Friday, March 22, 2024

Bridging the gap: USUS computer scientists develop model to enhance water data from satellites

Pursuing NSF-funded research, Utah State University researchers publish findings in AGU's 'Water Resources Research' journal

UTAH STATE UNIVERSITY

USU Computer Scientists Develop Hydro-GAN Model to Enhance Satellite Water Data — IMAGE:
UTAH STATE UNIVERSITY COMPUTER SCIENTISTS POUYA HOSSEINZADEH, LEFT, DOCTORAL STUDENT, WITH FACULTY MENTOR SOUKAINA FILALI BOUBRAHIMI, RIGHT, ASSISTANT PROFESSOR IN THE DEPARTMENT OF COMPUTER SCIENCE, PUBLISHED A DESCRIPTION OF A MACHINE LEARNING METHOD TO ENHANCE WATER DATA COLLECTED BY SATELLITES IN AN AGU JOURNAL. HOSSEINZADEH PRESENTS THE RESEARCH AT USU'S 2024 SPRING RUNOFF CONFERENCE MARCH 26-27, IN LOGAN, UTAH, USA.
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CREDIT: USU/M. MUFFOLETTO

LOGAN, UTAH, USA -- Satellites encircling the Earth collect a bounty of water data about our planet, yet distilling usable information from these sources about our oceans, lakes, rivers and streams can be a challenge.

“Water managers need accurate data for water resource management tasks, including lake coastal zone monitoring, rising seas border shift detection and erosion monitoring,” says Utah State University computer scientist Pouya Hosseinzadeh. “But they face a trade-off when reviewing data from currently deployed satellites, which yield complementary data that are either of high spatial or high temporal resolutions. We’re trying to integrate the data to provide more accurate information.”

Varied data fusion approaches present limitations, including sensitivity to atmospheric disturbances and other climatic factors that can result in noise, outliers and missing data.

A proposed solution, say Hosseinzadeh, a doctoral student, and his faculty mentor Soukaina Filali Boubrahimi, is the Hydrological Generative Adversarial Network – known as Hydro-GAN. The scientists developed the Hydro-GAN model with USU colleagues Ashit Neema, Ayman Nassar and Shah Muhammad Hamdi, and describe this tool in the March 13, 2024, online issue of the American Geophysical Union journal Water Resources Research.

The team’s research is supported by the National Science Foundation.

Hydro-GAN, says Filali Boubrahimi, assistant professor in USU’s Department of Computer Science, is a novel machine learning-based method that maps the available satellite data at low resolution to a high-resolution data counterpart.

“In our paper, we describe integrating data collected by MODIS, a spectroradiometer aboard the Terra Earth Observing System satellite, and the Landsat 8 satellite, both of which have varied spatial and temporal resolutions,” she says. “We’re trying to bridge the gap by generating new data samples from images collected by these satellites that improve the resolution of the shape of water boundaries.”

The dataset used in this research consists of image data collected during a seven-year span (2015-2021) of 20 reservoirs in the United States, Australia, Mexico and other countries. The authors present a case study of Lake Tharthar, a salt water lake in Iraq, comparable in size to Great Salt Lake and facing similar climate and usage pressures.

“Using seven years of data from MODIS and Landsat 8, we evaluated our proposed Hydro-GAN model on Lake Tharthar’s shrinking and expansion behaviors,” Hosseinzadeh says. “Using Hydro-GAN, we were able to improve our predictions about the lake’s changing area.”

Such information is critical for the region’s hydrologists and environmental scientists, he says, who need to monitor seasonal dynamics and make decisions about how to sustain the lake’s water supply.

The scientists demonstrate Hydro-GAN can generate high-resolution data at historical time steps, which is otherwise unavailable, for situations where a large amount of historical data is needed for accurate forecasting.

“We think this will be a valuable tool for water managers and, moving forward with similar models, we can employ a multi-modal approach to provide data in addition to images, including information about topology, snow data amounts, streamflow, precipitation, temperature and other climate variables,” says Hosseinzadeh, who presents the research during USU’s 2024 Spring Runoff Conference March 26-27 at the Cache County Fairgrounds and Utah State’s Logan campus.

