Research Article
Ciprofloxacin Release Using Natural Rubber
Latex Membranes as Carrier

Heitor Dias Murbach,1 Guilherme Jaques Ogawa,1

Felipe Azevedo Borges,1,2 Matheus Carlos Romeiro Miranda,2 Rute Lopes,2

Natan Roberto de Barros,1,2 Alexandre Vinicius Guedes Mazalli,1

Rosângela Gonçalves da Silva,1 José Luiz Ferreira Cinman,1

Bruno de Camargo Drago,3 and Rondinelli Donizetti Herculano1,2

1Biological Sciences Department, Faculty of Language & Sciences, São Paulo State University (UNESP),
2100 Dom Antonio Avenue, 19806-900 Assis, SP, Brazil
2Chemistry Institute, São Paulo State University, 55 Professor Francisco Degni Street, 14800-060 Araraquara, SP, Brazil
3Physics Department, Faculty of Sciences, São Paulo State University, 14-01 Engenheiro Luiz Edmundo Carrijo Coube Avenue,
17033-360 Bauru, SP, Brazil

Correspondence should be addressed to Rondinelli Donizetti Herculano; rond.donizetti@gmail.com

Received 28 July 2014; Revised 26 October 2014; Accepted 10 November 2014; Published 22 December 2014

Academic Editor: Ravin Narain

Copyright © 2014 Heitor Dias Murbach 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.

Natural rubber latex (NRL) from Hevea brasiliensis is easily manipulated, low cost, is of can stimulate natural angiogenesis
and cellular adhesion, is a biocompatible, material and presents high mechanical resistance. Ciprofloxacin (CIP) is a synthetic
antibiotic (fluoroquinolone) used in the treatment of infection at external fixation screws sites and remote infections, and this use
is increasingly frequent in medical practice. The aim of this study was to develop a novel sustained delivery system for CIP based
on NRL membranes and to study its delivery system behavior. CIP was found to be adsorbed on the NRL membrane, according
to results of energy dispersive X-ray spectroscopy. Results show that the membrane can release CIP for up to 59.08% in 312 hours
and the mechanism is due to super case II (non-Fickian). The kinetics of the drug release could be fitted with double exponential
function X-ray diffraction and Fourier transform infrared (FTIR) spectroscopy shows some interaction by hydrogen bound, which
influences its mechanical behavior.

1. Introduction

Ciprofloxacin (CIP) is a fluoroquinolone, a synthetic antibi-
otic of the quinolone drug class [1]. Synthesized in 1981, it is
a second-generation antibacterial and recently was pointed
out as the most consumed antibacterial agent worldwide and
the 5th most commonly prescribed generic antibacterial in
the USA [2, 3]. This high level of use, some due to misuse
in the sense of unnecessary administration and consumption
in irregular dose or with methods neither approved nor
supervised by medical professionals, has been blamed for the
rapid development of bacterial resistance against this drugs’
class [2, 4].

Ciprofloxacin is effective in the eradication of a wide
spectrum of Gram-negative and some specific Gram-positive
bacteria, including most strains of bacterial pathogens
responsible for respiratory, urinary tract, gastrointestinal, and
abdominal infections. It is commonly administrated for P.
aeruginosa osteomyelitis and is widely used as a prophylactic
measure in osteomyelitis surgeries [5–7]. The drug shows
efficacy and safety in the treatment of adult patients with
serious skin and soft tissue infections caused by a variety of
bacterial pathogens [8]. The spectrum of activity of the CIP
and the location of several injuries which can be treated with
this drug open discussion for a new site-specific approach for
some infirmities.

