THE FORMATION AND CHARACTERIZATION OF CHITOSAN LIQUID CRYSTALS AS TRANSDERMAL PREPARATION CARRIER SYSTEMS
Liquid crystal is an intermediate phase between liquid and solid, therefore also called mesophase. In this phase the substance has the properties like a liquid but has the characteristics of a rigid arrangement and the orientation of molecules like crystalline solids. Nowdays, the use of liquid c...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/52088 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Liquid crystal is an intermediate phase between liquid and solid, therefore also
called mesophase. In this phase the substance has the properties like a liquid but
has the characteristics of a rigid arrangement and the orientation of molecules like
crystalline solids. Nowdays, the use of liquid crystals in medicine and pharmacy
has developed. Applications of liquid crystal in pharmaceuticals i.e as carriers of
drugs and cosmetics, increasing in solubility of poor water-soluble drug, controling
of drug release, and for drug stability. The material that can form liquid crystals is
called mesogen, can be formed from surfactants, polymer or drugs. Research of
liquid crystal in pharmaceutical applications mostly was performed from mesogen
surfactants and lipids. However, liquid crystal from polymers as mesogen,
especially hydrocolloid polymer is limited.
Chitosan (CH) is the natural hydrocolloid polymer which qualify as liquid crystalforming (mesogen) and potential to be applied as transdermal gel delivery system.
CH is ampiphile and anisotropic polymer so it can be self-assembly to form a liquid
crystal system. However, studies that examine the formation and characteristics of
liquid crystals in order to be applied in pharmaceuticals, such as drug/cosmetic
carriers are still very limited. The purpose of this research is to study the formation
of CH liquid crystals for pharmaceutical applications as a transdermal carrier
system. Caffeine anhydrous and sodium diclofenac were used as a model of the
drug.
The study was begun by characterization of physicochemical properties of CH
including crystal habit examination, X-ray diffraction analysis, thermal analysis
with DSC (Differential Scanning Calorymetry), and determination of CH molecular
weight by high presure gel permeation chromatography (HP-GPC). Screening
formation of CH liquid crystal systems is carried out by using a liotropic system
(with solvents). Several acids such as citric acid (CA), tartaric acid (TA), ascorbic
acid (ASC), lactic acid (LA) at various concentrations (5 to 20% w/w) were used to
dissolve CH to explore the impact on liquid crystals formation. CH with variations
in variously concentration in the range of 5-20% w/w (2.5% interval) was dissolved
in each of these solvents, homogenized with magnetic strirer at 200 ppm at room
temperature for 30 minutes in a tightly closed vial and evaluated after 2 days.
Evaluation of liquid crystal system was carried out by using a polarization
microscope/PLM), DSC, FTIR spectroscopy, and SAXS (Small Angle x-ray
Scattering). The results was expected to provide conclusions about the behavior and
characteristics of a stable CH liquid crystal system which can later be expected to
be applied to topical gel delivery systems that lead to the development of
transdermal gel preparations.
Furthermore, the trigger factors that can increase the self-assembly capability of
CH to form a rigid system in the liquid/semi-solid phase are found. The trigger
factors are physical (temperature and mechanical factors) and chemical factors. CH
gel was made and observed with the temperature raised at 60?and cooled again.
For mechanical factor, CH gel was change to a film form by using a film device
maker and dry at room temperature. Sodium diclofenac and anhydrous caffeine
were applied to gels and films, respectively. The gels and films were characterized
by polarizing microscopy, XRD and SAXS. The influence of chemical factors was
studied by modifying the CH which makes it more hydrophobic by adding fatty
acids (palmitic acid/PA). Chitosan-palmitate (CHPA) was formed into a binary
lyotropic system (dispersing it in acid solvents) and ternary lyotropic systems
(dispersing in acid solvents and adding oil). Both of these systems were used as
carriers for transdermal device with anhydrous caffeine and sodium diclofenac as
drug models.
Characterization of CH showed that CH is semicrystalline polymer with irregular
habits. Molecular weights of CH was 145 ± 3.94 kDa with specific characteristic
CH peaks 2?were 10.76° and 20.69° based on the confirmation results of FTIR,
XRD, and DSC and GPC. The result of screening of CH liquid crystal formation
show that it can be formed in 10 and 20% of CA, 10 and 20% of TA, 10% ASC
with the final pH of the system in the range of 2.5-4.5. CH will dissolve in dilute
organic acids at pH below pKa CH (pKa 6.3) and can form a gel at a lower pH.
Because of increasing the CH concentration above the pH of the gel formation (c*),
CH will be able to form a liquid crystal system which is indicated by the presence
of birefringence on the polarizing microscope. Characterization was performed by
microscope polarization to determine c* (the lowest concentration at which
birefringence. For further research, CA and TA were used because the system which
used CA and TA were more stable than LA and ASC. The SAXS results from CH
hydrogel in CA and TA show that the hydrogel structure has not shown ordered
structure, but has shown a hierarchical domain. In general, the higher the
concentration of CH the more the domain of the hierarchical is formed. The radius
of the domain formed in the region 1<q<4 nm
-1
(high q range) is around 0.7-0.9 nm
and at low q (0.1<q<1 nm
-1
) there is a domain cluster with a radius of 4-8 nm
indicated at all concentrations of CH in CA and TA 10%.
The research to determine the trigger factors for the structure of the CH hydrogel
system, including physics and chemistry, shown that physical factors (mechanical
and temperature) factors affect the stability of the drug model, especially caffeine.
It refers to characterization with polarization microscopy, XRD and SAXS of
hydrogels. CH gel can prevent caffeine recrystallization in aqueous carriers. The
SAXS results from this system of gel and CH films still show there is no an orderly
molecular arrangement (ordered structure) as shown by SAXS results even though
birefringence has been seen on a polarizing microscope. Meanwhile, for chemical
factors, modifying CH into more lipophilic by the addition of fatty acids (palmitic
acid / PA) can produce CH that can form a lyotropic system (liquid crystal) based
on the results of characterization with polarization microscopy, DSC, XRD and
SAXS. The SAXS pattern shows the existence of a CHPA lyotropic system that has
regularity with the lamellar structure, both binary and ternary systems.
Penetration test was carried out on CH gel system, the CHPA binary system and the
CHPA ternary system in order to study penetration of caffeine and sodium
diclofenac from the device. Penetration studies were done through in vitro diffusion
tests with Franz diffusion cells using snake skin membrane with Python Reticulus
sheed snake skin. In general, penetration both of caffeine and sodium diclofenac in
carriers with a liquid crystal system was better than ordinary gel of CH. Penetration
of caffeine, a hydrophylic drug was better in ternary system of liquid crystals CHPA
rather than in binary system. In contrast to lipophilic drug sodium diclofenac, its
penetration capability is better in binary CHPA liquid.
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