Illusion helps demystify the way vision works

Experiments imply brightness perception occurs deeper in the brain than thought

Peer-Reviewed Publication

UNIVERSITY OF TOKYO

For the first time, research shows that a certain kind of visual illusion, neon color spreading, works on mice. The study is also the first to combine the use of two investigative techniques called electrophysiology and optogenetics to study this illusion. Results from experiments on mice settle a long-standing debate in neuroscience about which levels of neurons within the brain are responsible for the perception of brightness.

We’re all familiar with optical illusions; some are novelties, while some are all around us. Even as you look at the screen in front you, you are being fooled into thinking that you’re seeing the color white. What you’re really seeing is lots of red, green and blue elements packed so tightly together it gives the impression of being white. Another example is a fast rotating wheel or propeller, which can briefly look like it’s reversing direction while it’s accelerating to full speed. In any case, it might be surprising to know that optical illusions are not just fun to look at but can also be a useful tool to learn more about eyes, nerves, minds and brains.

Associate Professor Masataka Watanabe from the Department of Systems Innovation at the University of Tokyo is on a mission to understand more about the nature of consciousness. It’s a vast subject area so naturally there are many ways to explore it, and amongst other things, he uses optical illusions. His most recent research looked at whether a certain kind of illusion that works on humans would also work on mice. And it turns out, it does. But why is this significant?

“Knowing this kind of illusion, called a neon-color-spreading illusion, works on mice as well as humans, is useful for neuroscientists like myself, as it means that mice can serve as useful test subjects for cases where humans cannot,” said Watanabe. “To really understand what goes on inside the brain during perceptual experiences, we need to use certain methods that we cannot use on people. These include electrophysiology, the recording of neural activity with electrodes, and optogenetics, where light pulses enable or disable firing of specific neurons in a living brain.”

Watanabe’s experiment was the first of its kind to make use of both electrophysiology and optogenetics at the same time in animal test subjects exposed to the neon-color-spreading illusion, which allowed his team to see precisely what structures within the brain are responsible for processing the illusion.

“After a visual stimulus lands on the eye, it’s carried to the brain by nerves and is then received by a series of layers of neurons called V1, V2 and so on, where V1 is the first and most basic layer, and V2 and above are considered higher layers,” said Watanabe. “There is a long-standing debate in neuroscience about the role higher levels play in the perception of brightness and it was not an easy thing to study. Our experiment on mice has shown us that neurons in V1 responded not just to the illusion, but also to a nonillusory version of the same kind of pattern shown. But only when the illusory version was shown to the mice did neurons in V2 also play a crucial role: that of modulating the activity of neurons in V1, thus proving that V2 neurons do in fact play a role in the perception of brightness.”

This experiment has shown that mice models can be effective in this area of neuroscience. Watanabe hopes this is just the beginning and that such experiments will help toward his grand aim of clarifying the neural mechanism of consciousness.

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Journal article: Alireza Saeedi, Kun Wang, Ghazaleh Nikpourian, Andreas Bartels, Nikos K. Logothetis, Nelson K. Totah, Masataka Watanabe, “Brightness illusions drive a neuronal response in the primary visual cortex under top down modulation”, Nature Communications, https://doi.org/10.1038/s41467-024-46885-6

Funding:
This work was funded by the Max Planck Society and the Helsinki Institute of Life Science at the University of Helsinki (NT).

Useful links:
Watanabe Laboratory https://www.bc2ac.t.u-tokyo.ac.jp/
Department of Systems Innovation https://www.sys.t.u-tokyo.ac.jp/en/?lang=en  
Graduate School of Engineering https://www.t.u-tokyo.ac.jp/en/soe  

Research contact:
Associate Professor Masataka Watanabe

Graduate School of Engineering, The University of Tokyo,
7-3-1 Hongo, Bunkyo-ku, Tokyo, 113-8654, Japan

watanabe@sys.t.u-tokyo.ac.jp

Press contact:
Mr. Rohan Mehra
Public Relations Group, The University of Tokyo,
7-3-1 Hongo, Bunkyo-ku, Tokyo, 113-8654, Japan
press-releases.adm@gs.mail.u-tokyo.ac.jp

About The University of Tokyo:

The University of Tokyo is Japan's leading university and one of the world's top research universities. The vast research output of some 6,000 researchers is published in the world's top journals across the arts and sciences. Our vibrant student body of around 15,000 undergraduate and 15,000 graduate students includes over 4,000 international students. Find out more at www.u-tokyo.ac.jp/en/ or follow us on X (formerly Twitter) at @UTokyo_News_en.

