MacworldAt a glanceExpert's RatingProsSuper fast 6GBps reading, 5GBps writing via Thunderbolt 5Rugged and weatherproofHandsome designA bargain compared to Apple internal SSD upgradesConsExpensive compared to Thunderbolt 3/USBRequires an M4 Pro/Max Mac for full 80Gbps performanceLimited compatibility with older hardware and software.Our Verdict We love that the new Envoy Ultra Thunderbolt 5 SSD from OWC is almost as fast as Apples internal storage, but its not cheap and backwards compatibility isnt all-encompassing.Price When ReviewedThis value will show the geolocated pricing text for product undefinedBest Pricing TodayIf youre looking to take full advantage of the Thunderbolt 5 ports on your M4 Pro Mac mini or M4 Pro/Max MacBook Pro and possibly circumvent Apples avaricious storage upgrade pricing, you should consider OWCs Envoy Ultra Thunderbolt 5 external SSD. The Envoy Ultra is hardly cheap, but its nowhere near what Apple charges.On the downside, there are more backwards compatibility issues than expected.This is the compatibility statement from the Thunderbolt 5 PR deck. Broadly apparently doesnt mean Completely. Especially with older software and hardware. Thunderbolt 5 compatibilityWhile the speed is alluring, and Thunderbolt 5 itself is backwards compatible with older Thunderbolt specs, its not nearly as backwards compatible as you might think, we wish, or is hinted at.First, you need a Thunderbolt 5-enabled Mac or Windows PC to take full advantage of Thunderbolt 5s 80Gbps transfer rates. 80Gbps? Yes. While you may have seen 120GBps quoted in some articles as Thunderbolt 5s top speed, thats only unidirectional for displays. Bi-directional, as with storage, is limited to 80Gbps.The first compatibility issue is that to utilize a Thunderbolt 5 drive, Apple silicon Macs need either macOS 14 Sonoma, or macOS 15 Sequoia. Thunderbolt 3 Macs with Intel chips must run Sequoia. Note that the Envoy Ultra did enumerate on my Mac Studio Thunderbolt 4 bus when I was back on Ventura, but it wasnt available in Disk Utility or Finder.Also, while the Envoy Ultras captive cable prevents me from testing it on older Thunderbolt 1/2 using an adapter, the image above indicates that this is off the table. OWC confirmed that Thunderbolt 5 wont work with the older standards, so stick with Thunderbolt 3 equipment for older Macs.OWCs Envoy Ultra Thunderbolt 5SSD.Jon L. JacobiAdditionally, in my testing for PCWorld, there was a rather large issue with the official test bed. That issue is that the Envoy Ultra completely failed to register in the BIOS, Disk Manager, or Thunderbolt utility. Oops. This is despite updating all the drivers, removing everything non-essential, and even updating Windows 11 to the latest release on the test bed. Eventually, a BIOS/Thunderbolt firmware update from Asus solved the issue.This iffy backwards compatibility could be a problem if youre working in a mixed operating system environment. Some older equipment might not be updated.FeaturesThe OWC Envoy Ultra shares the handsome, sculpted styling of the Thunderbolt 3 40Gbps/USB 3.2 10Gbps Envoy Pro FX. However, its a bit larger chunk of black metal, measuring about 0.75 inches thick, 2.8 inches wide, and 5 inches long. The Envoy Ultra weighs in at a satisfyingly substantial 10.5 ounces or so.The OWC Envoy Ultra attached to the MacBook Pro M4 Pro used for testing.I already mentioned the captive cable, which is for weatherproofing (its not IP-rated, but it seems as if it could pass the tests) and making sure you cant lose it. It does, however, make it a bit harder to stow the Envoy Ultra in tight quarters. Also, as with all captive cables, you should avoid stressing the attachment point for longevitys sake.The OWC Envoy Ultra carries a three-year warranty, but no TBW (Terabytes that may be Written) rating was given.PriceIf you thought a Thunderbolt 5 SSD was going to be cheap.well, I have some interesting real estate properties you might be interested in. The Envoy Ultra costs a cool $400 in its 2TB form and $600 at 4TB.Given that you can grab a Thunderbolt 3/USB4 SSD for roughly half that, and a 20/10Gbps unit for far less than half, youd better really need or want the speed. Note however, that despite a new 20Gbps 3.22 tunneling protocol that may work with docking stations, 3.22 SSDs still drop to 10Gbps when attached directly to a Thunderbolt 5 port. 20Gbps USB4 SSDs will operate at full speed attached to Thunderbolt 