2025 marks the 50th anniversary of the release of Jaws, the film that almost single-handedly rewrote the rules of summer movies. Over the next half century, summer became known as the home of cinematic spectacle, the time for films made on the largest scale possible, released into thousands of theaters all at once.A lot has changed since 1975, in the world at large and in the world of movies. But every summer, cinephiles still look forward to escaping the heat and the general awfulness of the world for two hours at the theater. And no matter how much things change, the movies playing in theaters during the summer still tend to be the big blockbusters; the sequels, the comic-book movies, the major star vehicles loaded with special effects.2025 is no exception. Below you’ll find 15 of ScreenCrush’s most-anticipated films this summer. Most are playing exclusively in theaters to start, although we did sneak in one notable streaming title too. We also threw a couple smaller titles from notable directors into the mix as well; sometimes you want a little intermezzo to cleanse the palate between bigger courses.Or if you just want to revisit Jaws for its 50th anniversary, keep your eyes out at your local theater, as Universal is holding special screenings this summer as well. (And let’s be honest, if any of these movies is even half as good as Jaws, that will be great news.)2025 Summer Movie PreviewHere are 15 can’t-miss summer movies for 2025.READ MORE: Great Songs You Forgot Were Originally Written For MoviesGet our free mobile app25 Big Blockbuster Movies You Forgot ExistedRemember these movies? They made a lot of money at the box office!

The Procurement Analyst is responsible for supporting procurement and finance teams in negotiating contracts and enhancing Paymentology’s purchasing processes. This role plays a key part in improving Paymentology’s commercial position and financial performance by identifying cost-saving opportunities, ensuring compliance with internal and external procurement policies, and implementing structured purchasing procedures.Contract Negotiation and Procurement Management:Assist in the negotiation of new contracts and contract renewals, ensuring optimal commercial terms for Paymentology.Identify cost-saving opportunities by analysing procurement data and monitoring expenditure.Maintain accurate and up-to-date records of supplier agreements, procurement activities, and savings opportunities.Financial and Data Analysis:Monitor and analyse procurement data to track expenditure trends and highlight efficiency opportunities.Develop dashboards to visualise spend, assess supplier performance, and identify key cost-reduction strategies.Compliance and Vendor Onboarding:Work closely with legal, compliance, and cybersecurity teams to onboard vendors in accordance with Paymentology’s internal policies, PCI regulations, and client requirements.Ensure that all procurement processes align with regulatory standards and risk management protocols.Cross-Functional Collaboration:Collaborate with internal stakeholders to proactively manage purchases and secure the best commercial deals.Support the rollout and continuous improvement of procurement processes, including the implementation of a third-party risk management system and purchase order process within the current ERP system.Outcome: A structured, data-driven procurement process that enhances financial performance, mitigates risk, and ensures Paymentology secures the best value in supplier agreements.What it takes to succeed:Strong analytical skills with the ability to interpret and compare complex, multi-layered commercial proposals.Excellent interpersonal skills, with the ability to engage and influence internal and external stakeholders.Proficiency in Microsoft Office, particularly Excel, for procurement data analysis and reporting.High attention to detail, with the ability to manage multiple concurrent tasks in a fast-paced environment.Experience in technology procurement, particularly in SaaS-based agreements.Understanding of legal contract review and negotiation.Familiarity with ERP systems is preferred.Years of Experience2–3 years of experience in a procurement or commercial-based role.Proven track record of contract negotiation, supplier management, and cost-saving initiatives.Experience in technology and SaaS procurement is highly desirable.Apply NowLet's start your dream job Apply now Meet JobCopilot: Your Personal AI Job HunterAutomatically Apply to Remote All Other Remote JobsJust set your preferences and Job Copilot will do the rest-finding, filtering, and applying while you focus on what matters. Activate JobCopilot

Rumor has it, we may soon see an ultra thin iPhone. The rumored iPhone 17 Air -- or it might be called the iPhone Slim -- could potentially replace the current iPhone Plus amid Apple's next iPhone release in the coming months. The buzzed-about "Air" is getting a lot of attention in the iPhone 17 rumor mill, but the prospect also has people asking if Apple may have to sacrifice features to get a super thin phone.Here's the skinny on what we could expect with the newest iPhone.iPhone 17 Air release date: Is the slimmer iPhone coming this year?For nearly a decade, Apple has held an event in September to announce its new phones. This year we expect Apple to reveal the iPhone 17 series, including the rumored iPhone 17 Air.If the iPhone 17 Air rumors are true, Apple would be the latest to join the ultra-thin phone trend this year. Last week, I got to try out Samsung's new lightweight Galaxy S25 Edge after previewing it and a slew of shockingly thin phones at the Mobile World