• Nintendo has released a new mobile game
• It’s called Pictonico! and it’s a minigame collection similar to the WarioWare titles
• The game is free to start and available for both iOS and Android devices

Nintendo has launched a new mobile game out of the blue, and it’s pretty similar to the WarioWare series.

The game is called Pictonico! and it’s a minigame collection that uses photos of people from your phone’s gallery in up to 80 rather amusing minigames. These range from chomping on dragging on someone’s mouth to force them to devour fruit to plucking their nose hairs.

You thought the Apple Vision Pro was expensive, but now you could choose between buying 180 of the headset, or one Ferrari Luce designed by Jony Ive. Or you could just enjoy the good, the bad, and the sometimes silly iPhone rumors that came out this week, on the AppleInsider Podcast.

It is the run-up to WWDC and it’s also not really that long until the launch of the iPhone 18 range, so as always we’re now bombarded with rumors and leaks. Some of them are actually likely, though, and some of them look rather good.

Here’s how to sort out the good leaks from the poor or even the downright silly. Plus forget leaks, there’s news for gamers on Apple Vision Pro and it’s something you can play right now.

That’s not something you can say for the Jony Ive-designed Ferrari Luce car. It’s the talk of the week, for its design, for how the Pope was shown one, and for its price.

But even if you happen to have a spare $640,000, you can’t buy Ferrari’s first-ever electric vehicle yet. It will be out sometime by the end of the year, so you’ll have to wait a while before you can go from 0 to speeding ticket in 2 seconds.

BONUS: Subscribe via Patreon or Apple Podcasts to hear AppleInsider+, the extended edition. This time, we’re a pixel away from WWDC, so this is what we’re crossing our fingers for with iOS 27, iPadOS 27, and watchOS 27.

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A new wave of Samsung monitors is targeting Mac users with OLED panels, Thunderbolt 5 connectivity, and workstation features that Apple still doesn’t offer in its own display lineup.

Samsung’s new lineup includes the 40-inch ViewFinity S8 S85TH, the 32-inch Odyssey OLED G8, and the 27-inch Odyssey OLED G8. The company built the displays for productivity and gaming, while adding features that fit naturally into MacBook, Mac mini, and Mac Studio setups.

Together, the monitors target capabilities Apple still doesn’t offer across its own display lineup.

Apple’s desktop display lineup remains limited to the Studio Display and Pro Display XDR. Apple doesn’t sell an OLED desktop monitor, an ultrawide display, or a monitor with integrated KVM switching and Thunderbolt 5 docking. Samsung’s latest displays target each of those categories.

ViewFinity S8 combines a large workspace with Thunderbolt 5

The 40-inch ViewFinity S8 S85TH is built around a curved 5K2K WUHD panel with a 144Hz refresh rate. The extra horizontal resolution creates room for multiple apps and documents without relying on a second display.

Thunderbolt 5 sits at the center of the design. The connection supports up to 80Gbps data transfers and up to 140W charging through a single cable, allowing a MacBook Pro to handle power, video, and data simultaneously.

40 Inch ViewFinity S8 S85TH 5K2K Curved Monitor (2026)

Samsung built docking features directly into the monitor instead of relying on separate accessories. The display includes Ethernet, USB-C, USB-A, HDMI, and DisplayPort connections, along with built-in speakers.

A built-in KVM switch also lets users control multiple computers with a single keyboard and mouse. For Mac users building a desktop workspace around a notebook, the display can replace a dock, Ethernet adapter, and KVM switch while providing more screen space than Apple’s Studio Display.

Samsung prices the 40-inch ViewFinity S8 S85TH at $1,399.99.

32-inch Odyssey OLED G8 pairs OLED image quality with creator-focused features

The 32-inch Odyssey OLED G8 combines a 4K QD-OLED panel with a 240Hz refresh rate, a 0.03ms response time, USB-C charging up to 98W, and DisplayPort 2.1 connectivity. The specification sheet reads like a gaming display, but several features extend well beyond gaming.

Pantone validation gives the monitor support for more than 2,100 Pantone colors and 110 SkinTone shades. VESA DisplayHDR True Black 500 certification and peak HDR brightness of up to 1,000 nits push the display beyond gaming.

32 Inch Odyssey OLED G8 G80SH 4K Gaming Monitor (2026)

The combination makes the monitor a viable option for photo editing, design work, and video production.

Apple doesn’t offer an OLED desktop monitor. The Odyssey OLED G8 brings OLED contrast and per-pixel lighting control to a category Apple still serves exclusively with LCD displays, while adding refresh rates far beyond Apple’s monitors.