Hindawi Publishing Corporation
International Journal of Biomaterials
Volume 2014, Article ID 157952, 7 pages
http://dx.doi.org/10.1155/2014/157952

http://dx.doi.org/10.1155/2014/157952


2 International Journal of Biomaterials

Drug encapsulation and dosage reduction as a result
of a site-specific approach is perhaps the most convenient
way for controlled drug release. The goal of a drug delivery
system is to provide the therapeutic dosage at the proper site
maintaining the drug concentration during a specific release
time. This requires not only a suitable material to hold the
drug, and later release it, but also a biocompatible material,
with high absorption rate and low rejection.Thedevelopment
of porous carriers had assisted drug delivery systems due to
their properties of tunable pore size and well-defined surface
properties, allowing a wide manipulation of the carrier in
order to control the adsorption and release of drugs in amore
reproducible and predictable manner [9]. Herculano et al.
showed that the pore density is inversely proportional to the
polymerisation temperature of natural rubber latex (NRL)
matrix, a strategy that can be used to control drug release
[10].

NRL membrane is an important inductor of the healing
process of wounds, being used in severalmedical applications
like prosthetics and bone grafts [10–17]. In addition, the treat-
ment of diabetic and phlebopathic ulcers with thismembrane
leads to a faster healing process due to a vascular growth
factor found in the latex and due to a physical blockage
of the entrance of new infectious agents in the treated site
[10, 12]. To sum up, the NRL membrane has some interesting
characteristics such as easymanipulation, low cost, the ability
to stimulate natural angiogenesis and cellular adhesion, being
a biocompatible material, and the ability to present high
mechanical resistance [11].

In this work, a novel release system is proposed based on
the encapsulation of CIP in NRL membrane for a sustained
and controlled delivery of the drug, possibly being a future
application in medicine as surgical bandage for bone and
tissue regeneration. Results showed that the NRL membrane
can release CIP for up to 312 h, which is relevant for
biomedical applications. In addition, the X-ray diffraction
(XRD), energy dispersive X-ray spectroscopy (EDS), attenu-
ated total reflection Fourier transform infrared (FTIR-ATR),
and mechanical properties are also reported and showed that
it is relevant for biomedical applications.

2. Materials and Methods

The NRL used in the present study was commercial high-
ammonia from BDF Rubber Latex Co. Ltd. (producer and
distributor of concentrated rubber latex, Guarantã, Brazil) of
about 60% dry rubber content, 4-5% weight of nonrubber
constituents such as protein, lipids, carbohydrates, and sugar,
and 35% of water [18–20]. After extraction, ammonia was
used to keep the latex liquid.The deproteinization of the NRL
was performed by centrifugation at 8,000 g. The cream frac-
tion after centrifugation was redispersed to make the desired
60% of dry rubber content latex and then washed twice by
centrifugation to reduce the cytotoxic protein content on the
solution.

CIP (C
17
H
18
FN
3
O
3
) was purchased from Callithea Phar-

maceutics Ltd., Brazil. CIP was incorporated by mixing 3mL
of NRL with 3mL of drug solution (5mg/mL). In addition,

the drug was found homogeneous (surface and bulk) in the
polymer.

These membranes were prepared by pouring the NRL +
CIP solution in a stainless steel plate with 5.00 ± 0.05 cm
diameter and 200 ± 5.00 𝜇m thickness. Typically the mem-
branes were left for 2 days to fully polymerize at room tem-
perature before use. For the release assay, latex membranes
were placed individually in 200mL of an aqueous solution,
fromwhich aliquotswere collected during an interval ranging
from 10 to 25,000min. The drug released into the solution
was monitored by measuring the UV-VIS spectra with a BEL
ENGINEERING SF 200 ADV spectrophotometer, as CIP has
a maximum absorption at 275 nm.

In order to describe the kinetics of release from
NRL membranes the semiempirical equations (first-order,
Higuchi, Hixson-Crowell, Baker-Lonsdale, and Korsmeyer-
Peppas) were used. To determine the parameter of the
equation the software Sigma Plot 12.5 (from Systat Software)
was used. First-order equation occurs due to differences
in concentration between the carrier and the media of
release (Fickian diffusion) [21], Higuchi equation is applied
to slightly soluble one-dimensionalmatrix that does not swell
[22], and Hixson-Crowell equation is used when surfaces
dimension diminishes proportionally but the initial geometry
keeps constant [21, 23]. In vitro data were also fitted to
Baker-Lonsdale equation, which describes the release from
spherical matrices [21, 23]. When the release follows a non-
Fickian release, a generic equation as Korsmeyer-Peppas
equation can be used, where the value of the release exponent
characterizes the release mechanism of drug from matrix
[21, 22].

