By Amalie Trewartha and John Dagdelen3 minute Read
在线看的免费网站黄2019, in both traditional journals and non-peer-reviewed preprints. There’s already far more than any human could possibly keep up with, and more research is constantly emerging.
在线看的免费网站黄2019And it’s not just new research. We estimate that there are as many as 500,000 papers relevant to COVID-19 that were published before the outbreak, including papers related to the outbreaks of SARS in 2002 and MERS in 2012. Any one of these might contain the key information that leads to effective treatment or a vaccine for COVID-19.
在线看的免费网站黄2019Traditional methods of searching through the research literature just don’t cut it anymore. This is why at Lawrence Berkeley National Lab are using the latest artificial intelligence techniques to build , a search engine dedicated to COVID-19. COVIDScholar includes tools that pick up subtle clues like similar drugs or research methodologies to recommend relevant research to scientists. AI can’t replace scientists, but it can help them gain new insights from more papers than they could read in a lifetime.
Why it matters
When it comes to finding effective treatments for COVID-19, time is of the essence. Scientists spend . Every second our search tools can save them is more time to spend making discoveries in the lab and analyzing data.
AI can do more than just save scientists time. Our group’s previous work showed that AI from text, making connections that humans missed. There, we showed that AI was able to suggest new, cutting-edge functional materials years before their discovery by humans. The information was there all along, but it took combining information from hundreds of thousands of papers to find it.
We are now applying the same techniques to COVID-19, to find existing drugs that could be repurposed, genetic links that might help develop a vaccine, or effective treatment regimens. We’re also starting to build in new innovations, like using molecular structures to help find which drugs are similar to each other, including those that are similar in unexpected ways.
How we do this work
在线看的免费网站黄2019The most important part of our work is the data. We’ve built web scrapers that collect new papers as they’re published from a wide variety of sources, making them available on our website within 15 minutes of their appearance online. We also clean the data, fixing mistakes in formatting and comparing the same paper from multiple sources to find the best version. Our machine learning algorithms then go to work on the paper, tagging it with subject categories and marking work important to COVID-19.
We’re also continuously seeking out experts in new areas. Their input and annotation of data are what allows us to train new AI models.
So far, we have assembled a collection of over 60,000 papers on COVID-19, and we’re expanding the collection daily. We’ve also built search tools that group research into categories, suggest related research, and allow users to find papers that connect different concepts, such as papers that connect a specific drug to the diseases it’s been used to treat in the past. We’re now building AI algorithms that allow researchers to plug search results into quantitative models for studying topics like protein interactions. We’re also starting to dig through the past literature to find hidden gems.
We hope that very soon, researchers using COVIDScholar will start to identify relationships that they might never have imagined, bringing us closer to treatments and a remedy for COVID-19.
Amalie Trewartha is a post-doctoral fellow at the University of California, Berkeley, and John Dagdelen is a graduate student researcher in the Persson Group at University of California, Berkeley. This article is republished from .