Samsung also includes a glare-reduction coating and support for AMD FreeSync Premium Pro and NVIDIA G-Sync Compatible technologies. The 32-inch Odyssey OLED G8 is priced at $1,299.99.

27-inch Odyssey OLED G8 brings OLED technology to a familiar size

The 27-inch Odyssey OLED G8 brings many of the same technologies as the larger model to a size familiar to Studio Display users. Samsung pairs a 4K QD-OLED panel with its Glare Free coating and OLED Safeguard+ protection features.

The display’s 166 pixels-per-inch density helps it stand out from many gaming-focused competitors. Its higher pixel density also produces a sharper image that’s better suited for productivity and creative work.

27 Inch Odyssey OLED G8 G80SH 4K Gaming Monitor (2026)

The 27-inch size also fits naturally into workspaces already designed around Apple’s displays. Users interested in OLED technology without moving to an ultrawide or larger-format monitor may find the smaller Odyssey OLED G8 easier to integrate into an existing setup.

Like the 32-inch model, the display combines OLED image quality with a 240Hz refresh rate and modern laptop connectivity. Samsung prices the 27-inch Odyssey OLED G8 at $1,099.99.

UL’s Prof George Barreto discusses his research and how it could help form new treatments for treating and protecting the brain.

Prof George Barreto is a professor in cell biology/immunology at the University of Limerick (UL), and a neuroscientist.

Outside the lab, Barreto is the assistant dean for equality, diversity and inclusion (EDI) in UL’s Faculty of Science and Engineering.

“And I teach,” he tells SiliconRepublic.com. “I run some courses for our undergraduate and master’s students, mostly on how the body works, how medicines work (pharmacology) and how cells behave (cell biology).

“So my job is really a mix of three things – running my research lab, teaching the next generation of scientists and helping build a better academic culture.”

Here, Barreto tells us more about his work.

Can you tell us about your current research?

My lab studies how the hormones in our bodies, the ones we usually link to being male or female, affect the brain, and how that differs between men and women. We pay special attention to a tiny part of every cell that acts like its battery or power plant. These are called mitochondria, and these little batteries do not just give our cells energy. They also help decide whether our cells stay healthy or die.

Our hormones have a big influence on how well these powerhouses work in the brain. A key point is that those hormone levels naturally drop as we get older. I believe that is possibly one of the main reasons why diseases like Alzheimer’s are more common in women than in men.

So, our lab works on a few connected questions. Why does the ageing brain go from being resilient to being vulnerable? How do hormones keep brain cells healthy, and why does that protection fade with age? How does a head injury throw the body’s hormones out of balance and cause harmful inflammation in the brain?

And finally, I think the part I find most hopeful, can we take drugs that already exist (and are FDA-approved) and use them in a new way to protect the brain?

What drew you to this area/subject?

It came from a question I just could not let go of – why are women hit harder by Alzheimer’s and similar diseases, and why does that risk seem to change around the time of menopause? For a long time, medical research either ignored the differences between men and women or treated them as a minor detail. The more I looked, the more I felt this was not a small detail at all, it was right at the heart of the problem.

And then there are the brain’s support cells, the astrocytes. They have fascinated me since my very first steps in research, back in Brazil and later in Madrid, and now in Ireland, and honestly, they still do.

People used to dismiss them as the glue that just holds the brain together, but I came to see them as real decision-makers. They have a big say in whether the brain heals after damage or not. Once I put that together with hormones, which fade so differently in men and women, and with those tiny batteries that hold the power of life and death over a cell, I finally felt I had a way to actually explain these differences, instead of just pointing at them.

Why is this research important?

I think there are two reasons. The first is very simple – as people live longer, more of us will face diseases like dementia, and women carry more of that burden. If we can really understand why the loss of hormones makes the female brain more vulnerable, we can start to design treatments that fit a person’s biology, rather than treating everyone the same way, which is mostly what we still do today.

The second reason is more about the bigger picture. When those little cell batteries start to fail, it is not a problem unique to one disease. We see it in ageing, in brain injury, in inflammation, in dementia. So, if we can find ways for hormones to keep those batteries running, we have found something that could help in many situations at once.

That is exactly why we focus on drugs that already exist and are already known to be safe. Taking an approved drug and giving it a new purpose is a much faster, cheaper way to reach patients than developing one from scratch. And for people who are suffering now, speed matters.

