Efficacy of vibration therapy on physical function, activity and participation in people with stroke: a systematic review and meta-analysis of randomized controlled trials

 All this vibration research and even this DOESN'T CREATE PROTOCOLS! My God, the ABSOLUTE STUPIDITY IN STROKE; no one ever accomplishes anything!

Absolutely fucking useless! You didn't write a rehab protocol from all this earlier research, did you?

• focal muscle vibration (7 posts to May2020)

• vibration (37 posts to February 2011)

• Whole Body Vibration Therapy (7 posts to January 2016)

Efficacy of vibration therapy on physical function, activity and participation in people with stroke: a systematic review and meta-analysis of randomized controlled trials

• Yage Wang,
• JingLan Wang,
• Beibei Lei,
• Di Zhang,
• Shenhong Ma,
• Heling Wang,
• Qiaohua Han &
• Weisheng Zhuang 

We are providing an unedited version of this manuscript to give early access to its findings. Before final publication, the manuscript will undergo further editing. Please note there may be errors present which affect the content, and all legal disclaimers apply.

Abstract

Objective

This study aimed to explore the effectiveness of vibration therapy (VT) in improving physical function, activity, and participation in people with stroke.

Methods

We searched six databases for randomized controlled trials (RCTs) investigating VT in people with stroke. The quality of included studies was assessed using the Cochrane Risk of Bias tool, and data were analyzed using RevMan and Stata. The quality of evidence was evaluated with the GRADEpro tool.

Results

Thirty-seven RCTs involving 1492 people with stroke were included. VT significantly improved physical function, including motor (SMD = 0.46, 95% CI 0.20–0.73), spasticity (SMD =  − 0.64, 95% CI − 0.99 to − 0.29), balance (SMD = 0.52, 95% CI 0.19–0.85), and gait (SMD =  − 0.41, 95% CI − 0.66 to − 0.16). Activity was also enhanced (SMD = 0.21, 95% CI 0.06–0.35), whereas participation did not show improvement (SMD = 0.01, 95% CI − 0.33 to 0.35). Subgroup analysis and meta-regression revealed that spasticity improvement was superior in people with chronic stroke (SMD =  − 0.8, 95% CI − 1.19 to − 0.4). Single-session vibration time ≥ 20 min for gait (SMD =  − 0.84, 95% CI − 1.36 to − 0.32), cumulative vibration time > 5 h for balance (SMD = 0.86, 95% CI 0.30–1.43), and intervention duration ≥ 4 weeks for spasticity (SMD =  − 0.5, 95% CI − 0.81 to − 0.2) yielded pronounced improvements.

Conclusions

Low to moderate quality evidence suggests that VT effectively enhances physical function and activity in people with stroke, while its impact on participation remains unclear. Moreover, VT produced superior spasticity relief in people with chronic stroke compared to those in acute and subacute phases; single-session vibration time ≥ 20 min for gait, cumulative vibration time > 5 h for balance, and intervention duration ≥ 4 weeks for spasticity were particularly effective.

The neuroscientist who thinks that doing nothing is the key to lowering Alzheimer’s risk

 Have your competent? doctor factually dispute this with SPECIFIC research references!

The neuroscientist who thinks that doing nothing is the key to lowering Alzheimer’s risk

Dr Joseph Jebelli says that restful activities activate the brain’s default network, which helps to protect against neurological risks

If a neuroscientist told you that it was possible to lower the chances of neurodegenerative disease in later life by kicking back a bit more, wouldn’t it be a no-brainer?

Last year, in one fell swoop, Dr Joseph Jebelli, a 40-year-old London-based neuroscientist, did just that. As he published his third book, The Brain at Rest: Why Doing Nothing Can Change Your Life, he lived and breathed its message to rest more and work less – in order to improve his brain health and keep brain disease at bay. And to show his readers it’s possible.

Your brain has two “networks”. There’s the “executive” network which you use to do all your task-driven thinking and the much less talked-about “default network”, the circuit of neurons that enables you to daydream and think imaginatively. This “network” kicks in when we think we’re being lazy.

Lounging on the sofa in front of Netflix is not “resting” in a productive way. Walking in greenery, being quiet, staring out the window is. Even allowing yourself to become bored is a good way to rest. The default network is powerful, Dr Jebelli says, in encouraging productivity and in nurturing our synapses, but we have to know how to help it in order to harness the neuroscience of rest.

“I think scientists [in the past] have been partly to blame for making us all think that the brain is like a muscle which ‘powers down’ when we aren’t ‘working’,” explains Dr Jebelli. “The opposite is true. When we rest, it’s ‘powering up’. Even with mild cognitive impairment, which is often a precursor to Alzheimer’s, or the early stages of it, there are restful activities that studies suggest may slow the decline.”

I meet Dr Jebelli today at his townhouse in North London. His nine-month-old son is asleep upstairs. He is youthful-looking, almost too boyish for an accomplished neuroscientist, with a training at University College London and the University of Washington in Seattle. He dedicated his twenties to understanding Alzheimer’s, but it was, he says now, a toxic cycle of overwork.

He published his first book at 32, How the Mind Changed, which was followed by In Pursuit of Memory. But it is this third book, written from the heart, that became a bestseller, and which was named Waterstones Book of the Month in January.