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JOURNAL

Nature Communications

DOI

10.1038/s41467-024-46885-6 

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Animals

ARTICLE TITLE

Brightness illusions drive a neuronal response in the primary visual cortex under top down modulation

ARTICLE PUBLICATION DATE

23-Apr-2024

 

Study shows climate change impact on China's dry–wet transition zones

INSTITUTE OF ATMOSPHERIC PHYSICS, CHINESE ACADEMY OF SCIENCES

 

IMAGE: 

A GRASSLAND NORTH OF CHINA’S CAPITAL BEIJING, WHERE GRAZING CATTLE ROAM AMIDST THE CHANGING ENVIRONMENTAL CONDITIONS.

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CREDIT: LI MINGXING

Climate change is significantly altering bioclimatic environments in China's dry–wet transition zones, according to a recent study published in the Journal of Hydrology.

The research conducted by scientists from the Institute of Atmospheric Physics at the Chinese Academy of Sciences, the UK Met Office and  Chinese Academy of Meteorological Sciences, addresses the challenges of assessing climate change impacts on vegetation ecosystems, which vary greatly across different spatiotemporal scales. The study examines how vegetation ecosystems respond and adapt to climate change, alongside the effects of soil water and heat processes. Bioclimatic environment change acts as a crucial link between climate change and local conditions affecting vegetation ecosystems.

"In areas where current vegetation models fall short, bioclimatic indicators offer an alternative for studying climate change impacts on ecological environments," notes Dr. Mingxing Li, the lead author of the study.

The study analyzes historical observations (1979-2018) and future scenario projections (2006-2100) under different climate scenarios. Among these scenarios is the Representative Concentration Pathway 8.5 (RCP8.5), which represents a high greenhouse gas emissions pathway leading to substantial global warming and climate change impacts. Under the RCP8.5 scenario, greenhouse gas emissions continue to rise throughout the 21st century, resulting in severe climate change consequences.

“We focus on ecological environments and habitat suitability for responsive ecosystems, considering climate change, bioclimatic water and heat conditions, and habitat suitability.” Says Dr. Li.

The findings reveal significant changes in bioclimatic environments across dry–wet climate transition zones, particularly under the RCP8.5 scenario. By the end of the 21st century, the local growing season length (GSL) could extend by 60 days, with 30% of the GSL facing heat stress. Despite some improvements in the middle parts of transition zones, overall water conditions worsen both in the air and soil. This leads to a northwestward shift of sustainable grasslands, with a reduction of approximately 131 million square kilometers in total area.

The study highlights the importance of winter and spring heat-water conditions in driving these changes and identifies climate transition zones as hotspots of ecosystem vulnerability, emphasizing the need for targeted impact assessment and adaptation studies.

"While our focus is on China, our findings offer insights for addressing climate change in other transition zones worldwide," adds Dr. Li.

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JOURNAL

Journal of Hydrology

DOI

10.1016/j.jhydrol.2024.131122 

ARTICLE TITLE

Climate change reshapes bioclimatic environments in China’s dry–wet transition zones

 

How to clean up New Delhi’s smoggy air

PAUL SCHERRER INSTITUTE

 

IMAGE: 

A STUDY BY ANDRÉ PRÉVÔT (LEFT) AND IMAD EL HADDAD FROM THE LABORATORY FOR ATMOSPHERIC CHEMISTRY AT THE PAUL SCHERRER INSTITUTE PSI PROVIDES A BASIS FOR DECISION-MAKING TO IMPROVE THE LIVING CONDITIONS OF MILLIONS OF PEOPLE.
 

