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Colloids and Surfaces B: Biointerfaces 103 (2013) 550 557
Contents lists available at SciVerse ScienceDirect
Colloids and Surfaces B: Biointerfaces
jou rna l h om epa g e: www.elsev ier .com/ locate /co lsur
fb
oloxamine micellar solubilization of -tocopherol for topical
ocular treatment
ndreza Ribeiroa, Isabel Sandez-Machob, Matilde Casasb, Susana
Alvarez-Prezb,armen Alvarez-Lorenzoa, Angel Concheiroa,
Departamento de Farmacia y Tecnologa Farmacutica, Facultad de
Farmacia, Universidad de Santiago de Compostela, 15782 Santiago de
Compostela, SpainDepartamento de Qumica Fsica, Facultad de
Farmacia, Universidad de Santiago de Compostela, 15782 Santiago de
Compostela, Spain
r t i c l e i n f o
rticle history:eceived 30 July 2012eceived in revised form 4
October 2012ccepted 18 October 2012vailable online 14 November
2012
eywords:-Tocopheroletronic 1107ataractscular drug deliveryA
isotherm
a b s t r a c t
Ophthalmic delivery of -tocopherol (TOC), which is the most
active and cost/effective form of vitaminE, is receiving increasing
attention as a way of preventing and treating glaucoma, cataracts,
and dryeye syndrome, among other ocular pathologies. The aim of
this work was to elucidate the possibilityof using poly(propylene
oxide) (PPO) and poly(ethylene oxide) (PEO) block copolymers of
poloxaminefamily (namely, Tetronic 1107) to develop polymeric
micelles that can host TOC, enhance the apparentsolubility and
sustain the release of this vitamin in lachrymal fluid. The
interactions of Tetronic 1107 withTOC were analyzed at the airwater
interface recording the A isotherms at various temperatures,
indi-cating favorable interactions as temperature increased from 10
to 29 C. In 0.9% NaCl aqueous medium,a sharp increase in TOC
solubility was observed when T1107 surpasses the critical micellar
concentra-tion (CMC); the apparent solubility in 20% T1107 being
more than 600-fold and 6000-fold that observedin the absence of
copolymer at 4 and 25 C, respectively. Micelles were characterized
before and after
olymeric micelles loading by means of dynamic light scattering
(DLS) and transmission electronic microscopy (TEM). TOCsustained
release profiles were recorded in Franz-Chien diffusion cells.
After storage for 3 months at 4 C,TOC-loaded T1107 10% micellar
system retained 84% TOC solubilized, which maintained the
antioxidantactivity. Furthermore, the rheological properties of the
micellar systems were not altered either; the vis-coelastic
parameters being dependent on T1107 concentration, which opens the
possibility of developing
ops to
from free-flowing eye-dr
. Introduction
Vitamin E is the common designation of eight naturally occur-ing
closely related compounds, of which -tocopherol (TOC;ppendix Fig.
A.1) is the most active and cost/effective form
1]. This lipophilic vitamin, which can be found in a variety
ofoods, is unstable when exposed to environment factors, such
asxygen, light and temperature [2]. TOC is commonly added
astabilizer to manufactured plastics, cosmetics and drug dosageorms
[3]. In the human body tissues, the levels of TOC are reg-lated
through specific transport proteins and receptors [4,5].itamin E is
rapidly absorbed from the intestinal lumen and read-
ly distributed between lipids and proteins in the cell
membranes,rotecting the cells from oxidative lysis and other free
radicaleactions [6,7]. TOC also has antiproliferative and protein
kinase-suppressing effects, which makes it useful for the
prevention of
therosclerosis, glaucoma, cataracts, and posterior capsule
prolif-ration [8]. Oral and parenteral administration of high doses
ofitamin E, up to 10001200 IU (i.e., 100-fold the recommended
Corresponding author. Tel.: +34 981563100x14886; fax: +34
981547148.E-mail address: [email protected] (A.
Concheiro).
927-7765/$ see front matter 2012 Elsevier B.V. All rights
reserved.ttp://dx.doi.org/10.1016/j.colsurfb.2012.10.055
in situ gelling systems. 2012 Elsevier B.V. All rights
reserved.
daily allowance), leads to TOC levels at retina and vitreous
suit-able for protecting the eye from light-induced pathologies
[5,9].However, these systemic routes do not lead to therapeutic
lev-els in aqueous humor and lens [10]. The direct ocular
applicationof TOC has been shown to be effective for the
prophylaxis andrelief of symptoms of glaucoma, age-related and
diabetic cataracts,dry eye syndrome, and photorefractive keractomy,
and for pro-tection against anti-inflammatory drug-induced
cataracts [1119].In healthy eyes, vitamin E is distributed at a
higher concentra-tion in the nucleus of the ocular lens than in the
cortex. Duringcataract development, this level ratio becomes the
opposite inorder to respond to the higher concentrations of
hydrogen per-oxide in the aqueous and vitreous humors surrounding
the lens[17]. Instillation of vitamin E liposomal and
emulsion-based for-mulations retards cataract progression in humans
and animalswith galactosemia or diabetes [18,20]. Topic
formulations are alsobeneficial for treatment of eye fatigue and
dry-eye syndromeof patients wearing contact lenses [14,21].
