23. ŌURA

Founders: Petteri Lahtela, Kari Kivelä, Markku KoskelaCEO: Tom HaleLaunched: 2013Headquarters: Oulu, FinlandFunding: $200 millionValuation: $5.2 billionKey Technologies: N/A Industry: Consumer technology, health carePrevious appearances on Disruptor 50 list: 2 (No. 33 in 2023)
Oura has pioneered the smart ring market since the San Francisco-based company launched its eponymous connected device in 2015. But over the last twelve months, Oura has hastened its disruption of the broader wearables market, showing its evolution well beyond the original roots in sleep tracking.
The company released the latest version of its flagship product, the Oura Ring 4, in October, which it says is its most accurate iteration yet thanks to additional signal pathways in the ring's sensors, allowing for better tracking of things like blood oxygen levels and heart rate.
It also helps dial in a wide range of metrics, features and health indicators that Oura provides wearers via its app, everything from daily readiness and sleep scores in the morning to stress and activity tracking during the day and into the evening.
Oura is also further leaning into the proactive side of wellness insights that its ring can provide. In March, the company launched an AI-powered health coach that uses algorithms and LLMs to analyze data and biometrics to offer personalized guidance around long-term trends in sleep or how meal timing might be impacting metabolic health. The AI health coach is also able to create plans around goals like improving sleep or improving stress resilience.
The company has also made major strides in women's health, adding features around menstrual, period and pregnancy cycles, both tracking and insights.
All of that is part of Oura's move into becoming an all-encompassing health and wellness tracker, with the goal of, as the company puts it, helping wearers "live healthier, longer."
In December 2024, Oura raised a $200 million Series D that it said would help "fuel" healthcare innovation. Participating in that round was Dexcom, the global leader in glucose biosensing, which also partnered with Oura to allow users of its glucose monitor to share data between the two products.
Oura CEO Tom Hale told CNBC in November that the company is testing out nutrition, allowing users to take pictures of their meal and load it into the Oura app. In September, Oura acquired Veri, a metabolic health startup that uses data from continuous glucose monitors to give users insight into their blood sugar levels.
"Metabolic health is the natural next dimension of the Oura Ring holistic health experience, and one that our customers have told us they want," Hale said in a release announcing the Veri acquisition.
Oura started with sleep, migrated to cardiovascular health, stress & resilience, and women's health, and is always looking for the "next pillar," according to Hale.
"Metabolic health is an important next horizon and the team at Veri brings deep experience in that space," Hale said.

Try Our AI Features

Explore what Daily8 AI can do for you:

Learn with AIFact CheckingText to SpeechAI Summary

Related Articles

Yahoo

9 hours ago

• Yahoo

Satellites are polluting Earth's atmosphere with heavy metals. Could refueling them in orbit help?

