¶ Intro / Opening
Är 100% digital. som 40 000 andra småföretag och välj när. Sedan vi började anbita asset inom ekonomi och lön har vi fått högre kvalitet och tillgång till rätt kompetens. Asset ger oss avlösning och stöd så att jag kan fokusera på resultatet. Asset, redovisning, revision och lön för dig som tänker nytt. Next term, I don't know yet. Why is it like so far? Like it sounds so simple. But now the data's peak. Nature.
¶ Uncovering Rete Ridge Secrets
Welcome back to the Nature Podcast. This week how mysterious skin structures could help regeneration. And the AI that helps with literature reviews. I'm Benjamin Thompson. And I'm Nick Petrichau. First up on the show, new research has been uncovering more about mysterious structures in the skin known as reet ridges. Which could help unlock ways to help human skin regenerate, combat aging, and may even give us clues as to why humans aren't furry.
Reet ridges are microscopic peaks and valleys found just below the surface of our skin. They are thought to harbour the stem cells that can help our skin heal and seem to play a structural role in holding the different layers of skin together. But despite this, not much has been known about them. So one of the questions has been, what is it? Uh And i is it a vestigial structure? Do we even need it?
This is Ryan Driscoll, a skin researcher at Washington State University. Part of the reason that we didn't know a lot about him is because there's so few models that are easily accessible. And ways to actually study it, that most of the understanding about how it works inside of us as humans. It's just unknown. But that may be starting to change, as Ryan and his colleagues are publishing a new study in Nature that details what may be the best animal to model Reet Ridges.
And if any of you are skin researchers listening to this, you may be saying, Well, there's one animal that's an obvious candidate. And you'd be thinking along the same lines as Ryan. So I don't think it's a secret, at least amongst skin biologists, that pig skin is more similar to human skin. The biggest problem is accessibility to the pig. and affordability to work with the pigs and then kinda also doing a little bit of the smelly work as well.
I didn't really want to work with pigs either, even though I knew as well as the rest of the field knows that pigs are the better model, because it's really tough to work with them. So I searched for everything else other than pigs. While it's been thought that pigs are the ideal model for human skin, Ryan and the team wanted to be sure. After all, pigs and humans are not exactly the closest of relatives. There are animals such as monkeys, though a lot closer evolutionarily to humans.
So with a blank slate, Ryan and the team saw skin from dolphins, monkeys, naked mole rats, mice, and even grizzly bears. They examined the thickness of the skin, hair density, and of course whether or not there were reet ridges, as they're not present in every animal. And with all this examination, they discovered that the animal that had the closest match to human skin was pigs. Which is not a surprise.
Not that there weren't some surprises, it turns out that the skin of grizzly bears was particularly similar to humans. Grizzly bears have re ridges. I could not believe that at all. Grizzly bears are not exactly close relatives of humans, and looking at them, they don't exactly seem like they have similar skin.
But Ryan and the team found that their skin was a better match for humans than that of Reese's macaques or common marmosets. By looking at all these animals, the team also found some clues about hairlessness. Generally speaking, it seems that the presence of reet ridges was associated with an animal having thicker skin and less hair. Animals like dolphins have more and larger reet ridges compared to that of hairier animals.
Although there were exceptions to this. Bears are quite hairy and did have reach ridges, and the naked mole rat lacked reach ridges and has relatively thin skin despite, famously, being pretty hairless. The reaches then could be to do with making the skin tougher. When animals had less fur, it's possible that they didn't have the same protection from that hairy layer, and so maybe reap ridges filled that need for the less hairy animals, like humans. But that remains to be seen.
¶ Rete Ridge Formation and Regeneration
What was clear though was that pigs were the best model for human skin, and with that the team were able to try and tease out some of the key questions about these ridges. Such as when do they form? This is a really important thing to know because it's like laying the blueprint, right? If you don't have the blueprint at a molecular and cellular level, you know it's like chance trying to get something to regenerate.
