Research Article
Gel Based Sunscreen Containing Surface Modified TiO2
Obtained by Sol-Gel Process: Proposal for a Transparent UV
Inorganic Filter

Marina Paiva Abuçafy,1 Eloísa Berbel Manaia,1 Renata Cristina Kiatkoski Kaminski,2

Victor Hugo Sarmento,2 and Leila Aparecida Chiavacci1

1School of Pharmaceutical Sciences, UNESP, Univ Estadual Paulista, Araraquara-Jaú, Km 1, 14800-903 Araraquara, SP, Brazil
2Federal University of Sergipe, Campus Itabaiana, Avenida Vereador Olimpio Grande, s/n, 409500-000 Itabaiana, SE, Brazil

Correspondence should be addressed to Leila Aparecida Chiavacci; leila@fcfar.unesp.br

Received 28 November 2015; Accepted 3 February 2016

Academic Editor: Tuncay Ozel

Copyright © 2016 Marina Paiva Abuçafy et al. This is an open access article distributed under the Creative Commons Attribution
License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly
cited.

Inorganic UV filters, as titanium dioxide (TiO
2
), have become attractive because of their role in protecting the skin against the

damage caused by the continuous exposure to the sun. However, their high refractive index, responsible for a white residue when
applied on the skin, has led to the development of alternative inorganic materials, such as TiO

2
nanoparticles. Thus, the aim of

this study was the development of transparent and stable gel formulations containing surface modified TiO
2
nanoparticles for

application in sunscreens. Also, the physical and chemical properties of formulations containing TiO
2
nanoparticles were evaluated.

The UV absorption spectroscopy analyses indicated that the formulations containing TiO
2
nanoparticles had a broad protection

spectrum. The diffuse reflectance spectroscopy revealed that the use of PTSH surface modified TiO
2
nanoparticles improved the

transparency of the sunscreen formulations compared to that containing commercial ones. The rheology analyses showed that the
amount of nanoparticles incorporated in the formulations influences the gel-like or liquid-like behavior. The results showed that
the surface modified TiO

2
nanoparticles are a promising innovative UV filter and the formulations containing these nanoparticles

are interesting candidates for being used as sunscreen.

1. Introduction

The exposure to ultraviolet (UV) radiations can cause exten-
sive damage to the skin, varying from sunburn and preco-
cious aging to serious lesions such as skin cancers [1]. A
manner to prevent skin cancers is the use of sunscreens that
absorb, scatter, and/or reflect UVA and UVB radiations.

Substances that act as filters are classified into two groups:
organic filters (chemical absorbers) and inorganic filters
(physical blockers) depending on their mechanism of action.
Among the inorganic filters, zinc oxide (ZnO) and titanium
dioxide (TiO

2
) are the mostly used. They interact with the

incident solar radiation by reflecting, absorbing, or scattering
it [2].

Inorganic filters are currently being used because they are
stable when exposed to UV radiation, they are not able to

penetrate the skin, they do not cause damage to the epidermal
cells, and they present low allergenicity. Furthermore, they
offer a wide spectrum of protection and provide efficacy
against UV-induced skin damage [3–5].

However, even considering all of their advantages, the
formulations containing opaque inorganic oxides show low
cosmetic acceptability.Thehigh refractive indexmay produce
on the skin a particularly white appearance because of the
light reflection mechanism, which makes the product with a
visual considered unpleasant by the consumers [3, 5, 6].

The solution to solve this problem may be the develop-
ment of smaller particles of titanium dioxide. It could be
reached by modifying the obtainment process and minimiz-
ing the interactions with the visible light (becoming trans-
parent when applied on the skin). Lot of studies, including

Hindawi Publishing Corporation
Journal of Nanomaterials
Volume 2016, Article ID 8659240, 9 pages
http://dx.doi.org/10.1155/2016/8659240



2 Journal of Nanomaterials

of industries, are seeking for alternatives to micronize or sub-
micronized these inorganic filters,making them innanoscale.
The nanoscale inorganic filters present advantages, such as
the facility in their incorporation on cosmetic formulations
and, also, the pleasant sensorial aspect of the final formulation
[7–11].