When you buy through links on our articles, Future and its syndication partners may earn a commission. The world at large is working to stop the fast-progressing degradation of Earth's environment. In the space sector, however, one-use-only products still reign supreme. The advent of megaconstellations has, in fact, accelerated the rate at which the space industry burns through resources, shifting from big satellites with decades-long lifespans to cheaper birds designed to expire within a few short years. The disposable approach worries some researchers, as too much aluminum is burning up in the atmosphere these days, threatening to cause a new kind of environmental disaster in the decades to come. But what can we do? Should we roll back the space revolution and put a cap on what we can do in space? Or could a circular economy, life extension, recycling and reuse be the solution to the space industry's dirty side effects? Proponents of in-orbit servicing and refueling laud the technology's potential. But most analysts remain cautious: Without strict environmental regulations, the expected cost of in-orbit servicing may not entice satellite operators to switch to reusable technology en masse. Dave Barnhart, chief executive officer of the California-based aerospace company Arkisys, first began developing concepts of recyclable satellite technology some 15 years ago as part of a project he oversaw at DARPA (the Defense Advanced Research Projects Agency). He and his colleagues investigated how to set up a satellite recycling facility in geostationary orbit — the region about 22,000 miles (36,000 kilometers) above Earth's surface where satellites appear fixed above one spot above the equator. "We wanted to know whether we can use parts from old geo satellites to recreate new ones, because the mass is already there," Barnhart told The geostationary ring is home to some of the largest and most expensive satellites. On top of that, the long distance between Earth and this orbit makes geo missions inherently costly, as they require the most powerful rockets with a lot of fuel to reach their destination. Yet, Arkisys, the company Barnhart cofounded in 2015, is focusing on low Earth orbit (LEO) — the buzzing region closest to Earth up to altitudes of about 1,200 miles (2,000 km). Arkisyshopes to set up an in-orbit servicing and refueling depot called the Port in LEO. The main goal is to spearhead a green revolution in this region, which gives rise to thousands of tons of dangerous space debris every year. "To date, everything we have ever designed to go into space has been one mission, one life," Barnhart told "It's sort of crazy. Every other domain on Earth, we maintain, we sustain, we grow. Not in space." In 2023, Arkisys secured a $1.6 million deal from the U.S. Space Force to test satellite assembly in orbit using the Port demo module — a basic building block of a scalable orbiting garage and gas station. The company wants to launch the first component of this orbital depot next year — a last-mile transportation device called the Cutter, which is designed to help satellites to dock with the garage. In 2027, the main Port module, a hexagonal structure about 9 feet (3 meters) wide, will join the Cutter in orbit to test how the mechanical interfaces of the two work together in space. The Port, in addition to serving as a fuel depot, will arrive with a supply of components and payloads that could be attached to worn-out satellites to give them a new lease on life. "Today, everything on a satellite is done on the ground, and the satellite is launched with an end date," Barnhart said. "We want to shift that to allow extensions of both — life and business — post-launch. We want to be able to add new revenue streams post-launch. You can do that if you can add something, change something in orbit, or even sell that satellite to somebody else who could make it part of a larger platform." Cameras or antennas could be replaced with more powerful ones once those get developed, worn-out batteries could be swapped for brand-new ones, and fuel tanks would get refilled. It all makes sense on paper, but Dafni Christodoulopoulou, space industry analyst at the consultancy company Analysis Mason, warns that whether satellite operators would be inclined to ditch their disposable ways will come down to the cost of the in-orbit maintenance services. LEO is currently dominated by small, relatively cheap satellites, she says, which can be replaced more cheaply than they can be serviced and maintained. "Right now, we expect in-orbit services to come at a cost that might be quite high for operators of small satellites," Christodoulopoulou told "The operators might not be interested in those services, because the price of building a new satellite might not be higher than that of a servicing mission." Barnhart agrees that the fledgling in-orbit servicing industry is likely to face resistance not just from operators but also from satellite manufacturers, who might feel threatened by the idea of reusability and life extension. "Every time you want to make a big shift like this, it's going to be a threat," Barnhart said. "Satellite manufacturers make money by building more satellites to throw away. It might take some time for them to see that by fitting satellites with interfaces that allow them to be serviced, they could actually add some cool functionality to them after launch." Related stories: — Kessler Syndrome and the space debris problem — Pollution from rocket launches and burning satellites could cause the next environmental emergency — 2 private satellites undock after pioneering life-extension mission Still, Christodoulopoulou thinks that in-orbit servicing will eventually make a difference to how things are done in space, and also to the state of the orbital environment. "The number of satellite launches is not expected to go down, so there will be a high need for constellation management, flexibility, disposal and life extension," she said. "I think in-orbit services can definitely help prevent the buildup of space debris and maintain long-term sustainability in orbit." The U.S. government certainly appears to think that life extension is the way forward. In addition to funding the Arkisys experiment, the Space Force also funds the Tetra-5 and Tetra-6 missions to test in-orbit refueling technologies in space. The two missions, designed to test hardware developed by Orbit Fab, Astroscale and Northrop Grumman, are set to launch in 2026 and 2027, respectively. In addition, intensifying geopolitical tensions are increasing the need for quick deployment of new systems in space, which, Barnhart says, could be more speedily addressed with servicing systems such as the Port, than by building new spacecraft from scratch on Earth. "If there is a new threat that has been identified, you might need a new type of sensor or a new payload to observe it," Barnhart said. "If we can augment the satellites that the government has already put up and provide them with a new capability, a new sensor, we can address those threats much faster." Christodoulopoulou thinks that new regulations designed to protect the environment and curb the air pollution related to satellite reentries could further help move the needle toward a less throwaway culture in space utilization. "There need to be a few changes," Christodoulopoulou said. "There needs to be more awareness among satellite operators to understand that in-orbit servicing offers a value in the long term. But also on the government side, there need to be more regulations to support the in-orbit servicing providers."

