Liz Truss Breaks The Irony Metre By Predicting Andy Burnham Will Cause ‘Financial Crisis’

Liz Truss has predicted that Andy Burnham will lead Britain into a “financial crisis” in a moment which feels like pure satire.

The former Conservative prime minister famously planned to implement £45 billion of unfunded tax cuts which sent the pound into decline and the markets into turmoil.

The Bank of England even had to step in and buy £65 billion worth of government bonds to prevent disaster.

The chaos unleashed by her mini-Budget meant Tory MPs quickly pushed Truss out of office after just 49 days – making her the UK’s shortest-serving prime minister in history.

However, speaking at CPAC GB – a right-wing conference which is a spin-off of its American counterpart – Truss has predicted that the incoming PM Burnham would send the UK into “financial crisis”.

According to the Mirror, she said: “The money’s going to run out. I think the problems with migration are going to get worse and the general decay and stagnation of Britain is going to continue.

“I think the question is how long the pro-progressive authorities can continue.

“My prediction is that there will be another prime minister before 2029.”

Burnham was announced as the Labour leader on Friday and is set to become the next prime minister on Monday when Keir Starmer hands over the keys.

There is some trepidation about his plans for the economy amid fears he could push public spending hikes.

Truss’s words also come after the International Monetary Fund (IMF) warned Burnham this week that the UK is still struggling with the scars left behind by Truss’s mini-budget of 2022.

Four years on, and gilt markets are still nervous about the UK fiscal policy than previously, and according to the IMF, there has been a “regime change” on bond markets as a result.

Truss also told the conference: “We’ve had seven prime ministers in ten years.”

She added: “That’s the equivalent of a crap football team changing its manager all the time but not changing what happens on the pitch.”

It seems to have escaped her attention that five of those seven prime ministers have been Conservative – and she was one of them.

Truss also tried to call for right-wing figures to join her “counter-revolution” rather than going for jobs outside of politics.

“It’s time for successful people in Britain who actually care about the future of our country to step up. To stop being such cowards because at the moment they’re being cowards,” she said.

Truss lost her seat to the Labour Party at the 2024 general election.

According to the Mirror, barely a third of the 500-seat hall was occupied for her appearance at CPAC GB.

Burnham’s team has been approached for comment.

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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Here’s Why Cats Really Lick Each Other, And It’s Less Cute Than I Thought

We’ve written before at HuffPost UK about the heartwarming reason cats might lick their owners, as well as the pretty cute meaning behind a feline headbutt.

So perhaps it’s overdue for us to look at some of the furry friends’ less pure intentions.

According to a new study published in the journal Applied Animal Behaviour Science, it turns out that cats’ “allogrooming” – including licking one another – isn’t always as wholesome as it looks.

Instead, the research, led by Morgane Van Belle, a cat behavioural scientist at Ghent University in Belgium, found the action has “multiple social functions”.

Allogrooming should therefore “not be used on its own to infer that the cats are socially bonded,” the study – which involved analysing 106 videos of feline pairs from 53 households – reads.

What does it mean when cats lick one another?

1) To show escalating tension

Sometimes, cats seem to lick each other as a kind of pre-conflict warning sign – like when one cat is annoyed by another pet stealing their favourite sunbathing spot.

This type of licking has been described as “passive-aggressive”.

In this case, the recipient of the lick might flatten their ears to show they’re not exactly loving the interaction.

Allogrooming in this case might be a “subtle agonistic signal to covertly solve conflict,” the paper reads. This type of licking might come alongside head shaking and even striking and biting.

2) To de-escalate a possible fight

Other times, the researchers said, licking can be “used as a form of appeasement to avoid escalation”.

Before a fight gets too serious, one cat might lick another as a way of re-establishing the peace.

“For me, [this] shows that they are quite elegant in the way they resolve conflict,” Van Belle told The New York Times.

“They could walk over and swat another cat in the face to get the blanket it is lying on. Instead, they lick it a little and fuss around. They have these very subtle ways of resolving conflict… that shows they are intelligent and flexible in their behavior, rather than simply being jerks.”

3) To intimidate each other

Some cases involved one cat “leaning over the other one” while licking them, which might be an intimidation or even bullying tactic.

Whatever the reason, the cat being licked in these cases typically shows signs of displeasure.

4) To clean one another

87% of the time, cats licked one another in the head and neck area.

That’s a hard spot for cats to reach by themselves, though it just so happens to be a very enjoyable place for most cats to be groomed, too.