To obtain TiO
2
nanoparticlesmodified andwith desirable

size, different synthesis routs have been assessed. One of
these routes is the sol-gel process that occurs by hydrolysis
followed by condensation reactions and the precursors are
generally alkoxides dissolved in organic solvents [12]. In this
route, the structural features of nanoparticles achieved are
strictly related to the control of the parameters involved
in the sol-gel reactions [13], such as temperature and time.
Moreover, the use of surface modifier agents, such as com-
plexing compounds, is an emerging strategy. In this way p-
toluene sulfonic acid (PTSH) has been demonstrated to be
a good candidate to the modification of TiO

2
nanoparticles

surface, allowing the control of size, shape, and aggregation
of TiO

2
nanoparticles obtained by the sol-gel process [13,

14]. Structural analysis of samples prepared with different
hydrolysis ratio and acidity ratio demonstrated that PTSH
involves TiO

2
surfaces preventing the nanoparticles aggrega-

tion and allowing the achievement of transparent and high
concentrated suspensions [14, 15].

The commercial formulations of sunscreens are usually
presented in the form of gel, cream, spray, or other topical
products [16].The gels are advantageous over other excipients
because they are less greasy and are constituted by a transpar-
ent base, being preferred by people of oily skin. The gels are
obtained through natural or synthetic hydrophilic thickeners,
such as polymers and copolymers [17, 18].

Despite the several gel favorable characteristics, the incor-
poration of inorganic filters, even though microparticulated,
is a challenge because the inorganic filters tend to easily
aggregate, resulting in an undesirable opaque aspect [18].
Accordingly, the present research studied how the surface
modified titanium dioxide nanoparticles may facilitate the
incorporation of them into a gel excipient.

During the development of formulations containing inor-
ganic UV filters, the stability and physical characteristics
of them must be considered to ensure their efficacy and
safety. Also, the characteristics of the excipient, the result of
combination between filters, and the stability of the formu-
lation must also be considered [19]. The physical stability of
a formulation can be evaluated by rheology. The prediction
of instability processes is possible due to alterations in some
parameters such as viscosity, solubility, creaming facilitation,
and hydration of polymers [20]. Therefore, it is important
to understand the rheological behavior during handling,
mixing, processing, transporting, storage, and application of
such formulations [20].

The purpose of this study was the development of
transparent and stable gel formulations containing surface
modified TiO

2
nanoparticles and the study of their physical-

chemical properties, such as diffuse reflectance, absorbance,
and rheological aspects related to the photoprotection activity
of the sunscreens.

2. Materials and Methods

2.1. Materials. p-Toluene sulfonic acid, PTSH (Vetec Quı́mi-
ca Fina), titanium tetraisopropoxide, Ti(OiPr)

4
(Sigma

Aldrich), isopropanol (Merck), Carbopol 940 (Labor), and
triethanolamine (Oxiteno) were used as received, with-
out further purification. Commercial TiO

2
microparticles

(Sachtleben, Krefeld, Germany) were used to compare with
TiO
2
nanoparticles synthesized via sol-gel process.

2.2. TiO
2
Nanoparticles Synthesis. The TiO

2
nanoparticles

with surface modified were prepared by the sol-gel method
earlier described [15]. Previously an aqueous solution of
PTSHwas prepared and subsequently a solution of Ti(OiPr)

4

in isopropanol in a dry chamber. The PTSH solution was
added into the solution of titanium isopropoxide under
continuous stirring at room temperature. The amounts of
water and PTSH used during the synthesis were calculated
from the molar ratio relative to Ti (H = [H

2
O]/[Ti] and P =

[PTSH]/[Ti]), being the nominal hydrolysis ratio (H) equal
to 1 and the nominal acidity ratio (P) equal to 0.05.

