Accepted Manuscript Title: PREPARATION AND CHARACTERIZATION OF QUERCETIN-LOADED LIPID LIQUID CRYSTALLINE SYSTEMS Author: A. Linkeviˇci¯ut˙e A. Misi¯unas E. Naujalis J. Barauskas PII: DOI: Reference:
S0927-7765(15)00076-4 http://dx.doi.org/doi:10.1016/j.colsurfb.2015.02.001 COLSUB 6891
To appear in:
Colloids and Surfaces B: Biointerfaces
Received date: Revised date: Accepted date:
15-10-2014 22-1-2015 1-2-2015
Please cite this article as: A. Linkeviˇci¯ut˙e, A. Misi¯unas, E. Naujalis, J. Barauskas, PREPARATION AND CHARACTERIZATION OF QUERCETIN-LOADED LIPID LIQUID CRYSTALLINE SYSTEMS, Colloids and Surfaces B: Biointerfaces (2015), http://dx.doi.org/10.1016/j.colsurfb.2015.02.001 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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PREPARATION AND CHARACTERIZATION OF QUERCETIN-LOADED
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LIPID LIQUID CRYSTALLINE SYSTEMS
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A. Linkevičiūtė1,2,*, A. Misiūnas2, E. Naujalis1,2, J. Barauskas3
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LT-03225 Vilnius, Lithuania
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Department of Analytical and Environmental Chemistry, Vilnius University, Naugarduko 24,
State Research Institute, Center for Physical Sciences and Technology, A. Goštauto 11,
LT-01108 Vilnius, Lithuania 3
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Biomedical Science, Faculty of Health and Society, Malmö University, SE-20506 Malmö,
Sweden
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E-mail addresses:
[email protected],
[email protected],
[email protected],
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[email protected] an
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*Corresponding author: Ausra Linkeviciute, State Research Institute, Center for Physical
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Sciences and Technology, A. Gostauto 11, LT-01108 Vilnius, Lithuania. Tel.: +370 5 2612758;
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Fax. +370 5 2627123. E-mail addresses:
[email protected] 17
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Abstract
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The aim of the present study was to investigate mixtures of soy phosphatidylcholine (SPC) and
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glycerol dioleate (GDO) as encapsulation matrices for antioxidant quercetin. The effects of
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quercetin loading into non-aqueous formulations, non-lamellar liquid crystalline phases and their
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colloidal dispersions were studied by using synchrotron small angle X-ray diffraction, dynamic
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light scattering, cryogenic electron microscopy and high performance liquid chromatography.
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Quercetin incorporation is discussed in the context of lipid aggregation behavior, self-assembled
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nanostructure and chemical stability. The obtained results show that SPC/GDO-based
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formulations can incorporate relatively high amounts of quercetin and serve as liquid crystalline
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delivery vehicles in the form of bulk phases or colloidal dispersions.
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Keywords:
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Quercetin, lipid liquid crystals, non-lamellar phases, lipid liquid crystalline nanoparticles, small
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angle X-ray diffraction, cryo-TEM, HPLC.
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1.
Introduction
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Flavonoids belong to the large and diverse group of polyphenolic compounds characterized by a
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common benzo-γ-pyrone structure and are ubiquitously present in plants [1, 2]. During recent
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years, these compounds are of growing interest due to broad pharmacological features, including
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anti-thrombotic, anti-inflammatory, anticancer and immunostimulator activities [3-5]. Moreover,
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in the human diet quercetin (QU) (3,3´,4´,5,7-pentahydroxyflavone) is one of the most abundant
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natural flavonoid, which antioxidant activity is higher than for the other well-known antioxidant
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molecules, i.e. ascorbylpalmitate, trolox and rutin [6, 7]. Besides antioxidant properties,
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quercetin also possesses anticancer, antiviral and antiallergic features [8, 9]. The anticancer
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properties of this natural antioxidant have been proved by in vivo and in vitro experiments which
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demonstrated that QU has a significant role in inhibition of breast, colon, prostate, ovary,
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endometrium, and lung tumor cancer cells [10-12].
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The main limitation in the therapeutic employment of QU is its low water solubility and
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instability in physiological medium which restricts its use to oral route of administration [13]. In
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order to extend clinical applications and to solve the solubility, instability, and bioavailability
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issues of QU it is necessary to develop an appropriate flavonoid delivery system by
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entrapping/adsorbing QU into the more favorable environment. A variety of different QU
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immobilization/incorporation strategies, such as using emulsions [14-16], nanosuspensions [17],
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microcapsules [18, 19], solid lipid nanoparticles [20-24], have been suggested to overcome at
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least some of these limitations. Much attention has been also made to a various types
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phospholipid-based vesicles and liposomes as potential vehicles for entrapment and delivery of
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QU [3, 25-30]. An advantage to use phospholipids is their amphiphilic nature that can modify the
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solubility behavior and rate of drug release and enhance drug absorption across the biological
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barriers [3, 31, 32]. However, complex preparation routines and low encapsulation capability of
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poor water soluble molecules restricts the potential application of vesicles and liposomes for the
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entrapment and delivery of QU.