Congress in March.The iPhone 17 lineup may be the last to follow this fall-release model, according to Apple analyst Ming-Chi Kuo and a report from The Information. Starting with the iPhone 18, Apple will reportedly split its phone releases so that lower-cost iPhones launch in the first half of the year (previously reserved for iPhone SE models) and higher-end pro models are announced in the latter half. That would likely mean a rumored iPhone 18 Pro, Pro Max, Air and new foldable iPhone model could debut in fall 2026. Keep in mind that an iPhone Flip or Fold has been rumored for years.You'll likely be able to preorder a new iPhone the Friday after the announcement, with the phone shipping a week later.What will the iPhone 17 Air cost?Early rumors about an iPhone 17 Air hinted that it could cost even more than the iPhone 17 Pro, but a March Bloomberg report suggested the phone could cost around $900. That price tag would align with the rumor that the "Air" could replace the Plus, which currently costs $899. For comparison, Samsung's Galaxy S25 Edge starts at $1,100.However, there's also the question of how tariffs could affect the price of an iPhone. Amid President Donald Trump's ongoing tariff drama, Apple has mostly escaped additional taxes by stockpiling inventory and getting most of its products on a tariff exemption list. Apple has moved some production of US iPhones to India to avoid the steeper tariffs imposed on China. However, Trump recently said he pushed Apple CEO Tim Cook to move US iPhone production from India to the US. How much all of this could affect iPhone prices is yet to be determined.Regardless of how tariffs play out, Apple is expected to raise the price of the iPhone. These price hikes are rumored to start with the iPhone 17 line, so prepare now to pay more for "Air." iPhone 17 Air camera: potential downgrade?Among the rumored potential sacrifices Apple may have to make to get a skinnier phone is limiting the camera features. The rumored iPhone 17 line is getting a new camera bar that extends across the width of the phone. But Front Page Tech shared an iPhone 17 Air video in February that showed a physical mockup of the phone based on rumors. One of the more surprising reveals was a smaller camera bar with one lens on the left, suggesting the "Air" phone has a single rear camera, similar to the iPhone 16E ($599). It's not clear if the camera would be the same as the 16E or if Apple would go the route Samsung did and include the main camera from the iPhone 17 Pro.The single camera theory is backed up by analyst Ming-Chi Kuo and a Bloomberg report, which said that the rumored Air may not have the ultrawide and 5x telephoto lenses that have become staples of Apple's premium iPhones. In a bit of good news, it's also rumored that the front-facing "selfie" camera on all iPhone 17 models, including the Air, will be upgraded to 24 megapixels, according to analyst Jeff Pu. iPhone 17 Air vs iPhone 17 ProIt may be getting a lot of attention, but the rumored Air appears to be less an advanced Pro model and more a replacement for the Plus.However, rumors are that the Air would have a 6.6-inch display, according to analysts Jeff Pu and Ming-Chi Kuo. If accurate, that would mean the Air's display is slightly smaller than the iPhone 16 Plus, with a 6.7-inch display, but larger than the iPhone 16 Pro, which features a 6.3-inch display. The iPhone 16 Pro Max leads with a 6.9-inch display. It's unclear if the 17 Air's screen would be a Pro Motion display like the one found on iPhone Pro models.If the rumored Air lives up to its name, then the biggest potential advantage it could offer over a Pro is its size and weight. A Bloomberg report from March notes that the iPhone Air could measure 5.5mm thick, compared to the iPhone 16 Pro at 8.25mm. Mac Rumors reported that a leaker on the Korean-langauge Naver blog, going by "yeux1122," said that the rumored iPhone 17 Air weighs approximately 145 grams (5.11 ounces). Compare that to the iPhone 16 Pro, which weighs in at 199 grams (7.03 ounces). If this rumor proves true, the Air would be just slightly heavier than the iPhone 13 mini, which weighs 141 grams (4.97 ounces).Bloomberg's report also notes that the iPhone 17 Air is expected to have super slim bezels compared to the rest of the line, along with a Camera Control button and a Dynamic Island cutout in the display.iPhone 17 Air battery life expectationsAmong the challenges of slimming down an iPhone could be figuring out how to reduce the battery size without compromising battery life.Initially, it was assumed that a skinnier iPhone would simply have a reduced battery life since there would be less space to house a large battery. But more recently, AppleInsider reported that a skinnier iPhone might use a silicon-anode battery that could help extend its battery life. Yeux1122 said the battery capacity is 2,800mAh, based on details that originate with "mass production confirmed sample," according to MacRumors. It added that a high density battery in the Air could increase its "actual capacity" by 15 to 20%.If the rumored iPhone 17 Air does use the silicon battery technology, it would be the first iPhone to do so.Are iPhone Air rumors and leaks to be trusted?Rumors are just that. The speculation leading up to the iPhone's release is often based on insider knowledge or leaked information from the teams working on the iPhone's design, but those plans can continue to evolve and are not necessarily reflected in the final product. We'll only be able to confirm these rumors with certainty when Apple officially releases the next iPhone and we can see it for ourselves.

