Steven Spielberg Says Sam Neill Will ‘Never Be Forgotten’ In Beautiful Tribute

Steven Spielberg has paid a heartfelt tribute to the actor Sam Neill, who he directed in the first Jurassic Park movie.

On Monday, the Oscar-winning filmmaker was among the Hollywood stars to pay their respects to Sam, following his death at the age of 78.

In a statement to Variety, Spielberg shared how “saddened” he was by the loss, beginning by expressing his “gratitude” to filmmakers Roger Donaldson, Gilliam Armstrong, Graham Baker and Phillip Noyce “for casting Sam Neill in the roles in which he was so brilliant that brought him to my attention”, which led to him being cast in Jurassic Park.

Spielberg enthused: “Sam was exceptionally collaborative. It was a stretch for him to play a character who acted as though children were messy and smelly because this was the opposite of the loving father he was to his children.

“I adored making all the Jurassic movies with him. Along with Laura Dern and Jeff Goldblum, we will always have our Jurassic family and Sam will never be forgotten by us or his many millions of fans around the world.”

Laura Dern then shared her own tribute with the US outlet, which read: “Sam was my beloved lifetime friend.

“He showed me the depths of loyalty, protectiveness and love always with the driest of wit. He was a true and noble gentleman, wrapped up in my dream leading man.”

Laura Dern and Sam Neill played the leads in 1993's Jurassic Park
Laura Dern and Sam Neill played the leads in 1993’s Jurassic Park

Amblin/Universal/Kobal/Shutterstock

“I will love you forever, Dr. Alan Grant,” she concluded.

Following the news of Sam’s death on Monday morning, a number of his Hollywood peers and former co-stars have been paying their respects on social media…

Oscar winner Cillan Murphy, who starred alongside Sam in the first two seasons of Peaky Blinders, told Deadline: “Like everyone who knew and worked with Sam, I admired him and adored him in equal measure.

“He was one of the kindest, funniest and gentlest people, and one of the finest actors.”

New Zealand and Australia’s prime ministers, Christopher Luxon and Anthony Albanese, also posted tributes of their own.

“It is with immense sadness that the whānau of Sam Neill share the news of his passing on Monday 13 July, in Sydney Australia,” his family announced in a statement.

“Sam was surrounded by family and passed with the dignity that has characterised his whole life.”

The Emmy nominee’s death was described as “sudden and unexpected but blessed by the fact that Sam remained cancer-free”.

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Nigel Farage Says He Is Being Treated Like ‘A War Criminal’ By The Media

Nigel Farage has been criticised after claiming he is being “treated like a war criminal” by his critics.

The Reform UK made the astonishing remark while being interviewed by the party’s in-house podcast.

He was speaking after he shocked Westminster last week by quitting as MP for Clacton to trigger a by-election in the seat.

Farage claimed he was the victim of a “witch hunt” as he faces a parliamentary standards investigation over a £5 million gift from a Thailand-based crypto billionaire but did not declare.

He could also face separate probes over support he received from convicted fraudster George Cottrell and lobbying he has done on cryptocurrency.

On the podcast, he said calling the by-election was “the right thing to do”.

“I think effectively I’m being treated like a war criminal,” he said.

“It’s quite astonishing, and it’s like our mainstream media think we have to defer to them at all times, and I just don’t buy that.

“You look at today’s press and they say he doesn’t want scrutiny. I don’t mind scrutiny, but I do mind illegally obtained information, I do mind computer hacking. I genuinely mind those things, and the intimidation of my family.

“I just thought it had all reached such a frenzy that I had to do something.”

The decision to trigger the by-election has backfired, though, after Labour, the Tories, the Lib Dems, Greens and Restore Britain all said they would not stand candidates in the contest.

The Reform leader said: “I’ve done something positive. They wanted a by-election here. Well now they’ve got one and they don’t want to stand.”

A Labour Party spokesperson said: “Farage needs to wake up and realise that the public expect all politicians to be held to account for their actions.

“Farage is not a war criminal, but he is trying to dodge scrutiny over a secret £5 million ‘gift’ from a crypto billionaire and undeclared donations from a convicted fraudster, and it’s perfectly reasonable for people to ask him questions about it.