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It was known for years that many phospholipids, such as phosphatidylcholines, spontaneously
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form flat lipid bilayers and fragmented vesicular particles in aqueous dispersions. It was early on
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also observed that a variety of polar lipids and their mixtures can self-assemble into different
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non-lamellar liquid crystalline (LC) phases in water under solution conditions similar to that of
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biological systems [33]. Non-lamellar LC phases, such as sponge, hexagonal, and cubic,
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typically comprise of hydrophilic and hydrophobic, which may be continuous or discrete, thus
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forming either mono- or bicontinuous networks, depending on the molecular nature of the lipid
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or lipid mixture [34]. They have generally much higher surface area per volume than lamellar
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structures, may better solubilize hydrophobic, hydrophilic and also amphiphilic molecules [35-
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37], and can be used as delivery systems for peptides, proteins and food bioactives [38, 39].
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Recently, a versatile drug delivery lipid system based on soy phosphatidylcholine (SPC) and
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glycerol dioleate (GDO) has been developed. It offers optimal functional properties, such as
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bioadhesion and controlled release, good drug loading ability, enhanced flexibility of self-
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assembly that can be tuned in the range from lamellar to various reversed non-lamellar LC
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phases [40, 41]. Furthermore, in the presence of polymeric particle stabilizer Polysorbate 80
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(P80) SPC/GDO mixtures can be easily dispersed into non-lamellar liquid crystalline
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nanoparticles (LCNPs) with controllable small size and inner morphology making such
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nanoparticles suitable for parenteral administration routes [42-44].
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Here we investigated the potential of SPC/GDO-based non-aqueous lipid formulations, non-
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lamellar LC phases and LCNPs as delivery vehicles of QU. To our best knowledge, only one
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study of QU entrapment into non-lamellar lipid-based LC system has been previously reported.
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Murgia and co-workers [45] have been studied the incorporation of QU into glycerol monooleate
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(GMO)-based bicontinuous cubic LCNPs and demonstrated that small amounts of QU does not
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alter size, charge and inner nanostructure of the nanoparticles. In this study several mono-, di-
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glyceride and SPC/GDO-based non-lamellar LC phase forming lipid compositions were explored
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in the context of their ability to solubilize QU. The main objective of the study was to elucidate
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the effects of QU solubilization on the nanostructure of lipid-based non-lamellar LC phases and
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their LCNPs as a function of lipid composition and QU concentration by means of polarized
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light microscopy, synchrotron small-angle X-ray diffraction (SAXD), dynamic light scattering
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(DLS) and cryogenic transmission electron microscopy (cryo-TEM). Finally, chemical stability
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of entrapped QU in different LC systems has been evaluated by using HPLC.
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2.
Materials and methods
2.1.
Materials
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Quercetin (QU) (CAS-No.117-39-5; purity ≥ 98.0%) was purchased from Sigma-Aldrich.
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Diglycerolmonooleate (DGMO) (Rylo PG 29) and glycerol dioleate (GDO) (Rylo PG 19) from
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Danisco, commercial mixture of mono-, di- and triglycerides denoted as Capmul GMO-50 from
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Abitec, polysorbate P80 (P80) from Croda, glycerylmonooleyl ether (GME) from Niko
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Chemicals, and soy phosphatidylcholine (SPC) denoted as SPC S100 from Lipoid were used as
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received. Methanol (MeOH) and acetonitrile (ACN) was purchased from Sigma-Aldrich, 99.7 %
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ethanol (EtOH) from either Merck or Solveco, and formic acid from Scharlau Chemie. All
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chemicals were of analytical grade. The water used was passed through the NANOpure Infinity
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(Branstead) water purification system.
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2.2.
Preparation of lipid-based formulations
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Non-aqueous lipid formulations were prepared by mixing appropriate amounts of lipid
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components (DGMO, GDO, Campul GMO-50, GME and SPC) without and in the presence of
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co-solvent ethanol to facilitate mixing. Lipid mixtures were then placed on a roller mixer at room
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temperature for 24 h until mixed completely. Prepared lipid formulations were kept at room
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temperature (RT) until further use. QU containing formulations were prepared by weighing
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appropriate amounts of QU and non-aqueous lipid formulations and placing on a roller mixer for
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24–48 h at RT until homogeneous mixture was obtained. Visual inspection between cross-
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polarizers and light microscopy were used to inspect samples for the presence of undissolved
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QU. In this manuscript, the concentration of QU is always expressed as wt% of the total
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formulation weight. Component ratios of lipid formulations are also always expressed in wt%.