5) To bond

Some licking is used for the adorable reason we assume it is: strengthening social bonds.

This is likely to be true if the cats are also playing together and have synchronised body posture.

Seeking physical contact with another cat, including snuggling, was followed by allogrooming in 41% of cases, for instance.

Licking was also sometimes used to initiate play.

6) To help one another relax

Lastly, licking may help the recipient relax.

Previous research showed that in various animals, “The behaviour has an immediate relaxing effect for the groomee, as it leads to a reduction in heart rate… and a release of beta-endorphins [natural pain and stress relievers].

“More research is needed to further explore and confirm the suggested functions for allogrooming in cats,” the paper ended.

“Ultimately, this knowledge can contribute to the recognition, resolution and prevention of social stress between cats in multi-cat households.”

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‘We’re Going To Give Them Hope Back’: Andy Burnham Officially Becomes Labour Leader

Andy Burnham has officially been crowned as the leader of the Labour Party, meaning he is days away from being de facto prime minister.

The Makerfield MP will have to wait until Monday to formally take over from Keir Starmer in No.10, as a quirk in the rules means he could not take both titles on the same day.

Burnham ran uncontested to be the next leader of the largest party in the Commons with the support of more than 350 of Labour’s 403 MPs.

In his first speech as Labour leader, he promised he would help to give Brits “hope back”.

He said his supporters “heard the call from the people of Makerfield on behalf of forgotten places everywhere, up and down this country, for a return of the Labour they once knew”.

He added: “And now we answer that call. We will be that version of Labour again.”

Burnham, who has run three times to lead the party, promised he is “ready” to lead Labour now after his nine-year stint as Greater Manchester mayor.

He also praised Starmer for making the party electable after its shocking defeat in the 2019 general election.

He then began to outline what changes he wants to implement, promising: “Change starts with honesty.

“We must recognise that this generation of politicians, myself included, have failed to challenge a political culture and an economic model that simply doesn’t work well enough for ordinary people.

“Four decades of neoliberalism that began in the 1980s have not been kind to the places that built our party, nor to the communities across the UK in rural and coastal areas. So we pledge today to them to be better.”

He added that the public has given his party a “last chance” to implement change – and that he will take the country in a direction which is “distinctively Labour”.

Burnham made five promises to improve the party, too.

He said he would work to build a “new politics”, change Labour’s “political direction”, be a leader for the entirety of the UK, take power back from Westminster and Whitehall and work to stop Labour in-fighting.

Burnham has had a rapid ascent to Downing Street in recent months.

Support for the then-Greater Manchester mayor started to rise as Starmer’s successor after the party’s disastrous performance in the May elections in England, Scotland and Wales.

However, as he did not have a seat in the Commons, Burnham was not able to challenge Starmer’s premiership.

So Josh Simons, Makerfield MP, stood aside to trigger a by-election and give Burnham a chance to return to the Commons.

His comfortable victory over Reform UK last month only strengthened calls for Starmer to step down.

The prime minister subsequently resigned and Labour MPs rushed to endorse Burnham.

There is still plenty of mystery around what Burnham intends to do in office as he avoided any major press conferences and is yet to announce who he wants in his cabinet.

But he insisted today that he “has a plan” and that he will “not change”, staying loyal to his style.

“I have listened and learned as I have gone along, you’ll be pleased to know. And hopefully I’ve got better as a result,” Burnham said. “You can be sure of this: I know what I believe after 25 years as an elected Labour representative, and I know what I want to do with you all. I have a plan.

“What I also want you to know is I won’t change. I have a style and it’s my style. I will always stay close to the ground, close to the people.”

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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Scientists tested 39 sweeteners and found unexpected gut effects

Commonly used sweeteners can directly interfere with the growth of bacteria that help support a healthy gut, according to laboratory research from the University of Cambridge.

The strongest effect appeared when researchers combined isosteviol, a sweetener used by the food and beverage industry, with the antidepressant duloxetine. Together, the two compounds sharply reduced the growth of two important bacterial species associated with digestive health, blood sugar regulation, and immune function.

The scientists caution that the experiments were conducted in a laboratory rather than in people. More research will therefore be needed to determine whether the bacterial changes lead to meaningful health effects under real-world conditions.

Sweeteners May Not Be Biologically Inactive

Sweeteners are found in countless everyday products, including soft drinks, candy, desserts, breakfast cereals, snacks, and some medications. They are commonly promoted as alternatives that provide sweetness with less sugar or fewer calories.