JOURNAL

Water Resources Research

DOI

10.1029/2023WR036342

METHOD OF RESEARCH

Computational simulation/modeling

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Spatiotemporal Data Augmentation of MODIS-Landsat Water Bodies using Adversarial Networks

Estimating coastal water depth from space via satellite-derived bathymetry

Researchers test a novel machine learning-based depth estimation technique on Korean coastal regions with unique characteristics

SPIE--INTERNATIONAL SOCIETY FOR OPTICS AND PHOTONICS

JARS-230615 920x450 — IMAGE:
THE PROPOSED SATELLITE DATA-BASED MODEL PROVIDED COASTAL DEPTH ESTIMATIONS FOR THREE KOREAN COASTAL AREAS WITH UNIQUE CHARACTERISTICS: CHEONSUMAN (A), HALLIM (B), AND SAMCHEOK (C).
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CREDIT: THE AUTHORS DOI: 10.1117/ 1.JRS.18.014522

Since ancient times, knowing the depth of coastal waters has been key to safe and successful navigation and to exploit the sea’s resources. Today, bathymetry—the measurement of sea depth—is even more important, playing essential roles in our understanding of marine environments and the development of large marine structures.

With the development of shipborne echo sounders in the early 20th century, bathymetric surveys saw massive leaps in both accuracy and convenience. However, even with modern echo sounders, there are still many hardships to overcome when conducting bathymetric surveys. These include high cost, unpredictable weather, high ship traffic, and potential geographic or diplomatic issues, to name a few.

To address these issues, scientists around the world have been developing satellite-derived bathymetry (SDB) techniques, which estimate water depth from multispectral satellite images. These methods can sometimes produce accurate results, especially for depths up to 20 meters. Unfortunately, most SDB models were developed using data from coastal regions with clear waters and a uniform distribution of seabed sediment. Since light reflects differently depending on water turbidity and the composition of the seabed, developing SBD models with consistent performance throughout different coastal environments has proven challenging.

Against this backdrop, a research team from Korea has been developing a new SDB model that leverages machine learning to shed light onto the various factors that can compromise accuracy, thus paving the way to potential solutions. Their latest study, which included Dr. Tae-ho Kim from Underwater Survey Technology 21 (UST21), was published in the Journal of Applied Remote Sensing on March 12, 2024.

One of the main goals of this study was to analyze how the model trained on different coastal regions would be affected by each region’s unique characteristics. To this end, they selected three areas around the Korean Peninsula: Samcheok, characterized by its clear waters, Cheonsuman, known for its turbid waters, and Hallim, where the seabed contains various types of sediments.

The team obtained multispectral satellite data of these regions from the Sentinel-2A/B missions, openly provided by the European Space Agency, and selected multiple images of these areas at different time points with clear skies. To train the SDB model on these data, they also acquired echo sounder-derived nautical charts from the Korea Hydrographic and Oceanographic Agency (KHOA); these charts were used as ground truth.

The SDB model itself was based on a well-established theoretical framework that links how light coming from the Sun is reflected by the atmosphere, the sea, and the seabed before reaching a satellite. As for the machine learning part of the model, the team employed a random forest algorithm because of its ability to adjust to multiple variables and parameters while handling large amounts of data.

Upon training and testing region-specific instances of the SDB model, the researchers found that accuracy was generally acceptable for Samcheok, with a root-mean-squared error of about 2.6 meters. In contrast, accuracy was markedly lower for both Cheonsuman and Hallim, with satellite-based depth predictions deviating significantly from KHOA measurements.

To understand these discrepancies better, the researchers first tried correcting the predictions by including a turbidity index in the calculations. This improved results mainly for Cheonsuman. Then, to further investigate the sources of error, the team acquired high-resolution satellite images from the WorldView-3 mission, as well as on-site photos. Analyses revealed the reflectance characteristics of the seabed sediments had a large impact on depth estimations, with dark-colored basalt leading to a consistent overestimation. “If we incorporate additional seabed spatial data into the training dataset in the future, we anticipate enhancements in model performance,” said Dr. Kim. “A sediment distribution map, created from airborne hyperspectral imaging, is scheduled to be provided by R&D project.”

Finally, the researchers then tested the generalization capability of their approach by applying region-specific SDB models on other coastal areas with similar characteristics. “Unlike previous studies that presented SDB model results for waters with high transparency only, we developed individual SDB models that can be applied to waters with various characteristics, and suggested methods for obtaining improved results,” Dr. Kim said.