Nevertheless, despitethe recent increase in patents [14,21,22], the
number of studies
with ophthalmic formulations is still limited probably
becausesolubilization of vitamin E at sufficient concentration in
stableformulations is a quite challenging issue. In fact, vitamin E
hasbeen proposed as an enduring hydrophobic coating for
medicateddx.doi.org/10.1016/j.colsurfb.2012.10.055http://www.sciencedirect.com/science/journal/09277765http://www.elsevier.com/locate/colsurfbmailto:[email protected]/10.1016/j.colsurfb.2012.10.055
-
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A. Ribeiro et al. / Colloids and Surfac
ontact lenses to regulate drug release on the corneal
surface23].
The aim of this work was to elucidate the possibilities of
devel-ping a polymeric micellar system for the ocular
administrationf TOC. Polyoxyethylated amphiphilic polymers are
particularlyuited for this purpose since they can increase drug
solubility,rolong the time on the precorneal area, and enhance
cornea per-eability, resulting in an increased ocular
bioavailability compared
o other ophthalmic liquid formulations [24]. Unlike other
nano-etric systems, the spontaneous formation of micelles allows
large
uantities to be prepared in reproducible manner. Specifically,he
work was carried with Tetronic 1107 (Appendix Fig. A.1), aoloxamine
block copolymer formed by four poly(propylene oxide)PPO) and
poly(ethylene oxide) (PEO) chains bonded to an ethyl-ne diamine
central group [25]. Compared to related copolymers,etronic 1107
combines two advantageous features: (i) its provenompatibility with
ocular and other tissues [26,27]; in fact, it is cur-ently being
used at 1% in FDA-approved multipurpose solutionsf contact lenses
to prevent protein adsorption [28,29]; and (ii)ts ability to
self-associate in hydrophobic core-hydrophilic shell
icellar structures that solubilize and stabilize apolar drugs
indverse aqueous environments [3034]. The CMC of Tetronic 1107n
0.9% NaCl is as low as 0.4 mM (i.e., 0.6% w/w) and micelles ofhis
poloxamine at 10% can increase up to 27-fold the apparentolubility
of ethoxzolamide, a carbonic anhydrase inhibitor, anduccessfully
pass the HET-CAM biocompatibility test according tohe
NICEATM-ICCVAM protocol [35]. To the best of our
knowledge,olubilization of TOC in polymeric micelles has not been
reportedet. Thus, as a first step, the interaction of Tetronic 1107
with TOCas analyzed at the airwater interface with the aim of
obtainingredictive information on the performance of the mixed
systemst bulk, namely the capability of the micelles to host TOC
and thehysical stability of the vitamin E-loaded micelles under
dilution36]. Then, the effect of copolymer concentration on the
solubilityf TOC was examined. Micelles were characterized, before
and afteroading, by means of dynamic light scattering (DLS) and
transmis-ion electronic microscopy (TEM). TOC release rate was
evaluatedsing Franz-Chien diffusion cells. Finally, physical
stability of theicelles and antioxidant activity of TOC throughout
three months
torage were evaluated in order to further elucidate the
feasibilityf poloxamine-based systems as ocular formulations.
. Materials and methods
.1. Materials
DL--tocopherol (TOC) (purity >98%) and
2,2-diphenyl-1-icrylhydrazyl (DPPH) were from Sigma Aldrich (St.
Louis, MO,SA). Tetronic 1107 (T1107, Mw 15,000, 70% PEO, 60 EO and
20O units per each four arms) was from BASF (New Milford, CT,SA).
Tween 80 was from Panreac (Barcelona, Spain). Purified wateras
obtained by reverse osmosis (resistivity >18.2 M cm;
MilliQ,illipore, Spain). Other reagents were of analytical
grade.