However, growing evidence has linked sweetener consumption with conditions including type 2 diabetes, obesity, and cancer. These associations do not prove that sweeteners directly cause those diseases, and researchers are still working to understand the biological processes that might explain the connections.

One possible factor is the gut microbiome, the enormous community of bacteria and other microorganisms living in the digestive system. These microbes help break down food, produce useful compounds, train the immune system, and influence metabolism. Changes in the number or balance of these organisms may affect health throughout the body.

Despite the widespread use of sweeteners, relatively little research has examined whether they directly affect individual gut bacteria.

Professor Kiran Patil from the Medical Research Council (MRC) Toxicology Unit at the University of Cambridge said: “Most of what we know about the potential impact of sweeteners on our health comes from animal research or from population studies. While these studies have indicated involvement of the microbiome in mediating the effect of sweeteners, it’s difficult to know how sweeteners act in the body — is it through direct interactions with our gut bacteria?”

“Answering this is further complicated by the fact that we rarely ever take sweeteners by themselves — we take them with drinks, in snacks, or even in medication to mask bitterness,” added Dr. Sonja Blasche, a lead author of the study, also the MRC Toxicology Unit.

Testing 39 Sweeteners Against Gut Bacteria

For the study, published in Molecular Systems Biology, Dr. Blasche and her colleagues investigated how artificial and low-calorie sweeteners influence gut bacteria. They also examined whether those effects change when sweeteners are mixed with substances commonly encountered in foods, drinks, and medicines.

The team grew 25 bacterial species separately in the laboratory. The selection included bacteria considered beneficial, neutral, or potentially harmful.

Each species was then exposed to 39 commercially used sweeteners, including both natural and artificial varieties. The researchers monitored how quickly each bacterial culture multiplied and whether its growth slowed or stopped.

About three-quarters of the sweeteners affected the growth of at least one bacterial species. Several reduced or completely halted the growth of bacteria associated with a healthy digestive system.

These findings suggest that some sweeteners are not simply inactive substances that pass through the digestive tract without interacting with the organisms living there.

More Than 100 Unexpected Interactions

People rarely consume a sweetener in isolation. It may appear alongside caffeine in a beverage, flavoring in a dessert, or an active ingredient in a medication.

To recreate some of that complexity, the researchers paired the sweeteners with substances including caffeine, vanillin (vanilla extract), advantame (an artificial sweetener), and eight commonly used drugs.

The team identified more than 100 cases in which a sweetener’s effect changed when another compound was present. The combined effects became stronger in 34 cases and weaker in 68 cases.

This means that the impact of a particular sweetener may depend partly on what else is consumed at the same time.

Antidepressant Combination Stood Out

The most dramatic result involved isosteviol and duloxetine, an antidepressant prescribed to treat depression, anxiety, and certain types of chronic pain.

When used together, the compounds strongly suppressed Roseburia intestinalis and Parabacteroides merdae. Both species are considered important members of the gut microbiome and have been linked to digestive health and metabolic regulation.

Duloxetine is widely used. More than 4.2 million patients in the US received prescriptions for the drug in 2023.

Studying bacteria one species at a time can reveal direct effects, but the human gut is a crowded ecosystem in which microbes constantly interact. To better reflect those conditions, the scientists constructed a simplified microbial community containing all 25 bacterial species.

They allowed the community to develop and then exposed it to different combinations of sweeteners and drugs. The team tracked which species became more abundant, which declined, and whether the community retained its overall variety.

Gut Microbial Diversity Declined

The combination of isosteviol and duloxetine reduced microbial diversity within the synthetic community. Greater diversity is generally considered a feature of a resilient and healthy gut microbiome, although the ideal microbial composition can vary between individuals.

The combination also changed the community’s internal balance by allowing some bacterial species to flourish while others declined.

Additional experiments suggested that these changes increased toxicity toward certain host cells. They also disrupted the activity of other cells involved in inflammation and immune responses.

These results raise the possibility that interactions between sweeteners, medications, and microbes could influence more than digestion alone. However, the simplified laboratory system cannot fully reproduce the complexity of the human body.

Dr. Blasche said: “Sweeteners are often marketed as metabolically neutral, but our study challenges this idea. We found that they can directly affect gut bacteria, particularly when mixed with other compounds such as medication and food additives. These common combinations could have unintended effects on our gut microbiome.”

Human Studies Are Still Needed

The researchers emphasize that the findings should not be interpreted as proof that sweeteners or the tested combinations cause harm in people.