May 20, 2025Could Mitochondria Be Rewriting the Rules of Biology?New discoveries about mitochondria could reshape how we understand the body’s response to stress, aging, and illness. Scientific AmericanSUBSCRIBE TO Science QuicklyRachel Feltman: Mitochondria are the powerhouse of the cell, right? Well, it turns out they might be way more complicated than that, and that could have implications for everything from diet and exercise to treating mental health conditions.For Scientific American’s Science Quickly, I’m Rachel Feltman.Our guest today is Martin Picard, an associate professor of behavioral medicine at Columbia University. He’s here to tell us all about our mitochondria, what they do for us and how they can even talk to each other. If you like to watch your pods instead of just listening, you can check out a video version of my conversation with Martin over on our YouTube page. Plus, you’ll get to see some of the aligning mitochondria we’re about to talk about in action.On supporting science journalismIf you're enjoying this article, consider supporting our award-winning journalism by subscribing. By purchasing a subscription you are helping to ensure the future of impactful stories about the discoveries and ideas shaping our world today.Martin, would you tell us a little bit about who you are and where you work?Martin Picard: Sure, I work at Columbia University; I’m a professor there, and I lead a team of mitochondrial psychobiologists, so we try to understand the, the mind-mitochondria connection, how energy and those little living creatures that populate our cells, how they actually feed our lives and allow us to, to be and to think and to feel and to experience life.Feltman: Before we get into the details, most people know mitochondria as the “powerhouse of the cell”—which, fun fact, Scientific American actually coined in the 1950s—but what are mitochondria, to start us off with a really basic question?Picard: [Laughs]Yes, 1957 is the “powerhouse of the cell.” That was momentous.That shaped generations of scientists, and now the powerhouse analogy is expired, so it’s time for a new perspective.Really, mitochondria are, are small living organelles, like little organs of the cell, and what they do is they transform the food we eat and the oxygen that we breathe. Those two things converge inside the mitochondria, and that gets transformed into a different kind of energy. Energy is neither created nor destroyed, right? It’s a fundamental law of thermodynamics. So mitochondria, they don’t make energy; they transform the energy that’s stored in food from the plants and from the energy of the sun and then the oxygen combining this, and then they transform this into a little electrical charge. They dematerialize food—energy stored in food—into this very malleable, flexible form of energy that’s membrane potential, so they become charged like little batteries and then they power everything in our cells, from turning on genes and making proteins and cellular movement; cellular division; cell death, aging, development—everything requires energy. Nothing in biology is free.Feltman: Well, I definitely wanna get into what you said about the powerhouse analogy not working anymore ’cause that seems pretty huge, but before we get into that: you recently wrote a piece for Scientific American, and you referred to yourself as, I think, a “mitochondriac.” I would love to hear what you mean by that and how you got so interested in these organelles.Picard: Yeah, there’s a famous saying in science: “Every model is wrong, but some are useful.” And the model that has pervaded the world of biology and the health sciences is the gene-based model (the central dogma of biology, as it’s technically called): genes are the blueprint for life, and then they drive and determine things. And we know now [it] to be misleading, and it forces us to think that a lot of what we experience, a lot of, you know, health or diseases, is actually determined by our genes. The reality is a very small percentage [is].Whether we get sick or not and when we get sick is not driven by our genes, but it’s driven by, you know, emergent processes that interact from our movement and our interaction with other people, with the world around us, with what we eat, how much we sleep, how we feel, the things we do. So the gene-based model was very powerful and useful initially, and then, I think, its, its utility is dwindling down.So the powerhouse analogy powered, you know, a few [laughs] decades of science, and then what started to happen, as scientists discovered all of these other things that mitochondria do, we kept getting surprised. Surprise is an experience, and when you feel surprised about something, like, it’s because your internal model of what that thing is, it was wrong, right?Feltman: Right.Picard: And when there’s a disconnect between your internal model and the, the reality, then that feels like surprise. And I grew up over the last 15 years as a academic scientist, and, like, every month there’s a paper that’s published: “Mitochondria do this. Mitochondria make hormones.” Surprise! A, a powerhouse should have one function: it should make, or transform, energy, right? This is what powerhouses do. Mitochondria, it turns out, they have a life cycle. They make hormones. They do transform energy, but they also produce all sorts of signals. They turn on genes; they turn off genes. They can kill the cell if they deem that’s the right thing to do.So there are all of these functions, and, and I think, as a community, we keep being surprised as we discover new things that mitochondria do. And then once you realize the complexity and the amazing beauty of mitochondria and their true nature, then I think you have to become a mitochondriac [laughs]. You have to, I think, be impressed by the beauty of—this is just a—such a beautiful manifestation of life. I fell in love with mitochondria, I think, is what happened [laughs].Feltman: Yeah, well, you touched on, you know, a few of the surprising things that mitochondria are capable of, but could you walk us through some of your research? What surprises have you encountered about these organelles?Picard: One of the first things that I saw that actually changed my life was seeing the first physical evidence that mitochondria share information ...Feltman: Mm.Picard: With one another. The textbook picture and the powerhouse analogy suggests that mitochondria are these, like, little beans and that they, they kind of float around and they just make ATP, adenosine triphosphate, which is the cellular energy currency, and once in a while they reproduce: there’s more mitochondria that come from—mitochondria, they can grow and then divide. So that’s what the powerhouse predicts.And what we found was that when—if you have a mitochondrion here and another mitochondrion here, inside the mitochondria, they’re these membranes ...Feltman: Mm.Picard: They’re, like, little lines. They look, in healthy mitochondria, look like radiators, right? It’s, like, parallel arrays. And it’s in these lines that the oxygen that we breathe is consumed and that the little charge—the, the food that we eat is converted into this electrical charge. These are called cristae.And in a normal, healthy mitochondria the cristae are nicely parallel, and there’s, like, a regularity there that’s just, I think, intuitively appealing, and it, it looks healthy. And then if you look at mitochondria in a diseased organ or in a diseased cell, often the cristae are all disorganized. That’s a feature of “something’s