With any luck, these efforts will lead to improvements in SDB technology and pave the way for more convenient coastal depth mapping. Satisfied with the results, Dr. Kim concludes: “Ultimately, SDB results will be applied as depth monitoring data to facilitate safe ship passage in coastal areas, as well as input data for numerical ocean models, contributing to various scientific fields.”

Read the Gold Open Access paper by Jae-yeop Kwon et al., “Estimation of shallow bathymetry using Sentinel-2 satellite data and random forest machine learning: a case study for Cheonsuman, Hallim, and Samcheok Coastal Seas,” J. App. Rem. Sens. 18(1) 014522 (2024) doi 10.1117/1.JRS.18.014522.

JOURNAL

Journal of Applied Remote Sensing

DOI

10.1117/1.JRS.18.014522

METHOD OF RESEARCH

Observational study

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Estimating coastal water depth from space via satellite-derived bathymetry

ARTICLE PUBLICATION DATE

21-Mar-2024

Satellite data assimilation improves forecasts of severe weather

PENN STATE

Images of the 2020 Midwest Derecho — IMAGE:
CLOCKWISE FROM TOP LEFT: IMAGES OF THE 2020 MIDWEST DERECHO FROM RADAR AND MICROWAVE SATELLITE OBSERVATIONS SHOW SIMILAR PATTERNS, WHICH ARE OBSCURED IN INFRARED BRIGHTNESS SATELLITE OBSERVATIONS. A TECHNIQUE TO COMBINE MICROWAVE AND INFRARED SATELLITE OBSERVATIONS COULD IMPROVE FORECASTS OF SEVERE WEATHER, AND MAY BE ESPECIALLY USEFUL IN AREAS THAT LACK GROUND-BASED WEATHER MONITORING RADAR NETWORKS, THE SCIENTISTS SAID.
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CREDIT: PROVIDED BY YUNJI ZHANG

UNIVERSITY PARK, Pa. — In 2020, a line of severe thunderstorms unleashed powerful winds that caused billions in damages across the Midwest United States. A technique developed by Penn State scientists that incorporates satellite data could improve forecasts — including where the most powerful winds will occur — for similar severe weather events.

The researchers reported in the journal Geophysical Research Letters that adding microwave data collected by low-Earth-orbiting satellites to existing computer weather forecast models produced more accurate forecasts of surface gusts in a case study of the 2020 Midwest Derecho. Derechos are lines of intense thunderstorms notorious for their damaging winds.

“The computer model is able to produce a series of forecasts that consistently emphasize the most powerful storms and strongest wind damage at where it happened,” said Yunji Zhang, assistant professor in the Department of Meteorology and Atmospheric Science at Penn State and lead author. “If we have this kind of information in real time, before the events occur, forecasters might be able to pinpoint where the strongest damage is going to happen.”

The technique could be especially useful, the scientists said, in areas that lack ground-based weather monitoring infrastructure — like radars traditionally used in weather forecasting. In the study, the researchers only used data available from satellite observations.

“In regions where there are no surface observations, or basically no radar, we show that this combination of satellite observations can generate a decent forecast of severe weather events,” Zhang said. “We can probably apply this technique to more regions where there are no radar or dense surface observations. That’s the fundamental motivation behind this study.”

The research builds on the team’s prior work using data assimilation, a statistical method that aims to paint the most accurate picture of current weather conditions. This includes even small changes in the atmosphere as they can lead to large discrepancies in forecasts over time.

In prior work, scientists with Penn State’s Center for Advanced Data Assimilation and Predictability Techniques assimilated infrared brightness temperature data from the U.S. Geostationary Operational Environmental Satellite, GOES-16. Brightness temperatures show how much radiation is emitted by objects on Earth and in the atmosphere, and the scientists used infrared brightness temperatures at different frequencies to paint a better picture of atmospheric water vapor and cloud formation.

But infrared sensors only capture what is happening at the cloud tops.

Microwave sensors view an entire vertical column, offering new insight into what is happening underneath clouds after storms have formed, the scientists said.