Since its publication, he has suddenly started receiving invitations to talk on the radio. His Oxford Literary Festival talk is a sell-out. Maybe it is because in a time of great uncertainty and fear, his message of the healing power of rest has hit a nerve.

Learning from burnout

Dr Jebelli works only four to five hours a day now. He grew up in Bristol watching both his parents work themselves into the ground. He followed in their footsteps until he was on the point of burnout, ill and anxious.

“On paper I was excelling, but in reality I was a mess”, he recalls. He spent long days at the lab followed by hours in a coffee shop doing more work. His father suffers from long-lasting and profound depression from burnout.His mother works so hard her blood pressure is high enough to warrant hospitalisation. “Guided by my knowledge as a neuroscientist and driven by my family’s toxic relationship with work, I started to explore the neuroscience of rest – and what I discovered was extraordinary,” he writes. (His next book will be on the neuroscience of work). You can, he says, quite literally make your brain bigger by 15 cubic centimetres – the volume of a small plum – by looking after its default network. Studies have shown that people who engage in regular exercise – light or heavy (more below) – have default network areas that are more developed, especially the areas of the brain responsible for memory and learning.

Dr Jebelli says that you can increase the size of your brain by looking after its default network - David Rose By activating your default network, your brain is getting healthier with the growth of new synapses. This is a deterrent for brain degenerative diseases (Alzheimer’s is a disease of synapse loss). “I think there is a lack of scientific understanding about what rest actually is. It’s only in the last 10 to 20 years that we’ve started to understand it.” So, where exactly is the default network located? It fans out across the brain, encompassing the frontal, parietal and temporal lobes. It occupies 20 per cent of the brain – it’s a very big network – whereas your “executive” network is only 5 per cent.

By looking after it, with exercise and with daydreaming, “you improve your intelligence, creativity, memory, and problem-solving abilities. You also lower your risk of developing illnesses such as depression and dementia”, Dr Jebelli says.

It can take three years for your brain to recover from overworking

“When you look at our culture and our working lives, the effects of burnout and overwork on the brain are really profound,” explains Dr Jebelli. “We know that overwork thins the frontal cortex in the same way that ageing does. It literally makes your brain ‘older’.

“It enlarges the amygdala region of your brain, responsible for fight-or-flight, which is why overworked people are anxious and on edge. It shrinks your hippocampus, important for memory, particularly short term.”

Overwork physically “ages” our brain because chronic stress and long hours cause neurons to lose their branch-like structures, known as dendrites. These are essential for communication between brain cells. They are hard to recover and in the long term, their loss leads to cognitive decline. It’s a progressive condition and it can take up to three years of rest and relaxation to put right.

Dr Jebelli points to how 745,000 people a year are dying of overwork, a 29 per cent increase since 2000. Three in five employees report a lack of interest and motivation and energy – a 39 per cent increase since 2019:

“We’re not resting our brains anywhere near as much as we should be. I’m not saying people should not watch their favourite show on Netflix, or be on their phone, or work hard ever again. I’m a hard worker, all I am saying is that we just need to balance that more with rest – and understand that ‘rest’ is your brain doing a lot more.

“Currently, society’s understanding of work and rest is upside down.” Rest, from a business point of view, makes sense too: “Many studies now show that if you give employees more rest, it actually helps the company’s bottom line.” Dr Jebelli pauses, smiling ironically: “although the corporate world is yet to knock on my door and ask for my help.”

Rest as medicine

The brain’s “default network” is our brain’s inbuilt protection against the neurological risks that could harm it. There are different ways of resting that activate the all-important default network. Exercise “in all its forms” is one way, a word not usually synonymous with “rest” but in terms of the default network, Dr Jebelli calls it “active rest”.

“What’s important to remember,” he explains, “is that ‘active rest’ doesn’t just serve as rest for the brain, it also improves the function of our default network.” Any aerobic exercise will stimulate your brain and the default network, as long as you aim for around thirty minutes a day, five days a week.” He adds that a much smaller amount of exercise has anti-anxiety and anti-depression effects, protecting the brain’s neuroplasticity (its ability to adapt and grow).

Dr Jebelli adds: “Active rest in particular does a huge amount for your cardiovascular health. For people with Alzheimer’s and many dementias, there is nearly always some kind of cardiovascular issue as well.”

“Ultimately the crucial thing to remember is that ‘active rest’ – literally just four minutes of gentle exercise every day – lowers your risk of developing a devastating neurological disorder,” he says. “Just as stopping smoking lowers your risk of cancer, embracing active rest lowers your risk of Alzheimer’s disease.”

“In active rest, your brain is releasing a protein called brain-derived neurotrophic factor (BDNF) in the hippocampus, a crucial part of the default network, which has been shown to [help] sprout new synapses and new connections which are really important for brain health. It acts like fertiliser on a garden. All the pharmaceutical companies are really interested in it [as a way] of preventing Alzheimer’s.”

Re-learning how to rest

“The core message of my book is “Do nothing” Dr Jebelli reiterates. Boredom, he says, is vastly underrated by society: “I would argue that true inner self-generated thought is becoming like an endangered species.”