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CREDIT: PAUL SCHERRER INSTITUTE/MAHIR DZAMBEGOVIC

An international study led by atmospheric researchers at PSI shows for the first time what portions of particulates in the air over northern India are especially harmful to health.

Nowhere else do people breathe air as dirty as in India. According to the World Health Organisation, as many as 1.3 million deaths per year on the subcontinent can be attributed to polluted air. With its National Clean Air Programme, the Indian government wants to enact countermeasures. To do this, decision-makers need to know what sources the particulates come from, how they are distributed regionally, and how harmful certain compounds are to human health. This important information has now been provided for the first time by a study led by members of the Laboratory for Atmospheric Chemistry at PSI, with partners from India, China, Germany, Denmark, France, Spain, and Switzerland. The researchers have not only determined the amounts and origins of particulates in the air, but also their oxidative potential – an important factor for the harmful effect a chemical compound can have on living cells and thus on health. The study has now been published in the journal Nature Communications.

The focus of the study was on the Indian capital New Delhi, and not for the first time. Of all the cities on earth, it is considered the metropolis with the highest concentration of particulates in the air. Over the past four years, the researchers had already gained groundbreaking insights into the air pollution there. In a study from 2023, they demonstrated for the first time that chemical processes run differently in the skies over New Delhi than in other major cities.

Incomplete combustion is the primary cause

This time the team was interested in the sources of particulate emissions and the pathogenic effect of certain substances. According to the study, incomplete combustion plays an especially big role in polluting the air. Even non-experts recognise this: «If it smokes, the combustion is incomplete,» explains Imad El Haddad. He and André Prévôt from the Laboratory for Atmospheric Chemistry at PSI led the latest study. Most notably, the burning of biomass or waste is a major contributor to the formation of particulates and smog. This includes the burning of cow dung for heating and cooking, which also produces high levels of particulate matter. Added to this is the outdated vehicle fleet, especially the small vehicles called tuktuks, widely used in India, and motor scooters with inefficient two-stroke engines.

To better assess the local and regional distribution of particulates, the team expanded the network of measuring sites compared to the previous study, adding two locations in the urban area of New Delhi, one in the area surrounding the capital, and one in Kanpur, around 500 kilometres southeast of the capital. The samples from these sites were examined at PSI by means of mass spectroscopy to determine their composition.

Particulates cause oxidative stress

The quantity of particulates in the air is an important factor – but not the only one. How harmful to health a dust particle is depends on its chemical composition and its oxidative potential. Simply put, this refers to the stress that a chemical compound puts on living cells and, ultimately, entire organs such as the lungs or blood vessels. This stress can lead to asthma, inflammation, hypertension, and other illnesses. The team determined this oxidative potential and correlated it with local and regional particulate sources. Despite the fact that the chemical composition of particulates was different at different locations, the high oxidative potential of organic aerosols in particular traces back to the incomplete combustion of biomass and fossil fuels, together with their organic oxidation products in the atmosphere. Compared to Europe or China, a larger proportion of these components are emitted locally, with a still substantial contribution from regional sources. This is consistent with the findings of last year’s study.

The research in New Delhi is funded by the Swiss Agency for Development and Cooperation. The first phase of the four-year programme is now coming to an end. For programme leader André Prévôt, it was a complete success and an important contribution to the assessment of air quality for the 900 million people living in the lowlands of the Ganges River. «Nevertheless, we still have a long way to go,» Prévôt says. «India needs strict measures and long-term monitoring, as well as societal change and better public awareness of environmental protection.» So it will still take some time before environmental conditions in northern India improve.