The experiments involved bacteria and cell models under controlled laboratory conditions. In the human digestive system, sweeteners may be absorbed, chemically altered, diluted, or broken down before reaching particular microbes. Diet, genetics, medication use, and the existing composition of a person’s microbiome could also change the outcome.

Future studies will need to determine whether similar interactions occur in humans, what doses would be required, and whether any microbial changes produce measurable effects on health.

Professor Patil, the study’s senior author, added: “Our study suggests that artificial sweeteners don’t just pass through the body passively — they can interact with gut microbes, and these effects can be amplified or altered by other substances like medications. These findings can help guide new studies towards understanding how sweeteners might influence health in unexpected ways.”

The research was funded by the European Union’s Horizon 2020 program and the UK Medical Research Council.

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Scientists built a camera that can track invisible particles in 3D

Some breakthroughs in physics come from brand new inventions. Others begin with a new theory. But many advances happen when researchers combine familiar technologies in an unexpected way and create something more powerful than the individual parts.

That strategy could be especially valuable in the search for weakly interacting particles, including neutrinos and certain dark matter candidates. These particles are notoriously difficult to detect because they rarely interact with ordinary matter. Building larger detectors and improving their spatial resolution can increase the odds of observing the faint signals they produce, but doing so often makes the instruments more complicated and expensive.

Similar demands apply to calorimeters, the devices used in collider experiments to measure the energy carried by particles.

Why Particle Detectors Are So Complex

Most particle physics experiments need to reconstruct the three-dimensional (3D) paths of elementary particles as they move through large volumes of dense material.

One common detector material is a scintillator. When a charged particle passes through a scintillator, the material gives off tiny flashes of visible light. Scientists use those flashes to determine where the particle traveled and how it interacted with the detector.

To pinpoint the particle’s location, the scintillator is usually divided into a vast number of small active sections. Optical fibers collect the photons produced in each section and carry the light to photomultiplier tubes or silicon photomultipliers, which count the photons.

This approach can be highly precise, but it becomes difficult to scale.

The T2K neutrino-oscillation experiment in Japan, for example, uses a detector with about two tons of sensitive material made from approximately two million cubes and 60,000 fibers. At CERN and the Paul Scherrer Institute, the LHCb and Mu3e experiments reach sub-millimeter spatial resolution by using millions of thin scintillating optical fibers.

These systems demonstrate what segmented detectors can accomplish, but they also reveal a growing problem. As detectors become larger, manufacturing, assembling, and reading out millions of individual components can become a major technological and financial bottleneck.

A Radical New Approach to Particle Tracking

Researchers at ETH Zurich and EPFL are now proposing a very different strategy.

PhD student Till Dieminger, senior scientist Dr. Saúl Alonso-Monsalve, Professor Davide Sgalaberna and colleagues in his group, together with members of the Advanced Quantum Architecture Lab at EPFL in Lausanne led by Professor Edoardo Charbon, developed and tested the first prototype of a detector designed to perform ultrafast, high-resolution 3D particle imaging inside a large, unsegmented block of scintillator material.

Instead of dividing the detector into millions of tiny units, the system uses advanced camera technology to reconstruct where the light originated.

The prototype demonstration and an extensive series of simulations were described recently in Nature Communications.

Turning Light Field Photography Into a Physics Tool

The detector draws inspiration from plenoptic cameras, also known as light field cameras.

Unlike an ordinary camera, which mainly records the intensity of incoming light, a light field camera also captures information about the direction from which the light arrived. This allows it to recover depth and reconstruct a scene in three dimensions.

The technology relies on a micro-lens array (MLA) placed between the camera’s main lens and imaging sensor. Each microscopic lens acts like a tiny camera, recording the same scene from a slightly different angle. When the information from all of these lenses is combined, the system can reconstruct a light field, which describes the intensity, position, and direction of the incoming light.

For particle detection, this ability is particularly useful because the light inside a scintillator may be extremely faint.

When plenoptic cameras are paired with single-photon avalanche diode (SPAD) array sensors, they can detect individual photons and potentially reconstruct particle tracks even when very little light is available. Despite that promise, light field cameras had not previously been explored for particle tracking.

Inside the PLATON Prototype

The new system was developed through the PLATON project, which is funded by the Swiss National Science Foundation.

The ETHZ-EPFL team built a proof-of-concept detector that combines a micro-lens array with a SPAD imaging sensor. The sensor, known as SwissSPAD2, was developed by the EPFL team. Raytrix GmbH designed the MLA and mounted it directly onto the sensor to create the complete plenoptic imaging system.

