Instability Mechanisms of Water-in-Oil Nanoemulsions with

Dec 8, 2017 - Many food preparations, pharmaceuticals, and cosmetics use water-in-oil (W/O) emulsions stabilized by phospholipids. Moreover, recent te...
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Instability mechanisms of water in oil nanoemulsions with phospholipids: temporal and morphological structures Jan-Hendrik Sommerling, Maria Betania Carreira de Matos, Ellen Hildebrandt, Alberto Dessy, Robbert J. Kok, Hermann Nirschl, and Gero Leneweit Langmuir, Just Accepted Manuscript • DOI: 10.1021/acs.langmuir.7b02852 • Publication Date (Web): 08 Dec 2017 Downloaded from http://pubs.acs.org on December 9, 2017

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Instability

mechanisms

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water

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nanoemulsions with phospholipids: temporal and morphological structures Jan-Hendrik Sommerling1,2, Maria B.C. de Matos2,3, Ellen Hildebrandt1,2, Alberto Dessy2, Robbert Jan Kok3, Hermann Nirschl1, and Gero Leneweit2,4* 1 Institute for Mechanical Engineering and Mechanics, Karlsruhe Institute of Technology, Straße am Forum 8, 76131 Karlsruhe, Germany 2 Abnoba GmbH, Hohenzollernstraße 16, 75177 Pforzheim, Germany 3 Utrecht Institute for Pharmaceutical Sciences, Department of Pharmaceutics, Utrecht University, The Netherlands 4 Carl Gustav Carus-Institute, Association for the Advancement of Cancer Therapy, Am Eichhof 30, 75223 Niefern-Öschelbronn, Germany * Corresponding author KEYWORDS: Dipalmitoylphosphatidylcholine (DPPC), coalescence, Ostwald ripening, sonication, adsorption kinetics, co-solubility, critical aggregation concentration ABSTRACT Many food preparations, pharmaceuticals, and cosmetics use water in oil (W/O) emulsions stabilized by phospholipids. Moreover, recent technological developments try to produce liposomes or lipid coated capsules from W/O emulsions, but are faced with colloidal instabilities. To explore these instability mechanisms, emulsification by sonication was applied in three cycles and the sample stability was studied for 3 hours after each cycle. Clearly identifiable temporal structures of instability provide evidence about the emulsion morphology: an initial regime of about 10 minutes is shown to be governed by coalescence after which Ostwald ripening dominates. Transport via molecular diffusion in Ostwald ripening is commonly

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based on the mutual solubility of the two phases and is therefore prohibited in emulsions composed of immiscible phases. However, in the case of water in oil emulsified by phospholipids these form water-loaded reverse micelles in oil which enable Ostwald ripening despite the low solubility of water in oil as is shown for squalene. As is proved for the phospholipid dipalmitoylphosphatidylcholine (DPPC), concentrations below the critical aggregation concentration (CAC) form monolayers at the interfaces and smaller droplet sizes. In contrast, phospholipid concentrations above CAC create complex multilayers at the interface with larger droplet sizes. The key factors for stable W/O emulsions in classical or innovative applications are: first, the minimization of the phospholipids’ capacity to form reversed micelles; and second the adaption of the initial phospholipid concentration to the water content to enable an optimized coverage of phospholipids at the interfaces for the intended drop size.

Introduction Water in oil (W/O) emulsions are regularly used in many food preparations, pharmaceutics and cosmetics. Commonly, these dispersed systems are stabilized by increasing the viscosity of the continuous phase and thus nearly immobilizing droplets. Phospholipids (PL) are widely used emulsifiers as they are gained from natural, sustainable sources1 with approved biocompatibility regarded as a substance which is “Generally Recognized As Safe (GRAS) by the Food and Drug Administration (FDA)2 due to their ubiquitous occurrence in humans as in most organisms. PL are commonly used as emulsifiers for oil in water (O/W) emulsions but are faced with unexplored instability problems in W/O emulsions. This contradicts to the expectations raised by their hydrophilic-lipophilic balance (HLB) value – which for dipalmitoylphosphatidylcholine (DPPC) is around 5 – which indicates their suitability as an W/O emulsifier3. Further arguments to explore their use in W/O emulsification are the high solubility of phospholipids in most oil phases and their molecular shape. The molecular geometry is comparable to a cylinder or cone, 2 ACS Paragon Plus Environment

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depending on the degree of saturation of the fatty acids and the size of the hydrophilic group. It makes them more suitable for W/O than for O/W emulsions when considering interfacial curvatures – a contradiction which has not yet been solved rigorously in the literature4. W/O emulsions consisting of two low-viscous phases emulsified by phospholipids are frequently reported as unstable1,5. However, more stable W/O emulsions based on PL could trigger new applications in a wide range of pharmaceutical and food related products and lead to innovations. The stability of an emulsion is governed by the emulsifier at the interface between continuous and dispersed phase, as well as the viscosity of the continuous phase and density difference of the two immiscible phases6. During the formation, the diffusion speed of the surfactant is crucial to the initial coverage of the interface and therefore for the formation and stability of the emulsion7. PL have a molecular weight of 700 to 800 g/mol and are therefore much slower in diffusion than other common surfactants like e.g. SDS with a molecular weight of 288 g/mol The duration and efficiency of the dispersion process are decisive for the choice of surfactant and vice versa. Mechanical dispersion methods differ significantly in input energy density, depending on the physical principle and residence time. High-shear mixers have a relatively low energy input while high pressure homogenization and ultrasonication provide a higher energy input which makes them especially suitable for fast diffusing surfactants8. During ultrasonication the sample is continuously mixed in a batch or pumped through a chamber

9,10

, while for high

pressure homogenization the number of passages determines the residence time in combination with the mass flow. The optimal processing parameters for a homogenizer are in the high pressure range above 1,000 bar with very fast mass flows and therefore short residence times