The membranes were characterized by X-ray powder
diffraction, using a Siemens D5005 X-ray diffractometer
and a graphite crystal as monochromator to select Cu K𝛼1
radiation (1.5406 Å), in a step of 0.02∘ s−1. The surface
morphology of the NRL membrane was observed using a
scanning electron microscope (SEM) model Zeiss EVO 50
(20KV) and takeoff angle of 35∘.

IR spectroscopy of samples was studied by Fourier trans-
form infrared (FTIR) spectrophotometer in the attenuated
total reflectance (ATR) mode using a VERTEX 70 (Bruker,
Germany) (4000–500 cm−1) with resolution of 4 cm−1.

Tensile tests were carried out on an EMIC DL2000 fitted
with 10 kgf load cell at a speed. The triplicate was pulled
at a rate of 500mm/min (according to ASTM D412) and
elongated to failure at room temperature. NRL membranes
(44 × 15 × 1.0mm, length ×width × thickness) were prepared
with 6mL of pure NRL or with 2mg of CIP.

3. Results and Discussion

Pharmaceutical innovation and research are increasingly
focusing their attention on the development of delivery
systems to enhance desirable therapeutic purposes while
minimizing side effects [9, 24]. For the CIP study, the
interaction between drug and NRL membrane was evaluated
and how it can be incorporated and released from the
membrane was also evaluated. Figure 1 shows the absorbance



International Journal of Biomaterials 3

0.01 0.02 0.03 0.04 0.05

0.4

0.6

0.8

1.0

1.2

1.4

1.6

1.8

Ab
so

rb
an

ce
 (A

U
)

Concentration (mg/mL)

Calibration curve

200 250 300 350
0.0

0.2

0.4

0.6
Ab

so
rb

an
ce

 (A
U

)

Wavelength (nm)

275nm

Figure 1: Absorbance intensity as a function of ciprofloxacin
concentration in solution.

0 10 20 30 40 50

0

200

400

600

800

1000

1200

1400

1600

10 20 30 40 50

In
te

ns
ity

NRL + ciprofloxacin

In
te

ns
ity

 (a
.u

.)

2𝜃 (deg)

2𝜃 (deg)

Ciprofloxacin (5mg/mL)
NRL + ciprofloxacin (5mg/mL)
Natural rubber latex

Figure 2: X-ray diffraction pattern of NRL (black line), cipro-
floxacin powder (blue line), and NRL membrane prepared with
5mg/mL of ciprofloxacin (red line).

intensity as a function of CIP concentration in solution. This
calibration curve is important to establish a pattern between
absorbance and the drug concentration. In this experiment,
several drug concentrations from 0.005 to 0.05mg/mL were
used and then the absorbance of the different solutions was
measured at 275 nm (spectrophotometer LGS53, BEL Pho-
tonics). Using the calibration curve, a sample’s concentration
can be derived by measuring its absorbance and then finding
the corresponding𝑦-axis intercept.Note that the graph shows
the drug’s absorbance range.

Figure 2 shows the X-ray diffraction pattern for the NRL
membrane, CIP powder, and NRL membrane prepared with
5mg/mL of CIP, which indicates the amorphous nature
of NRL, as expected. In contrast, the drug exhibits an X-
ray diffraction pattern of a crystalline material with no

Table 1: Kinetic parameters of equations for mechanism of release
5mg/mL.

𝑅
2
𝑘 (units per hour) 𝑛

Baker-Lonsdale equation 0.88 1.10 × 10
−8 Not applied

Korsmeyer-Peppas equation 1.00 8.00 × 10
−4 1.15

Hixson-Crowell equation 0.99 6.08 × 10
−6 Not applied

Higuchi equation 0.89 2.57 × 10
−2 Not applied

First-order equation 0.99 1.83 × 10
−5 Not applied

amorphous component. Most importantly, its crystallinity
was preserved when incorporated into the NRL membrane
(the lower-intensity peaks are due to traces of the drug). The
changes in the NRL + CIP pattern are caused by the presence
of CIP molecules and can be explained by the drug being
intercalated in the polymeric structure [9, 25].