5.Then again, compared with Apples egregious price gouging for internal storage upgrades ($1,200 for 4TB???), the Envoy Ultra is a fantastic bargain.PerformanceShort answer: Very fast. Benchmarks showed anywhere from 5.2GBps (Blackmagicdesigns Disk Speed Test), to 6.5GBps reading (AmorphousDiskMark), to near 7GBps reading and 5.57GBps writing (ATTO). Even my real-world read of approximately 330GB of .mov files showed an excellent turn of formalmost 6GBps reading. Alas, writing was considerably slower, only around 1.5GBps.Note I copied to and from the same M4 Pro MacBook Pro (2TB) that I ran the synthetic benchmarks on. By way of comparison, and for the enlightenment of those who might be looking to avoid paying ridiculous sums for Apples internal storage, I included the benchmark results from the MacBooks internal SSD. These are shown to the right of the OWC Envoy Ultras in the images below.The difference between the internal and external storage isnt as severe as you might expect. Long story short, read results are remarkably close for the most part, though the internal SSD was a good deal faster writing under nearly all circumstances. Note that the fastest external SSD weve previously tested, the USB4 Adata SE920 only just exceeded 3GBps reading. YesVery fast.Blackmagicdesigns Disk Speed test showed consistent 5.2GBps performance in both reading and writing for the OWC Envoy Ultra (left). The Internal M4 Pro MacBook Pro SSD results are shown on the right.AmorphousDiskMark showed better numbers for the Envoy Ultra readinga rather scintillating 6.44GBps. Not that far off the MacBook Pro M4 Pros internal SSD. Approximately 5GBps writing from the Envoy Ultra seems to be the consensus from all three synthetic benchmarks.AmorphousDiskMark showed the Envoy Ultra reading far faster than Disk Speed test. Nearly 6.5GBps. ATTO Disk Benchmark paints largely the same picture, though read speeds for the Envoy Ultra actually exceeded those of the MacBook Pro M4 Pros internal SSD. Writes? No, though around 5GBps is hardly anything to sneeze at. ATTO Disk Benchmark paints largely the same picture, though read speeds for the Envoy Ultra actually exceeded those of the MacBook Pro M4 Pros internal SSD. Writes? No, though around 5GBps is hardly anything to sneeze at. Although our real-world file writes didnt match the benchmarks, they were still quite good. In total, the OWC Envoy Ultra is a very nice upgrade performance-wise from the average Thunderbolt 3 SSD, and a worthy companion for any Thunderbolt 5 Mac.Note that the SSD inside the Envoy Ultra is the Auro Pro IV. You can read more about its performance (good at the time, not so much now) in sister publication PCWorlds review. That said, the Envoy Ultra, once running on our updated test bed, turned in a very, very slow 450GB write time.Should you buy the OWC Envoy Ultra?If you want, and can afford the absolute fastest storage for your new Thunderbolt 5 Mac, then the answer is yes. Have at it. Also, its a heck of a lot cheaper than Apples rapaciously priced internal storage and nearly as fast. That said, Thunderbolt 3/USB4 SSDs are still plenty fast, cheaper, and far more compatible with older Mac hardware and software. Ill leave the value equation up to you.

MacworldJealous of those fancy new Macs with their Apple Intelligence that magically enhances photos and videos? Well, you dont need to upgrade your perfectly good Mac just to get in on the AI action. This photo and video enhancer adds the same capabilities to your machineno Apple Store visit required. Just pay $35.99 for a lifetime download (reg. $119).VideoProcs AI-powered video enhancer is like having a whole team of editors at your fingertips. It lets you edit, convert, and resize even those massive 4K UHD videos without your MacBook sounding like its about to launch into orbit. But its not just about speed; VideoProc also uses AI to boost video quality. Think smoother footage, sharper images, and even noise reduction.And if youre into photography, VideoProc has you covered there as well. It can help you touch up photos, create slideshows with music, and even convert images between different formats. Basically, its like having a mini version of Apples Photos app with Apple Intelligence.Get a VideoProc lifetime license here for $35.99 (reg. $119). You wont find a better price anywhere else.VideoProc Converter: Lifetime Family License $35.99See DealStackSocial prices subject to change.