“Farage can keep trying to distract, but the public can increasingly see that he’s just in it for himself and he thinks the rules don’t apply to him.”

Listen to Commons People, the podcast that makes politics easy. Every week, Kevin Schofield and Kate Nicholson unpack the week’s biggest stories to keep you informed. Join us for straightforward analysis of what’s going on at Westminster.

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So THAT’s Why Your Fingers Suddenly Have Tiny Itchy Bumps

A few summers ago, I noticed tiny, tapioca-like clusters of bumps on my fingers. They were flesh-coloured and incredibly, hand-bitingly itchy.

This turned out to be a condition called pompholyx or dishydrotic eczema. The issue is sometimes nicknamed “summer finger bumps”, due to how much worse it tends to get in the hotter months.

In fact, warm weather and excessive sweating are listed as factors that may cause pompholyx to form or flare up.

Disyhdrotic eczema

Amy Glover / HuffPost UK

Disyhdrotic eczema

What are the symptoms of dishydrotic eczema?

These include:

  • extreme itchiness
  • the sudden appearance of tiny blisters on your hands (especially the sides of your fingers) or feet
  • a prickling sensation
  • dry or cracking skin after the blisters burst
  • feelings of heat in your soles or hands.

Symptoms typically last two to three weeks.

It’s more common among women, people under 40, individuals with another type of eczema, those with asthma and heavy sweaters.

It’s a chronic condition, meaning that though there are ways to manage the symptoms, we don’t have an outright cure yet.

Flare-ups may be more likely during times of stress, hot weather or contact with soaps, cleansers and detergents.

The first eruptions of dishydrotic eczema blisters

Amy Glover / HuffPost UK

The first eruptions of dishydrotic eczema blisters

What should I do if I suspect I have dishydrotic eczema?

Don’t try to diagnose yourself, the NHS says. If you have new skin issues you suspect are due to dishydrotic eczema, see a GP.

The same goes if you have pompholyx that’s already been diagnosed but “the blisters are very painful, leak yellow or green pus or are covered in a yellow-brown crust – these are signs of an infection”, they added.

Soaking your hands in potassium permanganate may help if they’re weeping or oozing. Using an emmolient moisturiser on the affected area is one of the main ways to manage flare-ups.

Sometimes, your doctor may prescribe a steroid cream to help you manage the itching or send you to see a specialist for UV or other treatments.

Other steps include:

  • washing your hands with warm water and using a moisturising soap,

  • wearing protective gloves (ideally with a cotton lining) when using chemicals like shampoos, cleansers and detergents

  • wearing socks, tights or stockings made from cotton or silk, rather than nylon, if the condition affects your feet,

  • wearing shoes made from leather, rather than plastic or rubber (again if the condition affects your feet),

  • avoiding anything you think causes your symptoms, such as cleansers, some metals, or detergents.

Don’t burst your blisters, as this can lead to further damage and leave your skin open to infection.

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Losing just 80 minutes of sleep a night could make you gain weight

Getting a little less sleep each night may have a bigger impact on your health than you realize. Researchers at Columbia University Vagelos College of Physicians and Surgeons found that adults who cut their nightly sleep by about 80 minutes for six weeks gained an average of one pound and spent more time being inactive.

The findings add to growing evidence that consistently getting enough sleep may play an important role in preventing weight gain and lowering the risk of obesity related diseases.

“Our study shows that getting adequate sleep may help reduce the risk of weight gain and obesity-related conditions like heart disease and diabetes,” says Marie-Pierre St-Onge, a professor of nutritional medicine in Columbia’s Department of Medicine and Institute for Human Nutrition and study leader. “People tend to gain weight over the course of their adulthood, and obesity is a major risk factor for heart disease. But focusing on eating a healthier diet and getting more physical activity to offset weight gain is simplistic and can be difficult to maintain.”

Looking Beyond Extreme Sleep Deprivation

Much of the previous research connecting poor sleep with obesity has focused on severe sleep deprivation, often limiting people to only four hours of sleep. Those studies have shown that extreme sleep loss can increase appetite and overeating, factors that contribute to weight gain.

