Photopolymerization of Methacrylated Chitosan/PNIPAAm Hybrid Hydrogels PDF

Summary

This research article details the photopolymerization of methacrylated chitosan/PNIPAAm hybrid hydrogels as drug delivery carriers, focusing on their dual sensitivity to pH and temperature. The authors investigated the hydrogel's properties using techniques such as FT-IR, DSC, and SEM, exploring their potential applications, particularly for controlled drug release.

Full Transcript

International Journal of Biological Macromolecules 44 (2009) 229–235

Contents lists available at ScienceDirect

International Journal of Biological Macromolecules
journal homepage: www.elsevier.com/locate/ijbiomac

Photopolymerization of methacrylated chitosan/PNIPAAm hybrid
dual-sensitive hydrogels as carrier for drug delivery
Jing Han, Kemin Wang, Dongzhi Yang, Jun Nie ∗
State Key Laboratory of Chemical Resource Engineering, The Key Laboratory of Beijing City on Preparation and Processing of Novel Polymer Materials,
Beijing University of Chemical Technology, Beijing 100029, PR China

a r t i c l e i n f o a b s t r a c t

Article history: A series of hybrid hydrogels based on glycidyl methacrylated chitosan (CS-GMA) and N-
Received 22 November 2008 isopropylacrylamide (NIPAAm) were designed and prepared via photopolymerization technology. The
Received in revised form 11 December 2008 hydrogels were characterized by Fourier transform infrared (FT-IR), differential scanning calorimetry
Accepted 15 December 2008
(DSC) and optical transmittance. The interior morphology of hydrogels was investigated by scanning
Available online 25 December 2008
electron microscopy (SEM). The swelling experiment results revealed that hybrid hydrogel exhibited
combined pH and temperature sensitivities. Acid orange 8 (AO8) and 5-flurouracil (5-Fu) were selected as
Keywords:
model drugs for examining their release from hydrogels. The results suggested that hydrogel composition
Hybrid hydrogel
Chitosan
and pH value of buffer solution had great influences on release profiles.
Poly(N-isopropylacrylamide) © 2008 Elsevier B.V. All rights reserved.
Drug delivery

1. Introduction groups. Besides, chitosan has several favorable biological properties
such as excellent biocompatibility, non-toxicity and biodegradabil-
Over the last several decades, considerable research attention ity. Further, chitosan is natural cationic polyelectrolytes, which
has been focused on hydrogel materials, especially environment could be used to synthesize gene carriers or drug carriers based on
sensitive hydrogels (smart hydrogels or intelligent hydrogels), interaction of charges.
which change their various properties in response to slight envi- Poly(N-isopropylacrylamide) (PNIPAAm) is one of the most
ronmental stimuli such as pH , temperature , ionic strength well-known temperature sensitive polymer, exhibiting a lower crit-
, light , electric field and magnetic field. These environ- ical solution temperature (LCST) at 32 ◦ C [16–18]. There exists
ment sensitive hydrogels have potential applications in biomedical a hydrophilic/hydrophobic balance in the NIPAAm unit resulting
and pharmaceutical areas. Intelligent hydrogels have been studied from the hydrophilic (amide group) and hydrophobic (isopropyl
for controlled drug delivery , molecular separation and tissue group) regions of the PNIPAAm. Below the LCST, hydrogen bonding
engineering. between hydrophilic segments and water molecules are domi-
Among these smart hydrogels, pH and temperature sensitive nant, leading to enhanced dissolution or swelling in water. As the
hydrogels have been most widely investigated because these two temperature increases, hydrophobic interactions among hydropho-
factors are crucial to human body. For example, the large differences bic segments become strengthened, while the hydrogen bonding
of pH value between stomach ( Sample C2 > Sample C1 due
hybrid hydrogels were much faster that of PNIPAAm hydrogel. After to the different chitosan composition ratio. The result demonstrated
100 min in 37 ◦ C distilled water, the SR of Samples C1, C2 and that swelling rate and SReq could be controlled via composition ratio
C3 reached 50, 75 and 140%, respectively. In the contrast, the SR of chitosan and NIPAAm.
of PNIPAAm exhibited only approximately 10% within the same
time frame. Although PNIPAAm owned hydrophilic amide groups, 3.7. pH and temperature dependence of SReq
PNIPAAm hydrogel exhibited shrinking state at 37 ◦ C due to the
dominant hydrophobic interaction. The introduction of chitosan Polyelectrolyte hydrogels show pH-sensitivity due to the ionic
enhanced the SR of hybrid hydrogel at 37 ◦ C for hydrophilic nature reaction. In present work, the pH value of the external buffer solu-
of chitosan bearing a large amount of hydrophilic groups including tion had been varied in the range from 2.2 to 8.0 and the effect on the
hydroxyl and amino groups. Besides, covalently crosslinked struc- SReq of hybrid hydrogels was shown in Fig. 7. All hybrid hydrogels
ture between chitosan and PNIPAAm chains would influence the (Samples C1, C2 and C3) had the similar swelling tendency: the SR of
hydrophobic interaction between hydrophobic isopropyl groups. hybrid hydrogels decreased gradually as the pH value of buffer solu-
tion increased from 2.2 to 8.0. However, the SR of PNIPAAm hydrogel
(Sample B) did not exhibit obviously difference with the variation of

Fig. 6. Swelling kinetics of various compositions hydrogels. Fig. 7. Equilibrium swelling ratio of hydrogels at different media value at 37 ◦ C.
234 J. Han et al. / International Journal of Biological Macromolecules 44 (2009) 229–235

the differences of SR of hybrid hydrogels between 25 and 37 ◦ C were
affected by pH value of buffer solution. Generally, the differences
of SR at acidic solution were more obvious than those at neu-
tral solution. In hybrid hydrogels PNIPAAm chains behaviors were
influenced by chitosan chains because of covalently crosslinked
structure. In acidic solution, chitosan exhibited swelling state and
thus the degree of freedom of PNIPAAm chains was bigger. As a
result, the differences of SR between 25 and 37 ◦ C were larger than
those at neutral solution.

