EXPLORATION OF THE INULIN POTENTIAL AS A TARGETED DRUG DELIVERY SYSTEM IN CANCER THERAPY: DFT INVESTIGATION AND MOLECULAR DYNAMICS SIMULATION
According to World Health Organization (WHO) data, cancer is a fatal disease. Chemotherapy, which many people rely on for treatment, has various negative effects that are dangerous to normal cells. A potential treatment for this problem is the development of a drug delivery system. Density functi...
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id-itb.:813742024-06-20T13:20:03ZEXPLORATION OF THE INULIN POTENTIAL AS A TARGETED DRUG DELIVERY SYSTEM IN CANCER THERAPY: DFT INVESTIGATION AND MOLECULAR DYNAMICS SIMULATION Andrew Sudijanto, Jason Indonesia Theses 5-fluorouracil; DFT; drug delivery; inulin INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/81374 According to World Health Organization (WHO) data, cancer is a fatal disease. Chemotherapy, which many people rely on for treatment, has various negative effects that are dangerous to normal cells. A potential treatment for this problem is the development of a drug delivery system. Density functional theory (DFT) was used in this study to thoroughly investigate the potential of inulin as a drug delivery agent for 5-fluorouracil (5FU). The binding energy resulting from the docking of 5FU into inulin was 13.22 kJ/mol. The structures of inulin, 5FU, and the In-5FU complex were optimized. The In5FU complex has been shown to have a highly stable structure. By reviewing the ?H and ?G values, it was found that In-5FU is an exothermic and non-spontaneous process at 287 K. Additionally, non-covalent interactions were described and simulated as part of the complicated stabilizing process using NBO, NCI-RDG, and IGMH studies. Charge decomposition analysis (CDA) was used to learn more about the charge-transfer process. ?EELEC contributed significantly to the stabilized structure based on ALMO-EDA analysis. The calculations in the excited state showed a 67.12 nm redshift in the ?max of the In-5FU complex in the solvent phase. In conclusion, the analyses revealed that inulin is a good transporter for delivering 5FU to certain areas within cancer sites. text |
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| description |
According to World Health Organization (WHO) data, cancer is a fatal disease.
Chemotherapy, which many people rely on for treatment, has various negative effects that
are dangerous to normal cells. A potential treatment for this problem is the development
of a drug delivery system. Density functional theory (DFT) was used in this study to
thoroughly investigate the potential of inulin as a drug delivery agent for 5-fluorouracil
(5FU). The binding energy resulting from the docking of 5FU into inulin was 13.22
kJ/mol. The structures of inulin, 5FU, and the In-5FU complex were optimized. The In5FU complex has been shown to have a highly stable structure. By reviewing the ?H and
?G values, it was found that In-5FU is an exothermic and non-spontaneous process at
287 K. Additionally, non-covalent interactions were described and simulated as part of
the complicated stabilizing process using NBO, NCI-RDG, and IGMH studies. Charge
decomposition analysis (CDA) was used to learn more about the charge-transfer process.
?EELEC contributed significantly to the stabilized structure based on ALMO-EDA
analysis. The calculations in the excited state showed a 67.12 nm redshift in the ?max of
the In-5FU complex in the solvent phase. In conclusion, the analyses revealed that inulin
is a good transporter for delivering 5FU to certain areas within cancer sites.
|
| format |
Theses |
| author |
Andrew Sudijanto, Jason |
| spellingShingle |
Andrew Sudijanto, Jason EXPLORATION OF THE INULIN POTENTIAL AS A TARGETED DRUG DELIVERY SYSTEM IN CANCER THERAPY: DFT INVESTIGATION AND MOLECULAR DYNAMICS SIMULATION |
| author_facet |
Andrew Sudijanto, Jason |
| author_sort |
Andrew Sudijanto, Jason |
| title |
EXPLORATION OF THE INULIN POTENTIAL AS A TARGETED DRUG DELIVERY SYSTEM IN CANCER THERAPY: DFT INVESTIGATION AND MOLECULAR DYNAMICS SIMULATION |
| title_short |
EXPLORATION OF THE INULIN POTENTIAL AS A TARGETED DRUG DELIVERY SYSTEM IN CANCER THERAPY: DFT INVESTIGATION AND MOLECULAR DYNAMICS SIMULATION |
| title_full |
EXPLORATION OF THE INULIN POTENTIAL AS A TARGETED DRUG DELIVERY SYSTEM IN CANCER THERAPY: DFT INVESTIGATION AND MOLECULAR DYNAMICS SIMULATION |
| title_fullStr |
EXPLORATION OF THE INULIN POTENTIAL AS A TARGETED DRUG DELIVERY SYSTEM IN CANCER THERAPY: DFT INVESTIGATION AND MOLECULAR DYNAMICS SIMULATION |
| title_full_unstemmed |
EXPLORATION OF THE INULIN POTENTIAL AS A TARGETED DRUG DELIVERY SYSTEM IN CANCER THERAPY: DFT INVESTIGATION AND MOLECULAR DYNAMICS SIMULATION |
| title_sort |
exploration of the inulin potential as a targeted drug delivery system in cancer therapy: dft investigation and molecular dynamics simulation |
| url |
https://digilib.itb.ac.id/gdl/view/81374 |
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1822997287293419520 |