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2.3.
Preparation of bulk lipid liquid crystalline (LC) phases
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LC phases were prepared by injection of QU containing non-aqueous lipid formulations (about
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300 mg) into water at the formulation/water weight ratio of 5/95. Samples were immediately
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sealed and left to equilibrate at RT in still standing vials for at least 10 days before experiments.
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2.4.
Preparation of lipid liquid crystalline nanoparticle (LCNP) dispersions
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Non-aqueous lipid formulations for LCNP preparation were prepared by mixing appropriate
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amounts of lipids (SPC/GDO = 35/65, 60/40 wt%), polymeric particle stabilizer P80, and ethanol
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at fixed (SPC+GDO)/P80/EtOH weight ratio of 75/15/10. QU containing formulations were
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prepared by weighing appropriate amounts of QU and mixing with non-aqueous formulations at
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QU concentration of 0.5, 1.0, 2.0 and 4.0 wt%. Lipid mixtures were placed on a roller mixer for
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24 h until mixing was complete, and were then dispersed in 82.5 wt% water (17.5 wt% LCNPs).
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The aqueous dispersions were immediately sealed, shaken, and left to vortex for 72 h on a
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mechanical mixing table at 300 rpm at RT. Prepared dispersions were stored at RT until further
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use.
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2.5.
Polarizing light microscopy (PLM)
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The texture and temperature-induced phase transitions of LC phases were examined by a
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polarizing microscope Optiphot equipped with a digital camera DS-2Mv (Nikon) and a heating
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table Analysa LTS350 (Linkam). A small specimen of sample was placed between two
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microscope slides and their edges were immediately sealed with a thermo stable silicon grease to
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prevent evaporation of water from the specimen. A stepwise increase of temperature (typically
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5 °C in every step with a heating rate of 1 °C/min) was used to induce phase transitions. QU
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loaded lipid LCNPs were examined at RT by a polarizing microscope DM 750 (Leica) equipped
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with a digital camera MC170 (Leica).
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2.6.
Small-angle X-ray diffraction (SAXD)
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The nanostructure of LC phases was studied using synchrotron SAXD measurements, which were performed at the I911-4beamline at MAX-lab (Lund University, Sweden), using a 1M
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PILATUS 2D detector containing a total of 981 x 1043 pixels. Bulk lipid LC samples were
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mounted between kapton windows in a steel sample holder at the sample to detector distance of
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1917 mm. Diffractograms were recorded with a wavelength of 0.91 Å and the beam size of 0.25
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× 0.25 mm (full width at the half-maximum) at the sample. Temperature control within 0.1 °C
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was achieved using computer controlled Julabo heating circulator F12-MC (Julabo Labortechnik
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GMBH, Seelbach, Germany). The experiments were performed successively at 25, 35, 45, 55,
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and 65 °C with a 60 s exposure time at each temperature and a wait of 10 minutes between
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temperature steps. The resulting CCD images were integrated and analyzed using the Fit2D
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software provided by Dr. A. Hammersley [http://www.esrf.fr/computing/scientific/FIT2D].
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Silver behenate calibrated sample-to-detector distance and detector positions were used.
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Particle size and zeta potential
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LCNP particle size distributions and zeta potentials were measured using Zetasizer Nano ZS
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analyzer from Malvern Instruments. For particle size distributions the disposable cuvette filled
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with 1 mL of LCNP dispersion, which was first diluted to 99.5 wt% of water. The obtained data
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were averaged from 30 measurements (10 s each). The refractive indices used for lipid particles
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and water were 1.48 and 1.33, respectively. The particle size distributions were reported as
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intensity-averaged. The surface charge of the particles was measured using disposable zeta cells
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filled with 1 mL of LCNP dispersion which was first diluted to 99.5 wt% of water. The zeta
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potential was calculated using the Smoluchowski approximation for dispersion in water with
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viscosity of 0.8872 cP, refractive index of 1.33, and dielectric constant of 78.5.
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2.8.