MacworldPicture your beloved AirTag, but so flat it actually fits in your wallet. Yup, no awkward bulge in your pocket to keep track of your cards and cashjust this wallet tracker in the shape of a credit card.Bold claim: These KeySmart SmartCards might be better than the AirTag. They work with Apples Find My app, are Qi-wireless rechargeable, and are almost the same price during Cyber Week! Get this AirTag alternative for only $29.97 with free shipping through December 8 (reg. $39.99) AirTags are $29.Unfamiliar with how Find My trackers work? Once paired with your iPhone or other Apple devices, you can track your wallet, luggage, or passport on a live map. You also get notifications when its left behind and play sounds to help locate it.Another perk of these wallet tracker cards is that you dont have to purchase a keychain holder like you do with the AirTag. They have a lanyard slot if you want to add them to your keys or ID reel.Get a KeySmart SmartCard for $29.97 with free shipping (reg. $39.99) during Cyber Week. Deal ends December 8 at 11:59 p.m. PT and no coupon is needed.KeySmart SmartCard Thinnest Card Tracker & Works with Apple Find My $29.97See DealStackSocial prices subject to change.

In the era of digital transformation, public safety stands at a critical crossroads. Law enforcement agencies globally are under increasing scrutiny to enhance transparency, efficiency, and trust within their communities. Against this backdrop, Kazakhstans Digital Policeman initiative has emerged as a shining example of technological innovation in policing.The initiative leverages state-of-the-art technologies like smart badges and military-grade mobile devices, designed to empower officers while ensuring accountability. These smart badges go beyond conventional body cameras, offering features such as continuous, tamper-proof video recording, GPS tracking, encrypted data handling, and emergency alert systems. This cutting-edge approach has turned routine policing into a sophisticated operation backed by real-time data and insights.Why it matters: Key impactsThe numbers speak volumes. Since its inception, the Digital Policeman project has documented over 6,000 bribery attempts, recorded 443,765 administrative violations, and solved 2,613 crimesall while saving Kazakhstans national budget $6 million. With over 10,000 smart badges and 21,000 tablets deployed, the project is reshaping the very fabric of public safety.These advancements extend beyond technology. By addressing the limitations of traditional tools, such as unreliable video recorders prone to tampering, the project has reduced corruption, streamlined workflows, and enhanced officer safety. Moreover, officers now have access to tools that enable quicker decision-making and more effective resource allocation, fostering greater community trust.Global leadership in law enforcement innovationThe success of the Digital Policeman initiative positions Kazakhstan as a leader in police modernization, standing shoulder-to-shoulder with global pioneers like the United States, Korea, and Scotland. The initiatives integration of secure, military-grade technology sets a benchmark, inspiring other nations, including Azerbaijan, Kyrgyzstan, and Uzbekistan, to explore similar advancements.Looking ahead: The future of public safetyKazakhstan is not stopping here. The initiative is poised for expansion, with plans to incorporate advanced features like facial recognition and direct integration with law enforcement databases. These enhancements will further amplify operational efficiency, enabling real-time communication of alerts and seamless access to critical information during patrols.Beyond policing, this technology holds potential applications in other public safety domains such as traffic management, fisheries supervision, and forestry oversight. By extending the reach of smart badges, Kazakhstan continues to redefine the possibilities of public safety in the digital age.Why read the full spotlight paper?This article only scratches the surface of the profound impact the Digital Policeman project is making. For a comprehensive look at the strategies, technologies, and lessons learned from this groundbreaking initiative, download the full spotlight paper. Discover how Kazakhstan is charting the future of law enforcement, balancing technological innovation with community trust.Unlock the future of policing. Download the full report today!

With her claim that retailers are seeing high returns of Arm PCs, Intel interim CEO Michelle Johnston Holthaus appears to be trying to scare buyers off the rival processor architecture. But enterprise buyers who look before they leap have little to fear.Speaking at Barclays annual technology conference late last week, Holthaus said if you look at the return rate for Arm PCs, you go talk to any retailer, their number one concern is, I get a large percentage of these back because you go to set them up and the things that we just expect [to work], dont work.Continue reading on CIO.com.