To obtain the xerogel (powder), the earlier prepared sol
was dried at 100∘C until complete evaporation of the solvent.
Subsequently, the powder was macerated.

2.3. Preparation of Sunscreen. The sunscreen formulations
were prepared using Carbopol 940 (2% dispersion) as poly-
mer of the gel cosmetic excipient and the TiO

2
xerogel was

used as inorganic filters. Firstly, the polymer was homoge-
nized in water and then the TiO

2
xerogel was added under

stirring. Hereafter, the pH was adjusted with the addition of
triethanolamine 50% (w/w) until reaching pH between 5 and
7.

2.4. Physical-Chemical Characterization

2.4.1. UV Absorption Spectroscopy. The measurement of the
spectral absorption of UV radiation (290–400 nm) through
a substrate before and after application of the sunscreen
was performed. The formulation containing 10 and 15% of
TiO
2
xerogel P0.05H1 and the formulation containing 15%

of the commercial TiO
2
were measured. The gel formulation

without TiO
2
particles was, also, measured.

The substrate used was a 3M� Transpore tape applied on
clean 2mm thick quartz slides. Approximately 2mg/cm2 of
the formulation was uniformly spread using a finger glove.
The sampleswere allowed to air dry and the plateswere placed
inside the UV-2000S Ultraviolet Transmittance Analyzer.
Before running the sample, the blank slide was loaded into
the sample holder for the blank scan. Irradiation took place
at nine different areas of the substrate. The experiment was
performed in triplicate and the spectral data were processed
by the Labsphere software where the critical wavelength was
calculated.

2.4.2. Diffuse Reflectance Spectroscopy. The diffuse reflec-
tance spectra of the formulations were carried out in the Cary
spectrophotometer equipped with a HARRICK attachment



Journal of Nanomaterials 3

Table 1: Sunscreen formulations developed varying components and concentrations (%).

Formulations % TiO
2
P0.05H1 % commercial TiO

2
% Carbopol 940 (2% dispersion) % H

2
O

Formulation 1 2.5 — 10 87.5
Formulation 2 5 20 75
Formulation 3 10 — 25 65
Formulation 4 15 40 45
Formulation 5 20 — 45 35
Formulation 6 25 — 50 25
Base formulation — — 50 50
Commercial TiO

2
formulation — 15 50 35

diffuse accessory. The same amount of each sample was
placed in the sample holder and the surface of the sampleswas
homogenized using a glass slide. The reflectance measure-
ments of the formulations containing commercial TiO

2
and

xerogel TiO
2
were referenced to the MgO optical standard in

the visible spectrum (400–700 nm).The resultswere obtained
in percentage of reflectance (𝑅%).

2.4.3. Rheology. Rheological tests were performed using a
stress controlled rheometer AR2000ex (TA Instruments,
Surrey, England) in flow mode with a cone-plate geometry
(40mm) and gap of 200𝜇m. Steady shear rate sweep tests
(upward and downward) were conducted over a range of
shear rates from 0 to 200 s−1. Rheological measurements
in the oscillatory shear mode were performed using the
same geometry. In dynamic frequency sweep tests, firstly, the
linear viscoelastic region (LVR) was identified through an
oscillatory stress sweep at a fixed frequency (1Hz). Secondly,
samples were subjected to frequency sweep tests at 25∘C over
the frequency range of 0.6 to 100 rad/s, at a constant stress
(1 Pa). The elastic modulus (𝐺󸀠) and loss modulus (𝐺󸀠󸀠) were
determined using the programRheologyModifier Advantage
Control AR.

3. Results and Discussions

3.1. Synthesis of Nanoparticles and Development of the Sun-
screen Gel Formulation. Table 1 presents several sunscreen
formulations developed with various concentrations of TiO

2

xerogel, obtained by sol-gel process and commercial TiO
2
.

