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Biotech AI Robotics Software Hardware Technology

AI Plus a Chemistry Robot Finds All the Reactions That Will Work (arstechnica.com) 39

A team of researchers at Glasgow University have built a robot that uses machine learning to run and analyze its own chemical reaction. The system is able to figure out every reaction that's possible from a given set of starting materials. Ars Technica reports: Most of its parts are dispersed through a fume hood, which ensures safe ventilation of any products that somehow escape the system. The upper right is a collection of tanks containing starting materials and pumps that send them into one of six reaction chambers, which can be operated in parallel. The outcomes of these reactions can then be sent on for analysis. Pumps can feed samples into an IR spectrometer, a mass spectrometer, and a compact NMR machine -- the latter being the only bit of equipment that didn't fit in the fume hood. Collectively, these can create a fingerprint of the molecules that occupy a reaction chamber. By comparing this to the fingerprint of the starting materials, it's possible to determine whether a chemical reaction took place and infer some things about its products.

All of that is a substitute for a chemist's hands, but it doesn't replace the brains that evaluate potential reactions. That's where a machine-learning algorithm comes in. The system was given a set of 72 reactions with known products and used those to generate predictions of the outcomes of further reactions. From there, it started choosing reactions at random from the remaining list of options and determining whether they, too, produced products. By the time the algorithm had sampled 10 percent of the total possible reactions, it was able to predict the outcome of untested reactions with more than 80-percent accuracy. And, since the earlier reactions it tested were chosen at random, the system wasn't biased by human expectations of what reactions would or wouldn't work.
The research has been published in the journal Nature.
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AI Plus a Chemistry Robot Finds All the Reactions That Will Work

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  • by petes_PoV ( 912422 ) on Friday July 20, 2018 @02:10AM (#56978904)

    And equally important: can it be networked to similar machines (preferably made by other manufacturers and run by different labs) to set up its own peer reviews?

    And how soon before the drug cartels are buying up every machine that is produced to discover new substances?

  • by Anonymous Coward

    I wonder if it's possbile to automatically design an industrial scale chemical process, an entire factory complex?
    Say I want to produce x amount of this or that product. What raw materials do we need? Where should we build the factory? What would it cost? What are the options?
    The system should of course take into account costs, externalities and regulations. Automatic procurement of commodity materials should be possible as well.

    • by Richard Kirk ( 535523 ) on Friday July 20, 2018 @06:40AM (#56979324)

      It would have to learn how to do the chemistry at factory scales to do that. This is possible but unlikely to be economic.

      If anything, the interesting work would be to go in the other direction. It is possible to make lab-on-a-chip units where the reagents are sealed in and each experiment is done in a small drop. This means you can repeat each experiment many times and see whether the results are repeatable. If your process is catalysed by some low concentration impurity, then that effect will vary with the number of molecules of that impurity, and you would expect a larger scatter in the yield.

  • Interesting (Score:5, Insightful)

    by wierd_w ( 1375923 ) on Friday July 20, 2018 @03:21AM (#56979028)

    A carefully selected group of these working in parallel could theoretically parse the entire possible set of reactions, given sufficient time. (Yes, I know that with infinite molecular weight, there is an infinite number of possible compounds. However, only so many heavy molecules are interesting or useful, and of those, there will be certain classes that are more interesting than others. This approach would permit investigation of pathways without actually expending reagents, once its models are accurate enough. That means after a certain amount of training, a theoretical molecule of interest could be presented to the AI, and it could shit out the ideal synthesis pathway, and the next efficient arbitrary "n" pathways.)

    This is the kind of thing that is the beginning of universal replicators.

    • and it could shit out the ideal synthesis pathway, and the next efficient arbitrary "n" pathways.)

      Of all the places it could produce information, does it really need to come out of it's anus?

    • by tkotz ( 3646593 )

      I think all compounds below a certain arbitrarily high molecular mass is a lot larger of a search space than you think. And if you want to try any possible experiment you really need one large machine more than a bunch of smaller machines however a matrix of smaller machine could fill in holes in the knowledge base for limited number of reactors. the number of possible reactions input combinations is 2^N where N is the number of known compounds, which will go up as the reactions uncover new compounds. I

    • by tlhIngan ( 30335 )

      A carefully selected group of these working in parallel could theoretically parse the entire possible set of reactions, given sufficient time. (Yes, I know that with infinite molecular weight, there is an infinite number of possible compounds. However, only so many heavy molecules are interesting or useful, and of those, there will be certain classes that are more interesting than others. This approach would permit investigation of pathways without actually expending reagents, once its models are accurate e

  • why would you use AI with a 80% success rate for this?
    isn't chemistry all maths? can't you just calculate the same reactions and have a 100% success rate?

    • And, how does pattern-matching on 72 known products not just give you all the
      products that are similar to the known set? How is that testing "all possible" combinations?

    • by Anonymous Coward

      Simulating reactivity accurately requires absolutely stupid amounts of compute. Also FORTRAN: https://en.wikipedia.org/wiki/List_of_quantum_chemistry_and_solid-state_physics_software

      Really "crude" analyses to predict absorption spectra of small biomolecules took everything we could throw at it in 2010, and we weren't exploring molecular interactions at all. The algorithms can be O(n^8) or worse.

    • by AHuxley ( 892839 )
      How many scientists and technicians can a nation keep working over decades?
      How many really great super computer labs can a nation spare from its nuclear weapons simulations?
    • >isn't chemistry all maths? can't you just calculate the same reactions and have a 100% success rate?

      Because chemistry is applied quantum mechanics, and the math is HARD. I think they finally managed to simulate the chemical properties of a hydrogen molecule, but last I heard that was the most complicated molecule we've been able to simulate accurately - and it's literally the simplest molecule that exists, by a wide margin.

  • Inputs (Score:5, Interesting)

    by msauve ( 701917 ) on Friday July 20, 2018 @06:35AM (#56979314)
    Be careful what you feed it [sciencemag.org].
  • by pubwvj ( 1045960 ) on Friday July 20, 2018 @07:54AM (#56979570)

    This is a prime example of why patents are absurd and should be discontinued.

  • by muhula ( 621678 ) on Friday July 20, 2018 @07:59AM (#56979590)

    it was able to predict the outcome of untested reactions with more than 80-percent accuracy

    The skeptic in me wonders if 80% of the combinations had no reaction

  • by PPH ( 736903 ) on Friday July 20, 2018 @09:52AM (#56980176)

    ... does it pour all the products down the lab sink?

  • But it is backwards chemistry. Nobody in industry has a bunch of stuff on the shelf and says 'what can I make with this'. There is a chemical they need to make and they ask themselves 'how can I make this'.
    • But so many things have been stumbled upon - like Saccharine. The really fancy version of AI would suggest possible uses for whatever it creates.
  • ... at this guy's blog [sciencemag.org] as a training data set. And then watch it reply to a query [youtube.com].

Every nonzero finite dimensional inner product space has an orthonormal basis. It makes sense, when you don't think about it.

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