Text: Bernd Müller

 

 

About PSI

The Paul Scherrer Institute PSI develops, builds and operates large, complex research facilities and makes them available to the national and international research community. The institute's own key research priorities are in the fields of matter and materials, energy and environment and human health. PSI is committed to the training of future generations. Therefore about one quarter of our staff are post-docs, post-graduates or apprentices. Altogether PSI employs 2200 people, thus being the largest research institute in Switzerland. The annual budget amounts to approximately CHF 420 million. PSI is part of the ETH Domain, with the other members being the two Swiss Federal Institutes of Technology, ETH Zurich and EPFL Lausanne, as well as Eawag (Swiss Federal Institute of Aquatic Science and Technology), Empa (Swiss Federal Laboratories for Materials Science and Technology) and WSL (Swiss Federal Institute for Forest, Snow and Landscape Research). Insight into the exciting research of the PSI with changing focal points is provided 3 times a year in the publication 5232 - The Magazine of the Paul Scherrer Institute.

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JOURNAL

Nature Communications

DOI

10.1038/s41467-024-47785-5 

METHOD OF RESEARCH

Experimental study

ARTICLE TITLE

Local incomplete combustion emissions define the PM2.5 oxidative potential in Northern India

ARTICLE PUBLICATION DATE

25-Apr-2024

 

Air pollution and depression linked with heart disease deaths in middle-aged adults

EUROPEAN SOCIETY OF CARDIOLOGY

Athens, Greece – 26 April 2024:  A study in more than 3,000 US counties, with 315 million residents, has suggested that air pollution is linked with stress and depression, putting under-65-year-olds at increased risk of dying from cardiovascular disease. The research is presented today at ESC Preventive Cardiology 2024, a scientific congress of the European Society of Cardiology (ESC).1

“Our study indicates that the air we breathe affects our mental well-being, which in turn impacts heart health,” said study lead author Dr. Shady Abohashem of Harvard Medical School, Boston, US.

According to the World Health Organization, air pollution is estimated to have caused 4.2 million premature deaths worldwide in 2019.2 Mental illness has also been linked with premature death.3 This study examined whether air pollution and poor mental health are interrelated and have a joint impact on death from cardiovascular disease.

The study focused on particles less than 2.5 micrometres in diameter, also referred to as fine particles or PM2.5. They come from vehicle exhaust fumes, power plant combustion, and burning wood, and present the highest health risk. To conduct the study, county-level data on annual PM2.5 levels were obtained from the Centers for Disease Control and Prevention (CDC).4 PM2.5 exposure was categorised as high or low according to World Health Organization (WHO) standards. The researchers gathered data on the average number of days (age-standardised) that county residents experienced mental health issues—including stress, depression, and emotional problems—from the CDC.5 Each county was then categorised into three groups based on these numbers. Counties in the top third reported the most days of poor mental health (PMH).4 Age-adjusted premature cardiovascular mortality rates (under 65 years of age) per county, were obtained from the CDC.6 County characteristics were sourced from the County Health Rankings project.

The study included 3,047 US counties, representing 315,720,938 residents (with over 207 million aged 20 to 64 years and 50% females) in 2013. Between 2013 and 2019, some 1,079,656 (0.34%) participants died from cardiovascular disease before the age of 65 years. The researchers analysed the associations between pollution, mental health, and premature cardiovascular mortality after adjusting for factors that could influence the relationships.7

Counties with dirty air (high PM2.5 concentrations) were 10% more likely to report high levels of PMH days compared to counties with clean air (low PM2.5 concentrations). That risk was markedly greater in counties with a high prevalence of minority groups or poverty.  The link between PMH and premature cardiovascular mortality was strongest in counties with higher levels (above WHO recommended levels: ≥10 µm2) of air pollution. In these counties, higher levels of PMH were associated with a three-fold increase in premature cardiovascular mortality compared to lower PMH levels. Further, one-third of the pollution-related risk of premature cardiovascular deaths was explained by increased burden of PMH.

Dr. Abohashem said: “Our results reveal a dual threat from air pollution: it not only worsens mental health but also significantly amplifies the risk of heart-related deaths associated with poor mental health. Public health strategies are urgently needed to address both air quality and mental wellbeing in order to preserve cardiovascular health.”