The polymer used in the formulations was Carbopol 940,
a strongly coiled polymer when dried. After its dispersion in
water its chains are hydrated and tightly knotted by hydrogen
bonding, exhibiting a pH in solution around 3.0. Thus,
an alkali, that is, triethanolamine, is applied for obtaining
the maximum thickening effect (pH between 6 and 10). A
uniform gel structure is obtained when the chain of the
polymer is kept uncoiled due to the repulsive forces between
two adjacent negatively charged groups along the polymer
chain [21]. In this way, the gel structure stability was strongly
influenced by the presence of charges in solution. The TiO

2

nanoparticles were modified by PTSH and present negative
charges in their surface as showed in our previous study [22].

Table 1 shows the maximum concentration of TiO
2
that was

incorporated in the gel based formulations.
Figure 1 shows the visual aspect of (a) commercial TiO

2

powder, (b) TiO
2
xerogel nanoparticles powder, (c) sunscreen

formulation with commercial TiO
2
, (d) sunscreen formula-

tion with TiO
2
xerogel nanoparticles, and (e) and (f) these

last two formulations, respectively, applied in a surface. It can
be observed that nanoparticles obtained by sol-gel process (b)
presented finer powder when compared to the commercial
TiO
2
used (a), improving its dispersion into the formulations

and, probably, also, the stability of the sunscreens. Figure 1
also shows that the formulation containing TiO

2
xerogel

nanoparticles (f) appears more homogeneous and transpar-
ent when applied to a surface, differing from the formulation
containing commercial TiO

2
(e), which produces a more

whitish residue. This difference could be attributed to the
transparency promoted by the PTSH surface modifier that
can prevent the particles aggregation in the formulation.

Figure 2 presents the scheme of the Carbopol 940 chain
coiled before neutralization and the behavior of the inorganic
filters nanoparticles with and without charges into the gel
chain after neutralization. The inorganic nanoparticles are
surrounded by negative charges, which prevent their aggre-
gation, forming a uniform system. By the other side, the
unmodified nanoparticles are tightly aggregated due to the
insufficient charges on their surface. In addition, unmodified
nanoparticles can be synthesized using methodologies that
do not ensure homogeneous size and shape, leading to
the formation of heterogeneous system, which affects the
photoprotection activity of the sunscreen formulation.

3.2. UV Absorption Spectroscopy. Figure 3 shows the absorb-
ance spectra of the sunscreen formulations with 10 and 15%
of P0.05H1 TiO

2
nanoparticles, 15% of commercial TiO

2

particles, and also the gel based formulation without TiO
2

nanoparticles in order to compare the absorption activity
of the samples. It is noteworthy that the PTSH modified
TiO
2
nanoparticles and commercial TiO

2
particles are solely

responsible for the UV protection in the formulations ana-
lyzed in this study. The gel based cosmetic formulation
prepared with Carbopol 940 without TiO

2
does not affect

the absorption of UVB and UVA radiation, presenting
absorbance about 0 in this spectral range. Two important
pieces of information can be extracted from the absorbance



4 Journal of Nanomaterials

(a) (b)

(c) (d)

(e) (f)

Figure 1: Photographs of (a) commercial TiO
2
powder, (b) TiO

2
xerogel nanoparticles powder, (c) sunscreen formulation with commercial

TiO
2
, (d) sunscreen formulationwith TiO

2
xerogel nanoparticles, and (e) and (f) these last two formulations, respectively, applied to a surface.

spectra: the shape of the absorbance spectra, which points
out the protection capability in different spectral regions,
and the amplitude of the spectra, which indicates the pro-
tection degree [23]. It can be observed that the higher
the concentration of TiO

2
nanoparticles is, the higher the

absorbance intensity throughout UVA andUVB range is, and
thus the higher the protection of the sunscreen formulation
against UVA andUVB radiations is.The absorbance intensity
of the formulation containing commercial TiO

