Hydrophobic modification of chitosan nanoparticles for increased therapeutic delivery and anticancer properties towards human cancer cell lines
Lung cancer is the leading cause of cancer-related deaths for men and second for women worldwide, with approximately 1.6 million of deaths reported annually. Conventional delivery of anticancer drugs for treatment is less effective due to intrinsic obstacles such as poor aqueous solubility and po...
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| Format: | Thesis |
| Language: | English |
| Published: |
2020
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| Subjects: | |
| Online Access: | http://psasir.upm.edu.my/id/eprint/90666/1/FBSB%202020%2013%20-%20IR.pdf http://psasir.upm.edu.my/id/eprint/90666/ |
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| Summary: | Lung cancer is the leading cause of cancer-related deaths for men and second for
women worldwide, with approximately 1.6 million of deaths reported annually.
Conventional delivery of anticancer drugs for treatment is less effective due to
intrinsic obstacles such as poor aqueous solubility and poor cellular accumulation
of drugs. Additionally, chemotherapy incurs various concomitant undesirable side
effects including cytotoxicity, cardiotoxicity and neurotoxicity. Thus, the utilization
of natural anticancer therapeutics as an alternative is required to prevent these
undesirable consequences. Silibinin (SLB) is a poorly-soluble plant extract derived
from Silybum marianum which is commonly used for treatment of liver diseases.
SLB exhibits anti-cancer properties by inhibiting cell growth, angiogenesis,
proliferation, cell migration and inducing apoptotic death. However, poor solubility
and cell accumulation of SLB limits the use of this compound as an alternative
anticancer therapeutic. Therefore, the employment of nanotechnological-based
applications have aided in the advancement of better diagnosis and more efficient
treatment of cancer. Additionally, the utilization of nanoparticulate delivery can
reduce the dosage of the natural therapeutic compound, reducing potential side
effects of therapeutics. Based on the results, a low encapsulation efficiency was
achieved by conventional chitosan nanoparticle (CNP) system. This necessitates
modification of the CNP through hydrophobic modification to develop a palmitoylchitosan
nanoparticle (pCNP) system for enhanced encapsulation efficiency and
therapeutic efficacy. Various physico-chemical characterization analyses was
conducted to evaluate the pCNP system. Utilization of free amine percentage of
pCNP increased by 15% due to the conjugation of –NHS palmitic acid to the
polymer, in addition to TPP. The pCNP synthesized revealed an expansion in size and decrease in polydispersity index (PDI) compared to CNP, indicating greater
monodispersity in pCNP. The encapsulation of SLB into pCNP showed an
expansion in size and PDI, signifying the heterogeneity of nanoparticles after
encapsulation and correlating to morphological analyses. Moreover, the
encapsulation efficiency improved 1-fold from 25% of CNP-SLB to 50% of pCNPSLB.
Subsequently, MTT cytotoxicity assay showed enhanced efficacy of pCNPSLB
over CNP-SLB and free SLB. It was found that pCNP-SLB was most
competitive in A549 cell line compared to SW620 and 786-O cell lines as shown
by the lowest IC50 value of 7.77 μM among different cancer cell lines and time
points. Further study conducted using A549 cell line has demonstrated that pCNPSLB
has enhanced the anti-invasive effect of SLB through cell migration assay
and suggested the synergistic effect between pCNP and SLB. On the other hand,
Annexin V apoptosis assay and cell cycle analysis have also shown that pCNPSLB
revealed a correlated results of enhanced apoptotic death and G1 cell cycle
arrest in A549 cells with sustained release properties. These results have
therefore revealed the enhanced therapeutic efficacy and sustained release
properties of pCNP-SLB which required low dosing to achieve high therapeutic
efficacy. Additionally, subsequent study on pCNP encapsulation on protocatechuic
acid (PCA) has revealed that pCNP can be utilized to other poorly soluble
compounds other than SLB. Conclusively, various physico-chemical analyses
have indicated the modification on CNP system and signified the successful
encapsulation of SLB into pCNP. Besides, the in vitro cellular study has suggested
an enhanced therapeutic efficacy of pCNP-SLB compared to conventional CNPSLB
and free SLB towards A549 cells with sustained release properties. This
system can potentially be developed into novel delivery system for many other
hydrophobic therapeutics to aid in pharmaceutical and biomedical fields. |
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