.2. A isotherms
The surface pressure was measured using a Wilhelmy plateade from
chromatography paper (Whatman Chr1, UK) as the
ressure sensor (accuracy of 0.1 mN/m) in a single
barrierpparatus (NIMA 611, UK) of total area 550 cm2, placed on an
anti-ibration table. Prior to experiments, the trough was cleaned
with
hloroform and ethanol and rinsed with water. The monolayer
sta-ility was verified by monitoring the change in surface
pressurehile holding the area constant. The subphase was purified
water
nd the temperature was set at 10, 20, 25 or 29 C. Solutions
of
iointerfaces 103 (2013) 550 557 551
TOC (0.1 mg/mL) and of copolymer (0.1 mg/mL) were prepared
inchloroform, to which a drop of amyl alcohol was added to favorthe
extensibility. To record the A isotherms of each single com-ponent,
a volume of ca. 150 L of the solution was deposited bymeans of a
syringe (Hamilton, USA) at the airwater interface andallowed to
stand for at least 10 min in order to ensure the
completeevaporation of the solvent. The monolayers were compressed
at aspeed of 15 cm2/min. To record the A isotherms of the binary
sys-tems, adequate volumes of each solution were previously
mixed.For example, T1107TOC mixture with a TOC molar fraction of
0.4was prepared by mixing 1 mL of 0.1 mg/mL T1107 solution and19.5
L of 0.1 mg/mL TOC solution. Then, the experiments werecarried out
in the same way as for the single components.
2.3. Solubilization of TOC in polymeric micelles
Solutions of T1107 (020% w/w) were prepared by adding
thecopolymer to cold 0.9% NaCl aqueous solution under stirring
and,then, the solutions, were stored for 24 h at 4 C or 25 C.
Aliquots(5 mL) of each solution were transferred into vials
containing TOCin excess (240 mg) and kept under magnetic stirring
at 4 0.5 Cor 25 1 C for 72 h. The samples were then filtered
through PTFEmembranes of 0.45 m pore size (Sartorius, Gottingen,
Germany)to remove insoluble TOC. The concentration of dissolved TOC
wasspectrophotometrically quantified at 292 nm (Agilent 8453,
Wald-bronn, Germany), after adequate dilution with ethanol, using
acalibration curve obtained with TOC solutions (0.010.1 mg/ml)
inethanol. The filtered solutions were stored for three months at 4
Cprotected from light and then the amount of TOC that
remaineddissolved was again quantified as explained above.
2.4. Dynamic light scattering (DLS)
DLS was used to determine the apparent hydrodynamic diam-eter
(Dh) of the micelles before and after loading of TOC.
DLSmeasurements were carried out at 90 scattering angle using
anALV-5000 F optical system equipped with CW diode-pump
Nd:YAGsolid-state laser (400 mW) operated at a wavelength of 532
nm(Coherent Inc., Santa Clara, USA). The experiments were
carriedout in triplicate and the apparent hydrodynamic radius
(Rh,app) ofthe micelles was calculated from the apparent diffusion
coefficientapplying the StokesEinstein equation [37].
2.5. Transmission electron microscopy (TEM)
Drug-free and drug-loaded micellar systems (10%, 10 L)
wereplaced onto a copper grid covered with Formvar film and, after
60 s,the excess was carefully removed and dried at room
temperaturefor 15 min. Then, phosphotungstic acid (2% w/v, 10 L)
was addedand the excess removed after other 60 s. Finally, the
sample wascarefully washed with distilled water, dried in a closed
containerand observed using a Philips CM-12 TEM apparatus (FEI
Company,Eindhoven, Netherlands).
2.6. Rheology
Viscoelastic behavior of 10 and 20% (w/w) T1107 dispersionswith
and without TOC, freshly prepared and after three monthsstorage
protected from light, was evaluated at 10 (the lowest tem-perature
permittable with the available equipment), 25 and 37 Cin a Rheolyst
AR-1000N rheometer (TA Instruments, New Castle,
DE, USA) equipped with an AR2500 data analyzer, and fitted witha
Peltier plate. The storage (G) and the loss (G) moduli wererecorded
at 0.5 Pa in the 0.550 rad/s angular frequency intervalusing a
cone-plate geometry (diameter 6 cm, angle 2).