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Cryogenic transmission electron microscopy (Cryo-TEM)
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Lipid LCNP dispersions for electron microscopy were prepared in a controlled environment
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vitrification system to ensure stable temperature and to avoid loss of water during sample
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preparation. The climate chamber temperature was kept at 25−28 °C, and the relative humidity
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was kept close to saturation to prevent sample evaporation. The samples were prepared by
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placing 5 μL of LCNP dispersion on lacey carbon filmed copper grids and gently blotted with
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filter paper to obtain a thin liquid film (20−400 nm) on the grid. Immediately after blotting, the
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grids were rapidly plunged into the liquid ethane at −180 °C to vitrify the water-rich samples to
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prevent ice crystal formation and to preserve the internal crystalline structure. The vitrified
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specimens were stored in liquid nitrogen (−196 °C) until measurements. An Oxford CT3500
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cryo-holder and its work station were used to transfer the samples into the electron microscope
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(Philips CM120 BioTWINCryo) equipped with a post-column energy filter (Gatan GIF100). The
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acceleration voltage was 120 kV, and the working temperature was kept below −180 °C. The
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images were recorded digitally with a CCD camera under low electron dose conditions.
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2.9.
QU stability study
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The chemical stability of QU entrapped in different lipid non-aqueous formulations, LC phases
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and LCNP dispersions were monitored for 3 months. During stability study all samples were
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kept at RT in the darkness. For the evaluation of the residual QU concentration a portion of the
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sample (about 10-15 mg) was collected at predetermined time points (1, 15, 30, 60 and 90 days),
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dissolved in ACN:MeOH (1:1 v/v) solvent mixture at the lipid sample to solvent weight ratio of
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1:100 and immediately analyzed using HPLC. Each sample was analyzed in triplicate.
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2.10.
High performance liquid chromatography (HPLC)
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QU concentration was determined using an Agilent HPLC 1100 Series (Agilent Technologies,
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USA) chromatography system equipped with a quaternary pump, a vacuum degasser module, a
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manual injector with a 20 µL sample loop, a temperature controlled column compartment and a
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diode array detector (DAD) set at 370 nm. Chromatographic separation was achieved using a
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Zorbax Eclipse XDB–C18 (5 µm, 150×4.60 mm, Agilent Technologies, USA) reversed phase
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column coupled with an Eclipse XDB–C18 guard column (5 µm, 12.6×4.6 mm, Agilent
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Technologies, USA). Determination was carried out in a solvent system of methanol–formic
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acid–water as previously described, with minor modifications [46]. Data were collected and
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processed using a ChemStation software version B.01.03. The obtained values with standard
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methanolic QU solutions showed linearity over the concentration range of 0.1–100 μg/g with a
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correlation coefficient (r2) of 0.999. The quantification limit in the HPLC assay was 0.1 μg/g and
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standard deviation under repeatability conditions was no more than 5.6% in all concentrations
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tested. The calibration curves for quantification of QU in QU-loaded non-aqueous lipid
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formulations, LC phases and LCNP dispersions were prepared using QU standard with
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respective lipid compositions. The obtained results of the quantification of various formulations
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are summarized in Table S1 (Supporting information).
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3.
Results and discussions
3.1.
Solubility of QU in lipid formulations
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It is known that some poorly water soluble compounds like QU may also have low solubility in
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lipid excipients due to different physical chemical reasons [31]. As shown in other lipid- and
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amphiphile-based systems, such as microemulsions [19], liposomes [26], lecithin-chitosan
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nanoparticles [23] and solid lipid nanoparticles [24], the maximum solubility of QU is quite low
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and often is in the order of 0.5 wt%, which can be somewhat improved by using additional
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polymeric surfactants and/or co-solvents [16].
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Therefore, before further experiments several non-lamellar LC phase forming non-aqueous lipid
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mixtures were investigated with respect to their ability to solubilize QU. First, binary mixtures of
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DGMO/GDO (85/15 and 60/40) (here and everywhere in the text formulation compositions are
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expressed in wt%), DGMO/Capmul GMO-50 (85/15 and 60/40), DGMO/GME (85/15 and
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60/40) and SPC/GDO (50/50) were explored. The results have shown that independently from
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lipid ratio the solubility of QU in all tested mono- and di-glyceride-based mixtures was very low
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and varies between 0.3 and 0.4 wt%. The addition of up to 10 wt% of ethanol (in respect to total
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lipid) did not improve the solubility of QU in neither of the formulations. The observed solubility
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in mixtures of mono- and di-glycerides was in line with previous results in similar systems. The
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solubility of QU in commercial mixtures of long chain monoglycerides (i.e., Miglyol 812,
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Capmul MCM, Labrafil 1944) is usually well below 1 wt% [16].