3.8. Drug release analysis

Hydrogels are widely used in drug delivery systems for their
excellent biocompatibility and permeability. Drug release from
hydrogel matrices is influenced by many factors including the pro-
cesses of swelling, diffusion and erosion therefore its assessment
is complicated by the limitations of the in vitro evaluation proce-
dures. Drug–polymer interactions, network porosity, and degree of
hydrophilicity of the matrix are also important factors influencing
Fig. 8. Comparison of swelling ratio of hybrid hydrogels in different external condi-
controlled release.
tions. In this paper, AO8, and 5-Fu were selected as controlled release
model drugs and their molecule structures are shown in Fig. 9. AO8
as an acid dye bearing sulfonate group might bound to chitosan
pH value at 37 ◦ C. Chitosan derivate (CS-GMA) as cationic polyelec-
due to ionic interaction as reported. The binding of drug to chi-
trolytes bearing a large amount of amino groups dissolved more or
tosan is dependent on pH value of condition, which influences the
swelled more if crosslinked at low pH value due to amino ioniza-
release behavior. 5-Fu is a commonly used anticancer drug for
tion. The amino group protonated from NH2 to NH3 + with pH value
a variety of malignancies, including cancers of the colon, head and
ranging from 8.0 to 2.2, which changed the electrostatic repulsion
neck, breast and skin. The sustained releases of 5-Fu are desirable
among charges present on chitosan chains and thus influenced the
in cancer therapy and have been investigated widely [32–34].
SR of hydrogels. Fig. 7 also implied the dependence of SReq on the
Release kinetics of AO8 from hybrid hydrogel (Sample C2) in
composition of CS-GMA/PNIPAAm hybrid hydrogel at 37 ◦ C. The SR
buffer solution (pH 2.2 and 7.4) at 37 ◦ C was depicted in Fig. 10. Evi-
of hydrogels reduced in the order Sample C3 > Sample C2 > Sample
dently, the release of AO8 was strongly dependent on pH value. At
C1 > Sample B in various buffer solution. The reduction in SR from
pH 7.4, AO8 released gradually from hydrogel; whereas the release
Sample C3 to Sample B was attributed to the decrease of chitosan
rate was rather low in pH 2.2 buffer solutions. Such release behavior
derivative composition ratio. The hydrophilic nature of chitosan
could be explained by the pH-dependent interaction between AO8
contributed to SR of hybrid hydrogels. At 37 ◦ C, hydrophobic inter-
and hydrogel. At pH 2.2 the sulfonate group of AO8 dissociated and
action among hydrophobic segments in PNIPAAm was dominant
was converted to dye anions, while at pH 7.4 AO8 existed in the form
which led to the shrinking state of PNIPAAm. Thus PNIPAAm chain
of undissociated molecule. In acid solution chitosan behaved as
contributed little to SR of hybrid hydrogels at 37 ◦ C. Therefore, the
a cationic polyelectrolyte due to protonation of the amino groups.
reduction of chitosan derivative in composition caused the decline
It is reported the amino groups of the chitosan are at pH 4.2 pro-
of SR. At the same time, the reduction of CS-GMA led to the decrease
tonated to form cationic amino groups, but chitosan should have
of amino groups which influence the pH sensitivity of hybrid hydro-
very low positive charge at pH 6.5. Therefore, the interaction
gels.
based on the formation of chitosan–NH3 +/− O3 S-dye exited in acid
The temperature dependence of SR of hydrogels was illustrated
solution. There was a lack of strong interaction of AO8 with chitosan
in Fig. 8. Though Sample C2 did not exhibit obvious phase transition
measuring by DSC and optical transmittance, the SReq of Sample
C2 was greatly dependent on temperature as well as Sample C1 in
buffer solution with various pH values. At 25 ◦ C both Samples C1 and
C2 showed higher SR than those of them at 37 ◦ C. At 25 ◦ C, PNIPAAm
chains exhibited swelling state due to the strong hydrogen bond
interaction between amide group and water molecules. At 37 ◦ C,
PNIPAAm chains showed shrinking state because of the strength-
ened hydrophobic interaction between hydrophobic groups among
PNIPAAm chains which led to sharp decline of SR. It was found that

Fig. 9. The molecule structures of model drugs. Fig. 10. Cumulative release profiles of AO8 from hybrid hydrogels in different media.
 J. Han et al. / International Journal of Biological Macromolecules 44 (2009) 229–235 235

of hydrogels. Further, the hydrogels were used as drug carriers for
controlled drug release study. The pH value of external buffer solu-
tion had great effect on drug release rate due to the interaction
between drug and hydrogel network. At the same time, hydrogel
composition also influenced the release rate based on the release
experiments results.

Acknowledgements

The authors are grateful to the Program for Changjiang Schoolars
and Innovative Research Team in University.

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