-
5 es B: Biointerfaces 103 (2013) 550 557
2
aoeS(t2(s3mrdw
P
rt
A
wCP
2
ucSm8dvut8ebw
3
3
amamimmttpdmt
(mN/m)0 5 10 15 20 25
Cs-
1 (m
N/m
)
0
10
20
30
40
50
60
70 20C
25C29C
10C
Area (A2/molecu le)0 20 40 60 80 10 0 12 0 14 0 16 0 18 0 20
0
(m
N/m
)
-5
0
5
10
15
20
25
30
35
20C25C29C
10CA
B
52 A. Ribeiro et al. / Colloids and Surfac
.7. Antioxidant activity
The free radical DPPH method [38] was applied to quantify
thentioxidant activity of TOC solubilized in 10% T1107 solution
afterne day and after three months from the preparation. Aliquots
ofach sample were diluted 25-fold with ethanol:water 50:50
(v/v).imilarly, fresh TOC 0.076 mg/mL solutions in ethanol:water
50:50v/v) (positive control) were prepared. The diluted samples
andhe reference were further diluted 8, 20 and 40-fold (final
volume
ml) in ethanol:water 50:50 (v/v). Then, 2 ml of a DPPH
solution30 g/mL, in ethanol:water 50:50 v/v) were added to each
dilutedolution and the mixtures were kept protected from the light
for0 min. The reference consisted of 2 ml ethanol:water 50:50
(v/v)ixed with 2 ml of the DPPH solution. Then, the absorbance
was
ecorded at 525 nm (Agilent 8453, Waldbronn, Germany). For
eachilution of micellar system, the power of inhibition of free
radicalsas calculated as [38]:
I(%) =(
1 AsampleAreference
) 100
The values of PI of two dilutions of each micellar system
thatesulted to be above (PI1) and below (PI2) 50% were used to
estimatehe anti-radical power (ARP) as follows
RP (%) =(
1CI50
) 100
here CI50 = C1 C and C = [(C1 C2)(PI1 50)]/(PI1 PI2) with1 and
C2 the concentrations of the dilutions that render PI1 andI2
respectively.
.8. In vitro release studies
TOC release from 10% (w/w) T1107 micellar system was eval-ated,
in triplicate, using Franz-Chien diffusion cells fitted
withellulose acetate membrane filter (0.45 m, Albet,
Barcelona,pain). The diffusion area was 0.785 cm2. The receptor
compart-ent (7 mL) was filled with NaCl 0.9% solution containing
Tween
0 0.5% (w/v) [39]. The micellar system (1 mL) was placed in
theonor compartment and gently covered with parafilm to pre-ent
evaporation. The receptor solution was kept at 37 0.5 C andnder
stirring with a magnetic bar. The concentration of TOC inhe
receptor solution was monitored over time at 292 nm (Agilent453,
Waldbronn, Germany) by taking 500 L samples at pre-stablished time
points, which were diluted with 500 L ethanolefore absorbance
measurement. The volume sample was replacedith fresh 0.9% NaCl
solution containing 0.5% (w/v) Tween 80.
. Results and discussion
.1. A isotherms
The few papers that report on the behavior of TOC at theirwater
interface indicate that this vitamin can form stableonolayers
[4042]. We observed that the isotherm of TOC exhibits
firm influence of temperature (Fig. 1a). At 20 C or below,
theonolayer behaves as a condensed liquid. As the temperature
ncreased from 20 to 29 C, a transition in the isotherm becameore
evident and the collapse pressure diminished. The plot of
theonolayer compressibility vs. surface pressure (Fig. 1b) enabled
us
o identify the regions at which the phase transitions occurred
bet-er. The local minimum in the compressibility corresponds to
the
ressure of the transition [43,44]. The plots corresponding to 10
Cid not show a defined minimum. As the temperature increased,
theinimum shifted toward lower pressure. The effect of the tempera-
ure has been attributed to an increase in entropy and enthalpy
due
Fig. 1. A isotherms of TOC at the airwater interface recorded at
various temper-atures (A) and dependence of the monolayer
compressibility on surface pressure(B).
to the freedom of motion of the phytol hydrophobic side chain
ofTOC and to their larger interactions, which leads to more
expandedand less rigid monolayers [42]. As can be appreciated from
Fig. 1a,the limit area (i.e., the intercept on the X axis of the
tangent straightline to the isotherm in the condensed region)
notably increasedwhen temperature was raised from 20 to 29 C. The
increase inentropy and enthalpy was confirmed applying Motomura
equation,which is an adaptation of ClausiusClapeyron model to
bidimen-sional systems [45]:
H =(
dtdT
ddT
) T A
where H and A represent the changes in enthalpy and molecu-lar
area in the transition region from expanded liquid to
condensedliquid, respectively. The difference between the molecular
areasoccupied by the monolayer at the end (Ac) and the beginning
(Ae)of the pseudoplateau was used to estimate A. Since the
pseu-doplateau region is not rigorously flat and the pressure
slightlychanges during the transition, d/dT was estimated from the
meanvalues of pressure at the beginning and at the end of the
transi-
tion. The term d/dT corresponds to the change of water
surfacetension as the temperature increases, which is 0.153 mN/(m
K)in the 540 C range. At 293 K, H and S/T values obtained inthis
way were 6796.94 cal/mol and 22.81 cal/mol K (for Ae = 82.23
-
A. Ribeiro et al. / Colloids and Surfaces B: Biointerfaces 103
(2013) 550 557 553
Area (A2/molecu le)0 200 0 400 0 600 0 800 0 1000 0 1200 0
(m
N/m
)
0
5
10
15
20
25
30
XTOC0.0 0.2 0.4 0.6 0.8 1.0
Gex
c (KJ
/mol
)
-2
-1
0
1
2
10C X=0X=0.2X=0.4X=0.6X=0.8
2.55.010
1520
Fig. 2. A isotherms and excess free energy change of mixing of
T1107TOC mono-layers at the airwater interface, recorded at 10 C
(XTOC indicates the molar fractionor
vA
vcXfaloo(8pTarussblacabI
Area (A2/molecu le)0 200 0 400 0 600 0 800 0 1000 0 1200 0
(m
N/m
)
0
5
10
15
20
25
30
XTOC0.0 0.2 0.4 0.6 0.8 1.0
Gex
c (KJ
/mol
)
-2
-1
0
1
2
3
4
5
20C X=0X=0.2X=0.4X=0.6X=0.8
2.55.010
152025
Fig. 3. A isotherms and excess free energy change of mixing of
T1107TOC mono-
f TOC in each mixture with the copolymer). The coefficient of
variation (CV) ofepeated measurements was in all cases below 6.7%.