The levels of pollution across ESC countries can be viewed in the ESC Atlas of Cardiology:

https://eatlas.escardio.org/Data/Risk-factors/Enviromental-risk-factors/rf_avpmpol-average-annual-population-weighted-pm2-5-ug-m3.

 

Authors: ESC Press Office
Tel: +33 (0)489 872 075

Email: press@escardio.org

Follow us on X @ESCardioNews 

 

Notes to editor

Funding: There were no specific funds directed toward this study; however, Dr. Abohashem’s other research is partly supported by funds from Harvard Medical School and the American Heart Association.

Disclosures: None.

References and notes

1The abstract ‘Air pollution associates with poor mental health and amplifies the premature cardiovascular death in the United States: longitudinal nationwide analysis’ will be presented during the session ‘Young Investigators Award - Population Science and Public Health’ which takes place on 26 April 2024 at 11:30 EEST on the Open stage.

2World Health Organization: Ambient (outdoor) air pollution.

3Byrne P. Meeting the challenges of rising premature mortality in people with severe mental illness. Future Healthc J. 2023;10(2):98–102.

4CDC PLACES databases.

5CDC Behavioral Risk Factor Surveillance System.

6CDC WONDER databases.

7The analyses were adjusted for calendar year and county characteristics such as demographics, median household income, unemployment rates, violent crime rates, education level, food environment index, rates of health insurance, level of mental health provision, level of primary care provision.

About the European Association of Preventive Cardiology

The European Association of Preventive Cardiology (EAPC) is a branch of the ESC. Its mission is to promote excellence in research, practice, education and policy in cardiovascular health, primary and secondary prevention.

About ESC Preventive Cardiology          #ESCPrev2024

ESC Preventive Cardiology, formerly EuroPrevent, is the leading international congress on preventive cardiology and the annual congress of the European Association of Preventive Cardiology (EAPC) of the European Society of Cardiology (ESC).

About the European Society of Cardiology

The European Society of Cardiology brings together health care professionals from more than 150 countries, working to advance cardiovascular medicine and help people lead longer, healthier lives.

 

Medscape removes education courses for doctors funded by tobacco giant

Company acknowledges “misjudgment” following a BMJ investigation, but medics call for a global ban on industry-funded medical education

BMJ

Medical education provider Medscape has bowed to pressure and agreed to permanently remove a series of accredited medical education courses on smoking cessation funded by the tobacco industry giant Philip Morris International (PMI), The BMJ and The Examination have found.

The global company has acknowledged its “misjudgment” in a letter to complainants and says it will not accept funding from any organisation affiliated with the tobacco industry in the future. .

The move comes after an investigation by The BMJ revealed the PMI deal and the widespread protests among doctors and academics in reaction to the partnership.

According to an internal Medscape document seen by The BMJ and the Examination, Medscape had planned to deliver 13 programmes under a multi-million dollar deal with PMI - called the "PMI Curriculum" - as well as podcasts and a "TV-like series.”

Other PMI-funded programmes with different continuing medical education (CME) providers have also emerged in Saudi Arabia and South Africa.

This apparent global push by the tobacco giant into certified medical education has been met with alarm and calls for certification bodies to issue a ban. 

In response to the criticism, a spokesperson for Philip Morris International told The BMJ: “Health agencies around the world have recognized the beneficial role that smoke-free products can play to improve public health. We are concerned that known special interest groups are actively blocking medical education that the U.S. Food and Drug Administration and medical community have determined are needed. These actions stand to prolong use and possibly increase consumption of combustible cigarettes—the most harmful form of nicotine use.”

But Tim McAfee at the University of California, San Francisco and former director of the Centers for Disease Control and Prevention Office on Smoking and Health, called PMI’s partnership with Medscape, “the ultimate example of the fox not only signing up to guard the hen house but offering to sit on the eggs. 

“It is a perversion of ethics surrounding continuing medical education to allow the very companies that caused and profit from the continuing epidemic of tobacco-related death and disease to be involved in any way,” he said.