“Just based on the cloud tops, it’s more difficult to infer what the convection of these storms looks like underneath,” Zhang said. “So that’s one of the benefits of adding in the microwave observations — they can provide information on where the strongest convections are.”

By combining assimilated infrared and microwave data in the study of the derecho, the researchers were able to predict surface gust locations and maximum wind values more accurately.

In future work, Zhang said he plans to apply the method to regions that lack the resources and infrastructure to support high-spatiotemporal-resolution weather observations.

“We know that there have been several times in the past several years in West Africa where very strong torrential rainfall events have brought on a lot of precipitation to those countries,” Zhang said. “And one thing about these countries is that they are also the places that will likely be impacted most by global warming. So I think if we can use these available satellite observations to provide better forecast for those regions, it will be really beneficial for the people there as well.”

Also contributing from Penn State were David Stensrud and Eugene Clothiaux, professors, and Xingchao Chen, assistant professor, all in the Department of Meteorology and Atmospheric Science.

NASA and the U.S. Department of Energy provided funding for this work.

JOURNAL

Geophysical Research Letters

DOI

10.1029/2023GL106602

METHOD OF RESEARCH

Computational simulation/modeling

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Enhancing Severe Weather Prediction With Microwave All-Sky Radiance Assimilation: The 10 August 2020 Midwest Derecho

ARTICLE PUBLICATION DATE

22-Mar-2024

Best way to bust deepfakes? Use AI to find real signs of life, say Klick Labs scientists

Researchers identify audio deepfakes with new algorithm and vocal biomarkers

KLICK APPLIED SCIENCES

NEW YORK, NY / TORONTO, ON – March, 21, 2024 – Artificial intelligence may make it difficult for even the most discerning ears to detect deepfake voices – as recently evidenced in the fake Joe Biden robocall and the bogus Taylor Swift cookware ad on Meta – but scientists at Klick Labs say the best approach might actually come down to using AI to look for what makes us human.

Inspired by their clinical studies using vocal biomarkers to help enhance health outcomes, and their fascination with sci-fi films like “Blade Runner,” the Klick researchers created an audio deepfake detection method that taps into signs of life, such as breathing patterns and micropauses in speech.

“Our findings highlight the potential to use vocal biomarkers as a novel approach to flagging deepfakes because they lack the telltale signs of life inherent in authentic content,” said Yan Fossat, senior vice president of Klick Labs and principal investigator of the study. “These signs are usually undetectable to the human ear, but are now discernible thanks to machine learning and vocal biomarkers.”

‘Investigation of Deepfake Voice Detection using Speech Pause Patterns: Algorithm Development and Validation,’ published today in the open-access journal JMIR Biomedical Engineering, describes how vocal biomarkers, along with machine learning, can be used to distinguish between deepfakes and authentic audio with reliable precision. As part of the study, Fossat and his team at Klick Labs looked at 49 participants from diverse backgrounds and accents. Deepfake models were then trained on voice samples provided by the participants, and deepfake audio samples were generated for each person. After analyzing speech pause metrics, the scientists discovered their models could distinguish between the real and fakes with approximately 80 percent accuracy.

These findings follow recent high-profile voice cloning scams, Meta’s announced plan to introduce AI-generated content labels, and the Federal Communications Commission’s February ruling to make deepfake voices in robocalls illegal. In December, a PBS NewsHour report cited public policy and AI experts’ concerns that deepfake usage will increase with the upcoming U.S. presidential election.

While the new study offers one solution to this growing problem, Fossat acknowledged the need to keep evolving detection technology as deepfakes become more and more realistic.

Today’s news highlights Klick’s ongoing work in vocal biomarkers and AI. In October, it announced groundbreaking research in Mayo Clinic Proceedings: Digital Health around the AI model it created to detect Type 2 diabetes using 10 seconds of voice.

About Klick Applied Sciences (including Klick Labs)

Klick Applied Sciences’ diverse team of data scientists, engineers, and biological scientists conducts scientific research and develops AI/ML and software solutions as part of the company’s work to support commercial efforts using its proven business, scientific, medical, and technological expertise. Its 2019 Voice Assistants Medical Name Comprehension study laid the scientific foundation for rigorously testing voice assistant consumer devices in a controlled manner. Klick Applied Sciences is part of the Klick Group of companies, which also includes Klick Health (including Klick Katalyst and btwelve), Klick Media Group, Klick Consulting, Klick Ventures, and Sensei Labs. Established in 1997, Klick has offices in New York, Philadelphia, Toronto, London, São Paulo, and Singapore. Klick has consistently been ranked a Best Managed Company, Great Place to Work, Best Workplace for Women, Best Workplace for Inclusion, Best Workplace for Professional Services, and Most Admired Corporate Culture.