2
particles

is higher than the other containing PTSH modified TiO
2



Journal of Nanomaterials 5

COOH

Neutralization

Surface modified
nanoparticles surrounded

by negative charges

Unmodified nanoparticles

CO
O

H

COOH

CO
O

H

CO
O

H

COOH

CO
O

H

COOH

−

−−
−
−

−
−
−

−

−
−
−−

−

− −
Cation +

Cation +

Cation +
Cation +

Cation +
Cation +

Cation +

Cation +
Cation + Cation +

Cation +
Cation +

Cation +
Cation +

Cation +

Cation +

−

−
−
−−

−

− −

−

−
−
−−

−

− −
−

−
−
−−

−

− −

−

−
−
−−

−

− − −

−
−
−−

−

− −

−

−
−
−−

−

− −

−

−
−
−−

−

− −

−

−
−
−−

−

− −

−

−
−
−−

−

− −

−

− −
−−

−

− −

−

−
−
−−

−

− −

−

−
−
−−

−

− − −

−
−
−−

−

− −

−

−
−
−−

−

− − −

−
−
−−

−

− −

−

−
−
−−

−

− −

−
−
−−

−
COO −

COO −

COO
−

CO
O

−

COO
−

COO −
COO −

COO −

COO
− COO

−

CO
O

−

COO
−

COO −

Figure 2: Scheme of the Carbopol� 940 chain coiled before neutralization and the behavior of the inorganic filter nanoparticles with and
without charges into the gel chain after neutralization.

nanoparticles. According to Yang et al. this behavior was not
expected once nanosized particles usually absorb more UV
radiation than submicrometer-size particles [24].

Among the in vitro methodologies used to evaluate the
efficiency of sunscreen protection, Diffey proposed the crit-
ical wavelength (𝜆𝑐) method which studies the absorbance
spectrum reduced to a single index by means of UV substrate
spectrophotometry [25]. 𝜆𝑐 is determined when the area
under the spectrum from 290 nm (the approximate lower
wavelength limit of terrestrial sunlight) to 𝜆𝑐 is 90% of the
integral of the absorbance spectrum from 290 to 400 nm
[26]. Figure 3 appoints also the 𝜆𝑐 at 384 nm of the sun-
screen formulations containing 15% and 10% of P0.05H1
TiO
2
nanoparticles. 𝜆𝑐 of both formulations were higher

than 370 nm; thus, the formulations are classified as broad-
spectrum protection [26]. In this case, there are no significant
differences between the UVA (320 to 400 nm) and UVB
(290 to 320 nm) intensity absorption. This behavior was not
expected once TiO

2
is absorbed mainly in the UVB range;

thus, the PTSH surface modified TiO
2
nanoparticles present

broad-spectrum protection. It is important to highlight that

TiO
2
acts as inorganic filter blocking UV radiation phys-

ically by scattering and reflecting the incoming radiation
and chemically by absorbing it [27]. Therefore, the UV
absorbance measurements evaluate only the physical activity
of TiO

2
.

Mie law gives a general relation on the diffusion of
radiation, while Rayleigh relates the radius dispersion to
the intensity at a given wavelength, for very small parti-
cles. According to Rayleigh, the radiation scattered can be
inversely proportional to the fourth power of the wavelength.
It is possible to conclude that when the particles are smaller,
the scattering of UV radiation is better, in a wavelength below
400 nm [28, 29].

3.3. Diffuse Reflectance Spectroscopy. Diffuse reflectance
spectroscopy has been used to evaluate the transparency
of several materials in the visible spectrum [30]. Figure 4
presents the visible diffuse reflectance spectra of sunscreen
formulations containing commercial TiO

2
and PTSH surface

modified TiO
2
nanoparticles. Formulations containing TiO

2

nanoparticles displayed lower reflectance (about 45%) in the



6 Journal of Nanomaterials

1.0

0.8

0.6

0.4

0.2

0.0

Ab
so

rb
an

ce

300 320 340 360 380 400

Wavelength (nm)

𝜆c = 384nm

15% P0.05H1

10% P0.05H1

Base formulation

15% commercial TiO2

Figure 3: Absorbance spectra of sunscreen formulations with 10%
and 15% of P0.05H1 TiO

2
nanoparticles, 15% of commercial TiO

2

particles, and without TiO
2
nanoparticles (base formulation).

