, despite pronounced lipolytic degradation and change in vesicle size. In conclusion, the tested dynamic in vitro lipolysis model is suitable for the assessment of liposome stability in the intestine. Furthermore, liposomes might be a useful alternative to other lipid based delivery systems for the oral delivery of poorly soluble drugs. Refereed/Peer-reviewed

Published
2012

72. Influence of lipid composition and drug load on the In Vitro performance of self-nanoemulsifying drug delivery systems

Author

Anja Graf, Anette Müllertz, Nicky Thomas, Thomas Rades, Thomas, Nicky, Mullertz, Anette, Graf, Anja, and Rades, Thomas

Subjects
Drug, oral drug delivery, Lipid composition, media_common.quotation_subject, Pharmaceutical Science, self-nanoemulsiying drug delivery system (SNEDDS), precipitation, Pharmacology, In Vitro Techniques, Self nanoemulsifying, lipids, Drug Delivery Systems, Pulmonary surfactant, medicine, Lipolysis, Nanotechnology, drug load, in vitro models, media_common, Chromatography, Chemistry, Lipids, In vitro, Simvastatin, Drug delivery, dispersion, Emulsions, lipid chain length, medicine.drug
Abstract

The influence of lipid composition and drug load on the in vitro performance of lipid-based drug delivery systems was investigated during dispersion and in vitro lipolysis of two self-nanoemulsifying drug delivery systems (SNEDDS). SNEDDS preconcentrates consisted of the same mass ratios of lipid, surfactant, and cosolvent but varied in the chain length of the lipid component. Utilization of the surfactant Cremophor EL resulted in pronounced changes in the droplet size of dispersed SNEDDS containing increasing drug loads of the poorly water-soluble compound simvastatin (SIM). In contrast, the droplet size of dispersed medium-chain (MC)-SNEDDS based on the surfactant Cremophor RH40 was not affected by increasing drug loads of SIM, whereas the droplet size of the corresponding long-chain (LC)-SNEDDS increased. During 60 min in vitro lipolysis, MC-SNEDDS maintained approximately 95% of SIM in solution, independent of the drug load. At the start of lipolysis of LC-SNEDDS, up to 34% of the drug precipitated. However, the initial precipitate dissolved in the lipolysis medium 30 min after start of in vitro lipolysis. The study suggests that drug load and lipid composition should be considered for the design of SNEDDS. © 2012Wiley Periodicals, Inc. and the American Pharmacists Association J Pharm Sci 101:1721–1731, 2012

Published
2011

73. The preparation of magnetically guided lipid based nanoemulsions using self-emulsifying technology.

Author

Bakandritsos A, Zboril R, Bouropoulos N, Kallinteri P, Favretto ME, Parker TL, Mullertz A, and Fatouros DG

Subjects
3T3 Cells, Animals, Colloids chemistry, Drug Delivery Systems, Emulsions chemistry, Mice, Sodium Chloride chemistry, Temperature, X-Ray Diffraction, Ferrosoferric Oxide chemistry, Lipids chemistry, Nanotechnology methods
Abstract

This paper reports an easy and highly reproducible preparation route, using self-emulsifying technology, for an orally administered high quality magnetically responsive drug delivery system. Hydrophobic iron oxide nanoparticles of about 5 nm in diameter were prepared and incorporated into the lipid core of the produced oil droplets of a self-nanoemulsifying drug delivery system (MagC(18)/SNEDDS). The produced nanoemulsion exhibits colloidal stability at high ionic strengths and temperatures. The observed value of the saturation magnetization at 2 K is approximately 4.1 emu g(-1). The nanoemulsion displayed the magnetic properties of a non-interacting assembly of superparamagnetic particles and a low blocking temperature. Moreover the effect of MagC(18)/SNEDDS on biological systems in vitro was investigated in rodent fibroblasts (3T3 cells). The cytotoxicity studies show that none of the formulations tested affected cell activity significantly over the 24 h incubation. Such systems might have a potential use for oral delivery of poorly soluble compounds by extending the residence time of the formulation in the small intestine resulting in increased drug absorption values.

Published
2010
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74. Characterization and physical stability of spray dried solid dispersions of probucol and PVP-K30.

Author

Thybo P, Pedersen BL, Hovgaard L, Holm R, and Mullertz A

Subjects
Chemistry, Pharmaceutical methods, Crystallization, Drug Stability, Drug Storage, Humidity, Particle Size, Powders, Solubility, Wettability, Anticholesteremic Agents chemistry, Excipients chemistry, Povidone chemistry, Probucol chemistry
Abstract

The main purpose of this study was to obtain stable, well-characterized solid dispersions (SDs) of amorphous probucol and polyvinylpyrrolidone K-30 (PVP-K30) with improved dissolution rates. A secondary aim was to investigate the flow-through dissolution method for in-vitro dissolution measurements of small-sized amorphous powders dispersed in a hydrophilic polymer. SDs were prepared by spray drying solutions of probucol and different amounts of PVP-K30. The obtained SDs were characterized by dissolution rate measurements in a flow-through apparatus, X-ray Powder Diffraction (XRPD), Differential Scanning Calorimetry (DSC), Scanning Electron Microscopy (SEM), particle sizing (laser diffraction) and Brunauer-Emmett-Teller Method (BET) and results were compared with starting material and a physical mixture. The physical stability was monitored after storage at 25 degrees C and 60% RH for up to 12 weeks. The flow-through method was found suitable as dissolution method. All SDs showed improved in-vitro dissolution rates when compared to starting material and physical mixtures. The greatest improvement in the in-vitro dissolution rate was observed for the highest polymer to drug ratio. By means of the results from XRPD and DSC, it was argued that the presence of amorphous probucol improved the dissolution rate, but the amorphous state could not fully account for the difference in dissolution profiles between the SDs. It was suggested that the increase in surface area due to the reduction in particle size contributed to an increased dissolution rate as well as the presence of PVP-K30 by preventing aggregation and drug re-crystallization and by improving wettability during dissolution. The stabilizing effect of the polymer was verified in the solid state, as all the SDs retained probucol in the amorphous state throughout the entire length of the stability study.

Published
2008
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75. In vitro lipid digestion models in design of drug delivery systems for enhancing oral bioavailability.

Author

Fatouros DG and Mullertz A

Subjects
Animals, Biological Availability, Drug Carriers, Drug Design, Humans, Lipolysis, Drug Delivery Systems, Lipids chemistry, Pharmaceutical Preparations administration & dosage, Pharmaceutical Preparations metabolism
Abstract

This review focuses on recent progress in the in vitro lipid digestion models and how these models can underpin in vitro-in vivo correlations which are a key element for drug development. A plethora of articles are dealing with development of lipid-based formulations of poorly soluble compounds for oral administration; however, most studies base formulation development and proof of concept on bioavailability studies and do not consider the use of in vitro studies. A major challenge is the development of in vitro models simulating the gastric or intestinal fluids to assess their in vivo performance. The use of in vitro lipolysis models has been proposed as an approach to probe solubilisation in the aqueous phase during the progress of enzymatic degradation of lipid based-formulations. Moreover, the in vitro digestion models, coupled with biophysical methods, offer insights into the mechanisms underlying lipid digestion, by characterising the generated intermediate colloidal phases, and thereby can serve as a screening tool for designing and optimising lipid-based formulations.

Published
2008
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