For more information, or a copy of the abstract, please contact Klick PR at pr@klick.com or 416-214-4977.

Kulangareth NV, Kaufman J, Oreskovic J, Fossat Y

Investigation of Deepfake Voice Detection Using Speech Pause Patterns: Algorithm Development and Validation

JMIR Biomed Eng 2024;9:e56245

URL: https://biomedeng.jmir.org/2024/1/e56245/

doi: 10.2196/56245

JOURNAL

JMIR Biomedical Engineering

DOI

10.2196/56245

METHOD OF RESEARCH

Data/statistical analysis

SUBJECT OF RESEARCH

People

ARTICLE TITLE

Investigation of Deepfake Voice Detection Using Speech Pause Patterns: Algorithm Development and Validation

ARTICLE PUBLICATION DATE

21-Mar-2024

International graduate and postdoctoral trainees in biomedicine are struggling with career confidence, study says

Peer-Reviewed Publication

UNIVERSITY OF NORTH CAROLINA HEALTH CARE

Self-Efficacy Graph — IMAGE:
MAIN EFFECTS OF CITIZENSHIP AND GENDER ON TRAINEE CAREER SELF-EFFICACY.
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CREDIT: CHATTERJEE ET AL (2024)

Chapel Hill, NC – Biomedical programs in the United States attract a significant number of graduate and postdoctoral trainees from around the world. Non-citizen trainees face several systemic barriers that negatively affect their confidence in their careers and ability to take charge of their career decisions, termed career self-efficacy.

Using national data from 6,000 respondents across 17 institutions, a new study in PLOS ONE found that citizenship status and gender were associated with different levels of career self-efficacy. Most notably, international and female trainees reported lower career-self-efficacy across the national sample.

Rebekah L. Layton, PhD, director of professional development programs in the Office of Graduate Education (OGE) at the UNC School of Medicine, and Ana T. Nogueira, PhD, an education research scholar and postdoctoral research fellow in the UNC Department of Pharmacology, co-led the study on this multi-institutional team.

“The challenges addressed resonate deeply with my experiences as an international woman in the United States,” said Nogueira, who is also a former education research fellow in the OGE and co-first author on the study. “The study highlights how much barriers limit and impact international trainees and their own perceived and actual career options, depending on visa status, lived experience, and access to professional development support.”

Deepshikha Chatterjee, PhD, assistant professor of psychology at Baruch College and the Graduate Center at the City University of New York, and Sunita Chaudhary, PhD, associate professor at Rutgers Robert Wood Johnson Medical School and director of research education at Rutgers Cancer Institute of New Jersey, co-led the study as well.

Chaudhary echoes the sentiments of many others on the research team who, at some point in their careers, worked as international trainees in the United States.

“The findings of this study resonate with my lived experience as a brown woman who immigrated to United States for my own PhD degree,” said Chaudhary, who as co-senior author on the study.

Systemic barriers, such as complex visa regulations, significantly limit the opportunities of non-citizen trainees. Visas can also restrict where non-citizen trainees intern or work off-campus. During the COVID-19 pandemic, for example, the United States government issued a policy that international students must leave the country if all their classes had been moved online.

“I hope this work inspires urgent conversations around the precarious conditions facing our talented and highly skilled trainees due to a US immigration system that creates barriers and disparities which marginalize our human capital and limit potential,” said Chatterjee, who was co-first author on the study.

“This study sheds light on how immigration status intersects with individuals’ perceptions of their own capabilities, influencing their career trajectories and opportunities for advancement,” added Christiann Gaines, PhD, assistant director of doctoral success in the OGE. “Visa restrictions, cultural adaptation, and limited access to resources, can significantly impact trainees’ confidence in navigating career paths within the biomedical field.”