Medscape claims that the course content complied fully with standards set by the Accreditation Council for Continuing Medical Education (ACCME), but Pamela Ling, director of the Center for Tobacco Control Research and Education at the University of California San Francisco, said if so, “then the standards need to be strengthened to ensure they don’t allow merchants of death to educate doctors.”

This view is supported in a linked editorial by Professor Ruth Malone at the University of California San Francisco, who says “health professionals, health leaders, their societies and professional organisations must demand that the bodies accrediting continuing medical education for clinicians enact policies banning content sponsored by tobacco-affiliated organisations.”

Health professional and patient organisations should also caution their members to be aware that the tobacco industry is attempting to influence patient care in favour of its products, she adds.

She highlights that Medscape is not the only company offering CME, and PMI may not be the only tobacco company working to influence health professionals in this way, and says similar offerings should be widely publicised and the relevant educational providers notified that tobacco industry sponsorship is unacceptable.

“The tobacco industry cannot be allowed to influence medical education, health practitioners, or patient care in this way as it desperately seeks to secure its future profits,” she concludes.

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JOURNAL

The BMJ

DOI

10.1136/bmj.q948 

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Investigation: Medscape caves in on courses funded by tobacco giant while medics fear global Philip Morris push into medical education

ARTICLE PUBLICATION DATE

26-Apr-2024

Isabelle Anguelovski, selected by the U.S. government for the First National Nature Assessment

UNIVERSITAT AUTONOMA DE BARCELONA

 

IMAGE: 

ICTA-UAB RESEARCHER ISABELLE ANGUELOVSKI 

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CREDIT: ISABEL LOPERA / ICTA-UAB

Isabelle Anguelovski, researcher at the Instituteof Environmental Science and Technology of the Universitat Autònoma de Barcelona (ICTA-UAB), in Span, is one of the authors selected for the first-ever National Nature Assessment (NNA1). The U.S. Global Change Research Program announced the selection of authors who will contribute to the drafting of this document, which aims to shed light on the current challenges posed by climate change and nature loss.

To better understand the full picture of what is happening with nature, the NNA1 will provide a holistic picture of America’s lands, waters, wildlife, and ecosystems and the benefits they provide to the economy, health, climate, environmental justice, and national security. The Assessment will also look ahead at how nature might change in the future, and what those changes may mean for our economy and people’s lives.

The diverse team that will number over 150 experts was selected by the 11 leaders of the chapters in consultation with federal leadership, and they come to NNA1 from a range of organizations across the United States —from universities to federal, and state government, national laboratories, businesses, and nonprofits.

Isabelle Anguelovski will be participating in the chapter on Nature and Equity, led by Chris Schell, Assistant Professor at the University of California, Berkeley. Together with the other authors, they will bring deep experience and expertise in fields like ecology, health, economics, nature-based solutions, urban systems, environmental justice, agriculture, engineering, and much more. The author team also includes Indigenous Knowledge holders with place-based knowledge reflecting local experiences with nature.

Over the next two years, NNA1 authors will take stock of what nature provides in terms of its inherent worth, culture, health, and well-being, jobs and livelihoods, safety, and more, while looking ahead to understand how these benefits might change in the future. The final report is expected in late 2026.

Isabelle Anguelovski is an ICREA Research Professor at ICTA-UAB. She obtained a PhD in Urban Studies and Planning from MIT before returning to Europe in 2011 with a Marie Curie International Incoming Fellowship. Her research examines the extent to which urban plans and policy decisions contribute to more just, resilient, healthy, and sustainable cities, and how community groups in distressed neighborhoods contest the existence, creation, or exacerbation of environmental inequities as a result of urban (re)development processes and policies. Between 2016 and 2022, she was the leader of GreenLULUs, an ERC-funded project which examined green inequalities in 40 cities in Europe, the US, and Canada and she now coordinates a new POC ERC, ClimateJusticeRead, on predicting and preventing green gentrification.