100

80

60

40

20

0

Re
fle

ct
an

ce
 (%

)

400 500 600 700

Wavelength (nm)

10% commercial TiO2

10% P0.05H1

5% P0.05H1

2.5% P0.05H1

Base formulation

Figure 4: Diffuse reflectance spectra in the UV-Visible region
of formulations containing 2.5%, 5%, and 10% of P0.05H1 TiO

2

nanoparticles and 10% commercial TiO
2
formulation.

visible region compared with the formulation containing the
same concentration of commercial TiO

2
(about 100%).

The lower the percentage of reflectance is, the greater
the transparency of the formulation is. A difference in the
transparency among the samples can be observed, which
decreases with the increase of TiO

2
nanoparticles concen-

tration. The formulation with 10% TiO
2
nanoparticles has

almost half of the reflectance of the formulation with the
same concentration of commercial TiO

2
. Thus, the use of

PTSH surface modified TiO
2
nanoparticles improved the

transparency of the sunscreen formulations compared to
that containing commercial ones. This is mainly due to the
repulsion of negative charges which surrounds the PTSH
modified TiO

2
nanoparticles, as shown in Figure 2, that

prevents the nanoparticle aggregation. In this way, it is

600

400

200

0

Vi
sc

os
ity

 (P
a·

s)

0 50 100

Shear rate (1/s)

Gel base formulation
15% of modified TiO2

25% of modified TiO2

15% of commercial TiO2

40

20

0

Vi
sc

os
ity

 (P
a·

s)

0 40 80 120

Shear rate (1/s)

Figure 5: Shear viscosity as a function of shear rate of gel based
formulation and, also, formulations containing 15% of commercial
TiO
2
and 15% and 25% of P0.05H1 TiO

2
nanoparticles. The insert

displays a zoom in the formulations without commercial TiO
2

nanoparticles.

possible to incorporate the same amount of nanoparticles
obtaining a more transparent and desirable system than the
commercial ones.

3.4. Rheology. Figure 5 shows the shear viscosity as a function
of shear rate of the gel based formulation and, also, of the
formulations containing 15% of commercial TiO

2
and 15%

and 25% of P0.05H1 TiO
2
nanoparticles. The rheograms

showed that the addition of modified inorganic UV filters
to the base formulation did not change the properties of
it; however, 15% of commercial TiO

2
caused a meaningful

increase in viscosity.
A reduction in the viscosity of the formulations was

verified as a function of shear rate. These results suggest that
the addition of these inorganicUVfilters led to changes in the
viscosity of the formulation compared to the concentration
of nanoparticles incorporated. This is a common behavior
[31] of sunscreens containing a higher percentage of inorganic
UV filters powders added directly to the vehicle, resulting in
flocculation in the formulation.

Figure 6 presents the storage (𝐺󸀠) and lossmoduli (𝐺󸀠󸀠) as
a function of frequency of (a) gel based formulation and, also,
the formulations containing (b) 15% of commercial TiO

2
and

(c) 15% and (d) 25% of P0.05H1 TiO
2
nanoparticles. In the

gel based formulation (Figure 6(a)) it is possible to observe
𝐺
󸀠 higher than 𝐺󸀠󸀠 and frequency independent, indicating

the predominance of the consolidated elastic structure. This
behavior is due to cross-linking between the gel polymer
chains, as expected for gels. In the formulations containing
15% of commercial TiO

2
(Figure 6(b)) and 25% of P0.05H1



Journal of Nanomaterials 7

100

10

1 10 100

Frequency (rad/s)