What has been the most surprising insight/discovery in your research?

The biggest surprise has been just how much sex matters, right down to a single cell.

We tend to assume a drug does roughly the same thing in everyone. But when we studied a hormone-based drug called tibolone, we found it acted differently in cells taken from females than in cells taken from males.

The cells responded in their own distinct ways, and the drug even restored their natural cleaning-up ability differently depending on whether they were male or female. The idea that a cell sitting in a dish still ‘knows’ whether it is male or female and reacts to the very same drug differently because of it is striking, and it is still something a lot of people do not fully understand.

What surprised me even more was that this difference goes right down to those tiny batteries (mitochondria) inside the cell that I mentioned earlier.

We discovered that, in the brain’s support cells (astrocytes), mitochondria from females were tougher and coped far better than the ones from males when we exposed them to high levels of saturated fat, the kind of stress the body goes through in obesity.

In other words, the female brain cells’ energy systems were simply more resilient under that pressure. That was a real eye-opener for me, because it suggests these male/female differences are not just small details, but they are built deep into how a cell powers itself and protects itself. And it reinforces why we cannot keep designing treatments as if one size fits all.

What are your thoughts on Ireland’s research landscape? What improvements would you suggest?

I think Ireland is at a really interesting turning point. In 2024, the Government brought its two main research funding bodies together into one, now called Research Ireland, which now funds work across every subject, from science and engineering to the arts and social sciences. I see that as a good move. Before, some subjects were not properly included in the funding system, which put Ireland a step behind other countries. For me, whose work crosses several fields at once, a system that genuinely supports that kind of crosstalk between different areas is very much welcome!

There is real ambition behind it too. Ireland plans to invest in its universities and wants to support thousands of new PhD students and researchers who are early in their careers. And for such a small country, what strikes me most is the talent and the genuinely close links between academia, industry and pharma. That combination is honestly quite unique in the world, and it is part of what made me want to build my lab here.

That said, there are a few things I would push on. First, I would love to see steadier, more predictable money for fundamental research. Applied work matters enormously, but the truly big breakthroughs so often start as curiosity-driven science with no obvious (and long-term impact) commercial angle. My own tibolone work began exactly like that.

Second, we have to look after our younger researchers, the PhD students, the postdocs, the research assistants and the new group leaders. The ambition to train thousands of them is wonderful, but only if we then value them and build real ways to keep them here, instead of losing them abroad.

Third, our infrastructure. Modern biomedical research needs advanced imaging, computing power, data science and shared facilities, and that needs continued investment.

And fourth, and this one is close to my heart given my EDI role, I would like to see equality, diversity and inclusion treated as part of research excellence, not as a box-ticking exercise on the side. For me, they are the same thing. Broader participation, inclusive teams, and fair structures simply produce better science.

My own field is the proof. Ignoring the differences between men and women held the science back for decades. This is not acceptable.

Finally, I think Ireland is perfectly placed to connect academia, healthcare, industry, policy and communities. For areas like dementia, women’s health and menopause, the real progress will come from people working across those boundaries. Ireland is small enough that you can actually get those people into a room quickly, and ambitious enough to lead the world if we support those connections properly.

Don’t miss out on the knowledge you need to succeed. Sign up for the Daily Brief, Silicon Republic’s digest of need-to-know sci-tech news.

Apple’s big yearly software event looks set to focus a lot on on-device AI, with reports suggesting the company’s in-house chip architecture will give it a key advantage over rivals.

WWDC 2026 kicks off on 9 June, with iOS 27 for iPhone and software updates for iPad, Mac, Apple Watch, and Apple Vision Pro all expected to be previewed at the event, and AI is widely anticipated to be integrated into pretty much every new feature Apple introduces.

The shift toward on-device processing addresses a core limitation of most AI implementations, where queries travel to remote data centres and back before a result reaches the user, introducing latency that depends entirely on network quality and connection speed.

Apple’s silicon lineup, which powers everything from the iPhone through to the Mac, carries enough processing headroom to handle AI inference locally, cutting out that round trip entirely and keeping the workload on the device itself.

Partner Content This
year, the global build-out of datacenters has become impossible to
ignore, with the debate spilling into national media, local
newspapers, and community council meetings alike. From Arkansas to
Southern California, Nevada, Pennsylvania, West Virginia, and most
recently Box Elder, Utah, communities are weighing the economic
promise of datacenter expansion against mounting concerns over
energy, infrastructure, and residential impact. The same dynamic is
playing out in the UK, where OpenAI’s “Stargate UK” project
has been partly shelved
amid energy consumption concerns and regulatory pressure.