2/molecule and Ac = 99.87 A2/molecule). At 302 K, H and S/Talues
resulted to be 9363.85 cal/mol and 31.01 cal/molK (fore = 89.31
A2/molecule and Ac = 113.29 A2/molecule).
The A isotherms of poloxamines on HCl aq. have been pre-iously
described [30]. Similarly to that observed under acidonditions, the
A isotherms of T1107 on water (see plots for
= 0 in Figs. 24, and Appendix Fig. A.2) showed three well
dif-erentiated regions that are attributed to the fact that their
long EOrms undergo conformational changes as the pressure
increases. Atow pressure, the copolymer adopts a flat (pancake)
conformationn the surface. The total PO (17.5 A2) and EO (1316.5
A2) groupsf T1107 at the airwater interface, plus the water
molecules8.5 A2) that are interacting with these groups, roughly
occupy000 A2/molecule. When the area becomes smaller, the
pressurerogressively increases up to a conformational change
occurs.he copolymer adopts a mushroom conformation above 5 mN/mnd a
pseudoplateau was observed up to 10 mN/m, due to theearrangement of
the PPO coils into loops and the immersion of EOnits in the aqueous
subphase. The end of the pseudoplateau corre-ponded to the
situation in which all EO units were immersed in theubphase, while
the surface was exclusively occupied by the PPOlocks. This
pseudoplateau is particularly evident for polymers with
ong EO arms, such as T1107, and leads to monolayers that behaves
expanded-like films [36,4648]. As the monolayer was
furtherompressed, a rapid increase in occurred. The copolymer
adopts
brush conformation, characterized by the stretching of the
PPOlocks due to space limitations and to increased lateral
interactions.n the subphase, the helical PEO chains entangle with
neighboring
layers at the airwater interface, recorded at 20 C (XTOC
indicates the molar fractionof TOC in each mixture with the
copolymer). The coefficient of variation (CV) ofrepeated
measurements was in all cases below 6.7%.
copolymer molecules, whilst the PPO blocks at the interface
canform loops and even be partially solubilized in the aqueous
PEOlayer (this process may be facilitated by the hydrophilic
ethylene-diamine group). As compression increased more, both
hydrophilicand hydrophobic blocks became stretched (condensed
state). Aminor effect of temperature from 10 to 29 C was observed
onthe isotherm pattern of T1107: at low pressures, the increase
intemperature led to a small increase in pressure (up to 1 mN/m)
forthe same area, while at relatively high pressure ( > 1415
mN/m),the isotherms superimposed. These observations are related to
thedecrease in affinity for water of T1107 as temperature
increases.
The A isotherms of T1107TOC mixed monolayers (Figs. 24,and
Appendix Fig. A.2) revealed that as the proportion in TOCincreased,
the pressure diminished for the same area value. Thecharacteristic
pseudoplateau of T1107 isotherm progressively van-ished as the
proportion in TOC rose. Miscibility of the componentswas evaluated
through the excess free energy of the mixed mono-layers estimated
as the difference between the experimental dataand those values
that would be obtained if the behavior of themixture was ideal, as
follows [49,50]:
Gexc = NA
0
A1,2d X1
0
A1d X2
0
A2d
where NA is Avogadros number, and A1, A2 and A1,2 are the
molec-ular areas of the pure components and of the mixture,
respectively,at a given surface pressure . Upper limits of the
integral were 2.5,
-
554 A. Ribeiro et al. / Colloids and Surfaces B: Biointerfaces
103 (2013) 550 557
XTOC0.0 0.2 0.4 0.6 0.8 1.0
Gex
c (KJ
/mol
)
-5
-4
-3
-2
-1
0
1
2
Area (A2/molecu le)0 200 0 400 0 600 0 800 0 1000 0 1200 0
(m
N/m
)
0
5
10
15
20
25
3025C X=0
X=0.2X=0.4X=0.6X=0.8
2015
2.55.0
10
Fig. 4. A isotherms and excess free energy change of mixing of
T1107TOC mono-layers at the airwater interface, recorded at 25 C
(XTOC indicates the molar fractionof TOC in each mixture with the
copolymer). The coefficient of variation (CV) ofr
5ao(
i(wtatbctafiFimtfaFsl
T1107 co ncent ration (M)0.00 0 0.00 2 0.00 4 0.00 6 0.00 8 0.01
0 0.01 2 0.01 4
TOC
(M)
0.00
0.02
0.04
0.06
0.08
0.10
0.12
4C25C
TOC, multimodal distributions were obtained (Fig. 6), which is
inagreement with previous reports [35]. The presence of
different
epeated measurements was in all cases below 6.7%.