Our 24/7 connectivity means phones constantly ping with texts and emails, leaving no space for intellectual rumination, for play, or for being entirely off-task.

“Our brains haven’t evolved to spend 8 to 12 hours at a time focusing on a cognitively demanding task. We’ve evolved to spend time in nature and yet people still think of ‘rest’ as a kind of luxury.”

Silence, he says, activates the default network, inviting daydreaming and wandering thoughts. In silence, your default network is working creatively and imaginatively in a way that is impossible to achieve with music and podcasts blaring through your headphones. Take the dog for a walk without earphones.

“People always ask me about meditation,” says Dr Jebelli, “because they can think that it’s doing nothing. Meditation is slightly separate but related. It’s focused attention on the present, but what I’m asking people to do is actually much more effortless.”

Being in nature – a park, a wood, a city green square – activates the default network. The rustling of the leaves, for example, and the lapping of waves (if you are by the sea on holiday) are what psychologists call health-giving “soft fascinations”.

In contrast, “hard fascinations” – billboards, train announcements, phones, emails, overbearing bosses – are, explains Dr Jebelli, “all those things which become cognitively draining, not good for your brain”.

A working day, whatever it is, only needs 20 minutes of built-in “rest” through exposure to some kind of greenery. “Twenty minutes seems to be the point at which you get all the neurological and psychological benefits of being in a green space.

“I often get from people “Oh, I don’t have time for 20 minutes a day in the green!” to which I say “Okay, open up your phone for me. Oh look, there’s five hours of screen time right there. Are you not telling me that some of that time could be used on [improving your brain health]?

“My point is that you are going to be more productive in the long run with rest. You are going to perform better and do your best work.” And it might just save your brain too.

World Health Assembly recognises stroke as a public health priority for the first time

 Won't do a damn bit of good unless YOU get involved and DEMAND 100% RECOVERY PROTOCOLS! Because otherwise you're just going to GET AWARENESS CRAPOLA!

World Health Assembly recognises stroke as a public health priority for the first time

Calls for stronger national, global action on prevention, acute care, rehabilitation, and health systems; Indians suffer 108 to 172 strokes per 1,00,000 people annually, with an 18% to 42% one-month case fatality rate

 The World Health Assembly (WHA) passed the first-ever resolution on strokes on Friday (May 22, 2026), urging member states to recognise the medical condition as a public health priority and to strengthen national policies across the full care pathway. This involves prevention and risk‑factor control, timely acute treatment, expanded rehabilitation, and long‑term support. The WHO definition of stroke is a medical emergency that occurs when blood flow to the brain is interrupted, either due to a blockage or bleeding. This lack of blood flow can lead to brain cell death and serious complications. Strokes can be fatal and need immediate treatment. It is estimated that strokes affect 12 million people every year, killing more than half of them, and leaving two out of three survivors with a lasting disability. The resolution calls for stronger national and global action to reduce the burden of strokes, through prevention, acute care, rehabilitation, and improved health system readiness. It also reinforces reporting accountability. Kouamivi Agboyibor, WHO’s medical officer for cardiovascular diseases and strokes, called the resolution “historic”, saying it created a political mandate. Khaled Abdel Ghaffar, Egypt’s Minister of Health and Population, who submitted the resolution to the Assembly, said: “The resolution gives every country a framework to close the gaps in stroke care systematically... Commitment today means fewer deaths and fewer disabled citizens tomorrow.” 

Stroke in India

 As per estimates published in an article in the peer-reviewed International Journal of Stroke, the crude incidence of stroke in India ranges from 108 to 172 per 1,00,000 people per year, with a one-month case fatality rate between 18% and 42%. There are only 8,000-odd neurologists and neuro surgeons for India’s entire population, and this compounds concerns about the inadequacy of care. “One detail that is more important than new strokes annually or even the one-month case fatality is the millions of man hours lost (including that of the caretakers),” points out K. Ganapathy, senior neurologist and past president of the Neurological Society of India.   ‘Wakeup call’ “There is enough data now to show that strokes occur much earlier in India than in other countries. While specific genes have been identified, it is their interaction with a modifiable environment that actually increases the risk of stroke in the young,” he says. The good news is that risk factors such as hypertension, diabetes, tobacco use, obesity, physical inactivity, unhealthy diet, air pollution, and alcohol misuse are all reversible. Prof. Ganapathy adds: “This resolution should be a wakeup call for India. With the current state of digital literacy and an excellent telecom network, India can show the rest of the world that stroke prevention(YOU need to change this to stroke recovery!) is eminently doable.”   E.S. Krishnamoorthy, a neuropsychiatrist and founder of the Buddhi Clinic, says, “WHO’s first dedicated stroke resolution is a landmark moment because it recognises stroke not merely as an acute medical emergency, but as a lifelong neurological and rehabilitation challenge. For countries such as India, where stroke-related disability is rising rapidly, the emphasis on prevention, rehabilitation, health-system readiness and scalable neurorehabilitation models is especially important.”

Nose-to-Brain Delivery of mRNA-Loaded Lipid Nanoparticles Bypasses the Blood–Brain Barrier for Effective Brain Disease Therapy

 For when our researchers finally discover drugs to repair the brain.

