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Technology

Halo Infinite is getting better Battle Pass progression later this week

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If you’re still stuck on level 1 of the Halo Infinite Battle Pass, fear not, as 343 Industries is making some much-needed changes to progression later this week. “To address the feedback on Battle Pass progression we will be making targeted tunings to our model later this week,” says Halo community manager John Junyszek.

The existing Halo Infinite Battle Pass makes it difficult to level up, as you’re limited to completing daily or weekly challenges instead of earning XP for every game you play. While that isn’t changing yet, 343 Industries is adding “Play 1 game” challenges “to help make sure you consistently progress through the Battle Pass by playing matches the way you want,” according to Junyszek.

343 Industries will also be removing some weekly challenges and fixing bugs with others, but these changes do have a small price. “When we make this update, we’ll need to reset your challenges, including your progress towards weekly ones,” explains Junyszek. “To make up for this reset, we’ll be granting this week’s Ultimate Reward, the Sigil Mark VII Visor, to everyone who logs in from November 23rd to November 30th.”

XP boosts will also now double in duration, lasting for an hour instead of 30 minutes, which will help for longer Big Team Battles games. We may even see further changes to the XP and progression systems in Halo Infinite in the future, too. “We’ll be watching these changes closely to make sure they have the positive impact we all want on your progression,” says Junyszek. “This is only our first step – we are committed to continue evolving these systems but it will take time.”

The XP boost changes should help during Big Team Battles.
Screenshot by Sean Hollister / The Verge

Criticism around the Halo Infinite Battle Pass progression has been getting increasingly louder across the community of Halo fans this week after the surprise early release of Halo Infinite multiplayer on Monday. While multiplayer previews over the summer felt like an exciting return to form, we had concerns around the Battle Pass progression and XP systems. 343 Industries still went ahead with the same systems, despite concerns from many during the technical previews.

It’s encouraging to see quick changes, though. This opening Halo Infinite season will last until May, which is double the three months that had originally been promised. That extra time could be why 343 Industries kept the slow Battle Pass progression in the first place, but we’ll have to check out the changes later this week to see if they make a big difference.



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Technology

Halo Infinite: 343 Says It’s Assessing Controversial Multiplayer Progression

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Following the launch of Halo Infinite’s multiplayer mode, 343 Industries has confirmed that it’s currently assessing the game’s controversial multiplayer progression system.

The announcement was made in a tweet by studio community director Brian Jarrard. “Thank you to everyone who has jumped into the Halo Infinite beta so far,” said Jarrard in the tweet.

“FYI the team is looking at Battle Pass progression and gathering data from yesterday’s sessions and we’ll share updates as we have them,” he continued before asking fans to share further feedback as and when they felt necessary.

Halo Infinite has adopted a Battle Pass system to reward players with cosmetic content, similar to modern multiplayer shooters such as Fortnite and Call of Duty – but the way in which you progress along that Pass is slightly different. The crux of the issue that players have with Infinite’s Battle Pass comes down to how XP is rewarded. In its current state, players are only able to progress through the battle pass by completing daily and weekly challenges in the game, meaning that XP isn’t necessarily granted just by completing matches and playing games.

Following the launch of the game’s multiplayer mode, a number of players on the game’s subreddit have commented that progress through the pass feels too slow with at least one fan calling it a “slog” and another an “unenjoyable grind.”

Despite the game’s multiplayer mode launching to fans this week, the issue of Halo Infinite’s multiplayer progression was raised by players during the game’s previous technical playtests. At the time, a statement from 343 addressed the issue, saying:

“While we understand the community’s feedback around wanting a steady drip of match XP and more ways to earn XP for the Battle Pass, we are optimistic that the system available at launch will give players adequate means of continually having something to accomplish and a means to progress. Looking further ahead beyond launch, we expect these systems to evolve in direct partnership with player feedback.”

Halo Infinite Multiplayer: Season 1 Rewards

Multiplayer progression aside, the launch of Halo Infinite’s multiplayer mode has been largely positive. While some versions of the game did experience some teething issues to begin with, the game has amassed a large audience of players in its opening few days.

On Steam alone, data from SteamDB suggests that the game saw over a quarter of a million concurrent players during its opening 24 hours. While it will be interesting to see whether that number increases over the weekend period, the figure already places it as the 22nd highest concurrent peak in the platform’s all-time history.