wrong,” right?And I’ve seen thousands of pictures and I’ve taken, you know, several thousands of pictures on the electron microscope, where you can see those cristae very well, and I’d never seen in the textbooks or in articles or in presentations, anywhere, that the cristae could actually, in one mitochondrion, could be influenced by the cristae in another mitochondrion.And what I saw that day and that I explained in the [laughs], in the article was that there was this one mitochondrion there—it had beautifully organized cristae here, and here the cristae were all disorganized. And it turns out that the part of this mitochondrion that had beautifully organized cristae is all where that mitochondria was touching other mitochondria.Feltman: Mm.Picard: So there was something about the mito-mito contact, right? Like, a unit touching another unit, an individual interacting with another individual, and they were influencing each other ...Feltman: Yeah.Picard: And the cristae of one mitochondrion were bending out of shape. That’s not thermodynamically favorable [laughs], to bend the lipid membrane, so there has to be something that is, you know, bringing energy into the system to bend the membrane, and then they were meeting to be parallel with the cristae of another mitochondrion. So there was these arrays that crossed boundaries between individual mitochondria ...Feltman: Wow.Picard: And this was not [laughs] what I, I learned or this was not what I was taught or that I’d read, so this was very surprising.The first time we saw this, we had this beautiful video in three dimension, and I was with my colleague Meagan McManus, and then she realized that the cristae were actually aligning, and we did some statistics, and it became very clear: mitochondria care about mitochondria around them ...Feltman: Yeah.Picard: And this was the first physical evidence that there was this kind of information exchange.When you look at this it just looks like iron filings around a magnet.Feltman: Mm.Picard: Sprinkle iron filings on the piece of paper and there’s a magnet underneath, you see the fields of force, right? And fields are things that we can’t see, but you can only see or understand or even measure the strength of a field by the effect it has on something. So that’s why we sprinkle iron filings in a magnetic field to be able to see the field.Feltman: Right.Picard: It felt like what we were seeing there was the fingerprint of maybe an underlying electromagnetic field, which there’s been a lot of discussion about and hypothesis and some measurements in the 1960s, but that’s not something that most biologists think is possible. This was showing me: “Maybe the powerhouse thing is, is, is, is not the way to go.”Feltman: Did you face any pushback or just general surprise from your colleagues?Picard: About the cristae alignment?Feltman: Yeah.Picard: I did a lot of work. I took a lot of pictures and did a lot of analysis to make sure this was real ...Feltman: Mm.Picard: So I think when I presented the evidence, it was, it was, you know, it was clear [laughs].Feltman: Right.Picard: This was real.Feltman: Yeah.Picard: Whether this is electromagnetic—and I think that’s where people have kind of a gut reaction: “That can’t be real. That can’t be true.”Feltman: Mm.Picard: The cristae alignment is real, no questioning this, but whether this—there’s a magnetic field underlying this, we don’t have evidence for that ...Feltman: Sure.Picard: It’s speculation, but I think it, it hits some people, especially the strongly academically trained people that have been a little indoctrinated—I think that tends to happen in science ...Feltman: Sure.Picard: I think if we wrote a grant, you know, to, to [National Institutes of Health] to study the magnetic properties of mitochondria, that’d be much harder to get funded. But there was no resistance in accepting the visual evidence of mitochondria exchanging information ...Feltman: Yeah.Picard: What it means, then, I think, is more work to be done to—towards that.Feltman: If, if we were seeing an electromagnetic field, what would the implications of that be?Picard: I think the implications is that the model that most of biomedical sciences is based on, which is “we’re a molecular soup and we’re molecular machines,” that might not be entirely how things work. And if we think that everything in biology is driven by a lock-and-key mechanism, right—there’s a molecule that binds a receptor and then this triggers a conformational change, and then there’s phosphorylation event and then signaling cascade—we’ve made a beautiful model of this, a molecular model of how life works.And there’s a beautiful book that came out, I think last year or end of 2023, How Life Works, by Philip Ball, and he basically brings us through a really good argument that life does not work by genetic determinism, which is how most people think and most biologists think that life works, and instead he kind of brings us towards a much more complete and integrative model of how life works. And in that alternate model it’s about patterns of information and information is carried and is transferred not just with molecules but with fields. And we use fields and we use light and we use, you know, all sorts of other means of communication with technology; a lot of information can be carried through your Bluetooth waves ...Feltman: Mm.Picard: Right? Fields. Or through light—we use fiber optic to transfer a lot of information very quickly. And it seems like biology has evolved to, to harness these other ways of, of nonmolecular mechanisms of cell-cell communication or organism-level communication.There’s an emerging field of quantum biology that is very interested in this, but this clashes a little bit with the molecular-deterministic model that science has been holding on to [laughs]—I think against evidence, in, in some cases—for a while. Nobody can propose a rational, plausible molecular mechanism to explain what would organize cristae like this across mitochondria. The only plausible mechanism seems to be that there’s a—there’s some field, some organizing electromagnetic field that would bend the cristae and organize them, you know, across organelles, if that’s true.Feltman: Right.Picard: It was a bit of an awakening for me, and it turned me into a mitochondriac because it made me realize that this is the—this whole thing, this whole biology, is about information exchange and mitochondria don’t seem to exist as little units like powerhouses; they exist as a collective.Feltman: Yeah.Picard: The same way that you—this body. It’s a bunch of cells; either you think it’s a molecular machine or you think it’s an energetic process, right? There’s energy flowing through, and are you more the molecules of your body or are you more the, the energy flowing through your body?Feltman: Mm.Picard: And if you go down this, this line of questioning, I think, very quickly you realize that the flow of energy running through the physical structure of your body is more fundamental. You are more fundamentally an energetic process ...Feltman: Hmm.Picard: Than the physical molecular structure that you also are. If you lose part of your anatomy, part of your structure, right—you can lose a limb and other, you know, parts of your, of your physical structure—you still are you ...Feltman: Right.Picard: Right? If your energy flows differently or if you change the amount of energy that flows through you, you change radically. Three hours past your bedtime you’re not the best version of your, the best version of