Nose-to-Brain Delivery of mRNA-Loaded Lipid Nanoparticles Bypasses the Blood–Brain Barrier for Effective Brain Disease Therapy

• Xiaolu Yu
• Xiao-Meng Deng
• Yi Lin
• Hongyu Ren
• Lu Jia
• Yanan Meng
• Fan Liu
• Qiang Cheng*
• Zhao-Qian Teng*
• Tuo Wei*

Abstract

mRNA-loaded lipid nanoparticles (mRNA-LNPs) show great therapeutic potential, but their use in central nervous system (CNS) disorders is limited by poor blood–brain barrier (BBB) penetration. Intranasal (IN) administration can bypass the BBB via olfactory/trigeminal pathways, enabling direct brain targeting and rapid screening of brain-specific lipid nanoparticles (LNPs). Using a peptide-based ionizable lipid platform, we systematically evaluated how LNP surface charge affects IN brain delivery and found that positively charged mRNA-LNPs produced superior brain transfection. Iterative in vivo screening yielded an intranasal brain-targeting LNP (INBT LNP) that efficiently traverses the olfactory and trigeminal nerves, drives brain-specific mRNA expression, and minimizes off-target expression in peripheral organs. Co-delivery of mRNAs encoding brain-derived neurotrophic factor (BDNF) and interleukin-10 (IL-10) using INBT LNPs significantly reduced neuroinflammation, inhibited neuronal death, and improved cognition in a repetitive mild traumatic brain injury (rmTBI) mouse model. Overall, this work establishes a noninvasive, patient-compliant, intranasal mRNA-LNP platform for brain delivery, offering a promising therapeutic strategy for TBI and other CNS disorders.

© 2026 American Chemical Society

• Tuo Wei*

Treating the immune system to repair the brain

 Ask your competent? doctor EXACTLY HOW THIS WILL GET YOU 100% RECOVERED!

Do you prefer your doctor, hospital and board of director's incompetence NOT KNOWING? OR NOT DOING? Your choice; let them be incompetent or demand action! You do know incompetent doctors and hospitals can be fired!

Treating the immune system to repair the brain

Michal Schwartz https://orcid.org/0000-0003-4015-7507 and Tommaso Croese https://orcid.org/0000-0002-3805-3429Authors Info & Affiliations

 Science Translational Medicine

 20 May 2026 Vol 18 Issue 850 DOI: 10.1126/scitranslmed.aeb1677

Abstract

Non-neuronal brain cells and systemic immunity play a central role in Alzheimer’s disease (AD) and other brain disorders. The immune system, initially protective, becomes dysfunctional as the disease progresses. Here, we discuss next-generation therapeutic approaches aimed at treating the immune system rather than the brain to combat AD and other neurodegenerative diseases.

Access the full article

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Intensive Individualized Recovery in Chronic Post-stroke Disability: Functional Outcomes, Fatigue Modulation, and Implications for Extended Neuroplasticity

WOW! No knowledge at all of ways to motivate stroke survivors! That is a fireable offense!

 Intensive Individualized Recovery in Chronic Post-stroke Disability: Functional Outcomes,Fatigue Modulation, and Implications forExtended Neuroplasticity 

y Nurkyz U. Beishenalieva 1, 2 , Shafee U. Rehman 2 1. Exercise Physiology, Life University, Marietta, USA 2. Faculty of Medicine, Ala-Too International University, Bishkek, KGZ Corresponding author: Shafee U. Rehman, shafeeur.rehman@alatoo.edu.kg 

Abstract 

Chronic post-stroke disability is commonly associated with limited recovery potential, often due to insufficient intensity and duration of conventional interventions.(WRONG, WRONG, WRONG! It's because you don't have EXACT 100% RECOVERY PROTOCOLS! I guess you are that blitheringly stupid!) Emerging evidence suggests that neuroplasticity may persist beyond traditional recovery windows when interventions are appropriately intensified, individualized, and grounded in exercise physiology principles. This study aimed to evaluate functional recovery outcomes following an intensive, individualized recovery-oriented program in a patient with severe chronic post-stroke impairment and to explore the role of fatigue in modulating performance and adaptation. A single-case clinical study was conducted in a patient with long-standing post-stroke disability and minimal prior improvement. The intervention consisted of prolonged, high-dose daily recovery sessions incorporating task-specific training, neuromuscular re-education, endurance conditioning, and continuous real-time adaptation based on fatigue and performance. Clinical observations were supplemented with an illustrative dataset to model longitudinal trends and functional relationships. The patient demonstrated progressive improvements in mobility, balance, coordination, endurance, and independence in activities of daily living. Recovery tolerance and training capacity increased over time, enabling longer and more effective sessions. Longitudinal analysis indicated consistent functional gains and a negative association between fatigue and performance, suggesting that fatigue modulation may play a key role in optimizing recovery outcomes. This case supports the potential for meaningful functional recovery in chronic post-stroke populations through high-intensity, individualized, exercise physiology-based recovery strategies. The findings highlight the importance of intervention dose, adaptive programming, and fatigue management and suggest that recovery capacity may extend beyond conventional expectations. Further research using standardized outcome measures is warranted. Categories: Neurology, Sports Medicine, Physical Medicine & Rehabilitation Keywords: chronic stroke, fatigue management, intensive functional recovery, neuroplasticity, stroke rehabilitation Introduction Stroke remains one of the leading causes of long-term disability worldwide and is frequently associated with persistent impairments in mobility, coordination, balance, endurance, and activities of daily living (ADL). Although significant neurological recovery commonly occurs during the acute and subacute phases, many patients continue to experience substantial functional limitations years after the initial cerebrovascular event. Chronic stroke-related disability often results in reduced independence, impaired quality of life, and decreased participation in social and physical activities [1]. Traditional rehabilitation approaches have historically assumed that recovery potential declines substantially after the early post-stroke period. However, emerging evidence suggests that neuroplastic adaptation may persist beyond conventional recovery windows when rehabilitation is delivered with sufficient intensity, repetition, and task specificity [2,3]. High-intensity and prolonged rehabilitation programs have therefore gained increasing attention as potential strategies to promote continued functional recovery in chronic stroke populations. 