Jared Moore is a freelance writer for IGN. You can follow him on Twitter.



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Health

Vascular defects appear to underlie the progression of Parkinson’s disease

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Immunohistochemistry for alpha-synuclein showing positive staining (brown) of an intraneural Lewy-body in the Substantia nigra in Parkinson’s disease. Credit: Wikipedia

In an unexpected discovery, Georgetown University Medical Center researchers have identified what appears to be a significant vascular defect in patients with moderately severe Parkinson’s disease. The finding could help explain an earlier outcome of the same study, in which the drug nilotinib was able to halt motor and non-motor (cognition and quality of life) decline in the long term.

The researchers say their finding, detailed in a study published November 12, 2021, in Neurology Genetics, suggests that blood vessel walls called the blood brain barrier, which normally act as a crucial filter to protect the brain against toxins as well as allow passage of nutrients to nourish it, doesn’t work correctly in some Parkinson’s patients: It prohibits toxins from leaving the brain and inhibits nutrients such as glucose from entering. Perhaps even more damaging, the dysfunctional barrier allows inflammatory cells and molecules from the body to enter and damage the brain.

The research, the first longitudinal study to use such advanced genomics, now provides investigators with a new target for therapeutic intervention in Parkinson’s disease, says the study’s senior author, Charbel Moussa, MBBS, Ph.D., director of the Medical Center’s Translational Neurotherapeutics Program.

The new discovery comes from the second part of a Phase II clinical trial that featured next generation whole genome sequencing of the cerebrospinal fluid of 75 Parkinson’s patients, before and after treatment with a repurposed leukemia drug, nilotinib, or a placebo.

This study lasted 27 months; the initial trial was double-blinded and patients were randomized to either placebo, or 150mgs or 300mgs nilotinib for 12 months. The patients had severe Parkinson’s disease; all treated with optimal standard of care and many (30%) had also used the most sophisticated treatments possible, such as deep brain stimulation. The second part of the study employed an adaptive design and all participants had a 3-month drug washout period before re-randomization to either 150mgs or 300mgs for an additional 12 months. After 27 months, nilotinib was found to be safe, and patients who received nilotinib showed a dose-dependent increase of dopamine, the chemical lost as a result of neuronal destruction.

“It appeared nilotinib halted motor and non-motor decline in the patients taking the 300mgs higher dose,” says Moussa. The clinical outcomes of this study were published in Movement Disorders in March 2021.

The current part of the study, just published, examined the cerebrospinal fluid of patients via epigenomics, which is a systematic analysis of the global state of gene expression, in correlation with continuing clinical outcomes. The new analysis helps explain the clinical findings.

Nilotinib inactivated a protein (DDR1) that was destroying the ability of the blood brain barrier to function properly. When DDR1 was inhibited, normal transport of molecules in and out of the brain filter resumed, and inflammation declined to the point that dopamine, the neurotransmitter depleted by the disease process, was being produced again.

Moussa and his team have long been working on the effects that nilotinib (Tasigna) may have on neurodegeneration, including Alzheimer’s and Parkinson’s diseases. The drug was approved in 2007 for chronic myelogenous leukemia (CML), but Moussa reasoned that its mechanism of action may help the brain destroy toxins that develop in the brains of patients with neurodegenerative disorders.

“Not only does nilotinib flip on the brain’s garbage disposal system to eliminate bad toxic proteins, but it appears to also repair the blood brain barrier to allow this toxic waste to leave the brain and to allow nutrients in,” Moussa explains. “Parkinson’s disease is generally believed to involve mitochondrial or energy deficits that can be caused by environmental toxins or by toxic protein accumulation; it has never been identified as a vascular disease.”

“To our knowledge, this is the first study to show that the body’s blood brain barrier potentially offers a target for the treatment for Parkinson’s disease,” Moussa says. “Much work remains to be done, but just knowing that a patient’s brain vascular system is playing a significant role in the progression of the disease is a very promising discovery.”