However, such severe sleep restriction is difficult for most people to tolerate for more than a few days.

“These studies only show us what happens under the most extreme conditions and don’t tell us if mildly sleep-deprived people, like a lot of Americans who get 5 or 6 hours of sleep a night, will gain weight,” St-Onge says.

To better reflect real life, the researchers examined the effects of chronic, mild sleep loss, a pattern experienced by roughly 30% of adults.

Six Weeks of Less Sleep Led to Measurable Changes

The study included 95 adults who normally slept between 7 and 8 hours each night. During one six week study period, participants delayed their usual bedtime by 90 minutes. During another six week period, they followed their normal sleep schedule.

Throughout both phases, participants wore wrist monitors that tracked sleep and physical activity. Researchers also measured body weight, waist circumference, body composition, and fasting levels of several hormones involved in appetite regulation.

“While the one-pound weight gain observed with modest sleep curtailment is not overwhelming, it is important to remember this is occurring over just six weeks,” says Faris Zuraikat, assistant professor of nutritional medicine in Columbia’s Department of Medicine and Institute for Human Nutrition and first author of the study. “Our study was designed to mimic sleep patterns that most adults experience chronically. When extrapolated to a full year, we would expect that losing less than an hour and a half of sleep per night could result in clinically meaningful weight gain.”

Less Sleep Also Meant More Sitting

The researchers found that participants became less active during the sleep restriction phase. On average, sedentary time increased by 17 minutes per day. Among men and postmenopausal women, inactivity rose by nearly 30 minutes each day.

“Even when we accounted for the fact that they were awake longer when sleep was shortened, participants spent more time being inactive than when they got adequate sleep,” Zuraikat says. “This is notable, as people who are more sedentary have elevated risk for chronic diseases.”

Earlier Research Suggests Broader Health Effects

The same group of participants has also been examined in related studies. In one previous investigation, women with increased cardiometabolic risk who reduced their sleep by about 80 minutes each night for six weeks developed greater insulin resistance, an important risk factor for type 2 diabetes. The effect was especially pronounced in postmenopausal women.

Another study found that men and women with elevated heart disease risk developed an influx of inflammatory cells in the heart after experiencing mild sleep restriction.

“Though more research is needed to further understand how sleep restriction leads to weight gain, all of our findings suggest that insufficient sleep increases the risk of obesity-related conditions like type 2 diabetes and heart disease,” St-Onge says.

“Now we need to understand the health effects of improving sleep in those who fail to get adequate sleep on a regular basis.”

The study, titled “Skimping on Sleep and Its Impact on Body Weight and Composition: A Pooled Analysis of Randomized Trials,” was published on July 6 in Annals of Internal Medicine.

The authors are Faris Zuraikat, Samantha Scaccia, Justin Cochran, Bin Cheng, Keith Diaz, Seth Creasy (University of Colorado), Brooke Aggarwal, Sanja Jelic, and Marie-Pierre St-Onge.

The authors report no conflicts of interest.

The research was supported by the American Heart Association (16SFRN27950012) and the National Institutes of Health (R01 HL128226, UL1 TR001873, P30 DK026687, R01 HL173190, R01 HL155190, R01 HL153642, K01 HL145023, R01 HL169991, R01 HL106041, R35 HL155670, R01 AG071032, R56 DK136601, P30 DK048520, and R01 DK128154).

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Stephen Hawking’s black hole laws just got a major upgrade

Scientists have proposed a new way to describe black holes that could overcome a major limitation in one of Stephen Hawking’s most influential ideas. The research introduces an updated approach to black hole thermodynamics that works even when black holes are changing over time, potentially offering new insights into how they form, merge, and slowly evaporate.

Black holes are among the most extreme objects in the known universe. They squeeze enormous amounts of mass into an incredibly small region, creating gravity so intense that not even light can escape. To understand these cosmic objects, physicists rely on Einstein’s theory of general relativity and quantum mechanics.

In the early 1970s, Stephen Hawking and other researchers discovered surprising connections between the laws of thermodynamics, which describe familiar processes such as heating water on a stove, and the behavior of black holes.

