Abstract
Nanotubes, such as those made of carbon, silicon, and boron nitride, have attracted tremendous interest in the research community and represent the starting point for the development of nanotechnology. In the current study, the use of nanotubes as a means of drug delivery and, more specifically, for cancer therapy, is investigated. Using traditional applied mathematical modelling, I derive explicit analytical expressions to understand the encapsulation behaviour of drug molecules into different types of single-walled nanotubes. The interaction energies between three anticancer drugs, namely, cisplatin, carboplatin, and doxorubicin, and the nanotubes are observed by adopting the Lennard–Jones potential function together with the continuum approach. This study is focused on determining a favourable size and an appropriate type of nanotube to encapsulate anticancer drugs. The results indicate that the drug molecules with a large size tend to be located inside a large nanotube and that encapsulation depends on the radius and type of the tube. For the three nanotubes used to encapsulate drugs, the results show that the nanotube radius must be at least 5.493 Å for cisplatin, 6.452 Å for carboplatin, and 10.208 Å for doxorubicin, and the appropriate type to encapsulate drugs is the boron nitride nanotube. There are some advantages to using different types of nanotubes as a means of drug delivery, such as improved chemical stability, reduced synthesis costs, and improved biocompatibility.
Highlights
Cancer remains a large global health issue and is a major cause of deaths annually, despite there being several successful drugs that have been used for the treatment of tumour diseases, for example, cisplatin (CIS), carboplatin (CAR), and doxorubicin (DOX).CIS is utilized in the treatment of solid tumours, and it is deemed as the most effective anticancer drug
A mathematical model was developed to examine the encapsulation of three anticancer drugs into carbon nanotubes (CNTs), boron nitride nanotubes (BNNTs), and silicon nanotubes (SiNTs)
The study resulted in the development of the use of mathematical modelling to investigate the use of nanotechnology in the area of medicine, in drug delivery, to reduce the side effects and toxicity of drugs
Summary
CIS is utilized in the treatment of solid tumours, and it is deemed as the most effective anticancer drug. DOX is an anticancer that is utilized as a chemotherapy drug, and it was isolated from bacteria in the early 1960s [3]. It shows potential in the treatment of breast cancer, soft tissue sarcomas, childhood tumours, and many other cancers [4,5]. Anticancer drugs are toxic to deoxyribonucleic acid (DNA), and they target nuclear DNA These drugs may cause oxidative DNA death, and they considerably damage cells by inhibiting topoisomerase and generating free radicals [6]
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