A group of chemicals known as bi-metallics could help the pharmaceutical industry become more environmentally friendly by cutting the amount of energy used to produce drugs, according to Professor Eva Hevia from the University of Strathclyde, UK, who says that sustainability is a top priority for chemists.
She has been developing applications for mixed-metal chemicals, which combine the highly reactive nature of metals such as sodium and lithium with the properties of less reactive metals such as zinc or aluminium.
Can you tell us what green chemistry is?
‘There are certain chemical processes that are conducted on an everyday basis that use toxic and volatile compounds that are bad for the environment. Green chemistry is about trying to find a more sustainable way of doing things that has a low impact on the environment. This can be getting reactions to take place under milder conditions so they don’t require as much energy and using materials that are less harmful to the environment, or ideally, even biodegradable.’
Is chemistry in general going through a green revolution?
‘Outside of the scientific community, there is often this slightly negative perception of chemistry – that there is nothing green about it. But that is not the case. Making processes as environmentally friendly and sustainable as possible has become one of the top priorities for today’s chemists. You can also see that in the scientific journals over the past decade, there has been a real move to focus more on green chemistry.
‘In our work, we didn’t set out to find a green chemistry process, but it was one of the advantageous factors that arose from the reactions that we have been developing.’
Can you give an example of a process that could be made greener?
‘Many pharmaceuticals are made with large, complex, organic (carbon-containing) molecules. To create these synthetically, you have to use smaller molecules and assemble them in the right way to form these complicated scaffolds – it is a bit like putting together Lego bricks.
‘Many companies use lithium compounds to help functionalise the carbon-hydrogen bonds in the molecules they want to piece together. Carbon-hydrogen bonds are normally unreactive, so they need to be broken by the lithium so they will then form new reactive bonds that can be used to create the larger molecules.
‘The disadvantage is that these reactions need to be conducted at extremely low temperatures, which uses up energy. The solvents used in the reactions are also not very environmentally friendly.
‘As the lithium is so reactive, you can get a lot of other compounds being formed alongside the one you want. Separating these mixtures can be both time consuming and costly.’
You’ve been working on so-called mixed metal chemistry through the MIXMETAPPS project. How does this help to tackle this problem?
‘We have been able to show that you can design bi-metallic compounds that combine lithium and zinc. Zinc is very selective about what it reacts with, but is poor at activating, or breaking, carbon-hydrogen bonds. Lithium, by comparison, is very reactive and so is good at this, but unfortunately is not very selective about the bonds it activates.
‘We have found you can bring zinc and lithium together to create a new type of compound, which has a totally new structure and reactivity profile. It can be as reactive as lithium but with the selectivity that comes from zinc. You get the best of both worlds.’