“Hawking’s laws of black hole mechanics provided a satisfying connecting between extreme and ordinary physics and have been the paradigm for 50 years, but they have a serious limitation,” said Abhay Ashtekar, Atherton University Professor and Evan Pugh Professor of Physics Emeritus in the Eberly College of Science at Penn State and the leader of the research team. “They were formulated for black holes at equilibrium, or unchanging over time, but black holes are constantly changing, they form, merge and eventually evaporate. We wanted to find a way to overcome this limitation and extend the laws to black holes that are out of equilibrium.”

Ashtekar and his colleagues have now proposed a new method for determining a black hole’s entropy, a quantity that measures disorder and, according to the second law of thermodynamics, can never decrease. Their findings, published in Physical Review Letters and selected as an Editor’s Suggestion, introduce an entropy measure that is more closely connected to a black hole’s spin and energy. The researchers say this could improve scientists’ understanding of dynamic events such as black hole mergers and evaporation.

Why Hawking’s Framework Needed an Update

“The laws of black hole mechanics came directly from Einstein’s equations,” said Daniel E. Paraizo, a graduate student in physics at Penn State and an author of the paper. “Because you cannot see into a black hole, it seemed that there could be an infinite number of ways to make a black hole making their entropy infinite as well. They were also thought to only absorb energy and never radiate, so their temperature was zero.”

At first, those ideas made black holes appear incompatible with the familiar laws of thermodynamics because they seemed to have infinite entropy and no temperature. Hawking later changed that picture by using quantum mechanics to demonstrate that black holes can emit particles and energy.

“This changed the thinking about the thermodynamic properties black holes from a sort of mathematical concept described by equations, to being more of a physical reality,” Paraizo said. “This opened the door to finding analogies in black holes of entropy and temperature used in thermodynamics.”

Hawking proposed that the size of a black hole’s event horizon, the boundary beyond which even light cannot escape, is proportional to its entropy. He also showed that a black hole’s temperature depends on a combination of its mass and spin.

A Better Measure for Dynamic Black Holes

According to the researchers, the problem is that Hawking’s approach works only when a black hole is in equilibrium.

“There is a problem, though,” said Jonathan Shu, a graduate student in physics at Penn State and an author of the paper. “These analogies only really work for a black hole that is at equilibrium. In dynamic situations, event horizons can form and grow in what we call flat regions of space-time, where nothing is happening. This makes them teleological — their properties cannot be determined just by the local physics of the black hole but instead rely on prediction of events that may or may not happen in the future. Therefore, the area of event horizons cannot be a measure of the physical entropy of dynamical black holes. If we want to understand black holes that are growing, evaporating, and merging, we need a viable alternative.”

The team’s solution replaces the traditional event horizon with what physicists call a “dynamical horizon,” a concept that is already widely used in computer simulations of black holes. Unlike an event horizon, a dynamical horizon is defined by the black hole’s properties at a specific moment in time, avoiding the complications created by relying on future events.

“This allows us to extend the first and second laws of thermodynamics to black holes that are not at equilibrium, thereby overcoming the limitations of the paradigm that has been used for over half a century,” Ashtekar said. “We can apply these generalized laws to better understand evaporating black holes in quantum theory and black hole mergers, like those detected by the LIGO-Virgo-KAGRA collaboration using gravitational waves.”

The research was supported by the Penn State Atherton Professorship Program and the Penn State Eberly College of Science.

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Physicists say quantum mechanics may not need imaginary numbers after all

Quantum mechanics is the branch of physics that explains how matter and energy behave at the atomic and sub atomic scale. Developed in the early 1900s by pioneers including Max Planck, Niels Bohr, Werner Heisenberg, and Erwin Schrödinger, it has become one of the most successful scientific theories ever created.

The theory accurately describes a wide range of microscopic phenomena. These include the famous double slit experiment, in which particles also display wave like behavior, and quantum tunneling, where particles have a probability of passing through a barrier even when they do not have enough energy to overcome it in the classical sense. Other key quantum effects, such as entanglement and coherence, now form the foundation of emerging technologies including quantum computing and quantum communication.

Are Complex Numbers Really Essential?