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Much higher solubility of QU was found for the mixtures of SPC and GDO. Since solvent free
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SPC/GDO mixtures prepared at equal lipid weight ratio were difficult to mix and were very
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viscous their ability to solubilize QU were only tested in the presence of small amount of ethanol
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at fixed Lipid/EtOH weight ratio of 90/10. SPC/GDO composition in the formulations was
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varied between 60/40 and 35/65. Independently on lipid ratio about 5 wt% of QU was soluble in
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all formulations. From the solubility test it may be concluded that lipid mixtures composed of
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exclusively mono- and di-glycerides with and without EtOH have very limited ability to
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solubilize QU which may be increased by about 10-20 times with the introduction of SPC into
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the mixture. Considering these results, SPC/GDO-based formulations containing up to 4 wt% of
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QU and 10 wt% EtOH were selected for further studies.
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3.2.
SPC/GDO-based LC phases with entrapped QU
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The aim of this part was to investigate the effects of QU on the aggregation behavior of fully
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hydrated non-lamellar bulk LC phases of SPC/GDO. As shown in recent study, the aqueous
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phase behavior of mixtures of SPC and GDO is rather complex [40]. At 25 °C with increasing
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GDO content fully hydrated SPC/GDO mixtures in water form the following LC phase
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sequence: lamellar (Lα) reversed 2D hexagonal (H2, up to 62.5/37.5) reversed micellar
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cubic of Fd m space group (50/50 – 45/55) reversed 3D hexagonal of P63/mmc space group
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(42/58 – 40/60) unresolved “intermediate” (39/61 – 37/63) Fd m (35/65 – 22.5/77.5)
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reversed micellar solution (L2, from 20/80). In this study, the effects of QU on the nanostructure
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of different LC phases were investigated at four fixed SPC/GDO weight ratios (60/40, 50/50,
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40/60 and 35/65) and four temperatures (25, 35, 45 and 55 °C).
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Figure 1 shows SAXD data of fully hydrated SPC/GDO (60/40 and 35/65) LC phases with
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entrapped 0.0, 0.5, 1 and 4 wt% of QU as a function of temperature.
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As seen from Figure 1a, at weight ratio of 60/40 and at 25 °C SPC/GDO forms H2 LC phase,
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which features three strong Bragg reflections positioned in ratios 1: 3: 4. At 45 °C another
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coexisting LC phase, most likely Fd m cubic, also starts to form what is evidenced by the
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appearance of additional peaks. However, independently on temperature the appearance of all
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diffractograms is practically unaffected by the presence of up to 4 wt% of QU (Figures 1b-1d).
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In addition, the calculated lattice parameter (a) for this LC phase is constant regardless QU
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concentration and temperature and only slightly varies between 6.6 and 6.7 nm. This shows that
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H2 phase prepared at high SPC content is quite robust and can accommodate relatively high
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amounts of hydrophobic QU without changing nanostructure.
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At weight ratio of 35/65 and 25 °C SPC/GDO self-assembles into ordered reversed micellar
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Fd m cubic phase which is clearly characterized by the appearance of first 9 Bragg peaks
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located at relative positions in ratios 3: 8: 11: 12: 16: 19: 24: 27: 32 (Figure 1e).
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Contrary to H2 phase, the structure of Fd m cubic phase prepared at low SPC content is rather
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sensitive to QU entrapment and temperature. At 45 °C it starts to “melt” and at 55 °C completely
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transforms into unordered reversed micelles (L2), which is corroborated by the disappearance of
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the Bragg diffraction peaks and their smearing into two broad diffuse diffraction features. The
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entrapment of QU even further disturbs ordered structure of the Fd m cubic phase. At 0.5 and 1
281
wt% of QU ordered cubic phase is almost fully transformed into unordered phase at 45 °C
282
(Figures 1f and 1g). Moreover, only a fraction of the Fd m cubic arrangement with entrapped 4
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wt% of QU is present already at 35 °C (Figure 1h). As shown in Figure S1 (SI), both the
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entrapment of QU and temperature considerably enlarge the unit cell dimensions of the cubic LC
285
phase at the SPC/GDO ratio of 35/65. With increasing QU concentration from 0 to 4 wt% the
286
calculated a value increases from 14.9 to 15.6 nm at 25 °C. At elevated temperatures a further
287
increases and reaches maximum value of about 15.9 nm at 1 wt% of QU and 45 °C before
288
complete transformation of ordered Fd m structure into unordered L2 phase.