Knowing how reet ridges form at this level of detail could help skin scientists to understand how to get them to regenerate if they're damaged. Past a certain age, they don't grow back, and Ryan thinks that may be why skin regenerates less well when we get older. And that's why there was another surprise. It had been thought that reek ridges formed during embryogenesis, a very early stage of development, as this is when other parts of the skin, like hair follicles and sweat glands, form.
But Ryan and the team showed that, in pigs at least, wheat ridges form after birth. And they showed exactly how this happened. We found a different molecular mechanism that's distinct from the normal epidermal appendage. Unlike sweat glands or hair follicles which form similarly, the reet ridges form via their own mechanism, developing where sweat glands or hair follicles don't.
And Ryan and the team found a group of molecules that were involved in REIT RIDEG development bone morphogenic proteins or BMP. Reet ridges are thought to be the places where the stem cells needed to regenerate skin gather, and so these structures may play an important role in the process.
Now Ryan has some molecular clues and a good model animal, he hopes they can uncover how to restore reet ridges and skin. You know, one of the biggest unanswered questions is if you want to get human skin to regenerate, how do you get re-ridges to regenerate? And so now we have that blueprint.
Ryan's next step is to use some of the molecular evidence that he's found to develop a model of re-ridge formation in mice to figure out if they can use this knowledge to help coke skin to regenerate. They've really opened the door to essentially determine the importance of these organs and then use that to improve the regeneration of skin. This is Jana Kambarov, a skin scientist who wasn't associated with this new study.
kind of unique or really powerful about the study is just the breadth of species that were examined and using that comparative approach and how powerful it is. to actually give us biological information about the emergence of a trait. So that for me was something that differentiates this paper quite a bit from others of the literature.
Typically, skin researchers have tended to think about all the different parts of the skin being related to each other, like hair follicles and sweat glands having similar development mechanisms, for example. So Jana was intrigued by the result that Reet Ridges seem to have a distinct way to form. What was really fascinating for me to see was that the Reet Ridges are not abiding really by the rule. They're their own entity, they're their own class.
Essentially of appendages. The one thing that Jana thought the paper didn't explain is how humans lost their fur. Ryan and the team made this quite clear too. While there is an association between having reet ridges and not being furry, we can't quite say yet whether they explain humans' hairlessness.
It's possible that Reet Ridges allowed humans to develop tougher skin when they lost their fur, but it's hard to know whether humans lost their fur and then developed Reet Ridges or the other way around. Maybe one day we'll be able to figure it out. I would say it's too soon to tell because we can't go it'd be wonderful to take a time machine and be able to get, you know, a biological sample. from a long time ago to see what that was actually saying.
I think it remains unanswered, and hopefully a really interesting question that other scientists can then utilize this understanding to actually go back and really think about domestication, evolution, and the acquisition of unique appendages. That was Ryan Driscoll from Washington State University in the US. You also heard from Yana Kambarov, from the University of Pennsylvania, also in the US.
For more on that story, check out the show notes for some links. Coming up the AI system that aims to take the hallucinations out of literature reviews. Right now though, it's time for the research highlights with Dan Fox.
¶ Research Highlights: Science News
A pungent weed has been genetically edited to become a potentially profitable winter crop. Field penicress is a plant that grows quickly and can survive harsh cold temperatures. But it isn't particularly useful. Its distinctive smell led to it gaining the nickname stinkweed, and two molecules found in its seeds can be toxic to humans and animals. Researchers experimented with editing Pennycrest using CRISPR for more than a decade.
Eventually, finding a combination of gene variants that made a crop suitable for animal feed with seeds that produced an oil similar to rapeseed or canola. Besides increasing farm profitability, growing crops throughout the year can help to improve soil health, sequester more carbon, and reduce atmospheric greenhouse gas emissions. Sniff out that research in Nature Plants. Astronomers have released the most ambitious cosmic map to the first time.
and confirmed that matter in the universe is less clumpy than the theory would predict. From 2013 to 2019, the Dark Energy Survey team repeatedly imaged a large section of Earth's southern sky. This allowed the team to collect the positions, colours, and shapes of around 150 million galaxies and detect more than 1,500 supernova explosions. They looked at four aspects of the data the brightness and other characteristics of the supernovas, the clustering of galaxies across space and time.
