2 min readNovel Method Developed by Scientist could Help Produce Purer, Safer Drugs
Hong Kong, China — Physics and Chemistry scholars from Hong Kong Baptist University (HKBU) have invented a new method which could speed up the drug discovery process and lead to the production of higher quality medicinal drugs which are purer and have no side effects. The technique, which is a world-first breakthrough, uses a specific nanomaterial layer to detect the target molecules in pharmaceuticals and pesticides in just five minutes.
The new HKBU invention can be applied to the drug discovery process, as well as the production and quality control stages of pharmaceutical manufacturing. It can also be used in environmental monitoring. The paper, which is entitled “Chiral Nanoparticle-Induced Enantioselective Amplification of Molecular Optical Activity”, was published in the renowned international journal Advanced Functional Materials (volume 29, issue 8, February 2019).
The team was jointly led by Associate Professor Dr. Jeffery Huang Zhifeng and Postdoctoral Fellow Dr. Lin Yang from the Department of Physics, and Associate Professor Dr. Ken Leung Cham-fai and Postdoctoral Fellow Dr. Kwan Chak-shing from the Department of Chemistry at HKBU.
Medicinal drugs and pesticides are composed of organic molecules. Normally each molecule has two “chiral” versions which are mirror images of each other in terms of absolute configuration. While otherwise identical, these “right-handed” and “left-handed” molecules can have totally different effects. For example, anti-inflammatory drug naproxen of a particular type of chirality can treat arthritis pain while its mirror image twin can result in liver poisoning. As a result, selecting only useful chiral molecules during the drug discovery process can help produce pure drugs that can cure specific diseases with no adverse effects.
However, producing pure drugs is very expensive and time consuming. Current medicinal drugs are often made up of equal amounts of the left- and right-handed chiral molecules in what is known as a racemic mixture. While this fifty-fifty split has low production cost, it also leads to lower overall efficacy and, in some cases, can lead to toxic side effects in the human body.
According to Dr. Jeffery Huang, sensitively identifying and locating the correct form of a chiral molecule during the drug discovery process is essential, but is currently difficult and time-consuming because molecules are typically too small to be sensitively monitored. However, the specific nanomaterial designed and synthesised by the team, which is composed of silver chiral nanoparticles, can “amplify” the signal of the desired chiral molecules and improve detection sensitivity by more than 10-fold, making the location process faster, more accurate and less expensive.
Dr. Huang said that this work opens a new door for material scientists to apply these metallic chiral nanoparticles to drug production processes, as currently there are a limited number of nanomaterial fabrication techniques on offer. He said: “We have developed a breakthrough nanomaterial which uses a simple, one-step fabrication method to sensitively detect the target drug molecules in just five minutes. The ability of the chiral nanoparticles to amplify the detection sensitivity is practically desired for trace detection.”
Dr. Ken Leung said that in the current multi-step drug synthesis process, both the product and chiroptical purities – which refers to the use of optical techniques for investigating chiral substances – are crucial controlling factors for producing extra-pure synthetic drug molecules. The novel nanomaterial developed by the team will eventually provide a new platform for efficiently and effectively detecting the chiroptical purity of synthesised compounds, and will help to produce drugs without side effects. It is also a new breakthrough in the resolution of racemic drugs, he added.
Article adapted from a Hong Kong Baptist University news release.
Publication: Chiral Nanoparticle‐Induced Enantioselective Amplification of Molecular Optical Activity. Yang, L et al. Advanced Functional Materials (December 07, 2019): Click here to view.