In addition to assessing how trainees’ race and citizenship relate to career-efficacy, the current study also examined how these factors relate to their pursuit of research-intensive principal investigator-focused careers. Researchers found that trainees that are on the principal investigator career pathway had higher self-efficacy compared to trainees displaying diverse career interests.

Additionally, trainees who reported higher career self-efficacy felt more supported by their graduate program and/or department. Layton says that these results will help draw attention to the specific needs of the international trainee community within graduate and postdoctoral training, with a renewed focus on the value of offering tailored opportunities for career and professional development.

“Our work suggests that different career pathways, citizenship status, and gender combinations could benefit from tailored programming to address needs that may not currently be met, based on data from across the country,” said Layton.

This study represents another step in the right direction. By recognizing and addressing these intersecting factors, researchers and graduate educators will be able to work towards creating more inclusive environments and pathways for all aspiring scientists, regardless of their background or citizenship status. It is equally important to keep engaging in discussions and resolving obstacles that students face when trying to further their education, training, and career development.

“Understanding the barriers, and then providing a means for quantifying how these barriers affect learning, allow us to continue creating interventions and programs that have the potential to increase student support and success, no matter where they are from,” said Nisan M. Hubbard, PhD, who was a former UNC SPIRE Fellow and co-author on the paper.

The author team looks forward to continuing to explore factors that impact career success for biomedical graduate students and postdoctoral scholars. Read more about companion paper on career self-efficacy in underrepresented biomedical scientists at: https://news.unchealthcare.org/2023/03/researchers-examine-career-confidence-in-underrepresented-biomedical-scientist-trainees/.

This paper extends from Layton’s NIH R01 SCISIPBIO project on graduate education, training, and biomedical workforce development. The team’s ongoing work can be found at the UNC’s PhD Integrated Research on Education and Career Training Lab (PhDIRECT).

JOURNAL

PLoS ONE

DOI

10.1371/journal.pone.0296246

ARTICLE TITLE

Citizenship status and career self-efficacy: An intersectional study of biomedical trainees in the United States

ARTICLE PUBLICATION DATE

20-Mar-2024

The next antioxidant superfood? Canadian sea buckthorn berries offer diabetes and obesity potential

Peer-Reviewed Publication

SOCIETY OF CHEMICAL INDUSTRY

Renan Danielski, co-author of the study with powdered sea buckthorn berries — IMAGE:
RENAN DANIELSKI, CO-AUTHOR OF THE STUDY WITH POWDERED SEA BUCKTHORN BERRIES
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CREDIT: RENAN DANIELSKI, MEMORIAL UNIVERSITY OF NEWFOUNDLAND

New research, published in SCI’s Journal of the Science of Food and Agriculture illuminates the untapped potential of the shrub sea buckthorn as a rich source of natural antioxidants in North America.

The study, which was carried out by researchers at the Memorial University of Newfoundland in Canada and led by Professor Fereidoon Shahidi, outlines the unique nutritional profile of sea buckthorn berries grown in Canada and highlights their commercial potential as a bioactive-loaded superfood.

Sea buckthorn is a deciduous, thorny plant found along the coasts of northwestern Europe as well as temperate regions of central Asia. Its berries and leaves are widely used for their nutritional, pharmaceutical and functional properties – sea buckthorn oil is rich in omega-3 and omega-6 fatty acids, vitamins E, B, and A and polyphenols.

In Canada, the plant was introduced in the early 2000s following research by governmental agencies on the crop's commercial potential. As Renan Danielski, a PhD student at the University of Newfoundland and author on the study explains, ‘Sea buckthorn is a unique crop with vast potential for utilisation. Popular in Asia and North-Western Europe, there is an opportunity to replicate this success in North America by leveraging the unique qualities of locally grown varieties.’

Motivated by the experimental status and limited commercialisation of sea buckthorn in North America to date, the researchers set out to characterise the unique composition of polyphenols, a class of compounds with antioxidative properties, in Canadian cultivars.

‘Understanding how our cultivar compares globally can help communicate the benefits to consumers and establish a market presence,’ notes Fereidoon Shahidi, Professor of Biochemistry at Memorial University of Newfoundland and corresponding author of the study.