Researchers decode how cancer drug works in brains of Parkinson’s disease patients

More information:
CSF MicroRNAs Reveal Impairment of Angiogenesis and Autophagy in Parkinson Disease, Neurology Genetics (2021). DOI: 10.1212/NXG.0000000000000633
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Georgetown University Medical Center

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Vascular defects appear to underlie the progression of Parkinson’s disease (2021, November 12)
retrieved 13 November 2021
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Health

Scientists Identify the Cause of Alzheimer’s Progression in the Brain – Very Different Than Previously Thought

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For the first time, researchers have used human data to quantify the speed of different processes that lead to

“This research shows the value of working with human data instead of imperfect animal models.” — Tuomas Knowles

In Alzheimer’s disease, tau and another protein called amyloid-beta build up into tangles and plaques – known collectively as aggregates – causing brain cells to die and the brain to shrink. This results in memory loss, personality changes, and difficulty carrying out daily functions.

By combining five different datasets and applying them to the same mathematical model, the researchers observed that the mechanism controlling the rate of progression in Alzheimer’s disease is the replication of aggregates in individual regions of the brain, and not the spread of aggregates from one region to another.

The results, reported in the journal Science Advances, open up new ways of understanding the progress of Alzheimer’s and other neurodegenerative diseases, and new ways that future treatments might be developed.

For many years, the processes within the brain which result in Alzheimer’s disease have been described using terms like ‘cascade’ and ‘chain reaction’. It is a difficult disease to study, since it develops over decades, and a definitive diagnosis can only be given after examining samples of brain tissue after death.

For years, researchers have relied largely on animal models to study the disease. Results from mice suggested that Alzheimer’s disease spreads quickly, as the toxic protein clusters colonize different parts of the brain.

“The thinking had been that Alzheimer’s develops in a way that’s similar to many cancers: the aggregates form in one region and then spread through the brain,” said Dr. Georg Meisl from Cambridge’s Yusuf Hamied Department of Chemistry, the paper’s first author. “But instead, we found that when Alzheimer’s starts there are already aggregates in multiple regions of the brain, and so trying to stop the spread between regions will do little to slow the disease.”

This is the first time that human data has been used to track which processes control the development of Alzheimer’s disease over time. It was made possible in part by the chemical kinetics approach developed at Cambridge over the last decade which allows the processes of aggregation and spread in the brain to be modeled, as well as advances in PET scanning and improvements in the sensitivity of other brain measurements.

“This research shows the value of working with human data instead of imperfect animal models,” said co-senior author Professor Tuomas Knowles, also from the Department of Chemistry. “It’s exciting to see the progress in this field – fifteen years ago, the basic molecular mechanisms were determined for simple systems in a test tube by us and others; but now we’re able to study this process at the molecular level in real patients, which is an important step to one day developing treatments.”

The researchers found that the replication of tau aggregates is surprisingly slow – taking up to five years. “Neurons are surprisingly good at stopping aggregates from forming, but we need to find ways to make them even better if we’re going to develop an effective treatment,” said co-senior author Professor Sir David Klenerman, from the UK Dementia Research Institute at the University of Cambridge. “It’s fascinating how biology has evolved to stop the aggregation of proteins.”

The researchers say their methodology could be used to help the development of treatments for Alzheimer’s disease, which affects an estimated 44 million people worldwide, by targeting the most important processes that occur when humans develop the disease. In addition, the methodology could be applied to other neurodegenerative diseases, such as Parkinson’s disease.  

“The key discovery is that stopping the replication of aggregates rather than their propagation is going to be more effective at the stages of the disease that we studied,” said Knowles.

The researchers are now planning to look at the earlier processes in the development of the disease, and extend the studies to other diseases such as Frontal temporal dementia, traumatic brain injury, and progressive supranuclear palsy where tau aggregates are also formed during disease.

Reference: “In vivo rate-determining steps of tau seed accumulation in Alzheimer’s disease” by Georg Meisl, Eric Hidari, Kieren Allinson, Timothy Rittman, Sarah L. DeVos, Justin S. Sanchez, Catherine K. Xu, Karen E. Duff, Keith A. Johnson, James B. Rowe, Bradley T. Hyman, Tuomas P. J. Knowles and David Klenerman, 29 October 2021, Science Advances.
DOI: 10.1126/sciadv.abh1448

The study is a collaboration between researchers at the UK Dementia Research Institute, the University of Cambridge, and Harvard Medical School. Funding is acknowledged from Sidney Sussex College Cambridge, the European Research Council, the Royal Society, JPB Foundation, the Rainwater Foundation, the NIH, and the NIHR Cambridge Biomedical Research Centre which supports the Cambridge Brain Bank.



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