 

Traffic noise, a novel risk factor for cardiovascular diseases

New analysis involving Mainz University Medical Center published in Circulation Research

UNIVERSITY MEDICAL CENTER OF THE JOHANNES GUTENBERG UNIVERSITY MAINZ

An international group of noise experts from the Copenhagen Cancer Institute (Denmark), the Swiss Tropical and Public Health Institute (Swiss TPH), the Perelman School of Medicine at the University of Philadelphia (USA) and the Department of Cardiology at the Mainz University Medical Center have analyzed recent epidemiological data and found strong evidence that transportation noise is closely linked to cardiovascular and cerebrovascular disease. As a result, the researchers call for traffic noise to be recognized as a risk factor for cardiovascular disease. The results of their analyses were published today in the renowned journal of the American Heart Association, Circulation Research.

Epidemiological studies have shown that traffic noise - such as road, rail, or aircraft noise - increases the risk of cardiovascular morbidity and mortality, with high-quality evidence for the development of cardiometabolic diseases such as ischemic heart disease, heart failure, stroke, and diabetes. According to the WHO, more than 1.6 million healthy years of life are lost every year in Western Europe due to traffic-related noise.

Night-time traffic noise, in particular, leads to frequent interruptions and shortening of sleep, an increase in stress hormone levels and increased oxidative stress in the vascular system and brain - and thus to the increased formation of free radicals.  These factors can promote vascular disorders, inflammation, and high blood pressure, thereby increasing the risk of cardiovascular disease. In the current review, the international team of authors from Denmark, the USA, Switzerland, and Germany focused on transportation noise's indirect, non-auditory, cardiovascular health effects.

The authors provide an updated overview of the epidemiologic research on the effects of transportation noise on cardiovascular risk factors and disease, discuss the mechanistic findings from the latest clinical and experimental studies, and propose new risk markers to address noise-induced cardiovascular effects in the general population. A recent analysis on traffic noise and cardiovascular disease integrated into the review article impressively demonstrates that for every 10 dBA, the risk of developing cardiovascular diseases such as heart attack, stroke, and heart failure increases significantly by 3.2 percent.

The authors also explain in detail the possible effects of noise on changes in gene networks, epigenetic pathways, circadian rhythm, signaling along the neuronal-cardiovascular axis, oxidative stress, inflammation, and metabolism. Finally, current, and future noise protection strategies are described and the available evidence on noise as a cardiovascular risk factor is discussed.

"With an increasing proportion of the population exposed to harmful traffic noise even after the COVID pandemic has ended, noise control efforts and noise reduction laws are of great importance for future public health," summarizes the lead author of the paper, Prof. Dr. Thomas Münzel, Senior Professor at the University Medical Center Mainz. "It is also important for us that traffic noise is now finally recognized as a risk factor for cardiovascular disease due to the strong evidence."

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JOURNAL

Circulation Research

DOI

10.1161/CIRCRESAHA.123.323584 

METHOD OF RESEARCH

Meta-analysis

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Transportation Noise Pollution and Cardiovascular Health, Circulation Research

ARTICLE PUBLICATION DATE

25-Apr-2024

 

How the immune system learns from harmless particles

University of Bonn researchers demonstrate how tiny, innocuous particles strengthen the immune response

UNIVERSITY OF BONN

 

IMAGE: 

PROFESSOR ANDREAS SCHLITZER FROM LIMES AT THE UNIVERSITY OF BONN IS STUDYING IMMUNE CELLS TOGETHER WITH HIS WORKING GROUP.

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CREDIT: PHOTO: BARBARA FROMMANN/UNIVERSITY OF BONN

Our lungs are bombarded by all manner of different particles every single day. Whilst some are perfectly safe for us, others—known as pathogens—have the potential to make us ill. The immune system trains its response whenever it encounters such a pathogen. Yet researchers at the University of Bonn have now shown that even harmless particles help to improve the immune response and have published their results in the journal Nature Immunology.