Yahoo

9 hours ago

• Yahoo

University of Utah students win NASA Lunobotics grand prize

A team of over 30 students from the University of Utah took home the prestigious grand prize from the NASA Lunobotics competition thanks to their robot. Their design won multiple awards and cemented many of the students' love of STEM, space and collaboration. The team was comprised of students from the Utah Students Robotics club. To compete, the team had to apply for the competition. Out of 70 universities, the team was selected to be one of the 30 official competitors based on their project management plan. The competition was held at the University of Central Florida May 15-17. Over the course of a year, the students prepared for the competition. Early on in the process, the students received a rubric and competition layout for what to expect. The teams then began working on the systems engineering paper, presentation demonstration and, most importantly, the robot itself. 'You are building a robot to compete in a simulated lunar environment,' explained Jeffrey Hansen, a University of Utah chemical and computer engineering student. 'The goal is to navigate through an obstacle zone and then do digging and dumping to build a berm.' Judges look at numerous factors, including the size of the berm compared to the size and energy usage and the different amounts of autonomous operations. Those areas all contributed to the four main areas of scoring: the systems engineering paper, the outreach paper, the presentation demonstration and the construction competition. After competing at Florida, the top 10 teams are chosen to go to the Kennedy Space Center and compete for the grand prize. The Utah-based team split into three different subteams, including mechanical, electrical and software teams. Supporting teams also included an admin and systems team. Frequent meetings, collaborations and trial and error were a must for the students. Hansen called their work an 'evolutionary design style.' 'We had a systems engineering approach. We did it a bit differently than we had done in the past,' Hansen elaborated. 'We decided to start with building a version of the robot that met the basic competition requirements. … Once we had that, we went through different versions to improve upon that design.' Working with 30 students was no small feat. With so many minds hard at work, it was sometimes difficult to find the direction the team wanted to take. Additionally, the challenge was extremely open-ended. As long as the robot was under the specified maximum weight and dimensions, the robot could do anything. Digging systems, electronics, batteries and microcontrollers could all be chosen by the students. Another key piece of the journey was the collaboration with the U. The students worked with the administration to build a lunar simulation to test the robot. The chance to practice before the competition was everything for the team. 'We didn't have (the simulation) done until close to the end of the year, but even that little bit of time helped,' Hansen said. 'It was quite a big process to get that approved.' When they brought their robot to the competition, the team knew they had something special. After taking home the first place in presentation and demonstration, first place in STEM engagement and outreach, second place in construction, special recognition for exceptional use of systems engineering tools and various judges' awards, the team thought they may have a chance to compete in the top 10. Their suspicions were correct. The team ecstatically welcomed the invitation to present their robot at the finals. After an excellent demonstration, the team was awarded the Artemis Award, or grand prize. 'The team just erupted in energy when we found out we won. It felt like we had accomplished everything we went there to do,' Hansen said. 'It was very emotional. It was so much work across a lot of time with so many people. It felt incredible to have all that work come together and walk on stage knowing we had done it.' The experience has helped to shape the students' futures. 'It's been absolutely incredible for getting hands-on experience. … There are real-world applications of participating in this team that I would've never experienced in any of my classes,' Hansen said. To supplement their work, the students also traveled around to numerous K-12 schools around Utah. Their presentations aimed to inspire the future generation of students to try new things, specifically in the STEM field. 'It's how we keep improving the world. It's how we've gotten to where we are today,' Hansen said. 'It's the most important thing out there.'

New York Post

10 hours ago

• New York Post

Barron Trump made millions from family's lucrative crypto firm: report

Barron Trump, the youngest son of the 47th President, may have raked in millions of dollars from the sale of crypto tokens linked to the family's lucrative venture into digital tokens, according to report. The 19-year-old New York University student could have picked up a cool $40 million — $25 million after taxes — from the sale of digital assets by World Liberty Financial Group, the Trump family firm launched nine months ago after Barron persuaded his dad about the benefits of crypto, Forbes reported. 'Barron knows so much about this,' commander-in-chief said during an interview in September after the launch. 'Barron's a young guy, but he knows it — he talks about his wallet. He's got four wallets or something, and I'm saying, 'What is a wallet?'' Barron Trump, seen here at his father's second inauguration, is listed as a 'co-founder' on World Liberty Financial's website. AFP via Getty Images World Liberty has been a financial bonanza for the family. In March, World Liberty announced that it had sold $550 million worth of tokens. An Office of Government Ethics filing released by President Trump last week declared he had made $57 million from token sales. It also said that the real estate mogul held a 75% stake in his umbrella company, DT Marks Defi LLC, with unnamed 'third parties' holding the other 25%. Barron Trump is listed as a 'co-founder' of World Liberty Financial alongside the president, as well as Eric and Donald Trump Jr, the president's two eldest sons. Forbes, which provided no direct evidence for its claims of Barron Trump's massive digital windfall, suggested that he owned a 7.5% stake in Delaware-based World Liberty. The stake would mirror what the NYU freshman holds in the Trump Organization's Washington, DC hotel, Forbes said. The Post has approached a Trump Organization spokesperson for comment. Trump once derided digital assets such as Bitcoin as 'a scam' but he has since U-turned and embraced cryptocurrencies. REUTERS Barron Trump's name does not appear in the company's solitary SEC filing from October 30 last year. Also listed as business partners in the venture are Middle East envoy Steve Witkoff and his son, Zachary. An analysis by Bloomberg, the financial news outlet, estimates the president's net worth has doubled since the start of his 2024 campaign, standing at just over $5.4 billion