SwissSPAD2 also provides gated photon detection. This means that the sensor records photons only within defined time windows.

That timing control helps researchers focus on periods when genuine scintillation light is most likely to be present while filtering out random background signals and other spurious counts.

Testing the Detector With Just a Few Photons

The researchers tested PLATON’s spatial resolution in laboratory experiments using light levels ranging from several hundred detected photons down to only five.

They also evaluated whether the prototype could detect electrons and reconstruct their positions inside a block of plastic scintillator. The electrons were produced using a strontium-90 source.

Across the different test conditions, the simulations closely matched the laboratory measurements, giving the researchers confidence that their models accurately describe the detector’s performance.

The results from the first demonstrator have already shaped the team’s plans for the next version of PLATON.

Faster Timing and Greater Sensitivity

The researchers are developing a new SPAD array sensor designed to improve photon detection efficiency and provide sub-nanosecond timing for individual photons.

In the current system, photons are assigned to fixed time windows. In the upgraded version, each detected photon would receive its own precise time stamp.

That added timing information could help the system determine more accurately where each photon came from and improve the reconstruction of particle tracks.

The researchers have also optimized the plenoptic camera to expand its field of view and collect more light. Simulations presented in the paper suggest that these changes should further improve PLATON’s spatial resolution.

AI Reconstructs Hidden Particle Interactions

The team also used simulations to estimate how an upgraded PLATON system could perform when detecting neutrinos.

The simulations incorporated a new image-processing method based on a neural network (NN). The system uses a Transformer architecture adapted from the type commonly used in large language models.

Rather than analyzing words, however, this Transformer examines patterns among the scintillation photons recorded by the detector. It is designed to identify correlations in where and when the photons appear, allowing it to reconstruct the original particle interaction.

The simulations indicate that an unsegmented PLATON detector with a volume of (10x10x10)cm3 could realistically achieve spatial resolution below 1mm.

They also suggest that the system could identify neutrino interactions that produce final-state low-momentum protons with both high purity and high efficiency. In other words, the detector may be able to select the desired events while rejecting many unrelated signals.

Scaling Up to a Cubic Meter

The researchers also considered how the technology might perform in a much larger detector.

Because of limited computing resources, they did not run full neutrino simulations for a one-cubic-meter block of unsegmented scintillator. Instead, they modeled a simplified point-like source of photons.

The simulations suggest that a detector of this size could achieve spatial resolution of a few millimeters, placing it on par with state-of-the-art plastic scintillator detectors.

The result is especially notable because PLATON would achieve this performance without dividing the scintillator into millions of individual pieces.

The authors believe that additional improvements to the optical design and other parts of the system could eventually make sub-millimeter resolution possible in PLATON-type detectors with volumes larger than 1m3.

Potential Uses Beyond Particle Physics

The ETH Zurich researchers believe the technology could eventually be useful far beyond neutrino experiments and particle colliders.

Because PLATON is designed to reconstruct the position of faint light signals in three dimensions, it could improve a wide range of imaging systems.

Dieminger, Alonso-Monsalve and Sgalaberna have already filed three separate patents involving the use of PLATON technology in positron emission tomography (PET). PET is a medical imaging method that tracks radioactive tracers inside the body to reveal activity in organs and tissues.

The patents cover both the scanner design and the image-processing techniques, including the NN developed by Alonso-Monsalve.

Particle physics has a long history of producing technologies that later find broader uses. The world wide web was created at CERN, while proton therapy grew from advances in particle accelerators and radiation physics.

PLATON could become another example of a physics experiment leading to a technology with major scientific and medical applications.

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New “living plastic” self-destructs in just 6 days without leaving microplastics

Many plastic items are used for only a few minutes or hours, but the material can remain in the environment for decades or even centuries. Researchers are now exploring a different approach: plastics designed to break themselves down when activated.

Known as living plastics, these materials contain dormant microbes capable of degrading the surrounding polymer. In a study published in ACS Applied Polymer Materials, scientists developed a version that fully decomposed in six days without producing microplastics.

Zhuojun Dai, a corresponding author on the paper, explains that “the realization that traditional plastics persist for centuries, while many applications, like packaging, are short-lived, led us to ask: Could we build degradation directly into the material’s life cycle?”

Turning Microbes Into a Built-In Disposal System

Some microorganisms naturally produce enzymes that cut long polymer chains into smaller fragments. Since plastics are made from polymers, researchers have been investigating whether these enzymes, or the microbes that produce them, can be embedded directly into plastic materials.

