Katı Lipit Nanopartiküller Kullanılarak Kolloidal Mikrokapsül Üretimi
Özet
Nanoparticles have been driving much attention in the last years since they can be
used both in scientific studies and in medical and technological applications,
Nanoparticles can be synthesized by utilizing a variety of constituents, among
which the most studied ones are metallic, polymeric and lipid based nanoparticles.
The size, shape, and the surface functionalities of nanoparticles as well as the
material which is synthesized vary in accordance with and relative to their target
applications. Solid lipid nanoparticles (SLNs), which are synthesized by using
various physiological lipids, emulsifiers and water, have first come into use as an
alternative nanocarrier in 1990s. Due to their high biocompatibility, stability and
availability/efficiency to encapsulate various active materials, SLNs are positively
distinguished from other alternatives in many fields, pharmaceutical and
biomedical applications in particular. In addition, since they possess biocompatible
and physiologically related raw materials and adjustable release kinetics which
depend on the synthesis method, SLNs are an ideal alternative to be used in the
body for different purposes and with various administration routes. In the first
stage of the study, it has been aimed to prepare and characterize SLNs with
proper size and surface functionalities to calculate their drug
encapsulation/release capacities. In order to characterize the SLNs which are
prepared by using “Microemulsion Method”, Atomic Force Microscopy (AFM) and
v
Dynamic Light Scattering (DLS) have been utilized to get information regarding
size, the polydispersity, and geometry, while zeta potential measurements have
brought out surface charge density of the SLNs prepared. Moreover, thermal
properties and morphological structures of SLNs have been studied in detail with
Differential Scanning Calorimetry (DSC) technique. The size and zeta potential
values of SLNs have been re-measured three months after the synthesis in order
to evaluate high long-term stability feature, which is cited as one of the major
advantages of SLNs in literature. Ascorbic acid (AA) and methylene blue (MB)
have been used as model drugs to evaluate the drug encapsulation/release
capacities of SLNs prepared with certain specifications. MB has been attached to
the surface of the SLNs with electrostatic interaction whereas AA has been loaded
in the particle structure during the synthesis. Drug encapsulation/release
capacities have been analyzed by UV-vis spectrophotometry. In the second part of
the study SLNs have been used as building block to prepare colloidal
microcapsules. It is very common to use metallic nanoparticles to prepare
microcapsule structure. The synthesis of MCs whose shell-side is constructed by
SLNs, is the first in literature. While polystyrene particles and Ibuprofen drug
crystals have been used as the core material, SLNs, gold nanoparticles and
chitosan have been used in the shell-side. The shell of the MCs has been
prepared with “Layer-by-layer method” with use of electrostatic interaction of
materials. The coating performance of each layer has been monitored by
measuring zeta potential changes after each layer of coating. In addition, the
layers have been viewed with Scanning Electron Microscope (SEM). In addition,
encapsulation/release performance of MCs was investigated by using these
predetermined model molecules. As a result, the introduced MCs by this thesis
which has produced by using SLNs as building blocks has been achieved for the
first time in literature and a good alternative for both multiple drug delivery and as
a diagnostic tool which will launce lots of new project for more functional drug
delivery vehicles. What is more, with gold nanoparticles added to the MC
structure, new- generation colloidal structures have been produced which can be
used in both diagnosis and treatment.