A typical new hyperscale datacenter can face grid-connection
bottlenecks of up to seven
years in certain markets, well before the necessary
transmission, substations, generation capacity, and transformers are
in place. McKinsey, meanwhile, estimates that global datacenter
spending could reach $7
trillion by 2030 – a figure comparable to the size of a
top-12 global economy.

AI intelligence at scale now dominates enterprise strategy and
global politics because the promise of the technology is matched only
by the infrastructure required to deliver it. Energy consumption is
unavoidable in this new world, and the bet enterprise leaders are
making is that the value AI creates will outstrip the cost of the
power feeding it. That trade-off has produced a new equation for
executives: intelligence
per watt.

Is your agentic ambition constrained by energy?

AI-driven datacenters already account for
roughly 1.5 percent of global electricity consumption, and the IEA
expects that demand to more
than double by 2030, approaching three percent of global
electricity use. That’s more than many major industrial sectors,
including agriculture.

The pressure will compound over the next three years, with IDC
projecting onebillion
agents running 217 billion daily actions by 2029. From
Seattle to Barnsley in the UK, the race to build more datacenters
close to energy sources is now a daily occurrence.

If the right datacenter, grid, and power infrastructure for the
first billion agents takes up to seven years to build, supporting
two, three, or even eight billion agents implies timelines the
industry has yet to cost. The mismatch between enterprise intent and
energy capacity is widening.

For enterprise leaders, this is a defining moment of decision.
With 95
percent of global enterprises intending to become their
own AI and data platforms in less than 780 days, AI, data, and energy
can no longer be treated as separate priorities; they are now
interconnected parts of a single platform strategy. The harder
question is how executives can pursue those AI ambitions while
managing energy efficiently at agentic scale.

BFSI might be showing us the way forward

Banking, financial services, and insurance
(BFSI) enterprises have traditionally invested more heavily in
technology than any other major sector. McKinsey estimates banking IT
spending typically runs at between
six and 12 percent of revenue, compared with 3.75 percent
to five percent for the next-highest sector.

The pressure to deliver new technology value, particularly through
AI and agentic systems, is creating an operating language shared by
CIOs, CTOs, and business leaders alike. AI and data are increasingly
framed as the new competitive moat, yet the energy costs associated
with maintaining that moat introduce a fresh dynamic into technology
decision-making.

The 13
percent of global enterprises winning with AI and agentic
systems are more likely to build their data strategies around
control, efficiency, and sustainability. The common pattern is
repatriation: pulling AI and data out of single-hyperscaler silos and
into their own control planes, where they can govern and manage
information across clouds, on-premises environments, and systems they
own.

The pattern recurs among agentic AI leaders across EMEA, North
America, Singapore, and Japan. The principle is straightforward:
bring AI to the data, because the two must work together across the
front lines and back offices of the business rather than operating as
separate concerns.

That logic explains why BFSI leaders such as Wells Fargo,
Mastercard, HSBC, JPMorgan Chase, Bank of America, Citigroup, Goldman
Sachs, BNP Paribas, ING, Crédit Agricole, UBS, and NatWest have made
public carbon-neutrality commitments alongside ambitious plans to
become their own sovereign AI and data platforms.

AI and data sovereignty in Postgres wins on OpEx, environment, and
ROI

Agents operate at the data layer, which
means energy must be managed at the same layer, since this is where
much of the work happens. The alternative is the equivalent of
turning on the heat while leaving every window open in the middle of
winter. Only by controlling the data layer, agents, and broader data
estate can enterprises build the foundation for managing energy
consumption.

Energy efficiency has to begin where enterprise operations already
run, which is why PostgreSQL^®, the world’s most widely used database
among developers, is well suited to the challenge. EDB
Postgres AI is built specifically to address the
energy-intensive nature of modern datacenters by improving database
and AI efficiency at the point where workloads execute.

By shrinking core usage requirements and tightening data-intensive
agentic operations such as search, retrieval, and vector indexing,
EDB Postgres AI can cut datacenter energy consumption by up to 81
percent and reduce emissions by as
much as 87 percent.

The ambition to become an AI and data platform carries one
foundational requirement: AI and data sovereignty. Organizations that
adopt this model not only achieve 5x
ROI and deploy 2x more AI and agentic AI systems; they
also gain more control, greater efficiency, and a smarter way to
design and operate datacenters for the agentic era.