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The observed disordering effect of QU may be explained by reasonable assumption that in the
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LC phase water insoluble hydrophobic QU molecule is preferentially located between lipid
291
hydrocarbon chains. Accommodation of QU in the hydrophobic regions between ordered
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reversed micelles increases lipid chain packing stress and distance between micelles resulting in
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slightly larger a values. At some point, further accommodation of QU and unit cell dimension
294
increase is not possible without transformation into unordered L2 phase. At higher temperatures
295
this process occurs at lower QU concentrations due to additional temperature induced lipid chain
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packing disorder. Similar phase behavior trends were also observed for the SPC/GDO Fd m
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cubic phases with entrapped benzydamine, lidocaine and granisetron [41].
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In addition, less extensive but similar disordering effects of QU were also observed for the LC
299
phases prepared at intermediate SPC/GDO weight ratios of 50/50 and 40/60 (Figure S2, SI).
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Here, the entrapment of QU has little effect on the unit cell dimensions of the LC phases.
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However, in both cases QU decreases phase transition temperatures of ordered LC phases into L2
302
phase, which is observed for temperatures higher than 45 °C. Here it may be concluded that
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effect of QU on the nanostructure of the bulk SPC/GDO LC phases is lipid weight ratio-
304
dependent. Thus, at weight ratio of 60/40, H2 LC structure remains unaffected in the presence of
305
QU. In contrast, at weight ratio of 35/65 the structure of the cubic Fd m phase is very sensitive
306
to QU concentration increase and starts transformation into L2 phase already at 35 °C and 4 wt%
307
of QU. Finally, LC phases at the SPC/GDO weight ratios of 50/50 and 40/60 show moderate
308
sensitivity to QU.
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3.3.
SPC/GDO/P80-based LCNPs with entrapped QU
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The aim of this part was to investigate the effects of QU on size and stability of the dispersed
313
SPC/GDO/P80-based liquid crystalline nanoparticles (LCNPs). Dispersions were prepared at
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SPC/GDO weight ratios of 60/40 and 35/65 in the presence of polymeric stabilizer P80 at fixed
315
lipid to polymer ratio. Dispersions containing up to 4 wt% of QU were prepared and
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characterized with regards to particle size, charge and morphology.
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Figure 2 shows obtained particle size distributions as a function of QU concentration. As seen
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from Figures 2a and 2b, at low QU concentrations all LCNP dispersions are well-defined
319
displaying monomodal size distributions with polydispersity indices ranging between 0.13 and
320
0.16 µm. At 2 and 4 wt% of QU additional larger aggregates of about 5 m appear in the
321
dispersions prepared at both SPC/GDO ratios. Sample examination under polarized light
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microscope reveals that these larger aggregates are small needle-like crystals phase separated
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from LCNPs (Figure S3, SI). Since crystals have distinct yellow color (seen in microscope under
324
nonpolarized light), there is good reason to assume that they are formed exclusively by QU. This
325
show that SPC/GDO/P80 LCNPs can homogeneously entrap only up to 2 wt% of QU when
326
compared to 4-5 wt% of QU in the bulk LC phases. This difference may be attributed to a very
327
large surface-to-volume ratio of the particles and exposure to the excess aqueous phase creating
328
more defects and crystallization centers for QU. In addition, one cannot exclude that presence of
329
P80 may also change QU solubilization properties and induce precipitation. Note however, that
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QU crystallization and phase separation does not affect LCNP own size distribution
331
characteristics. The colloidal stability of the LCNP dispersions with entrapped QU is also good.
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Only minor changes in the size distributions are observed after 3 months of storage at RT (Figure
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2, dotted lines).
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Figure 3 demonstrates that the obtained mean particle size clearly depends on both lipid ratio and
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QU concentration. Thus, LCNPs at SPC/GDO ratio 60/40 are slightly larger with the mean
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particle size increasing from 140 to 210 nm as QU concentration is increased from 0 to 4 wt%. In
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contrast, LCNPs at SPC/GDO ratio 35/65 are smaller with the mean particle size ranging from
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about 80 to 110 nm. Unfortunately, we cannot explain such an effect of QU on the particle size
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considering only bulk phase behavior and nanostructural features of the LC phases. Since LCNP
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dispersions were prepared by mechanical agitation we believe that the entrapment of QU may
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slightly increase cohesion forces within LC structure and/or influence monocrystalline domain
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size. Therefore, more energy is required to brake LC phase with entrapped QU into smaller
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particles. In addition, LCNP zeta potential remains unaffected by the entrapment of QU and is
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about -16 and -10 mV for particles at SPC/GDO ratio 60/40 and 35/65, respectively. Considering
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size and surface to volume ratio differences the surface charge density of the particles is similar
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at both SPC/GDO ratios.