The study's findings highlight the presence of key polyphenolic compounds in sea buckthorn pomace and seeds, each boasting potential health benefits ranging from cardiovascular protection to anti-inflammatory properties. Importantly, geographical factors influence the polyphenolic profile of sea buckthorn berries, with the researchers identifying several distinct compounds with enhanced bioactivity which are only contained in the sea buckthorn cultivar grown in Newfoundland.

Moreover, the sea buckthorn extracts demonstrated promising in vitro antidiabetic and anti-obesity potential, paving the way for further investigation into their mechanisms and potential therapeutic applications.

‘This is a first step in understanding how sea buckthorn polyphenols can modulate our physiology in a beneficial manner. Future research needs to focus on understanding the mechanisms behind those effects and further experimentation using animal models and humans. If these effects are confirmed in vivo, we can envision the use of sea buckthorn polyphenols for therapeutic and pharmacological purposes, aiding in the prevention and treatment of diabetes, obesity, and many other conditions,’ remarked Danielski.

The findings of this study pave the way for harnessing sea buckthorn berries as a valuable source of natural antioxidants in North America. As consumer interest in functional foods and “nutraceuticals” continues to grow, sea buckthorn presents itself as a sustainable and health-enhancing option.

JOURNAL

Journal of the Science of Food and Agriculture

DOI

10.1002/jsfa.13386

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Phenolic composition and bioactivities of sea buckthorn (Hippophae rhamnoides L.) fruit and seeds: an unconventional source of natural antioxidants in North America

University of Calgary research finds a direct communication path between the lungs and the brain

Findings show that communication can alter the way the brain functions and the way someone behaves

UNIVERSITY OF CALGARY

University of Calgary researchers have discovered the lungs communicate directly with the brain when there is an infection. Findings show the brain plays a critical role in triggering the symptoms of sickness, which may change the way we treat respiratory infections and chronic conditions.

“The lungs are using the same sensors and neurons in the pain pathway to let the brain know there’s an infection,” says Dr. Bryan Yipp, MD '05, MSc'05, clinician researcher at the Cumming School of Medicine and senior author on the study. “The brain prompts the symptoms associated with sickness; that overall feeling of being unwell, feeling tired and loosing your appetite. The discovery indicates we may have to treat the nervous system as well as the infection.”

Prior to this study, conducted in mice, it was thought infections in the lungs and pneumonia induce inflammatory molecules that eventually made their way to the brain through the blood stream. Sickness was thought to be a consequence of the immune system kicking into action. However, findings reveal that sickness results from nervous system activation in the lung.

Understanding the lung-brain dialogue is important for treatment because bacteria that cause lung infections can produce a biofilm, a coating to surround themselves so the nervous system can’t see them. That allows the bug to hide out in the lungs for a long time, which may shed light across diverse serious lung infections that are less symptomatic. For example, an unexplained anomaly Yipp witnessed in the intensive care unit (ICU) during COVID. The phenomenon, coined “happy hypoxia”, was being recorded in ICUs throughout the world.

“We would have patients whose oxygen levels were extremely low and x-rays confirmed they may need to be put on life support. Yet, when I went to see the patient, they would say I feel fine,” says Yipp. “These people were experiencing limited sickness symptoms even though the virus was aggressively damaging their lungs.”

Yipp says understanding the lung brain communication pathways may also have broad implications for people with chronic lung infections like cystic fibrosis (CF). Many people with CF have a biofilm bacterium in their lungs and are asymptomatic. They feel okay, but then have a flare where they can become very ill. The reason for the flare can’t always be traced.

"It is possible the flare is also neurological that these people live asymptomatically because bacteria are hiding out,” says Yipp.

The findings, published in Cell, are the work of an interdisciplinary team including experts in neurobiology, microbiology, immunology, and infectious disease.

“Physician specialties are usually based on individual organs, with pulmonologists caring for the lungs and neurologists caring for the brain. Our study shows the lung is altering the brain and the brain is altering the organ. This intersection of communication is a different way of thinking about disease,” says Yipp. “It’s all connected to the brain and there are probably even more complex circuits that are happening. We can now think about targeting neurocircuitry along with antibiotics to deal with infections and the sickness they cause.”

University of Calgary researchers Drs. Christophe Altier, PhD, Joe Harrison, PhD, and Deborah Kurrasch, PhD, along with Dr. Jaideep Bains, PhD, Krembil Research Institute, Toronto, are corresponding authors on the study.