, 10, 15, 20 and 25 mN/m; except for the experiments carried
outt 29 C, in which the maximum upper limit was 15 mN/m becausef
the collapse of TOC monolayer at temperature below 20 mN/mFig.
1a).
The Gexc values of isotherms recorded 10 C were slightly
pos-tive, except for low pressures and high TOC relative
proportionsFig. 2). At 20 C, Gexc values were in all cases positive
(Fig. 3),hich means that T1107TOC interactions are less favorable
than
hose between each component itself. As explained above, TOC has
long phytol hydrophobic chain that is not easy to accommodate inhe
copolymer monolayer. Positive deviations from linearity haveeen
previously observed for mixtures of TOC with phosphatidyl-holines
[40], cholesterol [41], and vitamin C derivatives [42]. Onhe
contrary, as the temperature increased to 25 and 29 C the
Gexc of the T1107TOC mixtures became negative, particularlyt low
compression pressures. This finding suggests that as thereedom of
motion of the phytol hydrophobic side chain of TOCncreases (as
indicated by the conformational changes reported inig. 1 and the
associated H and S/T values), TOC finds it easier tonteract with
T1107 macromolecules. Furthermore, T1107 becomes
ore hydrophobic as temperature increases. As a consequence,he
mixed monolayer at 25 C is remarkably more stable than thatormed by
the components separately. Further increase in temper-ture up to 29
C also rendered negative values of Gexc (Appendixig. A.2), although
smaller than at 25 C probably because the tran-
ition of the TOC component from expanded liquid to condensediquid
occurs at lower pressures.
Fig. 5. Phase solubility diagrams for TOC with T1107 at 4 C and
25 C in 0.9% NaCl.The error bars represent the standard deviations
(n = 4).
3.2. Micellar solubilization
An important property of micelles with particular consequencesin
drug delivery is their ability to host poorly water-soluble
activesubstances. Fig. 5 shows the TOC apparent solubility in 0.9%
NaCl(isotonic with the lachrymal fluid) as a function of T1107
concentra-tion at 4 and 25 C. These temperatures were chosen to
resemblestorage conditions in the fridge and handling at room
tempera-ture. Above the CMC of T1107 (ca. 0.0004 M or 0.6%), the
solubilityof TOC rose linearly with increasing poloxamine
concentration.At 25 C, the micellar solution containing 0.013 M
(20%) T1107enhanced TOC solubility from 0.006 mg/mL to 40.7 mg/mL,
namely6783 times. As expected, the increase in solubility was
smaller (661times) when the test was performed at 4 C, which can be
attributedboth to a lower tendency of T1107 to aggregate as
micelles (asobserved for other poloxamines [34]) and particularly
to the loweraffinity of TOC for T1107 at temperature below the
transition ofTOC. As the A isotherms indicate, the interactions of
TOC withT1107 become more favorable as the temperature increases.
Theincrease in entropy may also enable TOC to adopt a conforma-tion
suitable for accommodation in the hydrophobic cores of
T1107polymeric micelles; thus, increasing the apparent
solubility.
Despite micellar solubilization in aqueous salt environment
isusually less favorable than in pure water [34], the increase in
theapparent solubility of TOC is in the range of the values
reportedfor the solubilization of other active substances by T1107
micelles;namely, 4.7, 27, 4870, and 15,100-fold the solubility in
water ofsimvastatin [30], ethoxzolamide [35], efavirenz [51] and
triclosan[52] respectively. Compared to other procedures for
increasingTOC solubility, T1107 micelles resulted to be more
efficient thanethanol:water 70:30 (v/v) medium (450-fold) [53] or
inclusioncomplexes with cyclodextrins (150-fold) [54]. It has been
alsoshown that incorporation in liposomes is limited to 5 mol%
[55].Subsequent studies were mostly carried out with micellar
systemsprepared with 10% T1107 since they can host relevant
quantities ofTOC while maintaining a low viscosity adequate for
instillation (asdiscussed below).