Could A Nasal Spray Reverse Brain Aging? What A New Study Reveals by mindbodygreen

 You incompetent? doctor better know about this before you tell them you want this intervention!

Could A Nasal Spray Reverse Brain Aging? What A New Study Reveals

Heart Attacks Release Toxin That Damages Brain Function

 Have your competent? doctor deliver an EXACT POROTOCOL THAT FIXES THIS! 

Will require ensuring the research continues to EXACTLY providing a protocol!

Heart Attacks Release Toxin That Damages Brain Function

Summary: Researchers cracked a critical hidden mechanism behind the “heart-brain axis,” revealing how a heart attack physically reshapes brain function to cause depression, anxiety, and cognitive decline. The research demonstrates that following a cardiac event, a highly reactive, toxic byproduct called methylglyoxal (MG) surges into the bloodstream and aggregates inside mood and memory centers of the brain.This discovery explains the biological link between cardiac stress and post-stroke psychiatric conditions while introducing an innovative peptide therapy designed to trap the toxin and shield vulnerable brain tissue.

Key Facts

• The Heart-Brain Axis: Neurological and cognitive conditions that manifest after a heart attack are directly fueled by specific, cascading molecular alterations kicked off by structural damage to heart tissue.
• The Toxic Byproduct Accumulation: Following a myocardial infarction, the human body enters a state of high metabolic stress characterized by oxygen drops and systemic inflammation. This hostile shift causes methylglyoxal (MG)—a reactive molecule famously studied in metabolic disorders like diabetes—to spike in the blood and pool in brain zones governing cognition and emotion.
• The Psychological Trap: Individuals recovering from a heart attack experience depression and anxiety at a rate up to three times higher than the general population. Alarmingly, cardiac patients who develop these mental health conditions are up to 2.7 times more likely to suffer a subsequent, fatal heart attack or death.
• Unveiling Chronic Risks: By establishing methylglyoxal as a primary instigator of cellular brain damage and localized chronic neuroinflammation, this study uncovers a distinct biological pathway explaining why a heart attack spikes long-term dementia risks.
• The MG-Trapping Peptide: Moving rapidly from raw discovery to targeted clinical therapeutics, the University of Ottawa team has engineered a unique peptide therapeutic engineered to physically trap methylglyoxal before it can damage neural cells.
• Dual-System Protection: Senior author Dr. Erik Suuronen notes that if forthcoming clinical trials prove successful, this trapping therapy will do more than preserve brain health; by alleviating depression and anxiety, it could drastically lower the 2.7x risk of repeat cardiac mortality, filling a massive unmet clinical gap.
• Source: University of Ottawa

A new study led by a team from the University of Ottawa takes a major step forward in understanding how a heart attack can dramatically reshape brain function and trigger neurological effects, from depression and anxiety to different types of cognitive decline.

This ‘heart-brain axis’ concept suggests that neurological conditions following a heart attack could be driven in part by molecular changes set in motion by damage to the heart. While there are many factors and signaling pathways involved in heart-brain interactions, this newly published research suggests that a toxic byproduct produced by the body plays a major role in the brain following a heart attack.

Brain inflammation after cardiac events

At the center of the discovery is methylglyoxal (MG), a highly reactive molecule, which surges in the bloodstream and accumulates in the brain following a heart attack. Following a heart attack, the body enters a state of stress—oxygen drops, inflammation rises, metabolism shifts—causing MG levels to surge in the bloodstream and then accumulate in the brain in specific brain regions linked to mood and cognition.

The occurrence of depression and anxiety in heart attack patients is up to three times higher than the general population, with patients who suffer depression or anxiety may be up to 2.7 times more likely to experience another heart attack or death.

Charting new territory in brain-heart connection

Published in the journal Advanced Sciences, this finding could potentially transform recovery and long-term outcomes for millions as it reshapes how scientists understand long-term risks after myocardial infarction and explain why emotional and cognitive disorders are so common after cardiac events.  

“Methylglyoxal has been widely studied for its role in metabolic diseases, including diabetes, but much less is known about its function in other diseases. In a previous study, we discovered that methylglyoxal was produced by dying heart tissue after a heart attack (…) based on this evidence, we predicted that methylglyoxal in the blood would target other organs and tissues, including the brain—and this is what we did indeed observe,” says senior author Dr. Erik Suuronen, a Full Professor in the Faculty of Medicine’s Department of Surgery, a scientist in the Division of Cardiac Surgery and director of its BEaTs Research Program at the University of Ottawa Heart Institute.