Fake AI clips of celebrities are becoming increasingly common, something that affects, among other things, artists and actors who have their voices and looks cloned without their permission.With that in mind, YouTube hasannounced a collaboration with Creative Artists Agency (CAA) aimed at detecting and removing fake AI clips of celebrities.CAA has created a database called the CAA Vault that contains digital copies of celebrities faces, bodies and voices. The idea is that the new tool can compare the content of uploaded Youtube clips with the information in the CAA Vault; if theres a match, the clips should be able to be deleted automatically.According to The Verge,YouTube has also developed a tool that detects when AI has been used to simulate someones singing voice.

A healthy heart beats at a steady rate, between 60 and 100 times a minute. Thats not the case for all of us, Im reminded, as I look inside a cardboard box containing around 20 plastic heartseach a replica of a real human one.The hearts, which previously sat on a shelf in a lab in West London, were generated from MRI and CT scans of people being treated for heart conditions at Hammersmith Hospital next door. Steven Niederer, a biomedical engineer at the Alan Turing Institute and Imperial College London, created them on a 3D printer in his office.One of the hearts, printed in red recycled plastic, looks as I imagine a heart to look. It just about fits in my hand, and the chambers have the same dimensions as the ones you might see in a textbook. Perhaps it helps that its red.The others look enormous to me. One in particular, printed in black plastic, seems more than twice the size of the red one. As I find out later, the person who had the heart it was modeled on suffered from heart failure.The plastic organs are just for educational purposes. Niederer is more interested in creating detailed replicas of peoples hearts using computers. These digital twins are the same size and shape as the real thing. They work in the same way. But they exist only virtually. Scientists can do virtual surgery on these virtual hearts, figuring out the best course of action for a patients condition.After decades of research, models like these are now entering clinical trials and starting to be used for patient care. Virtual replicas of many other organs are also being developed. Engineers are working on digital twins of peoples brains, guts, livers, nervous systems, and more. Theyre creating virtual replicas of peoples faces, which could be used to try out surgeries or analyze facial features, and testing drugs on digital cancers. The eventual goal is to create digital versions of our bodiescomputer copies that could help researchers and doctors figure out our risk of developing various diseases and determine which treatments might work best. Theyd be our own personal guinea pigs for testing out medicines before we subject our real bodies to them.To engineers like Niederer, its a tantalizing prospect very much within reach. Several pilot studies have been completed, and larger trials are underway. Those in the field expect digital twins based on organs to become a part of clinical care within the next five to 10 years, aiding diagnosis and surgical decision-making. Further down the line, well even be able to run clinical trials on synthetic patientsvirtual bodies created using real data.But the budding technology will need to be developed carefully. Some worry about who will own this highly personalized data and how it could be used. Others fear for patient autonomywith an uncomplicated virtual record to consult, will doctors eventually bypass the patients themselves? And some simply feel a visceral repulsion at the idea of attempts to re-create humans in silico. People will say I dont want you copying me, says Wahbi El-Bouri, who is working on digital-twin technologies. They feel its a part of them that youve taken.Getting digitalDigital twins are well established in other realms of engineering; for example, they have long been used to model machinery and infrastructure. The term may have become a marketing buzzword lately, but for those working on health applications, it means something very specific.We can think of a digital twin as having three separate components, says El-Bouri, a biomedical engineer at the University of Liverpool in the UK. The first is the thing being modeled. That might be a jet engine or a bridge, or it could be a persons heart. Essentially, its what we want to test or study.The second component is the digital replica of that object, which can be created by taking lots of measurements from the real thing and entering them into a computer. For a heart, that might mean blood pressure recordings as well as MRI and CT scans. The third is new data thats fed into the model. A true digital twin should be updated in real timefor example, with information collected from wearable sensors, if its a model of someones heart.Taking measurements of airplanes and bridges is one thing. Its much harder to get a continuous data feed from a person, especially when you need details about the inner functions of the heart or brain.And the information transfer should run both ways. Just as sensors can deliver data from a persons heart, the computer can model potential outcomes to make predictions and feed them back to a patient or health-care provider. A medical team might want to predict how a person will respond to a drug, for example, or test various surgical procedures on a digital model before operating in real life.By this definition, pretty much any