The DLS analysis of T1107 (10%) micellar systems prepared in0.9%
NaCl aqueous solution were carried out before and after theloading
with TOC at 25 C. All samples showed clean autocorrela-tion
diagrams, with a high number of counts. Both with and without
peaks in the population distribution obtained from DLS
measure-ments provided useful information about the existence of
several
-
A. Ribeiro et al. / Colloids and Surfaces B: Biointerfaces 103
(2013) 550 557 555
Inte
nsity
(a.u
.)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
rh (nm)0.1 1 10 10 0 100 0 1000 0
Inte
nsity
(a.u
.)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
Non-loaded T1107 10%
TOC-loaded T1107 10%
FT
sietwpwalnrpwiagOn(t(ts
awtlt1atoTatw
Angular frequ enc y (rad /s)0.1 1 10 10 0
G' a
nd G
'' (P
a)
0.001
0.01
0.1
1
10
100
1000
10000
G'' 10%, 10, 25 and 37C
G'' 20%, 10C
G' 20%, 25C
G'' 20%, 25C
G'' 20%, 37C
G' 20%, 37C
Fig. 7. Storage (G) and loss (G) moduli of T1107 10% and 20%
dispersions at 10 C(G blue lines), 25 C (G green lines, G gray
lines), and 37 C (G red lines, G black
ig. 6. DLS analysis of T1107 10% micellar systems before and
after loading withOC at 25 C. Three independent measurements were
registered for each system.
pecies with sufficient distinct sizes to be distinguished
coexistingn solution. In the present case, Tetronic copolymers
systems (eithermpty or loaded with vitamin E) display well
differentiated popula-ions, which can be assigned in the following
way: (i) the populationith mean sizes at ca. 23 nm might correspond
to singly dispersedolymeric chains, that is, polymer unimers; (ii)
polymeric micellesith sizes ranging from 10 to 30 nm (PDI = 0.468;
SD = 2.77), in
greement with previous reports [32]; and (iii) other two
popu-ations at ca. 200300 nm and at even larger sizes (ca. 2000
nm),ot fully resolved when the micelles are empty, which would
cor-espond to insoluble material residuals coming from the
syntheticrocess of the copolymers (these copolymers are commercial
andere used as received). This material can be partially
incorporated
n the micelles forming larger micelle clusters (the peak
centeredt ca. 200 nm), or to promote the formation of very large
aggre-ates of insoluble species (population centered at ca. 2000
nm).nce TOC was loaded, the micellar population became predomi-ant
and the size of the micelles slightly increased up to 3040 nmPDI =
0.475; SD = 1.33), suggesting that TOC favors the micelliza-ion
process. These results were further confirmed by means of
TEMAppendix Fig. A.3). All micelles showed spherical morphology
andhe presence of TOC did not modify their shape, but increased
theize from ca. 36 to 62 nm.
The stability of TOCT1107 10% micellar systems after stor-ge for
3 months at 4 C, protected from light, was tested in twoays: (a)
the amount of TOC that remained solubilized, and (b)
he antioxidant activity; which are two critical issues for the
shelf-ife of a micellar system intended for ocular application.
Regardinghe first issue, the initial TOC concentration 1.9 mg/ml
decayed to.6 mg/ml; namely more than 84% TOC still remained in
solutionfter three months. This is in agreement with previous
results onhe stability of T1107 micelles against intense dilution
[30]. On thether hand, the antioxidant power (ARP) of the freshly
prepared
OCT1107 micellar system was 13.0%, close to that of an equiv-lent
solution of TOC in ethanol:water 50:50 (v/v) (13.1%). Afterhe
storage, the ARP decayed to 12.7%, which is in close agreementith
the small decrease in the concentration of TOC solubilized.
lines). (For interpretation of the references to color in Figure
legend, the reader isreferred to the web version of the
article.)
Therefore, T1107 effectively protected TOC in the micellar
coreseven after storage under the less favorable conditions
forTOCT1107 interactions.
3.3. Viscoelasticity
Another relevant practical aspect refers to the easiness of
appli-cation of the micellar systems as eye-drops. T1107
dispersions atboth 10% and 20% behaved as free flowing fluids at 10
C, onlyexhibiting small G values and negligible G (Fig. 7). At 10%,
no rel-evant effect of temperature on the viscous behavior was
observed.By contrast, 20% dispersions behaved as viscoelastic
fluids withrelaxation times (i.e., the inverse of the angular
frequency at whichG crossovers G) close to 0.15 s at 25 C and
longer than 20 s at37 C. This temperature dependence could be
exploited for prepar-ing in situ gelling formulations that are
instilled as eye-drops andtransform into gel depots on the corneal
surface [26]. It should bealso noted that loading of TOC and
storage for 3 months did notchange the viscoelastic profile of the
T1107 dispersions.