Moving from discovery toward therapy

The team’s discoveries raise important questions about neurodegenerative disease as chronic inflammation and cellular damage in the brain are key drivers of cognitive conditions like dementia.

By identifying methylglyoxal as a trigger, this research suggests a new pathway through which heart attacks could increase long-term neurological risk. Having identified methylglyoxal as a potential target for treating neurological disorders after a heart attack, the next step is to explore how MG-driven inflammation leads to neuron death and mental health conditions.

Importantly, the research team has already developed a peptide therapeutic that can trap methylglyoxal and prevent it from damaging cells.

“This therapy will soon be tested to see if it can protect the brain from damage after a heart attack,” says Dr. Suuronen, who believes if successful, such treatments could do more than protect brain function; they could potentially reduce the risk of future cardiac events.

“Given the increased risk of subsequent heart attacks or death in heart attack patients who experience depression or anxiety, being able to alleviate these conditions could reduce subsequent major cardiac events and improve the lives of countless patients, filling an urgent unmet clinical need,” Dr. Suuronen adds.

Key Questions Answered:

Q: Why are people who survive a heart attack suddenly at a drastically higher risk for severe depression and dementia?

A: For decades, it was assumed to be purely psychological trauma, but this study proves a major physical, toxic link. When heart tissue dies during a heart attack, it pumps out a highly reactive, toxic byproduct called methylglyoxal (MG). This toxin travels through the bloodstream and pools inside the brain’s emotional and memory centers, triggering cellular damage and inflammation that degrades brain health.

Q: How does having post-heart attack anxiety make a patient nearly three times more likely to die from a second cardiac event?

A: The heart-brain axis is a two-way street. Once the toxic MG surge damages brain cells and triggers chronic mental health struggles, those psychiatric conditions feed straight back into your cardiovascular system. The persistent stress of anxiety and depression strains the heart, raising the likelihood of a secondary, fatal heart attack or death by 2.7 times.

Q: How does a simple “peptide trap” work to save a heart attack survivor’s brain from decay?

A: Think of it like a molecular sponge. The University of Ottawa team developed a custom peptide therapeutic specifically engineered to recognize, latch onto, and neutralize methylglyoxal in the body. By trapping this molecule before it can infiltrate the central nervous system, the drug prevents it from damaging brain tissue, shielding both your mental health and your long-term cognitive survival.

Editorial Notes:

• This article was edited by a Neuroscience News editor.
• Journal paper reviewed in full.
• Additional context added by our staff.

About this neurology research news

Author: Paul Logothetis
Source: University of Ottawa
Contact: Paul Logothetis – University of Ottawa
Image: The image is credited to Neuroscience News

Original Research: Open access.
“Methylglyoxal Accumulation is Associated with Brain Inflammation after Myocardial Infarction with Sex and Regional Differences” by Ramis Ileri, Xixi Guo, Erik J. Suuronen. Advanced Science
DOI:10.1002/advs.202522584

What Counts as Ultra-Processed Food? One Expert Panel Has An Answer by mindbodygreen

 Your competent? doctor already had the dietician remove all these foods from your hospital diet protocol and your take home diet protocol, right? Oh NO! NOTHING WAS DONE!

What Counts as Ultra-Processed Food? One Expert Panel Has An Answer

I Tried The Viral Lymphatic Jump Routine — Here’s What Surprised Me Most by mindbodygreen

 I can't jump at all, not even an inch off the floor, which is bizarre since my left leg still has massive power!

I Tried The Viral Lymphatic Jump Routine — Here’s What Surprised Me Most

Researchers Link Widely Used Food Preservatives to Higher Heart Disease Risk

 

Your competent? doctor already had the dietician remove all these foods from your hospital diet protocol and your take home diet protocol, right? Oh NO! NOTHING WAS DONE!

Researchers Link Widely Used Food Preservatives to Higher Heart Disease Risk

Intra-Arterial Alteplase Safe but Fails to Improve Functional Outcome After Basilar Artery Recanalization: JAMA

 Probably because you blithering idiots haven't figured out that the neuronal cascade of death continues occurring even if the artery was totally blown clear! My God, the absolute stupidity in stroke is mind blowing!

Intra-Arterial Alteplase Safe but Fails to Improve Functional Outcome After Basilar Artery Recanalization: JAMA

The Mobility Toolkit: What Actually Changes Your Range of Motion by SIM60

 I bet your incompetent? doctor gave you nothing like this!