For decades, quantum mechanics has relied on complex numbers, which combine a real component with an imaginary component. In the mathematical description of a quantum state, the real part represents the amplitude, while the imaginary part represents the phase. This framework has long been considered essential for describing many quantum processes.

Even so, physicists have continued to debate whether complex numbers are truly a fundamental part of nature or simply a convenient mathematical tool. That question naturally leads to another: Could quantum mechanics be formulated using only real numbers?

Revisiting a Key Quantum Assumption

A 2021 study concluded that complex numbers are indispensable under the standard postulates of quantum mechanics (Renou et al., Nature 600, 625 (2021)). Experimental results also supported that conclusion.

Researchers from Heinrich Heine University Düsseldorf (HHU) and the German Aerospace Center (DLR), led by Professor Dr Dagmar Bruß and doctoral researcher Pedro Barrios Hita, decided to take another look at the assumptions behind that earlier work.

In a new study published in Physical Review Letters, they found that one of the postulates used in the 2021 analysis was more restrictive than necessary. By replacing it with a different, physically motivated approach for describing how quantum systems combine, they identified a family of theories that can be expressed entirely with real numbers while remaining experimentally indistinguishable from conventional quantum mechanics.

Professor Bruß said: “This means that both frameworks yield identical predictions for any conceivable experiment. Within this framework, imaginary numbers are thus not fundamentally necessary in quantum mechanics and can in principle be replaced by alternative formulations using real numbers.”

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Starting uni? What to know about having the free NHS meningitis B jab

It follows the UK’s largest and fastest growing meningitis B outbreak to date in Kent earlier this year.

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Thousands may have died in UK’s exceptional May and June heatwaves

An early estimate suggests more than 2,700 people will have died from heat-related causes during the UK’s exceptionally hot weather in recent months.

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Why Do So Many People In Old Art Have A Long Second Toe?

Did you know that the (admittedly more recent) Statue of Liberty, the Venus de Milo, the Ancient Roman Boxer at Rest, and the Ancient Greek Laocoön and His Sons share a foot quirk in common?

In all of these iconic works of art, the characters depicted have second toes longer than their big toe – a phenomenon sometimes called “Morton’s toe”. The feature is also seen in Botticelli’s The Birth of Venus and da Vinci’s famous Vitruvian Man.

It’s a quirk that’s been noted as far back as 1897, when a writer for the Boston Medical and Surgical Journal noted that in “early Greek art, where there is any attempt at careful modelling of the toes, the first toe is separated from the second, and in most instances the second toe is represented as somewhat longer than the first”.

Morton’s toe wasn’t really a “thing” in Ancient Egyptian art, though, Atlas Obscura added. That suggests it became a trend that stuck in the West.

So what’s going on?

Why might “Morton’s toe” be so present in ancient art?

Hands up: the short answer is, we don’t know for sure. But theories abound.

“Morton’s toe” affects anywhere from 4-30% of the global population.

The condition is sometimes called “Greek foot”, because over time, it’s become associated with Greek people.

That might explain its presence in predominantly Ancient Greek art – except that evolutionary geneticist Dr John H McDonald told USA Today, “I haven’t seen any evidence that so-called ‘Greek foot’ is more common in Greece than anywhere else”.

Another theory is that a longer second toe better fitted Greek ideals of beauty because it was more closely aligned with the mathematical rules of the Golden Ratio.

But not everyone thinks those numbers quite run, including in Da Vinci’s Vitruvian Man, where the famous fella’s second toe on his upper right leg extends to perfectly touch the curve of the surrounding circle.

Then, there’s the copycat theory

There’s another option, too: simple repetition.

Whether some influential artists thought the feature was especially pleasing or just happened to use a model with Morton’s toe, there’s the chance that it was adopted by some of the greats and then endlessly aped.

“Many Roman statues have Greek feet, simply because the artists drew inspiration from one another,” Atlas Obscura posited.

A document from the US National Parks Service (NPS) seems to say the same thing: “As Roman statues sometimes are copies of the Greek originals, the Roman statues often have ‘Greek’ feet.”

Indeed, the person who created the Statue of Liberty, whose second toe is longer than her first, was pretty open about his Ancient Greek, Egyptian, and Roman inspiration.