Figure 3 shows the energy dispersive X-ray spectro-
scopy (EDS) of a NRL membrane (C

5
H
8
), CIP powder

(C
17
H
18
FN
3
O
3
), and NRL + CIP.

The release profile of CIP in a NRL matrix in Figure 4
shows saturation at approximately 170 hours. The large bolus
of drug released before stable profile rates is called “burst
release” (0–25 hours) and it is due to the drug near or
adsorbed on the surface of the NRL membrane [24, 26].

The slower release process, also called “stable profile”
(25–170 hours), could be associated with the CIP diffusing
slowly through the matrix. Thus, the drug is found in the
inner portion of the polymeric matrix. The drug release
depends mainly on the amount of encapsulated material (as
a reservoir).

The experimental data were fitted using a biexponential
function 𝑦(𝑡) = 𝑦

0
+ 𝐴
1
𝑒
−𝑡/𝜏
1 + 𝐴

2
𝑒
−𝑡/𝜏
2 , where 𝑦(𝑡) is the

amount of CIP in the NRL at a given time, 𝑡, 𝑦
0
is the initial

content of the drug,𝐴
1
and𝐴

2
are constants, equal to −0.012

and −0.014, respectively, and the characteristic times are 𝜏
1
=

70.842 hours and 𝜏
2
= 2.548 hours. After integration of these

curves until 312 hours, the total amount of drug released
by the membrane in 200mL aqueous solution was 8.86mg
(59.08%).

The parameters from each kinetic model equation are
shown in Table 1, and the best fit is Korsmeyer-Peppas equa-
tion, due to its high coefficient of determination (𝑅2). From
the equation𝑀𝑡/𝑀∞ = 𝑘 ∗ 𝑡𝑛, where𝑀𝑡/𝑀∞ (only less
than 0.6 should be used) is a fraction of the drug released at
time 𝑡, 𝑘 is the release rate constant (units per time), and 𝑛 is
the release exponent.

The 𝑛 characterizes the release mechanism, where 𝑛 <
0.5 corresponds to Fickian diffusion, 0.5 < 𝑛 < 1.0
corresponds to anomalous transport (non-Fickian diffusion),
𝑛 = 1.0 corresponds to relaxation of the polymer fibers (case
II transport), and 𝑛 > 1.0 corresponds to super case II.

The 𝑛 obtained indicates that the release mechanism for
CIP fromNRL is due to super case II.The release from a poly-
mericmatrix is dependent on the solubility of the compound,
erosion/degradation, swelling, and relaxation of the carrier
[22]. In super case II (non-Fickian) transportmechanism, the
velocity of solvent penetration in the carrier is higher than



4 International Journal of Biomaterials

(a) (b)

(c)

Figure 3: SEM-EDS spectra of (a) NRL membrane, (b) ciprofloxacin powder, and (c) NRL membrane + ciprofloxacin. Note that the drug is
present in the NRL matrix.

0 50 100 150 200 250 300
0.000

0.005

0.010

0.015

0.020

0.025

0.030

Ci
pr

ofl
ox

ac
in

 co
nc

en
tr

at
io

n 
(m

g/
m

L)

Time (hours)

Ciprofloxacin release

NRL + ciprofloxacin

Figure 4: Ciprofloxacin release as a function of time for NRL
membrane prepared at room temperature. Notice that the drug
concentration reaches a plateau after approximately 170 h.

the relaxation and swelling [27] of the polymer; this finding
may be due to the natural cross-linking in the NRL and the
low swelling and degradation due to its hydrophobicity [28].
Similarly, Verma et al. [27] demonstrated that the super case
II transport also happens to some formulations of chitosan to
release CIP.

Figure 5 shows the FTIR-ATR spectra of CIP, NRL, and
NRL loaded with CIP. In all spectra, absorption band from

3500 to 3450 cm−1 is due to the stretching vibrations of the
hydroxyl group or the intermolecular hydrogen bonding.