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Representative cryo-TEM images shown in Figure 4 together with the measured SAXD profiles (Figure S4, SI) give further insights into QU-loaded particle morphology and
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nanostructure. Overall, the observed particle sizes are consistent with DLS measurements. At
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SPC/GDO ratio 60/40 particles are larger and characterized by a denser inner core and a less
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dense shell comprising lamellar and “sponge”-like petals (Figures 4a and 4b). The observed
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particle morphology is comparable with those previously prepared at similar SPC/GDO weight
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ratio and P80 content without QU [47]. The obtained LCNP SAXD profiles as a function of QU
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concentration in Figure S4a (SI) are almost identical showing negligible effect of QU on particle
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nanostructure and are in line with the bulk phase behavior observations (Figures 1a-1d). The data
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show only weak diffuse scattering which is not surprising since it is know that dispersion agent
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P80 has a disordering effect on the internal SPC/GDO LCNP nanostructure [43]. Only small
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shoulder appearing at q value of about 1.1 nm-1 can be observed which position may be related to
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the first reflection of the undispersed H2 phase (Figures 1a-1d). Regardless of this relation SAXD
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data suggest that in dispersed state the long-range order of the H2 LC arrangement in the particle
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core is almost or completely lost.
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As shown in Figures 4c and 4d, particles prepared at SPC/GDO 35/65 ratio are smaller in size
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with more or less even density and hardly any noticeable features in the interior. This is also
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reflected in the SAXD profiles shown in Figure S4b where only weak scattering pattern is
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observed without any indications of the Bragg diffraction. From inspection of several dozen of
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cryo-TEM images it may be also concluded that GDO-rich particles, with entrapped QU do not
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possess pronounced swollen coronas of multiply connected bilayers which are always present for
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SPC/GDO LCNPs prepared at high fraction of P80 [47, 48]. The observed difference may be
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related to the bulk phase behavior where even low concentrations of QU were able to induce
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Fd m phase transformation towards more reversed L2 phase (Figures 1e-1h). Most likely, in the
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dispersed LC state the addition of small amount of QU is enough to allow more homogeneous
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distribution of components within the particle and to prevent the formation of lamellar-like
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corona.
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3.4.
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LCNPs
QU stability in SPC/GDO non-aqueous formulations, bulk LC phases and dispersed
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One of the important aspects of delivery formulations is the chemical stability of active
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substance. Therefore, HPLC was used to evaluate the chemical stability of QU entrapped in all
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three studied SPC/GDO-based systems: non-aqueous formulations, LC phases and LCNP
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dispersions. Samples were prepared at two different SPC/GDO weight ratios containing 0.5 and
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1 wt% of QU in respect to dry formulation weight.
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For up to 90 days QU showed very good chemical stability when solubilized in non-aqueous
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SPC/GDO-based formulations (Figures 5a and 5d). About 85–90% of QU is retained
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independently on lipid composition and QU concentration. Introduction of water and hydration
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of the formulations into bulk LC phases (Figures 5b and 5e) and LCNP dispersions (Figures 5c
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and 5f) had more pronounced effect on the stability of QU. Gradual but significant loss of QU
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content upon storage was observed in both systems. In the LC phases prepared at SPC/GDO ratio
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35/65 QU content decreased to about 65%, whereas only 25–40% of QU was found after the end
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of the study in the LC phases prepared at lipid weight ratio of 60/40. Such substantial difference
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may be explained by the fact that SPC used in this study contain considerable amounts of linoleic
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(C18:2) fatty acid chains. It is known that degree of unsaturation plays positive role in the lipid
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autoxidation processes, in which highly reactive primary and secondary lipid oxidation products
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are produced [49]. In SPC-rich LC phases larger amounts of reactive species may be formed,
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which interact and chemically degrade QU when compared to the GDO-rich LC phases where
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oleic fatty acid residues are dominant.
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The lowest stability of QU was found in the LCNP dispersions where only 30–45% was
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recovered after 90 days. Here, GDO-rich LCNPs showed only slight improvement over SPC-rich
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dispersions. Most likely, P80 which was used to stabilize LCNPs dispersions also influence lipid
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autoxidation complex processes and further decrease stability of QU. On the other hand, water
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penetration ability and diffusion of lipid components is less restricted within small particle when
402
compared to macroscopic bulk LC phase and may accelerate degradation of QU.
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Overall, QU shows good chemical stability when loaded in SPC/GDO-based non-aqueous
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formulations for up to 3 months of storage at room temperature. On the other hand, hydrated
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formulations (bulk LC phases and LCNP dispersions) show reduced QU chemical stability and
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therefore are not suited for a long-term shelf storage but can still serve as suitable delivery
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systems if are formed via in situ hydration of non-aqueous formulation (in case of LC phases) or
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freshly produced just prior application/administration (in case of LCNP dispersions). For real-life
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application, further studies on parameter optimization (e.g., sterilization, oxygen concentration,
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temperature, pH, additives and other) in order to extend long-term stability of the formulations
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will be needed.