yourself. When you’re hangry, you haven’t eaten, and you, like, also, you’re not the best version of yourself, this is an energetic change. Right?Feltman: Yeah.Picard: Many people now who have experienced severe mental illness, like schizophrenia and bipolar disease, and, and who are now treating their symptoms and finding full recovery, in some cases, from changing their diets.Feltman: Mm.Picard: And the type of energy that flows through their mitochondria, I think, opens an energetic paradigm for understanding health, understanding disease and everything from development to how we age to this whole arc of life that parallels what we see in nature.Feltman: Yeah, so if we, you know, look at this social relationship between mitochondria, what are, in your mind, the most, like, direct, obvious implications for our health and ...Picard: Mm-hmm.Feltman: And well-being?Picard: Yeah, so we can think of the physical body as a social collective. So every cell in your body—every cell in your finger, in your brain, in your liver, in your heart—lives in some kind of a social contract with every other cell. No one cell knows who you are, or cares [laughs], but every cell together, right, makes up who you are, right? And then together they allow you to feel and to have the experience of who you are. That kind of understanding makes it clear that the key to health is really the coherence between every cell.Feltman: Mm.Picard: If you have a few cells here in your body that start to do their own thing and they kind of break the social contract, that’s what we call cancer. So you have cells that stop receiving information from the rest of the body, and then they kind of go rogue, they go on their own. Their purpose in life, instead of sustaining the organism, keeping the whole system in coherence, now these cells have as their mind, like, maybe quite literally, is, “Let’s divide, and let’s make more of ourselves,” which is exactly what life used to be before mitochondria came in ...Feltman: Mm.Picard: Into the picture 1.5 billion years ago, or before endosymbiosis, the origin of, of multicellular life. So cancer, in a way, is cells that have broken the social contract, right, exited this social collective, and then to go fulfill their own little, mini purpose, which is not about sustaining the organism but sustaining themselves. So that principle, I think, has lots of evidence to, to support it.And then the same thing, we think, happens at the level of mitochondria, right? So the molecular-machine perspective is that mitochondria are little powerhouses and they’re kind of slaves to the cell: if the cell says, “I need more energy,” then the mitochondria provide and they kind of obey rules. The mito-centric perspective [laughs] is that mitochondria really drive the show. And because they’re in charge of how energy flows, they have a veto on whether the cell gets energy and lives and divides and differentiates and does all sorts of beautiful things or whether the cell dies.And most people will know apoptosis, programmed cell death, which is a normal thing that happens. The main path to apoptosis in, in our bodies is mitochondria calling the shot, so mitochondria have a veto, and they can decide, “Now, cell, it’s time to die.” And mitochondria make those decisions not based on, like, their own little powerhouse [laughs] perception of the world; they make these decisions as social collectives. And you have the hundreds, thousands of mitochondria in some cells that all talk to each other and they integrate dozens of signals—hormones and metabolites and energy levels and temperature—and they integrate all this information; they basically act like a mini brain ...Feltman: Hmm.Picard: Inside every cell. And then once they have a, a—an appropriate picture of what the state of the organism is and what their place in this whole thing is, then they actually, I think, make decisions about, “Okay, it’s time to divide,” right? And then they send signals to, to the nucleus, and then there’re genes in the nucleus that are necessary for cell division that gets turned on, and then the cell enters cell cycle, and we and others have shown in, in, in the lab, you can prevent a cell from staying alive [laughs] but also from differentiating—a stem cell turning into a neuron, for example, this is a major life transition for a cell. And people have asked what drives those kind of life transitions, cellular life transitions, and it’s clear mitochondria are one of the main drivers of this ...Feltman: Hmm.Picard: And if mitochondria don’t provide the right signals, the stem cell is never gonna differentiate into a specific cell type. If mitochondria exists as a social collective, then what it means for health [laughs] is that what we might wanna do is to promote sociality, right, to promote crosstalk between different parts of our bodies.Feltman: Hmm.Picard: And I suspect this is why exercise is so good for us.Feltman: Yeah, that was—that’s a great segue to my next question, which is: How do you think we can foster that sociality?Picard: Yeah. When times are hard, right, then people tend to come together to solve challenges. Exercise is a, a big challenge for the organism, right?Feltman: Mm.Picard: You’re pushing the body, you’re, like, contracting muscles, and you’re moving or, you know, whatever kind of exercise you’re doing—this costs a lot of energy, and it’s a big, demanding challenge for the whole body. So as a result you have the whole body that needs to come together to survive this moment [laughs]. And if you’re crazy enough to run a marathon, to push your body for three, four hours, this is, like, a massive challenge.Feltman: Sure.Picard: The body can only sustain that challenge by coming together and working really coherently as a unit, and that involves having every cell in the body, every mitochondria in the body talking to each other. And it’s by this coherence and this kind of communication that you create efficiency, and the efficiency is such a central concept and principle in all of biology. It’s very clear there, there have been strong evolutionary forces that have pushed biology to be evolved towards greater and greater efficiency.The energy that animals and organisms have access to is finite, right? There’s always a limited amount of food out there in the world. If there’s food and there are other people with you, your social group, do you need to share this? So if biology had evolved to just eat as much food as possible, we would’ve gone extinct or we wouldn’t have evolved the way we have. So it’s clear that at the cellular level, at the whole organism level, in insects to very large mammals, there’s been a drive towards efficiency.You can achieve efficiency in a few ways. One of them is division of labor. Some cells become really good at doing one thing, and that’s what they do. Like muscles, they contract [laughs]; they don’t, you know, release hormones—or they release some hormones but not like the liver, right?Feltman: Sure.Picard: And the liver feeds the rest of the body, and the liver is really good at this. But the liver’s not good at integrating sensory inputs like the brain. The brain is really good at integrating sensory inputs and kind of managing the rest of the body, but the brain is useless at digesting food or, you know, feeding the rest of the body. So every organ specializes, and this is the reason we’re so amazing [laughs]. This is the reason complex multicellular animals that, you know, that, that have bodies with organs can do so many amazing things: because this