“On her Greek/Roman feet, open sandals… define [the Statue of Liberty’s] heritage from the earliest days of civilization – we see her Morton’s toes,” the NPS added.

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Deep-sea life has a secret food source scientists never expected

Scientists have uncovered an unexpected source of food in the deep ocean that could change how researchers understand both marine ecosystems and Earth’s carbon cycle. A new study from the University of Southern Denmark (SDU) suggests that deep ocean microbes are not living in such a nutrient-starved environment after all.

The research found that tiny sinking particles known as marine snow release dissolved carbon and nitrogen as they descend into the deep sea. Those leaked nutrients become an immediate food source for microbes living in the surrounding seawater.

Deep ocean pressure unlocks hidden nutrients

Marine snow is made up of tiny clumps of dead algae, microbes, and other organic material drifting through the ocean. According to the study, once these particles reach depths of about 2 to 6 kilometers, the enormous hydrostatic pressure begins forcing dissolved organic matter out of them.

“The pressure acts almost like a giant juicer,” says first author of the study, biologist and Associate Professor Peter Stief from research centers Nordcee and Danish Center for Hadal Research, “It squeezes dissolved organic compounds out of the particles, and microbes can use them immediately.”

The findings were published in Science Advances in the paper, “Hydrostatic pressure induces strong leakage of dissolved organic matter from ‘marine snow’ particles.”

The researchers estimate that sinking marine snow can lose as much as 50% of its original carbon and between 58% and 63% of its original nitrogen during its descent through the deep ocean.

Discovery could reshape understanding of the carbon cycle

The results also have important implications for Earth’s carbon cycle.

Scientists have long assumed that much of the carbon carried by marine snow eventually becomes buried in deep ocean sediments. However, if large amounts of carbon leak out before the particles reach the seafloor, less carbon may be permanently stored in sediments than previously believed.

Instead, much of that dissolved carbon remains suspended in deep ocean waters, where it can stay for hundreds or even thousands of years before gradually returning to the surface ocean and eventually the atmosphere. Carbon that does become buried in seafloor sediments, by contrast, can remain locked away for millions of years, accumulating over vast stretches of time. Much of the oil and natural gas extracted today formed through this long-term burial process.

“This process affects how much carbon the ocean can store and for how long,” says Peter Stief, “It’s relevant for understanding climate processes and for improving future models.”

Simulating marine snow under extreme pressure

To investigate the process, the researchers recreated marine snow in the laboratory using diatoms, microscopic algae that naturally clump together as they sink through the ocean.

The team placed these artificial particles inside specially designed rotating pressure tanks that kept the marine snow suspended instead of allowing it to settle. This setup allowed the researchers to measure how much carbon and nitrogen escaped under conditions similar to those found in the deep ocean.

Their experiments showed that up to half of a particle’s carbon content leaked out while sinking. Most of the released material consisted of proteins and carbohydrates that free-living deep ocean microbes can readily consume.

Microbes respond almost immediately

The leaked nutrients quickly fueled microbial growth.

Within just two days, bacterial abundance increased 30-fold, while respiration rates rose dramatically. These results indicate that dissolved organic matter released from marine snow provides a rapid and valuable energy source for microbes living at great depths.

The researchers also observed the same leakage pattern across multiple species of diatoms, suggesting that this mechanism is likely widespread throughout the world’s oceans.

Next stop: The Arctic Ocean

The next phase of the research will move from the laboratory to the open ocean.

The team plans to search for molecular fingerprints of this process in both surface and deep waters during a future expedition to the Arctic aboard the German research vessel Polarstern. Detecting those signatures in nature would help confirm that the pressure driven leakage observed in the laboratory is occurring throughout the deep ocean.

The study, “Hydrostatic pressure induces strong leakage of dissolved organic matter from “marine snow” particles,” was authored by Peter Stief, Jutta Niggemann, Margot Bligh, Hagen Buck-Wiese, Urban Wünsch, Michael Steinke, Jan-Hendrik Hehemann, and Ronnie N. Glud.

The research was supported by the Danish National Research Foundation, the European Union’s Horizon 2020 Research and Innovation program, and the Independent Research Fund Denmark.

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