“By embedding these microbes, plastics could effectively ‘come alive’ and self-destruct on command, turning durability from a problem into a programmable feature,” explains Dai.

Earlier living plastic designs often depended on a single enzyme, which limited how efficiently the material could be broken down. To improve the process, Dai, Jin Geng, Dianpeng Qi and colleagues engineered Bacillus subtilis to produce two polymer-degrading enzymes that work together.

The first enzyme cuts the long polymer chains at random points, reducing them into shorter sections. The second then works from the ends of those fragments, breaking them down further into their individual monomer building blocks.

Complete Breakdown in Six Days

The researchers combined dormant B. subtilis spores with polycaprolactone (a polymer common in 3D printing and some surgical sutures). Keeping the bacteria in spore form protected them until the team was ready to begin the degradation process.

The finished living plastic had mechanical properties similar to ordinary polycaprolactone films. It remained strong and functional under normal conditions, suggesting that adding the spores did not significantly weaken the material.

To activate the bacteria, the team added a nutrient broth heated to 122 degrees Fahrenheit (50 degrees Celsius). The spores became active and began producing the two enzymes. Within six days, the plastic had been completely reduced to its basic building blocks.

Because the enzymes worked in sequence, the material did not simply crumble into smaller plastic fragments. The process was efficient enough to prevent microplastics from forming during decomposition.

A Wearable Device That Disappears

To demonstrate a possible real-world use, the researchers made a wearable plastic electrode from the living material. The device worked as intended and then fully degraded within two weeks after activation.

The result suggests that living plastics could eventually be used in products that need to remain durable for a limited time but should not persist after they are discarded.

Expanding the Technology to Other Plastics

The team now hopes to develop a method that activates the bacterial spores in water, where a significant share of plastic pollution accumulates.

Although the experiments focused on a single polymer, the researchers believe the same general strategy could be adapted for other materials, including plastics widely used in disposable products.

The authors acknowledge funding from the National Key Research and Development Program of China, the Shenzhen Medical Research Fund, the National Natural Science Foundation of China, the Guangdong Natural Science Funds for Distinguished Young Scholars, and the Shenzhen Science and Technology Program.

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Energy drinks to be banned for under-16s in England from April

It will be illegal to sell high-caffeine beverages to under-16s from April next year, but soft drinks with lower caffeine levels will not be affected.

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Teenagers from 15 should be given free MenB vaccine, say UK experts

Advisers are asking the government to consider introducing MenB jabs following concerns over an outbreak in Kent earlier this year, in which two people died.

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Claudia Winkleman Steps Down From BBC Chat Show: ‘I Was Too Nervous To Enjoy It’

Claudia Winkleman has confirmed that she won’t be returning to her BBC chat show.

The Claudia Winkleman ran for eight weeks earlier this year, and was met with mixed reviews from both critics and viewers.

On Thursday, the Bafta winner announced that she had made the decision not to carry on with the format – at least for the time being.

“Sometimes you have to try something to see how it fits, and I realised I was just too nervous to enjoy it,” she said in a statement.

“Maybe one day I will give it another try, but for now I already have the best jobs in the world and absolutely love the shows I’m doing.”

Claudia added: “I’m incredibly grateful to the BBC for giving me the opportunity, to the guests who agreed to come and chat to me, and the production team who were simply excellent.”

The Claudia Winkleman Show was executive produced by Graham Norton, who previously jumped to his fellow presenter’s defence amid criticism aimed at her programme.

He told the Daily Mail: “What Claudia did was The Claudia Winkleman Show, and that’s what she’s supposed to be doing.

“She shouldn’t be trying to be me. She should be trying to be Claudia, and she nailed that.”

The BBC’s director of entertainment enthused: “Claudia’s warmth and quick wit made The Claudia Winkleman Show an absolute joy.

“Whilst we loved the show, we fully respect her decision and would like to thank Claudia and the brilliant team at So Television for bringing the series to screen on the BBC.

Claudia can currently be seen in action in the latest season of the Channel 4 competition series The Piano, and will return to TV’s most famous castle for the second iteration of The Celebrity Traitors in the autumn.

This time around, the all-star cast will include comedians Miranda Hart, James Acaster and Joe Lycett, actor Bella Ramsey, former Little Mix star Leigh-Anne Pinnock and Oscar nominee Richard E Grant.

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NHS manager says trust wanted 4,000 reports ‘gone’

He tells an inquiry he believed a trust was ‘panicking’ and was discouraged from raising rota issues.

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