SATURDAY DEEP DIVE: THE EQUIPMENT

Sunday’s issue recommended a mobility stick or dowel as the primary tool for split squat work and movement assessment. Today we cover the full landscape of mobility equipment — what actually produces lasting change in active range of motion versus what feels productive in the moment without transferring to movement. THE MOBILITY EQUIPMENT STACK Tool 1: Mobility Stick / Dowel Rod (48 inches) A wooden dowel or PVC pipe is one of the highest-utility, lowest-cost tools in functional training. Primary uses: balance aid during split squats and single-leg drills (holds in one hand, used like a trekking pole), overhead mobility assessment (hold overhead with wide grip and overhead squat to assess shoulder and hip range simultaneously), hip hinge feedback tool (three-point contact along the spine as covered in Issue #30b), and thoracic extension guide. Cost: under ten dollars at any hardware store. Tool 2: Lacrosse Ball or Massage Ball For targeted soft tissue work in areas the foam roller cannot reach precisely: the piriformis (sit on the ball, cross one ankle over the opposite knee, slowly shift weight), the plantar fascia (roll underfoot before the foot mobility drills from Issue #29), the pec minor (place against a wall at chest height and lean into it with slow movement), and the posterior hip capsule. A lacrosse ball is harder than a tennis ball and less forgiving — start with a massage ball if tissue sensitivity is high. Tool 3: Yoga Strap or Long Resistance Band (for Assisted Active Stretching) A strap looped around the foot allows you to perform the Active Hip Internal Rotation drill from Sunday’s issue with greater control at end range. It also enables hamstring active stretching in supine position — loop around the foot, extend the leg toward the ceiling, then slowly work to decrease the angle while maintaining a flat lower back. The key: the strap provides a boundary, not a pulling force. You’re teaching the nervous system to control the end range, not forcing the limb past it. Tool 4: Slant Board (for Ankle Dorsiflexion) As covered in Thursday’s issue, ankle dorsiflexion is the limiting factor for split squat depth, squat depth, and stair climbing mechanics for a significant percentage of adults over 60. A slant board positions the foot at a fixed ankle flexion angle, allowing calf and Achilles stretching at a controlled depth without the unstable footing of a step edge. Adjustable models allow progressive increase in the incline as mobility improves. This is a more controlled and targeted approach than the eccentric calf lowering from Issue #29, and the two complement each other. What Feels Good But Does Little for Lasting Mobility Change Percussion massage guns are excellent for pre-workout tissue stimulation and reducing acute soreness. They do not produce lasting changes in active range of motion. The research on percussive therapy shows short-term improvements in passive flexibility (useful before training) but no evidence of sustained mobility change from use alone. Use them as a warm-up tool, not as a substitute for active mobility drills. Static stretching held for less than 20 seconds has minimal effect on either flexibility or mobility. The minimum effective duration for tissue length change is generally considered 30 to 45 seconds. Bouncing or pulsing at end range activates the stretch reflex and reduces the stretch’s effectiveness — hold still and breathe. ISSUE #33 WEEK IN REVIEW Sunday — Flexibility versus mobility: the passive/active range gap, why stretching alone doesn’t produce functional movement change, and the stretch-then-use sequence that does. Introduced the Active Hip Internal Rotation Drill and the Rear-Foot-Elevated Split Squat. Tuesday — Three hip rotation drills: Active Hip Internal Rotation (seated), Active Hip External Rotation (figure-4 chair), and the Hip Rotation Quadrant Drill (supine, both directions). Why hip rotation is the most undertrained range in the active adult population. Thursday — Three split squat progressions: Static Lunge Hold (beginner), Rear-Foot-Elevated Split Squat with the dorsiflexion cue (intermediate), Bulgarian Split Squat with dumbbell load (advanced). The front-heel-elevation modification for limited ankle mobility. Today — The mobility toolkit: dowel rod, lacrosse ball, yoga strap, slant board, and honest assessments of percussion guns and short static holds. The through-line: stretching creates access. Active work creates ownership. The goal is not more range — it’s more controlled range. Every drill this week was designed to produce both.

Advances in Stroke 2026: Recovery and Rehabilitation

 Obviously there were NO ADVANCES since there is NO STRATEGY BEING FOLLOWED!  With NO strategy, nothing ever gets accomplished. The strategy should lay out the EXACT STEPS TO 100% RECOVERY! And with NO leadership that will NEVER OCCUR!

Advances in Stroke 2026: Recovery and Rehabilitation

Encompass Health Rehab educates on stroke signs, recovery

 Very obviously a failure since NO discussion of 100% recovery! 'Hope' would be possible if you had EXACT 100% RECOVERY PROTOCOLS.

Encompass Health Rehab educates on stroke signs, recovery

7 Things Stroke Doctors Say You Should Never, Ever Do

 Never have a stroke, your stroke medical 'professionals' HAVE NOTHING TO GET YOU FULLY RECOVERED!

7 Things Stroke Doctors Say You Should Never, Ever Do

 

It's important to lead an active lifestyle, eat nutritious foods and manage things like your blood pressure, doctors say.

In the United States, strokes are a top cause of death and a major cause of disability, according to the American Stroke Association. This is a scary reality, especially since many of the stroke risk factors are pretty silent (like high cholesterol and high blood pressure) ― until they’re not.

But just because some of the risk factors aren’t always obvious doesn’t mean strokes can’t be controlled. In fact, it’s estimated that 80% of strokes are preventable through lifestyle changes like exercise, diet and more, according to the Centers for Disease Control and Prevention.

No one knows that more than the experts who treat the issue. Stroke doctors say they think a lot about the key ways to lower their risk (and their patients’ risk) of stroke.