smart device that tracks some aspect of your health could be considered a kind of rudimentary digital twin. You could say that an Apple Watch fulfills the definition of a digital twin in an unexciting way, says Niederer. It tells you if youre in atrial fibrillation or not.But the kind of digital twin that researchers like Niederer are working on is far more intricate and detailed. It could provide specific guidance on which disease risks a person faces, what medicines might be most effective, or how any surgeries should proceed.Were not quite there yet. Taking measurements of airplanes and bridges is one thing. Its much harder to get a continuous data feed from a person, especially when you need details about the inner functions of the heart or brain, says Niederer. As things stand, engineers are technically creating patient-specific models based on previously collected hospital and research data, which is not continually updated.The most advanced medical digital twins are those built to match human hearts. These were the first to be attempted, partly because the heart is essentially a pumpa device familiar to engineersand partly because heart disease is responsible for so much ill health and death, says El-Bouri. Now, advances in imaging technology and computer processing power are enabling researchers to mimic the organ with the level of fidelity that clinical applications require.Building a heartThe first step to building a digital heart is to collect images of the real thing. Each team will have its own slightly different approach, but generally, they all start with MRI and CT scans of a persons heart. These can be entered into computer software to create a 3D movie. Some scans will also highlight any areas of damaged tissue, which might disrupt the way the electrical pulses that control heart muscle contraction travel through the organ.The next step is to break this 3D model down into tiny chunks. Engineers use the term computational mesh to describe the result; it can look like an image of the heart made up of thousands of 3D pieces. Each segment represents a small collection of cells and can be assigned properties based on how well they are expected to propagate an electrical impulse. Its all equations, says Natalia Trayanova, a biomedical engineering professor based at Johns Hopkins University in Baltimore, Maryland.This computer modelof the human heart show how electrical signals pass through heart tissue. The model was created by Marina Strocchi, who works with Steven Niederer at Imperial College London.COURTESY OF MARINA STROCCHIAs things stand, these properties involve some approximation. Engineers will guess how well each bit of heart works by extrapolating from previous studies of human hearts or past research on the disease the person has. The end result is a beating, pumping model of a real heart. When we have that model, you can poke it and prod it and see under what circumstances stuff will happen, says Trayanova.Her digital twins are already being trialed to help people with atrial fibrillation, a fairly common condition that can trigger an irregular heartbeattoo fast or all over the place. One treatment option is to burn off the bits of heart tissue responsible for the disrupted rhythm. Its usually left to a surgical team to figure out which bits to target.For Trayanova, the pokes and prods are designed to help surgeons with that decision. Scans might highlight a few regions of damaged or scarred tissue. Her team can then construct a digital twin to help locate the underlying source of the damage. In total, the tool will likely suggest two or three regions to destroythough in rare instances, it has shown many more, says Trayanova: They just have to trust us. So far, 59 people have been through the trial. More are planned.In cases like these, the models dont always need to be continually updated, Trayanova says. A heart surgeon might need to run simulations only to know where to implant a device, for example. Once that operation is over, no more data might be needed, she says.Quasi patientsAt his lab on the campus of Hammersmith Hospital in London, Niederer has also been building virtual hearts. He is exploring whether his models could be used to find the best place to implant pacemakers. His approach is similar to Trayanovas, but his models also incorporate ECG data from patients. These recordings give a sense of how electrical pulses pass through the heart tissue, he says.So far, Niederer and his colleagues have published a small trial in which models of 10 patients hearts were evaluated by doctors but not used to inform surgical decisions. Still, Niederer is already getting requests from device manufacturers to run virtual tests of their products. A couple have asked him to choose places where their battery-operated pacemaker devices can sit without bumping into heart tissue, he says. Not only can Niederer and his colleagues run this test virtually, but they can do it for hearts of various different sizes. The team can test the device in hundreds of potential locations, within hundreds of different virtual hearts. And we can do it in a week, he adds.This is an example of what scientists call in silico trialsclinical trials run on a computer. In some cases, its not just the trials that are digital. The volunteers are, too.El-Bouri and his colleagues are working on ways to create synthetic participants for their clinical trials. The team starts with data collected from real people and uses this to create all-new digital organs with a mishmash of characteristics from the real volunteers.These