The researchers add there was one more unique finding. Male mice were much sicker than the females even though they had the same bacterial infection. Researchers found that male sickness was more dependent on neuronal communications then females. Yipp says this finding could lend credibility to the so-called “man flu”, a colloquial term where men are thought to wildly exaggerate sickness due to respiratory infections. Turns out they may not be exaggerating, after all.

"It is possible the flare is also neurological that these people live asymptomatically because bacteria are hiding out,” says Yipp.

The findings, published in Cell, are the work of an interdisciplinary team including experts in neurobiology, microbiology, immunology, and infectious disease.

JOURNAL

Cell

DOI

10.1016/j.cell.2024.03.001

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Animals

ARTICLE TITLE

Biofilm exopolysaccharides alter sensory-neuron-mediated sickness during lung infection

ARTICLE PUBLICATION DATE

21-Mar-2024

Species diversity promotes ecosystem stability

Biodiversity loss may accelerate ecosystem destabilization

MCGILL UNIVERSITY

Diversity in coral reef — IMAGE:
FROM TROPICAL RAINFORESTS TO CORAL REEFS, SOME OF EARTH’S MOST DIVERSE ECOSYSTEMS ARE ALSO THE MOST STABLE. THIS STAGGERING DIVERSITY STANDS IN OPPOSITION TO ECOLOGICAL THEORY, WHICH FOR DECADES HAS PREDICTED THAT DIVERSITY BEGETS INSTABILITY. BY USING A DIFFERENT APPROACH TO MODELLING SPECIES GROWTH, BASED ON EXTENSIVE DATA, THE RESEARCH SUGGESTS THAT ALTHOUGH ALL SPECIES IN ECOSYSTEMS INITIALLY GROW EXPONENTIALLY, THIS GROWTH EVENTUALLY SLOWS, CREATING A BALANCED ECOSYSTEM. [
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CREDIT: PHOTOS: RHETT BUTLER AND MAX PLANCK INSTITUTE

Species diversity promotes ecosystem stability

Biodiversity loss may accelerate ecosystem destabilization

What maintains stability within an ecosystem and prevents a single best competitor from displacing other species from a community? Does ecosystem stability depend upon the presence of a wide variety of species, as early ecologists believed, or does diversity do the exact opposite, and lead to instability, as modern theory predicts?

Resolving a long-standing debate among ecologists

A new study from McGill University and the Max Planck Institute and published recently in Science suggests an answer to this question that has been a subject of debate among ecologists for half a century.

The researchers approached the question of population growth using a model that, so far, had not been used in this context – though it aligns with conventional wisdom and the way that people have traditionally modelled individual growth (from birth to maturity).

The researchers used data about population abundance, growth and biomass from a variety of species – including insects, fish and mammals – from across the globe, collected over the past 60 years. Their results, based on extensive analysis, suggests that, contrary to contemporary ecological theory, species diversity leads to ecosystem stability, as early ecologists had believed.

Growth in populations slows with density

“While nearly all prior theory assumes that populations grow exponentially, there is growing evidence that species actually follow a slightly different course, one in which exponential growth continuously slows down. It’s a bit like the law of diminishing returns in economics.” says Ian Hatton, a research associate in the Department of Earth and Planetary Sciences, at McGill University and the corresponding author on the paper.

“What’s amazing is that such a small difference in population growth can have such a large effect on community interactions, completely reversing the predictions from decades of theory.”

Dangers of disturbing the balance

Their findings raise alarming questions about the potential large-scale impacts of biodiversity loss.

“This research is becoming increasingly urgent given the current rates of species extinction and loss of biodiversity,” says Hatton. “In addition to better aligning theory with data, the model makes an unsettling prediction: losses in biodiversity can further destabilize an ecosystem and prevent them from recovering after a disturbance.”

The study:

“Diversity begets stability: sublinear growth and competitive coexistence across ecosystems” by I. Hatton et al was published in Science

DOI: 10.1126/science.adg8488

JOURNAL

Science

DOI

10.1126/science.adg8488

METHOD OF RESEARCH

Meta-analysis

SUBJECT OF RESEARCH

Animals

ARTICLE TITLE

Diversity begets stability: sublinear growth and competitive coexistence across ecosystems