The evolving size of remnants of pressure waves generated in the universe's infancy, and the distortion of images of background galaxies by large concentrations of intervening, invisible, dark matter. The results refine previous measurements to confirm that gravity has not clumped galaxies together as much as observations of the early universe would lead us to anticipate, were the standard theory of the universe's evolution correct. You can find that preprint on archive.
¶ Open Scholar: AI for Reviews
When you're approaching a research question, it's important to do your homework. I've done it, and I'm sure listeners you have too. It's always best to figure out what other folks in your field have done relating to your idea, what they've uncovered already, and what the current evidence points to. You might hear this described as a literature review, or perhaps evidence synthesis. But either way, it's about combing through the existing research before you set off on your own work.
Of course, this can be a time consuming endeavor, and more and more frequently, researchers are turning to LLM backed AI systems to do the legwork. Ask them a question, and they get searching and respond with a written answer. But these systems do have drawbacks. They frequently hallucinate, inventing references or research that doesn't exist.
One of the reasons for this is that these systems rely on statistical patterns, and they can put together plausible sounding answers based on the dataset they're trained on. This training set could be from a broad range of sources, not just scientific papers, and it may only cover a certain time period. In our next story we hear about a team who are trying to do something about this. They have a paper in this week's Nature describing open scholar.
Their open source system that consists of a small LLM that's augmented to specialize at this task and which they say can outperform existing commercial systems. One of the members of the team is Hannah Hadges Shirzi from the University of Washington in the US. I called her up to hear about the system and she laid out how Open Scholar has been designed. So here is a very simple idea. It's called retrieval augmented generation. It became very popular over the past year. The idea is this.
add a really high quality data store, a collection of scientific documents. So then in order to answer my question, make sure you use this gigantic knowledge base, not just hallucinate from your own knowledge. So Open Scholar consists of A language model and this kind of information repository. So a user asks a question, the retrieval system first. Tries to figure out which scientific articles are most relevant and then I start to rank them. Which one is more relevant?
Now language model comes into play. Given this collection of a few articles that are relevant, Let's generate a response. So what you're saying then is it it kind of hones down on what it thinks is the useful information and then uses that to generate a response? 100%. Think of it as a draft. But now we start refining it. We use the LLM to read it. Is it good enough? Do we think we cover some important information? Or that document or scientific article that
we retrieve, is it relevant? Overall, asks a lot of questions and then refines it. So we do multiple iterations of this and then use the final kind of generated response as, okay, now this is the synthesized knowledge.
¶ Open Scholar's Impact and Future
This is the final piece of answer to you. And to test how good this final answers to queries was, I think as part of your work you also describe a benchmarking tool as well, Scholar QA bench. Which you designed to measure the efficacy of different systems that look to synthesise. scientific data in a way that you describe how does this system work? How does it benchmark things? So in general, when we build these language models, they generate long responses.
Even generic domains, not just scientific domains, it's very hard to evaluate if their responses are good or not, do they hallucinate or not, and so on. So as part of openness scholar, we actually build this benchmark. to understand the limitations and then start improving it. So basically what we did, we worked with scientists, with experts in physics, computer science, biomedicine and neuroscience.
to collect expert written questions and then we ask these scientists to write responses and then we ask them what is important to measure here. And it tells us metrics that we need to really care about. when we evaluate these systems. And then finally when we build a final system, we use again those experts.
to really go deeply compare generated responses by two systems side by side to see which one is better. So you put those questions into the computer and see what it chucks out and then compare those to a scientist doing the same job. Is that fair? Absolutely. What did your result Show then. So our new system decreases hallucinations significantly. Its citation accuracy is as good as human experts in generating citations and being accurate on those.
our final open scholar system outperforms proprietary models like GPT 4O more than 5% across different metrics on our benchmark. Right, so it outperforms other systems in your measures of correctness. But you also show that humans preferred the computer outputs in around fifty to seventy percent of cases, depending on how open scholar. is used. What is it about the system that allows it to provide the numbers that you show in your paper?