3.4. TOC release
Diffusion of TOC from the T1107 10% micellar systems, as
freshlyprepared and after three months storage, was recorded using
Franz-Chien diffusion cells filled with NaCl 0.9% medium
containingTween 80 0.5% in order to create sink conditions.
Diffusion stud-ies with TOC alone could not be carried out due to
its extremelylow aqueous solubility, which prevents homogenous
dispersion inwater. The micellar systems sustained the release for
one day; 80%released in the first 12 h (Fig. 8). Under the eye
physiological con-ditions, more efficient control of the release is
expected. Moreover,the micelles could enter into the corneal cells
while the unimers ofT1107 inhibited the efflux pumps; both favoring
the ocular absorp-tion of TOC and prolonging the therapeutic
effects [35,56].
After three months storage, TOC was released at a
slightlygreater rate and with more variability than the freshly
prepared
systems. This finding can be related to the presence of a greater
pro-portion of free vitamin outside the micelles or adsorbed on to
theirsurfaces after storage, which can diffuse faster than TOC
hosted
-
556 A. Ribeiro et al. / Colloids and Surfaces B: B
Tim e (h)0 2 4 6 8 10 12 24
TOC
rele
ased
(mg/
cm2 )
0.0
0.5
1.0
1.5
2.0
Freshly prepa red3 mon ths storage
Ffs
ia
wafi(1
4
Tmmaaoerfspai
S
ima1
A
(e
[
[[
[
[
[
[
[[
[[
[
[
[[[
[
[
[[
[
[[
[
[
[
[
[[[
ig. 8. Diffusion profiles at 37 C of TOC from T1107 10% micellar
dispersions asreshly prepared and after three months storage. The
error bars represent thetandard deviations (n = 3).
nside the micelles. Drug diffusion coefficient, D, was
estimatedpplying the Higuchi model [57]:
Q
A= 2 C0
(D t
)0.5
here Q/A represents the amount of TOC released per unit area,nd
C0 is the initial TOC concentration in the micellar system.
Thettings rendered R2 values above 0.99. D values were 1.23 1040.08
104) cm2/s for freshly prepared micellar systems and.41 104 (0.20
104) cm2/s after the storage.
. Conclusion
The analysis of the A isotherms of TOC with poloxamine1107 at
the airwater interface provides useful predictive infor-ation on
the feasibility of solubilizing TOC in the polymericicelles. In
close agreement with the Gexc values, the increase in
pparent solubility is larger (one order of magnitude) at 25 C
thant lower temperature. Hosted TOC molecules favor
self-aggregationf T1107 unimers and make the micelles physically
stable for sev-ral months at 4 C. Tuning T1107 concentration also
enables theegulation of the viscoelastic behavior of the micellar
systems fromree flowing liquids to in situ gelling systems.
Overall, the enhancedolubility and stability of TOC as well as the
sustained release profilerovided by T1107 micellar systems point
toward them being suit-ble drug carriers for the attainment of
therapeutic concentrationsn the ocular structures.
upplementary data
Chemical structure of TOC and Tetronic 1107 (Fig. A.1),
Asotherms and excess free energy change of mixing of T1107TOC
onolayers at the airwater interface recorded at 29 C (Fig.
A.2),nd TEM micrographs of T1107 10% micelles and TOC-loaded
T11070% micelles (Fig. A.3).
cknowledgments
Work supported by MICINN (SAF2011-22771), Xunta de
Galicia10CSA203013PR) and FEDER (Spain) and Fundac o para
Cincia
Tecnologia (FCT, Praxis grant SFRH/BD/40947/2007, Portugal).
[
[
[
iointerfaces 103 (2013) 550 557
Authors thank P. Taboada and B. Blanco-Fernandez for help
withthe DLS analysis and DPPH tests, and BASF Corporation
(VerenaGeiselhart and Valerie Akavi) for providing poloxamine
(Tetronic)samples.
Appendix A. Supplementary data
Supplementary data associated with this article canbe found, in
the online version, at
http://dx.doi.org/10.1016/j.colsurfb.2012.10.055.
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Poloxamine micellar solubilization of -tocopherol for topical
ocular treatment1 Introduction2 Materials and methods2.1
Materials2.2 A isotherms2.3 Solubilization of TOC in polymeric
micelles2.4 Dynamic light scattering (DLS)2.5 Transmission electron
microscopy (TEM)2.6 Rheology2.7 Antioxidant activity2.8 In vitro
release studies3 Results and discussion3.1 A isotherms3.2 Micellar
solubilization3.3 Viscoelasticity3.4 TOC release4
ConclusionSupplementary dataAcknowledgmentsAppendix A Supplementary
dataAppendix A Supplementary data
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