Chemical synthesis with artificial intelligence

03-Apr-2018 - Germany

The board game Go was long considered to be a bastion reserved for human players due to its complexity. Nowadays, however, the world’s best players no longer have any chance of winning against the “AlphaGo” software. Researchers at the University of Münster have now demonstrated that the recipe for the success of this software can be put to excellent use to plan chemical syntheses.

In 1996, when a computer won a match against the then reigning world chess champion Garry Kasparov, it was nothing short of a sensation. After this breakthrough in the world of chess, the board game Go was long considered to be a bastion reserved for human players due to its complexity. Nowadays, however, the world’s best players no longer have any chance of winning against the “AlphaGo” software. The recipe for the success of this computer programme is made possible through a combination of the so-called Monte Carlo Tree Search and deep neural networks based on machine learning and artificial intelligence. A team of researchers from the University of Münster has now demonstrated that this combination is extremely well suited to planning chemical syntheses – so-called retrosyntheses – with unprecedented efficiency. The study has been published in the current issue of the “Nature” journal.

Marwin Segler, the lead author of the study, puts it in a nutshell: “Retrosynthesis is the ultimate discipline in organic chemistry. Chemists need years to master it – just like with chess or Go. In addition to straightforward expertise, you also need a goodly portion of intuition and creativity for it. So far, everyone assumed that computers couldn’t keep up without experts programming in tens of thousands of rules by hand. What we have shown is that the machine can, by itself, learn the rules and their applications from the literature available.”

Retrosynthesis is the standard method for designing the production of chemical compounds. The principle is that, going backwards mentally, the compound is broken down into ever smaller components until the basic components have been obtained. This analysis provides the “cooking recipe”, which is then used for working “forwards” in the laboratory to produce the target molecule, proceeding from the starting materials. Although easy in theory, the process presents difficulties in practice. “Just like in chess, in every step or move you’ve got variety of possibilities to choose from,” says Segler. “In chemistry, however, there are orders of magnitude more possible moves than in chess, and the problem is much more complex.”

This is where the new method comes into play, linking up the deep neural networks with the Monte Carlo Tree Search – a constellation which is so promising that currently a large number of researchers from a variety of disciplines are working on it. The Monte Carlo Tree Search is a method for assessing moves in a game. At every move, the computer simulates numerous variants, for example how a game of chess might end. The most promising move is then selected.

In a similar way, the computer now looks for the best possible “moves” for the chemical synthesis. It is also able to learn by using deep neural networks. To this end, the computer draws on all the chemical literature ever published, which describes almost 12 million chemical reactions. Mike Preuss, an information systems specialist and co-author of the study, summarizes it as follows, in a somewhat simplified way: “The deep neural networks are used for predicting which reactions are possible with a certain molecule. Using the Monte Carlo Tree Search, the computer can test whether the reactions predicted really do lead to the target molecule.”

The idea of using computers to plan syntheses isn't new. “The idea is actually about 60 years old.” says Segler, “People thought it would be enough, as in the case of chess, to enter a large number of rules into the computer. But that didn’t work. Chemistry is very complex and, in contrast to chess or Go, it can’t be grasped purely logically using simple rules. Added to this is the fact that the number of publications with new reactions doubles every ten years or so. Neither chemists nor programmers can keep up with that. We need the help of an ‘intelligent’ computer.” The new method is about 30 times faster than conventional programmes for planning syntheses and it finds potential synthesis routes for twice as many molecules.

In a double blind AB test, the Münster researchers found that chemists consider these computer-generated synthesis routes to be just as good as existing tried-and-tested ones. “We hope that, using our method, chemists will not have to try out so much in the lab,” Segler adds, “and that as a result, and using fewer resources, they will be able to produce the compounds which make our high standard of living possible.”

Other news from the department science

These products might interest you

Limsophy

Limsophy by AAC Infotray

Optimise your laboratory processes with Limsophy LIMS

Seamless integration and process optimisation in laboratory data management

laboratory information management systems
ERP-Software GUS-OS Suite

ERP-Software GUS-OS Suite by GUS

Holistic ERP solution for companies in the process industry

Integrate all departments for seamless collaboration

software
LAUDA.LIVE

LAUDA.LIVE by LAUDA

LAUDA.LIVE - The digital platform for your device management

Comprehensive fleet management options for every LAUDA device - with and without IoT connectivity

laboratory software
ACD Spectrus Platform

ACD Spectrus Platform by ACD/Labs

Software for Analytical Data Handling in R&D

Standardized Analytical Data Processing & Knowledge Management

data management software
ZEISS ZEN core

ZEISS ZEN core by Carl Zeiss

ZEISS ZEN core - Your Software suite for connected microscopy in laboratory and production

The comprehensive solution for imaging, segmentation, data storage and analysis

microscopy software
Loading...

Most read news

More news from our other portals

So close that even
molecules turn red...

See the theme worlds for related content

Topic world Synthesis

Chemical synthesis is at the heart of modern chemistry and enables the targeted production of molecules with specific properties. By combining starting materials in defined reaction conditions, chemists can create a wide range of compounds, from simple molecules to complex active ingredients.

15+ products
4 whitepaper
15+ brochures
View topic world
Topic world Synthesis

Topic world Synthesis

Chemical synthesis is at the heart of modern chemistry and enables the targeted production of molecules with specific properties. By combining starting materials in defined reaction conditions, chemists can create a wide range of compounds, from simple molecules to complex active ingredients.

15+ products
4 whitepaper
15+ brochures