So that's the role of that data store that I described, like that information repository, and making sure that language model dips into it. I mean of course there are folk who would say that you've designed your system You've also designed a benchmark to test how good it is, and it said it is the best one. What would you say to them? That's the best question.
I agree. So we made a demo for Open Scholar and decided let's put it in the wild. Let's see if scientists use it. To our surprise, in the first few days, more than thirty thousand queries came in. And we saw a lot of evaluations from the community that way. Internally, we started evaluating the responses. Do we see any issues or not? And so on. So this is kind of how
we got the positive feedback from the community, but obviously we are still improving it. And it has to be said that this system isn't perfect. It is not perfect. Yeah, for example you say in your paper, you know, it doesn't consistently retrieve the most representative or relevant papers. So this isn't necessarily the complete article. Absolutely. This is just a start. And you do note some other limitations to open scholar as you describe it in this paper.
as well. I mean I think you mentioned some of the fields it looked at computer science, physics, neuroscience and biomedicine. Those fields are relatively narrow. You only use open access papers as well, which is obviously a huge amount of research papers, but there are many, many more that aren't necessarily accessible to this system. So we've mostly focused on these four domains for evaluation. This is something that we can say we are good at. we have only collected open access papers.
And our repository is still static, meaning that there are more papers that could be added, but we are working with this static collection of documents. And of course you've talked there about GPT four O. We're now a little bit further down the road and of course there are new iterations of GPT and of various other systems. as well. Have you looked forwards at how your system compares to more modern LLMs? If you compare with GPT five just out of the box
So our model is still better because GPT-5 is not designed again to deal with citations. However, these current systems have something called deep research. which are connecting to the knowledge repositories and try to ground their responses based on those knowledge repositories. This is great. It really improves the citation accuracies and so on in these most recent systems. They are pretty much using the same process that I just described.
to improve question answering. And that makes Open Scholar like one among many, really. There's lots of these things that are in existence from various companies. What do you think makes Open Scholar stand out? Obviously your papers out. What are the key things for you? So still a lot of these work from these companies are designed to answer any type of question. And as I resolved, the still hallucinations exist.
So Open Scholar still stands in this bigger collection of AI systems because it is specialized for science. It is really designed to kind of deal with scientific papers as this knowledge repository and so on and so forth. And you say you've used it yourself. Do you think it's been useful to you as a researcher? Absolutely. Yeah, it was actually very useful and this is how we kind of decided let's release the demo because we found very interesting responses.
One thing for us was we needed to kind of instruct a scientist how to query and how to ask question because for example we came with some queries like hi, how are you? This is not the type of queries that it is designed for. It's more like we are looking for a scientific question and then we want to kind of use the output. And we got actually very interesting responses and kind of
Testimonies of oh this was very useful, we love to continue using it. Are you maintaining it? Like these type of questions was very exciting to see. Hannah Hatchersey from the University of Washington there. To read her paper, look out for a link in the show notes. That's all for this week's show. Don't forget to look out for the briefing show on Friday. That'll be on the same feed as this one, so it should just appear in your podcast player of choice.
In the meantime, you can reach out to us on social media. We're at Nature Podcast. I'm Benjamin Thompson. And I'm Nick Petrichow. Thanks for listening. Mm. Smaken av lenmar och choklad med krämig nogat som smälter i munnen. Chokladiga praliner helt för mig själv. Eller kanske delar den goda stunden med någon. Marabo chokladhärtan. Den perfekta gåvan till mig själv eller någon annan palten dag. Mmm, marabo.
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