whole system has harnessed this principle of division of labor. So you have a heart that pushes blood, and you have lungs that take in oxygen, and that’s the main point: [it’s] the cooperation and the teamwork, the sociality between cells and mitochondria and, and organs that really make the whole system thrive.So exercise does that.Feltman: Yeah.Picard: It forces every cell in the body to work together. Otherwise you’re just not gonna survive. And then there are other things that happen with exercise. The body is a predictive instrument, right ...Feltman: Mm.Picard: That tries to make predictions about what’s gonna happen in the future, and then you adapt to this. So when you exercise and you start to breathe harder the reason you breathe harder, the reason, you know, you need to bring in more oxygen in your body, is because your mitochondria are consuming the oxygen. And when that happens every cell has the ability to feel their energetic state, and when they feel like they’re running out of energy, like if you’re exercising hard and your muscles are burning, your body says, “Next time this happens I’ll be ready.” [Laughs] And it gets ready—it mobilizes this program, this preparatory program, which, which we call exercise adaptation, right—by making more mitochondria. So the body can actually make more mitochondria after exercise.So while you’re exercising, the mitochondria, they’re transforming food and oxygen very quickly, making ATP, and then cells—organs are talking to one another; then you’re forcing this great social collective. Then when you go and you rest and you go to sleep, you lose consciousness [laughs], and then the natural healing forces of the body can work. Now the body says, “Next time this happens I’ll be ready,” and then it makes more mitochondria. So we know, for example, in your muscles you can double the amount of mitochondria you have ...Feltman: Wow.Picard: With exercise training. So if you go from being completely sedentary to being an elite runner, you will about double the amount of mitochondria in, in your muscle. And ...Feltman: That’s really cool.Picard: Yeah. And this seems to happen in other parts of the body as well, including the brain.Feltman: I know that your lab does some work on mitochondria and mental health as well. Could you tell us a little bit more about that?Picard: The ability to mitochondria to flow energy supports basic cellular functions, but it also powers the brain [laughs] and powers the mind, and our best understanding now of what is the mind—and consciousness researchers have been debating this for a long time—I think our, our best, most parsimonious definition of the mind is that the mind is an energy pattern. And if the flow of energy changes, then your experience also changes. And there’s emerging evidence in a field called metabolic psychiatry that mental health disorders are actually metabolic disorders ...Feltman: Hmm.Picard: Of the brain.There’s several clinical trials—some are published, many more underway—and the evidence is very encouraging that feeding mitochondria a certain type of fuel, called ketone bodies, brings coherence into the organism. And energetically we think this reduces the resistance to energy flow so energy can flow more freely through the neurons and through the structures of the brain and then through the mitochondria.And that—that’s what people report when they, they go into this medical ketogenic therapy: they feel like they have more energy, sometimes quite early, like, after a few days, sometimes after a few weeks. And then the symptoms of, of mental illness in many people get better. The website Metabolic Mind has resources for clinicians, for patients and, and guidance as to how to—for people to work with their care team, not do this on their own but do this with their medical team.Feltman: And I know that mitochondria have kind of a weird, fascinating evolutionary backstory.Picard: They used to be bacteria, and once upon a time, about two billion years ago, the only thing that existed on the planet that was alive were unicellular, right, single-cell, bacteria, a single-cell organism. And then some bacteria—there were different kinds—and then some bacteria were able to use oxygen for energy transformation; that was—those are called aerobic, for oxygen-consuming. And then there are also anaerobic, non-oxygen-consuming, bacteria that are fermenting cells.And then at some point, about 1.5 billion years ago, what happened is there was a small aerobic bacterium, an alphaproteobacterium, that either infiltrated a larger anaerobic cell or it was the larger cell that ate the small aerobic bacterium, the large one kept it in, and then the small aerobic bacterium ended up dividing and then became mitochondria. So mitochondria used to be this little bacterium that now is very much part of what we are, and what seems to have happened when this critical kind of merger happened is that a new branch of life became possible.Feltman: Yeah.Picard: And animals became possible. And somehow this acquisition, from the perspective of the larger cell, enabled cell-cell communication, a form of cell-cell communication that was not possible before. And this seems to have been the trigger for multicellular life and the development of, initially, little worms and then fishes and then animals and then eventually Homo sapiens.Feltman: Yeah, and that was really controversial when it was first proposed, right?Picard: Yeah. Lynn Margulis, who is, like, a fantastic scientist, she proposed this, and I think her paper was rejected [15] times ...Feltman: Wow.Picard: Probably by Nature and then by a bunch of [laughs] ...Feltman: [Laughs] Sure.Picard: A bunch of other journals. Fourteen rejections and then in the end she published it, and now this is a cornerstone of biology. So kudos for persistence ...Feltman: Yeah.Picard: For Lynn Margulis.Feltman: And mitochondria have just been shaking things up for, for decades [laughs], I guess.Picard: Mm-hmm, yeah, there’ve been several Nobel Prizes for understanding how mitochondria work—specifically for the powerhouse function of mitochondria [laughs].The field of [molecular] mitochondrial medicine was born in the ’80s. Doug Wallace, who was my mentor as a postdoc, discovered that we get our mitochondria from our mothers. The motherly nourishing energy [laughs] is passed down through mitochondria. There’s something beautiful about that.Feltman: Yeah. Thank you so much for coming in. This was super interesting, and I’m really excited to see your work in the next few years.Picard: Thank you. My pleasure.Feltman: That’s all for today’s episode. Head over to our YouTube page if you want to check out a video version of today’s conversation. We’ll be back on Friday with one of our deep-dive Fascinations. This one asks whether we can use artificial intelligence to talk to dolphins. Yes, really.While you’re here, don’t forget to fill out our listener survey. You can find it at sciencequickly.com/survey. If you submit your answers in the next few days, you’ll be entered to win some free Scientific American swag. More importantly, you’ll really be doing me a solid.Science Quickly is produced by me, Rachel Feltman, along with Fonda Mwangi, Kelso Harper, Naeem Amarsy and Jeff DelViscio. This episode was edited by Alex Sugiura. Shayna Posses and Aaron Shattuck fact-check our show. Our theme music was composed by Dominic Smith. Subscribe to Scientific American for more up-to-date and in-depth science news.For Scientific American, this is Rachel Feltman. See you next time!