FromFTIR spectra of CIP (Figure 5), it was found that the
peak at 3524 cm−1 is attributed to the stretching vibrations of
O–Hof the carboxylic group.At 1705 and 1620 cm−1 the peaks
are due to the stretching vibrations of the carbonyl group of
carboxylic acid and ketone, respectively. The 1444 cm−1 peak
is attributed to C–H bending or C–O, the 1271 cm−1 is due to
C–C–C of ketone, and the 1045 cm−1 is due to C–F [27, 29–
31].

The NRL FTIR spectra showed the isoprene absorption
peaks at 2956 and 2915 cm−1 due to CH

2
asymmetric stretch-

ing, at 2851 cm−1 it is due to CH
2
symmetric stretching, at

1662 cm−1 it is due to C=C stretching, at 1371 cm−1 it is due
to CH

3
asymmetric deformation, and at 840 cm−1 it is due

to =CH out-of-plane bending [32]. Furthermore, functional
groups of phospholipids and proteins have also been found at
1584, 1217, and 1036 cm−1 that are related to N–H bending,
C–O, and –O–O–, respectively [28]. The FTIR spectra of
the NRL incorporated with CIP showed interaction. The
overlapped band in the region of 3700–3200 cm−1 and the
slight shift of the bands attributed to the carbonyl group
indicate some interaction, most likely by hydrogen bonding,
which were also observed on chitosan [29].

The addition of CIP to the NRL membrane had influence
on the mechanical behavior of NRL (Figure 6). The new
material became stiffer and brittle, with a smaller plastic



International Journal of Biomaterials 5

Table 2: Mechanical properties.

Breaking force Tensile strength Elongation at break Young’s modulus
(N) (MPa) (%) (MPa)

NRL + CIP 9.23 ± 0.57 0.58 ± 0.085 750.00 ± 22.61 0.86
NRL 10.95 ± 0.85 0.76 ± 0.019 911.60 ± 12.60 0.68

4000 3500 3000 2500 2000 1500 1000 500

Tr
an

sm
itt

an
ce

 (%
)

–(C=O)–O–H

N–H

–O–O–
C=C

–(C=O)–

C–F

NRL
CIP
NRL + CIP

O–H

1578 cm−1

1
0
5
0

cm
−
1

2851 cm−1

1657 cm−1

2915 cm−1

1584 cm−1

1662 cm−1

1036 cm−1

2956 cm−1

1620 cm−1
1705 cm−1

3524 cm−1

CH2

Wavenumber (cm−1)

Figure 5: FTIR-ATR spectra of ciprofloxacin, NRL, andNRL loaded
with ciprofloxacin.

0 2 4 6 8 10

0.0

0.2

0.4

0.6

0.8

NRL
NRL + ciprofloxacin

𝜎
(M

Pa
)

𝜀 (mm/mm)

Figure 6: Representative stress-strain curvesNRL and ciprofloxacin
loaded NRL.

deformation (less ductile). Table 2 shows that the addition of
CIP reduced 1.2 times the elongation at break and reduced the
tensile strength.

The increase of hydrogen bonding with the incorporation
of CIP indicates interaction of the drug with rubber macro-
molecules, leading to higher interfacial interactions, acting as
reinforcement or creating cross-linking [33]which resulted in
loss of elasticity [34].

In this work, the method proposed by Langer and
Folkman was used [35], that is, to mix the protein with
the polymer (latex) in a colloidal state, in order to create a
membrane that works as a delivery system.

Already Löbler et al. [36] developed a device based on
polyhydroxyalkanoates (PHA) for implantation of a glau-
coma drainage system. In this study, PHA based on hydrox-
ybutyric acid was tested in terms of its potential suitability
tomanufacturemechanically stable tube components of drug
delivery drainage systems and in terms of biocompatibility.

Herculano et al. [10] proposed a drug release system
based on NRL for the sustained and controlled delivery of
metronidazole (MET). They concluded that the release time
of MET in in vitro tests was very promising for the kinetics of
release.