“I like to think of it more proactively — what I could do to prevent stroke,” said Dr. Anthony Kim, a vascular neurologist and medical director of the University of California at San Francisco Stroke Center.

Below, stroke doctors share the habits they personally avoid ― and why you should avoid them, too.

Have A Sedentary Lifestyle

According to Dr. Arthur Wang, director of endovascular neurosurgery at Tulane University School of Medicine, one of the modifiable risk factors for stroke is having a sedentary lifestyle.

While there isn’t one across-the-board definition of a sedentary lifestyle, overall, it means spending too much time sitting or lying down and not enough time exercising or moving around.

“It’s been shown that regular physical activity helps keep your blood vessels clog-free. It stops the buildup of plaque in the arteries,” Wang said. “And so we generally recommend that people get probably 30 minutes of moderate exercise maybe five times a week.”

This could mean going for walks, runs, biking, gardening or joining a group workout class — there is no wrong way to get moving.

Ignore High Blood Pressure

“It turns out that a lot of the same things that we would recommend for a healthy lifestyle also reduce the risk of both heart disease and stroke,” Kim said. “But if there’s one factor that is the most impactful it would be blood pressure, blood pressure, blood pressure.”

Elevated blood pressure, particularly over time, can lead to problems, he said: High blood pressure is the biggest modifiable stroke risk factor.

“If you took a magic wand and waved it and suddenly eliminated high blood pressure from the U.S. population, there would be 60% fewer strokes,” Kim said. “It’s by far the leading risk factor for stroke and we call it the silent killer because oftentimes, patients don’t feel it; you have to have it checked and monitored and treated.”

If you took a magic wand and waved it and suddenly eliminated high blood pressure from the U.S. population, there would be 60% fewer strokes.Dr. Anthony Kim, University of California, San Francisco, Stroke Center

Skip Regular Check-Ups

“These risk factors oftentimes don’t have any real symptoms,” Wang said, which is a worrisome thing to think about. “A patient would never know that their blood pressure’s high, they wouldn’t know whether they have high cholesterol unless all of this is routinely tested or screened on a regular basis.” This means it’s crucial that you visit your primary care doctor for the routine check-ups that they deem necessary. They’ll screen you for issues like high cholesterol and high blood pressure while checking other risk factors like your blood sugar and weight, too, he added.

“I think just being hyper-vigilant about those things, especially when these risk factors for stroke are very cryptic, meaning that they don’t manifest in any real symptoms, so it’s really important for patients to understand that so they take the actionable steps to see their doctor to get these routine screening tests,” Wang said.

Your doctor can also review any risk factors outside your control, like gender (strokes are more common in women, Wang said), race (they’re more common in Black people, he noted) and personal history.

“In terms of previous medical history, those who have had prior strokes in the past, or if one of their parents had a stroke in the past, are at a much higher risk of having a future stroke,” Wang said.

Smoke

According to both Kim and Wang, one of the habits that is high on a to-avoid list is smoking. 

“That definitely increases the risk of stroke, and heart disease, for that matter,” Kim said.

“And one of the ways that it does that is by causing the blood vessels to become narrowed over time, and that can ultimately lead to blockages in blood flow to part of the brain, which is essentially what a stroke is,” he explained.

High blood pressure is a huge stroke risk, doctors say, but it can be managed through diet and medication.

Drink Too Much Alcohol

You’re probably aware that alcohol is not good for you. It’s linked to certain kinds of cancer, liver disease, and yes, stroke, too. Specifically, Kim said there is an “association between ... excessive alcohol use and heart disease and stroke risk.”

Alcohol recommendations vary by person, but, the CDC considers more than four drinks in one sitting for women or five drinks in one sitting for men to be excessive drinking. More than eight drinks per week for women and 15 drinks per week for men is also considered excessive drinking.

Generally, it’s accepted that women should not have more than one alcoholic drink a day and men should not have more than two, Kim said. These are also the recommendations put forth by the Dietary Guidelines for Americans.

Ignore Your Diet

A proper diet is important for managing stroke risk, too. This means moderating foods that are full of saturated fats, sugar and salt, Wang said. (Additionally, Kim pointed out that there is a relationship between salt intake and high blood pressure, which, as we now know, is another stroke risk factor.)

When it comes to what you should eat, Kim points to the work of author and journalist Michael Pollan. This advice is “eat food, mostly plants, not too much,” Wang said. This means having a diet that’s rich in fruits and veggies with some meat added in.  

Dismiss Necessary Treatment

Since strokes are so common in this country (and this world), it’s important that you’re aware of the signs and get treated as soon as possible. Available stroke treatments work better the sooner they’re done, Kim said.

“Because many strokes aren’t painful, and the symptoms of stroke vary so much, it’s important to recognize symptoms of stroke,” he said.

And, there’s a useful acronym to help people remember the signs — and that acronym is FAST, Kim said. FAST stands for “facial drooping, arm weakness, speech difficulty and time to call 9-1-1,” according to the American Stroke Association website. 

“These are not the list of all potential stroke symptoms, but any one of those  [factors] raises the suspicion that it could be a stroke, especially if it happens suddenly,” Kim noted.

And, once again, it’s important to remember that getting treatment as fast as possible is vital, he said.