Fortnite finally back on Apple devices in US and Europe Victory Royale. Image credit: Epic News by Ed Nightingale Deputy News Editor Published on May 21, 2025 Fortnite is finally back on iOS devices in the US and Europe, after a five-year legal battle between Epic and Apple. Despite a "peace proposal" being offered by Epic at the start of the month, Apple later blocked the return of Fortnite in the US. When Epic returned to the judge of the legal case to review its Fortnite submission, the judge responded Apple is "fully capable of resolving this issue without further briefing or a hearing" and warned the official who is "personally responsible for ensuring compliance" would have to return for a hearing (thanks TheVerge). The two companies have since filed a joint notice stating they have "resolved all issues". Fortnite Galactic Battle Cinematic TrailerWatch on YouTube As such, Fortnite has now returned to iOS devices, with Epic boss Tim Sweeney writing on social media "we back fam". To see this content please enable targeting cookies. Though Fortnite had already returned to iOS devices in the European Union, Apple's block of the game in the US delayed a regular update to the game, forcing all versions to be taken down. Of course, the UK is no longer in the EU, meaning Fortnite is not yet available here on iOS. It's expected in the second half of this year. Back in 2020, Epic added a direct in-game payment option in Fortnite to circumvent Apple and Google's official in-app purchase options, from which those companies take a 30 percent cut. In retaliation, Apple pulled Fortnite from its App Store, sparking the five-year feud. A verdict was finally reached earlier this month, when the US District Court of Northern California found Apple in "wilful violation" of the court's previous injunction designed to prohibit the company's "anticompetitive conduct and anticompetitive pricing". That injunction meant Apple had to allow purchases for apps from outside websites, to which it agreed but levied a 27 percent fee. The court stated this move "strains credulity" and that Apple's goal "was to dissuade customer usage of alternative purchase opportunities and maintain its anticompetitive revenue stream". The court verdict added: "In the end, Apple sought to maintain a revenue stream worth billions in direct defiance of this Court's Injunction." Sweeney wrote on social media "Game over for the Apple Tax" and stated Fortnite would return to the iOS App store. Now, it finally has. Writing on social media last night, Sweeney said: "Thanks to everyone who supported the effort to open up mobile competition and #FreeFortnite from the very beginning. And thanks to all of the folks who initially sided with Apple then later came around to the winning side, supporting app developer rights and consumer rights." Fortnite has immediately risen to the top free game on iOS in the US. Epic has this week been in hot water due to the addition of AI Darth Vader to Fortnite, which was quickly used to spout bad language. A hot fix has since been issued, but actors' union SAG-AFTRA has filed an unfair labour practice charge in retaliation for the use of AI.

You can trust VideoGamer. Our team of gaming experts spend hours testing and reviewing the latest games, to ensure you're reading the most comprehensive guide possible. Rest assured, all imagery and advice is unique and original. Check out how we test and review games here Hideo Kojima’s Death Stranding was one of the best-looking games ever on PS4, and it still looks fantastic today. With Death Stranding 2: On the Beach launching very soon, some have argued that the game doesn’t look that much better than its predecessor. As it turns out, chief technical officer Akio Sakamoto agrees. Speaking to EDGE Magazine, Sakamoto explained that the jump from PS4 to PS5 hardware “isn’t so great”. However, the new hardware in the current-gen console allows for processes to be made more efficiently. Death Stranding 2 tech doesn’t PS5 is a huge jump Speaking to the magazine, via GamesRadar, Sakamoto explained that upgrades such as the PS5’s SSD and enhanced GPU does make development more efficient. However, the studio isn’t able to make huge leaps like we saw between PS3 and PS5. “The most obvious improvement from a technological point of view is the reduction in loading times, but to be honest, the difference between the two hardware systems isn’t so great,” Sakamoto told the magazine. “It’s more a case that on PS5 there are more efficient ways of arriving at similar goals.” The more powerful GPU in the PlayStation 5 and the PlayStation 5 Pro has allowed the artists on Death Stranding 2 to create a more varied world without having to craft obscure workarounds. However, Sakamoto explained that this can then have knock-on effects for the rest of the development team. “Having said that, our artists are less restrained to create the world, without having to come up with level workarounds,” the developer said. “But of course this freedom has had knock-on effects, and technical challenges for the programmers. In some ways, it’s created an environment where the artists are now out of control.” Death Stranding 2 honestly doesn’t look that much better than its predecessor in terms of sheer graphics, but then very little does. Kojima Productions’ work is some of the best-looking in the entire industry, and we haven’t seen much look substantially better. While technology such as ray-tracing has made games look more realistic, it’s a subtle effect compared to the jump we’ve seen in past generations. For more on the upcoming Kojima game, read about how the director has ideas for a third title but he won’t be making it. Additionally, read about how the upcoming sequel is more like Metal Gear than even Kojima expected it to be. Exciting, I know. Death Stranding 2 On The Beach Platform(s): PlayStation 5 Genre(s): Action, Action Adventure, Adventure Subscribe to our newsletters! By subscribing, you agree to our Privacy Policy and may receive occasional deal communications; you can unsubscribe anytime. Share

Behind the Scenes: Secret Bunker Roller Coaster Ride By Bart on May 21, 2025 Behind the Scenes Marty created this wild roller coaster ride and shares a detailed breakdown on Blender Artists.This is a project I’ve been working on for a while now – an animation of a wild roller coaster ride through a secret bunker hideout in the middle of the ocean!If you’re interested in how I made this thing, I’ve created a short write-up below that touches on most of the important parts.Read the full article on Blender Artists.