Wang et al. [37] prepared uniform-sized chitosan micro-
spheres by membrane emulsification technique. Uniform
chitosan microspheres were further used as a carrier of a
protein drug bovine serum albumin (BSA). They observed
that BSA loading efficiency was highest when pH value was
8.09, and it decreased with an increase of the cross-linking
degree.

The controlled release of proteins is of interest formedical
applications, since the dose can be adjusted according to
the application envisaged. The results indicate that, with
very simple changes in preparation of NRL membrane, it is
possible to control CIP release up to 13 days, according to
Wang et al. [37], Woo et al. [38], Herculano et al. [39, 40],
Malcolm et al. [41], and Langer and Folkman [35] results.

4. Conclusion

We have prepared NRL membranes containing CIP as a
model system for tissue and bone regeneration. The method
of preparation is reproducible and the NRL membrane is
very stable. The results indicate that NRL could be a future
candidate to be used as a drug delivery membrane. From the
results obtained with FTIR and mechanical behavior assay,
hydrogen bonding interactions between CIP and NRL mem-
brane can be observed. Nevertheless, theNRLmembranewas
able to release 59.08% of the drug in 13 days and could be



6 International Journal of Biomaterials

fitted by a biexponential equation which can help to predict
the release of the drug.The Korsmeyer-Peppas kinetic model
of release indicates that the mechanism of release is due to
super case II transport (non-Fickian diffusion). In addition,
the X-ray spectroscopy technique shows that the drug did not
interact chemically with the membrane. Likewise, the crystal
structure of CIP was essentially maintained, which shows the
encapsulation of the drug within the amorphous membrane.
The SEM-EDS and the release assay indicated that CIP was
present both inside and on the surface of the polymeric
matrix, thus making it a promising material for drug release
in in vivo applications. The possibility of a new treatment
method for osteomyelitis and skin wound with a surgical
bandagemade of NRL and CIP is promising.The use of lower
drug doses and the control of drug delivery and site-specific
releasemay improve the healing process and the quality of life
of the patient and, in addition, can reduce the indiscriminate
use of antibiotics. Further research is required to fulfill these
predictions, such as in vitro studies focusing on the release
rate and time and porosity required to achieve therapeutic
effect and in vivomodels to study the efficiency of the surgical
bandage theory. Other carriers can be tested, as alginate-
chitosan [42], carrageenan [43], and pectin [44], whichmight
also be promising candidates; however the characteristics and
availability of NRL in Brazil make it an attractive material for
further investigation.

Conflict of Interests

The authors declare that they have no conflict of interests.

Authors’ Contribution

This work was carried out in collaboration between all
authors. Heitor Dias Murbach, Guilherme Jaques Ogawa,
Bruno de Camargo Drago, and José Luiz Ferreira Cinman
performed the experiments. Felipe Azevedo Borges, Matheus
Carlos Romeiro Miranda, Natan Roberto de Barros, and
Rondinelli Donizetti Herculano wrote the draft of the paper.
In addition, the authors confirm that Rosângela Gonçalves
da Silva and Alexandre Vinicius Guedes Mazalli had con-
tributed to the paper. They contributed to the analyses of
the mathematical model of the mechanism of release. In
addition, Guilherme Jaques Ogawa and Rute Lopes had
corrected the typographical and grammatical errors. Finally,
the format of the paper has been updated by Matheus Carlos
RomeiroMiranda, Rute Lopes, andNatan Roberto de Barros.
Rondinelli Donizetti Herculano is the advisor and the head of
laboratory. All authors read and approved the final paper.

Acknowledgments

This work was supported by CNPq (Conselho Nacional de
Desenvolvimento Cient́ıfico e Tecnológico), FUNDUNESP
(Fundação para o Desenvolvimento da UNESP), PROPe/
UNESP (Pró-Reitoria de Pesquisa da UNESP), and FAPESP
(Fundação de Amparo à Pesquisa do Estado de São Paulo,
Processes: 2011/17411-8) (Brazil).

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