An adult takes around 12 breaths a minute, filling their lungs with life-giving air. But they also breathe in all kinds of particles: harmless, germ-free organisms as well as fungal spores and pathogenic bacteria and viruses. “Whether we’re on public transport where people are coughing or in air-conditioned rooms where the air is full of fungal spores, our lungs are constantly being impacted by our environment,” says Professor Andreas Schlitzer, head of the Quantitative Systems Biology working group in the Life & Medical Sciences Institute (LIMES) at the University of Bonn. “It’s a challenge that the immune system in our lungs has to cope with throughout our lives. It has to adapt to ever-changing requirements, distinguish harmless particles from dangerous ones and react accordingly.”

However, the macrophages—cells of the innate immune system that are responsible for this task—know what they have to do. These “scavenger cells” identify pathogenic particles, destroy them reliably—for the most part—and store the attackers’ details in the immune system’s memory so that they can respond even more effectively next time. But what do the macrophages do with information on harmless particles? This was the question investigated by the working group led by Andreas Schlitzer, who is also a member of the Cluster of Excellence ImmunoSensation2 and the Life and Health Transdisciplinary Research Area at the University of Bonn. “The macrophages could simply forget all about innocuous particles because they don’t do us any harm,” Schlitzer explains. “However, we suspected that they retain information on them anyway and incorporate this knowledge into subsequent immune responses.”

Immune response modified by fungal spores

To test their idea, the researchers made mice breathe in beta-glucan, a sugar found inside the cell wall of a fungus called candida. “We’re exposed to these fungal spores all the time in our daily lives,” Schlitzer points out. “You get them in particularly high concentrations inside rooms with air-conditioning, for example, which are ideal places for them to live.” Although this particular fungus is perfectly safe for healthy people, it can put those with a weakened immune system—due to conditions such as HIV, for instance—at risk of serious illness.

The researchers then used high-dimensional single-cell technologies to study how the mice’s immune system reacted to harmful pathogens. They found that mice that were exposed to the beta-glucan first before being infected with legionella bacteria responded differently to the pathogens than those that were not. “The mice were resistant to the legionella infection or, to put it another way, managed to recover better thanks to their modified immune response,” Schlitzer explains, summing up the findings.

In order to adapt the immune response after coming into contact with harmless particles, macrophages use specific proteins that also play a role in diseases such as Alzheimer’s and obesity. Says Schlitzer: “If we’re able to modulate macrophages in specific ways, they could serve as ‘dials’ that we could tweak in order to treat these conditions.” This is what his working group will be researching going forward.

Institutions involved and funding secured

Besides LIMES at the University of Bonn, the study also involved the German Center for Neurodegenerative Diseases (DZNE), ETH Zurich, the Technical University of Munich, the University of Edinburgh, Heinrich Heine University Düsseldorf, the University of Zurich, the University Medical Center Hamburg-Eppendorf, the Bernhard Nocht Institute for Tropical Medicine, the Shanghai Institute of Immunology, the University Hospital Schleswig-Holstein​, the University of Exeter, East Tennessee State University, the Singapore Immunology Network and the German Center for Infection Research.

It was funded by various sources: an Emmy Noether Research Grant from the German Research Foundation (DFG); Collaborative Research Center 1454 Metaflammation and Cellular Programming; the Diet–Body–Brain (DietBB) research cluster; the European Research Council (ERC); the Wellcome Trust; the Medical Research Council Centre for Medical Mycology at the University of Exeter; a Sir Henry Dale Fellowship jointly awarded by The Wellcome Trust and the Royal Society; the Swiss National Science Foundation, the US National Institutes of Health (NIH); and a UK Research and Innovation (UKRI) Postdoctoral Fellowship Guarantee.

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JOURNAL

Nature Immunology

DOI

10.1038/s41590-024-01830-z 

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Animals

ARTICLE TITLE

Apolipoprotein E controls Dectin-1-dependent development of monocyte-derived alveolar macrophages upon pulmonary β-glucan-induced inflammatory adaptation

ARTICLE PUBLICATION DATE

26-Apr-2024