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3.
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Conclusion
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The present study demonstrates the potential of liquid crystalline structures forming SPC/GDO
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lipid formulations as encapsulation and delivery matrices of QU. The results have shown that up
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to 5 wt% of QU can be effectively solubilized in non-aqueous SPC/GDO formulations by using
417
small amounts of EtOH as solvent. Prepared formulations are stable and have minimal effect on
418
the chemical stability of QU for few months. Upon hydration non-aqueous formulations can
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easily self-assemble into non-lamellar bulk LC matrices with different nanostructures. The effect
420
of QU on the nanostructure of LC phases is lipid composition dependent. At high SPC content,
421
the entrapment of QU has practically no effect on the nanostructure of H2 phase at
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physiologically relevant temperatures. At low SPC content, QU slightly increases the unit cell
423
dimensions of the reversed micellar Fd m cubic phase and promotes the formation of reversed
424
micellar solution at elevated temperatures. Finally, concentrated and colloidally stable non-
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lamellar SPC/GDO-based LCNP dispersions containing up to 2 wt% of entrapped QU can be
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easily prepared in the presence of stabilizer P80. Dispersion particle size can be tuned in the
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range of about 80 – 210 nm by changing lipid composition and entrapped QU concentration.
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Author’s contributions
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Linkeviciute A. executed the experiment, extracted the data and wrote the initial draft of the
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manuscript. Barauskas J. supervised the research, analysis of data and interpreted the results
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obtained from the models. Misiunas A. technical assistance, while Naujalis E. was co-
434
supervising the research.
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Conflict of interest
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The authors declare that they have no conflict of interest.
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Acknowledgements
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The authors acknowledge the Swedish synchrotron X-ray facility MAX IV Laboratory for
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allocated beamtime at the I911-4beamline and Ana Labrador for technical support during
443
experiments. Authors also thank Gunnel Karlsson and Viveka Alfredsson at Lund University for
444
their help with the cryo-TEM imaging. AL acknowledges financial support from the Research
445
Council of Lithuania "Promotion of Student Scientific Activities" (VP1-3.1-ŠMM-01-V-02-003).
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446 447
FIGURES
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Figure 1. SAXD profiles of SPC/GDO mixtures in excess water prepared at lipid weight ratios
450
of 60/40 (a-d) and 35/65 (e-h) as a function of QU concentration (0, 0.5, 1.0 and 4.0 wt%) and
451
temperature (25, 35, 45 and 55 °C). Arrows in (e) and (h) show indexing of the reflections from
452
the reversed Fd m cubic phase. An explanation is given in the text.
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Figure 2. Particle size distributions of freshly prepared (solid lines) and 3 months old (dotted
455
lines) SPC/GDO/P80 LCNPs at SPC/GDO weight ratios of 60/40 (a) and 35/65 (b) as a function
456
of QU concentration. Dispersions were prepared at fixed lipid/P80 weight ratio of 75/15 in
457
82.5% water.
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Figure 3. Dependence of mean particle size of the SPC/GDO/P80 LCNPs on QU concentration.
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Dispersions were prepared at SPC/GDO weight ratios of 60/40 (open circles) and 35/65 (filled
461
circles). The lines are drawn to guide the eye.
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Figure 4. Representative cryo-TEM images of SPC/GDO/P80 LCNPs with entrapped 1 wt% QU
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prepared at SPC/GDO weight ratios of 60/40 (a and b) and 35/65 (c and d). Dispersions were
465
prepared at fixed lipid/P80 weight ratio of 75/15 in 82.5% water.
466 467
Figure 5. Chemical stability of QU (normalized to initial) entrapped in SPC/GDO-based non-
468
aqueous formulations (a and d), LC phases (b and e) and LCNP dispersions (c and f). Samples
469
were prepared at fixed SPC/GDO weight ratios of 60/40 (open symbols) and 35/65 (filled
470
symbols) containing 0.5 (a-c) and 1.0 wt% (d-f) of QU in respect to dry weight. Results are
471
represented as mean values ± standard deviation (n=3).
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We examine the mixtures of SPC and GDO as encapsulation matrices for quercetin (QU). SPC/GDO-based formulations can incorporate relatively high amounts of QU. At high SPC content, the loaded QU has no effect on the nanostructure of H2 phase. At low SPC content, QU slightly increases the unit cell dimensions of Fd m phase.
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*Graphical Abstract (for review)
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