in silico trials could be especially useful for helping us figure out the best treatments for pregnant peoplea group that is notoriously excluded from many clinical trials.Specifically, one of El-Bouris interests is stroke, a medical emergency in which clots or bleeds prevent blood flow in parts of the brain. For their research, he and his colleagues model the brain, along with the blood vessels that feed it. You could create lots and lots of different shapes and sizes of these brains based on patient data, says El-Bouri. Once he and his team create a group of synthetic patient brains, they can test how these clots might change the flow of blood or oxygen, or how and where brain tissue is affected. They can test the impact of certain drugs, or see what might happen if a stent is used to remove the blockage.For another project, El-Bouri is creating synthetic retinas. From a starting point of 100 or so retinal scans from real people, his team can generate 200 or more synthetic eyes, just like that, he says. The trick is to figure out the math behind the distribution of blood vessels and re-create it through a set of algorithms. Now he is hoping to use those synthetic eyes in drug trialsamong other things, to find the best treatment doses for people with age-related macular degeneration, a common condition that can lead to blindness.These in silico trials could be especially useful for helping us figure out the best treatments for pregnant peoplea group that is notoriously excluded from many clinical trials. Thats for fear that an experimental treatment might harm a fetus, says Michelle Oyen, a professor of biomedical engineering at Wayne State University in Detroit.Oyen is creating digital twins of pregnancy. Its a challenge to get the information needed to feed the models; during pregnancy, people are generally advised to avoid scans or invasive investigations they dont need. Were much more limited in terms of the data that we can get, she says. Her team does make use of ultrasound images, including a form of ultrasound that allows the team to measure blood flow. From those images, they can see how blood flow in the uterus and the placenta, the organ that supports a fetus, might be linked to the fetuss growth and development, for example.For now, Oyen and her colleagues arent creating models of the fetuses themselvestheyre focusing on the fetal environment, which includes the placenta and uterus. A baby needs a healthy, functioning placenta in order to survive; if the organ starts to fail, stillbirth can be the tragic outcome.Oyen is working on ways to monitor the placenta in real time during pregnancy. These readings could be fed back to a digital twin. If she can find a way to tell when the placenta is failing, doctors might be able to intervene to save the baby, she says. I think this is a game changer for pregnancy research, she adds, because this basically gives us ways of doing research in pregnancy that [carries a minimal] risk of harm to the fetus or of harm to the mother.In another project, the team is looking at the impact of cesarean section scars on pregnancies. When a baby is delivered by C-section, surgeons cut through multiple layers of tissue in the abdomen, including the uterus. Scars that dont heal well become weak spots in the uterus, potentially causing problems for future pregnancies. By modeling these scars in digital twins, Oyen hopes to be able to simulate how future pregnancies might pan out, and determine if or when specialist care might be called for.Eventually, Oyen wants to create a full virtual replica of the pregnant uterus, fetus and all. But were not there yetwere decades behind the cardiovascular people, she says. Thats pregnancy research in a nutshell, she adds. Were always decades behind.TwinningIts all very well to generate virtual body parts, but the human body functions as a whole. Thats why the grand plan for digital twins involves replicas of entire people. Long term, the whole body would be fantastic, says El-Bouri.It may not be all that far off, either. Various research teams are already building models of the heart, brain, lungs, kidneys, liver, musculoskeletal system, blood vessels, immune system, eye, ear, and more. If we were to take every research group that works on digital twins across the world at the moment, I think you could put [a body] together, says El-Bouri. I think theres even someone working on the tongue, he adds.The challenge is bringing together all the various researchers, with the different approaches and different code involved in creating and using their models, says El-Bouri. Everything exists, he says. Its just putting it together thats going to be the issue.In theory, such whole-body twins could revolutionize health care. Trayanova envisions a future in which a digital twin is just another part of a persons medical recordone that a doctor can use to decide on a course of treatment.Technically, if someone tried really hard, they might be able to piece back who someone is through scans and twins of organs.Wahbi El-BouriBut El-Bouri says he receives mixed reactions to the idea. Some people think its really exciting and really cool, he says. But hes also met people who are strongly opposed to the idea of having a virtual copy of themselves exist on a computer somewhere: They dont want any part of that. Researchers need to make more of an effort to engage with the public to find out how people feel about the technology, he says.There are also concerns over patient autonomy. If a doctor has access to a patients digital twin and can use