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Fortnite's available on iOS in the US again, with Epic and Apple's legal tussle over it seemingly having concluded, at least for now. Epic Games has at least managed to get one of the outcomes it wanted out of all the hoohah, and its CEO has reponded as only he could - by letting all know we're his "fam". Read more

Damen Compact Crafts (DCCr), a division of the Dutch shipbuilding company Damen Shipyards Group, has partnered with CEAD, a developer of large-format additive manufacturing solutions, to build a 3D printed high-density polyethylene (HDPE) Workboat. The joint initiative will be carried out at CEAD’s Maritime Application Center (MAC) in Delft. This project brings together maritime design and industrial 3D printing expertise to investigate more sustainable and efficient vessel production methods. DCCr is designing the workboat for multipurpose operations including inspections, patrol, support, and logistics. As part of the research, the hull will be produced using CEAD HDPro material, a high-performance polyethylene blend. The aim is to determine whether additive manufacturing can introduce greater flexibility, reduce waste, and accelerate production timelines. 3D printing the hull enables more complex geometries and may allow integration of recycled or renewable materials into the build process. Nick Pruissen (Damen Compact Crafts) and Charlène van Wingerden (CEAD) formalize the collaboration to develop a 3D printed HDPE workboat at the Maritime Application Center in Delft. Photo via CEAD. Founded in 2014, CEAD develops turnkey large-format additive manufacturing systems for industrial use. Its portfolio includes robot-based and cartesian-style solutions capable of producing fiber-reinforced thermoplastic components. For this workboat project, CEAD is providing its hardware and process expertise in printing large polymer structures. “The MAC was founded to accelerate exactly these kinds of innovations – and a 3D printed HWB is a perfect example of that,” said Charlene van Wingerden, Chief Business Development Officer at CEAD. Damen Shipyards, which operates 35 shipyards and 20 affiliated companies across 20 countries, delivers approximately 100 vessels annually. The company focuses on serial construction, modularity, and integrated systems to streamline design and production. “3D printing allows us to respond more quickly and flexibly to what our customers really need,” said Nick Pruissen, Managing Director at Damen Compact Crafts. “It’s an exciting step toward smart, sustainable solutions that work.” Damen views additive manufacturing as a potential fit within its broader digitalization and standardization strategy. Both parties describe the initiative as an exploratory step toward incorporating additive manufacturing into maritime production workflows. The project will serve as a technical evaluation of process capabilities, material performance, and structural feasibility. According to the partners, the workboat program reflects a practical use case where market-specific vessel requirements can be tested against automated, large-scale 3D printing technologies. Facade of CEAD’s Maritime Application Center (MAC) in Delft. Photo via CEAD. Large-format additive manufacturing gains traction in marine sector In the United States, ErectorCraft has begun commercially producing 3D printed boat hulls using large-format additive manufacturing (LFAM). The company employs high-density polyethylene (HDPE) and proprietary ErectorBot extrusion systems to fabricate full-scale marine components without the use of traditional molds. ErectorCraft’s approach includes on-site production capabilities, engineering services, and 3D concrete printing (3DCP) for marine infrastructure. According to the company, its decentralized manufacturing model shortens production timelines and lowers material waste. Chief Technology Officer Leonard Dodd developed the ErectorBot system and previously contributed to Autodesk’s direct metal deposition process used in the first class-approved 3D printed propeller. In Europe, yacht builder Pershing has integrated LFAM into its GTX116 model through a collaboration with Caracol. The yacht’s side air grilles and visor were produced using Caracol’s Heron AM platform, a robotic extrusion system operating at the company’s Milan facility. The components, made from ASA reinforced with 20% glass fiber, were printed in 72 hours and finished with a gel coat. According to Ferretti Group, this production method resulted in a 50% lead time reduction, 60% less material waste, and a 15% weight savings compared to traditional fiberglass lamination. Caracol operates one of the largest LFAM centers in Europe and has expanded its applications across the aerospace, marine, and construction sectors. 3D printed intake grilles. Photo via Caracol. Ready to discover who won the 20243D Printing Industry Awards? Subscribe to the 3D Printing Industry newsletter to stay updated with the latest news and insights. Take the 3DPI Reader Survey — shape the future of AM reporting in under 5 minutes. Featured image shows Nick Pruissen (Damen Compact Crafts) and Charlène van Wingerden (CEAD) formalize the collaboration to develop a 3D printed HDPE workboat. Photo via CEAD. Anyer Tenorio Lara Anyer Tenorio Lara is an emerging tech journalist passionate about uncovering the latest advances in technology and innovation. With a sharp eye for detail and a talent for storytelling, Anyer has quickly made a name for himself in the tech community. Anyer's articles aim to make complex subjects accessible and engaging for a broad audience. In addition to his writing, Anyer enjoys participating in industry events and discussions, eager to learn and share knowledge in the dynamic world of technology.