The formula for success is sovereignty in Postgres — the most
practical path to achieving more intelligence per watt.

Contributed by EDB.

Autodesk has spent four decades selling the software that engineers and architects use to design buildings, factories and machines. With its latest acquisition, it is buying its way into what happens after those things are built.

The company has agreed to acquire MaintainX, a maintenance and operations platform, for about $3.6 billion in cash.

The deal, announced on 28 May, is an all-cash transaction Autodesk plans to fund with cash on hand and new debt. Closing is targeted for as early as 3 August, subject to regulatory and customary conditions.

Alongside the headline price, Autodesk said it would issue $150 million in restricted stock to MaintainX employees, the standard retention sweetener that signals the buyer wants the team, not just the product.

MaintainX is the kind of company that is invisible until something breaks. Founded in San Francisco in 2018 and led by chief executive Chris Turlica, it makes mobile-first maintenance software, a modern take on the computerised maintenance management systems, or CMMS, that factories and facilities use to track work orders, assets and repairs.

More than 500,000 frontline workers use it, and the company was last valued at around $2.5 billion privately, on annual recurring revenue reported near $115 million.

At roughly $3.6 billion, Autodesk is paying a clear premium to that last private mark, which is the going rate when a strategic buyer wants a category leader rather than a turnaround.

The number also looks large against MaintainX’s revenue, the kind of multiple that only makes sense if the buyer is pricing the strategic fit rather than the current financials.

That fit is the whole rationale. Autodesk frames its strategy as converging “design, make and operate,” the idea that data should flow continuously from the moment something is designed to the years it spends in service. It has the design and the make; operations was the gap.

MaintainX slots into a new division Autodesk is calling Autodesk Operations Solutions, giving it a foothold in the daily work of the maintenance teams who keep its customers’ physical assets alive.

There is an AI logic underneath the org chart. Maintenance data, every work order, every breakdown, every part replaced, is exactly the kind of structured operational record that trains useful predictive models, and Autodesk has been pushing its own generative-AI design tools.

Owning the operate layer gives it a data stream it did not have, at a moment when every enterprise-software company is racing to turn its workflows into AI features.

For MaintainX, a $3.6bn cash exit is a clean outcome for its backers and a fast one for a company not yet a decade old.

For Autodesk, the harder work begins after August: integrating a mobile-first frontline product into a design-software giant, and proving that “design, make and operate” is a platform customers will buy as one thing rather than a slide that explains an acquisition.

Call of Duty players on previous-generation consoles can’t seem to catch a break. First, Activision announced that the next Call of Duty, which we now know is Call of Duty: Modern Warfare 4, will not be released on PS4 and Xbox One. Now, the company is also taking Call of Duty: Warzone away from both older consoles.

The publisher has confirmed that Warzone support on PS4 and Xbox One will be reduced in stages before ending later this year. The first step begins on June 4, when Warzone will be removed from the PlayStation 4 and Xbox One digital storefronts. After that, new downloads will no longer be available on either platform.

Warzone’s last-gen exit starts in June

Players who already have Warzone in their library will still be able to install and play the game for a limited time. Activision says the game will remain playable on PS4 and Xbox One through the end of Season 06 for Call of Duty: Black Ops 7.

The next major change arrives on June 25, when the Warzone in-game store will be removed from both last-gen versions. COD Points can still be redeemed in the store until then, and gameplay will continue to count toward Battle Pass progression. Players without the paid Battle Pass can still unlock free-tier rewards, including new weapons, during the remaining Black Ops 7 seasons.

The final cutoff comes with Modern Warfare 4 Season 1. Once that season begins, Warzone will no longer be playable on PS4 or Xbox One.

Upgrading may sting for PS4 holdouts

For PlayStation players, the timing is awkward. Sony’s Days of Play 2026 sale is live, but the PS5 console itself does not appear to be getting a discount. The upside is that players who do upgrade can still pick up discounted PS5 games, accessories, and PlayStation Plus memberships while the sale runs through June 10.

Activision says players will not lose their Warzone progress if they move to PS5, Xbox Series X|S, or PC using the same linked Activision account. Items bought with COD Points will also carry over. However, unused COD Points stay tied to the same console family, so PS4 players can use them on PS5, and Xbox One players can use them on Xbox Series X|S.

Warzone gave PS4 and Xbox One players a long runway after the current-gen consoles arrived. That runway is now almost over, and anyone who wants to keep playing Call of Duty’s battle royale after this season will need to move to newer hardware soon.