G
󳰀

G
󳰀󳰀

G
󳰀
,G

󳰀󳰀
(P

a)

(a)

1000

1 10 100

Frequency (rad/s)

G
󳰀

G
󳰀󳰀

G
󳰀
,G

󳰀󳰀
(P

a)

(b)

1 10 100

Frequency (rad/s)

G
󳰀

G
󳰀󳰀

G
󳰀
,G

󳰀󳰀
(P

a)

(c)

10000

1000

100

1 10 100

Frequency (rad/s)

G
󳰀

G
󳰀󳰀

G
󳰀
,G

󳰀󳰀
(P

a)

(d)

Figure 6: Storage (𝐺󸀠) and loss (𝐺󸀠󸀠) moduli as a function of frequency of the (a) gel based formulation and, also, formulations containing
(b) 15% of commercial TiO

2
and (c) 15% and (d) 25% of P0.05H1 TiO

2
nanoparticles.

TiO
2
nanoparticles (Figure 6(d)), both moduli remain con-

stant with the increase of the frequency and 𝐺󸀠 is higher
than 𝐺󸀠󸀠. This frequency independence was also observed
in Carbopol 940 gel without nanoparticles, demonstrating
that the nanoparticles do not affect the cross-linking of the
polymer chains. Different behavior was observed for the
formulation containing 15% of P0.05H1 TiO

2
nanoparticles

(Figure 6(c)). A crossover between 𝐺󸀠󸀠 and 𝐺󸀠 occurs above
25 rad/s, showing more gel-like behavior with increasing
frequency. This result indicates that 15% of P0.05H1 TiO

2

nanoparticles were a disadvantage for the cross-linking of the
polymer chains. The same behavior could be expected with
increasing nanoparticles concentration, because the surface
charges also increase. However, the concentration increase
to 25% xerogel was accompanied by a slight increase of
𝐺󸀠, which shows favoring of the cross-linked system. This
is also confirmed by the great dispersion of 𝐺󸀠󸀠 values.
In the commercial TiO

2
formulation case, 𝐺󸀠 and 𝐺󸀠󸀠 are

frequency independent, indicating that it does not affect the
links between the polymer chains. Although the commercial
TiO
2
was added in the same concentration of the xerogel

(15%), which prevented cross-linking of the gel, this sample
is independent of frequency and possibly does not have
sufficient surface charge to disfavor cross-linking of the
polymer chains.

4. Conclusions

We developed broad-spectrum photoprotection gel based
formulations containing surface modified TiO

2
nanoparti-

cles.The purpose of obtainingmore transparent formulations
compared to commercial ones was achieved as showed by
diffuse reflectance spectra. As expected, commercial TiO

2

without surface modification seems to flocculate showing
accentuated viscosity compared to PTSH surface modified
TiO
2
nanoparticles. The gel based formulation and the



8 Journal of Nanomaterials

formulations containing 15% and 25% of TiO
2
nanoparti-

cles presented storage module higher than loss module as
function of frequency underling the predominance of the
consolidated elastic structure, which is characteristic from
the cross-linking between the gel polymer chains. However,
the formulation containing 15% of PTSH TiO

2
nanoparticles

presented a crossover between loss module and storage
module as function of frequency indicating a disadvantage
for the cross-linking of the polymer chains. The surface
modified TiO

2
nanoparticles obtained by sol-gel process

presented promising properties for transparent sunscreen
with broad-spectrum photoprotection.

Conflict of Interests

The authors declare that there is no conflict of interests
regarding the publication of this paper.

Acknowledgments

The authors thank FAPESP, CNPq, and PADC/FCF-UNESP
for the financial support. They would also like to thank
Professors André R. Baby (USP/São Paulo), Celso V. Santilli,
and Sandra H Pulcinelli (UNESP/Araraquara) for allowing
them to use their laboratory during the UV absorption
spectroscopy, rheology, and diffuse reflectance spectroscopy.

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