it to guide decisions about medical care, where does the patients own input come into the equation? Some of those working to create digital twins point out that the models could reveal whether patients have taken their daily meds or what theyve eaten that week. Will clinicians eventually come to see digital twins as a more reliable source of information than peoples self-reporting?Doctors should not be allowed to bypass patients and just ask the machine, says Matthias Braun, a social ethicist at the University of Bonn in Germany. There would be no informed consent, which would infringe on autonomy and maybe cause harm, he says. After all, we are not machines with broken parts. Two individuals with the same diagnosis can have very different experiences and lead very different lives.However, there are cases in which patients are not able to make decisions about their own treatmentfor example, if they are unconscious. In those cases, clinicians try to find a proxysomeone authorized to make decisions on the patients behalf. A digital psychological twin, trained on a persons medical data and digital footprint, could potentially act as a better surrogate than, for example, a relative who doesnt know the persons preferences, he says.If using digital twins in patient care is problematic, in silico trials can also raise issues. Jantina de Vries, an ethicist at the University of Cape Town, points out that the data used to create digital twins and synthetic quasi patients will come from people who can be scanned, measured, and monitored. This group is unlikely to include many of those living on the African continent, who wont have ready access to those technologies. The problem of data scarcity directly translates into technologies that are not geared to think about diverse bodies, she says.De Vries thinks the data should belong to the public in order to ensure that as many people benefit from digital-twin technologies as possible. Every record should be anonymized and kept within a public database that researchers around the world can access and make use of, she says.The people who participate in Trayanovas trials explicitly give me consent to know their data, and to know who they are [everything] about them, she says.The people taking part in Niederers research also provide consent for their data to be used by the medical and research teams. But while clinicians have access to all medical data, researchers access only anonymized or pseudonymized data, Niederer says.In some cases, researchers will also ask participants to consent to sharing their fully anonymized data in public repositories. This is the only data that companies are able to access, he adds: We do not share [our] data sets outside of the research or medical teams, and we do not share them with companies.El-Bouri thinks that patients should receive some form of compensation in exchange for sharing their health data. Perhaps they should get preferential access to medications and devices based on that data, he suggests. At any rate, [full] anonymization is tricky, particularly if youre taking patient scans to develop twins, he says. Technically, if someone tried really hard, they might be able to piece back who someone is through scans and twins of organs.When I looked at those anonymous plastic hearts, stored in a cardboard box tucked away on a shelf in the corner of an office, they felt completely divorced from the people whose real, beating hearts they were modeled on. But digital twins seem different somehow. Theyre animated replicas, digital copies that certainly appear to have some sort of life.People often think, Oh, this is just a simulation, says El-Bouri. But its a digital representation of an individual.

Apple's iOS 18 enhances FaceTime & calls with advanced audio modes and cinematic video effects for clearer communication. Here's how and when to use them.FaceTimeFaceTime and phone calls in iOS 18 include three new audio settings, starting with Standard, the standard microphone mode ideal for everyday use and balanced sound.The second one is Wide Spectrum. It actually includes more of the background noise into the call. Wide Spectrum can make the audio sound more natural, making it the one to useif you're at a birthday party and want to include all the excitement in the background. Continue Reading on AppleInsider | Discuss on our Forums

Episode One is a small, budget projector that delivers the features you'd expect, but it has weaknesses in brightness and audio.Episode One Projector reviewA small projector simply saves space. They're great to have in dorms, apartments, and other smaller or shared living spaces.The Episode One is made by Formovie, who's been making projectors since 2016. Continue Reading on AppleInsider | Discuss on our Forums

The FaceTime camera on a MacBook Pro is famously not as good as one on an iPhone, but new research shows Apple is continuing to work on it and may have decided that the answer involves mounting larger cameras on a rotating display.The notch could be replaced by a protruding camera but one which could also be repositionedMaybe you don't give the camera notch on the MacBook Pro a second thought. But even if you loathe it, and believe it's taking up screen real estate, the one thing you can't say is that it is thick.It's quite wide, wide enough that you wonder why it doesn't include Face ID yet. But it doesn't add to the thickness of the MacBook Pro lid, and maybe it's this thickness that limits how good a camera system Apple can fit in there. Continue Reading on AppleInsider | Discuss on our Forums