Western biologists solve long-held mystery of how crickets sing

Researchers reconstruct crickets’ call using computational modelling, preserved crickets

University of Western Ontario

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A composite image showing the pattern of vibrations experienced by the forewing of a living cricket at its song frequency (wing on the right) and the predictions of a physics based model of the same pattern (wing on the left). 

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Credit: (Natasha Mhatre)

Western biologists solve long-held mystery of how crickets sing

Researchers reconstruct crickets’ call using computational modelling, preserved crickets

Western University researchers have developed an innovative way to reconstruct how crickets sing, based on the physical formation of the chirping insects’ wings, using measurements from preserved samples and computational modelling.

The new best practices, published July 30 in Royal Society Open Science, were devised by Western biology professor Natasha Mhatre, Canada Research Chair in invertebrate neurobiology, and three former undergraduate students in her lab, which investigates the biophysics of insect and spider communication.  

In the new study, Mhatre and her collaborators detail a new computer modelling method that adheres more closely to a cricket’s actual physical characteristics than previous attempts. The new model can predict the precise vibration patterns of cricket wings even those of new wings that the model was not based on.  

Scientists, like Mhatre, often use preserved specimens for a deeper understanding of evolutionary history and genetics. But recreating how extinct or dead birds and mammals, including humans, once sounded is complex. Both communicate using a vocal tract, intricately controlled by the brain. But both structures are made of soft tissue, which rarely fossilizes or leaves a trace. Crickets, however, sing a different tune – literally and figuratively.

Cricket songs are not a vocalization at all but are created by vibrational mechanics within their forewings. These tough, leathery wings, located in front of the hindwings, act as protective shields for crickets. They also house specialized, hardened microstructures needed for chirping. (Their hardness means forewings preserve well as fossils or museum specimens.) Most importantly, the venation pattern, or arrangement of veins, within the cricket forewing determines its song frequency or pitch.

“Each cricket wing has a pattern of veins running through it, which are structurally critical to making songs,” said Mhatre, a professor in Western’s Faculty of Science. “Some of these veins are used to generate the forces that make the wing vibrate and make sounds. Others stiffen local areas within the wing and develop the resonant structures that vibrate at specific frequencies.”

What’s the frequency, cricket?

For years, Mhatre and others in the global neurobiology research community have attempted to use bioacoustics (sound produced by living organisms) and finite element modeling (a method for numerically solving differential equations) to understand cricket song with a primary goal of predicting wing vibration and sound production. Thousands of cricket wings are preserved in museums and their evolutionary relationships are clearly mapped out, making this tactic for predicting their sounds a perfect pathway to unlock the mysteries of signal evolution and how some of the first sounds on earth sounded.

In fact, Mhatre and her collaborators thought they had cracked the code in 2012 in a game-changing study published in PNAS, in which they used some simple assumptions to develop computational models for cricket wings.

“There is a high density of veins in cricket forewings, so we considered these parts of the wing effectively immobile in our model. And this approach has stuck around for more than a decade,” said Mhatre. “But something about this approach has always bugged me.”

The issue with earlier studies, including the 2012 PNAS paper, is that the modelled cricket wings were ‘clamped’ at points with a high density of veins and not just at the base, as wings are hinged in nature. This simplified the study but technically, these parts of the wing are free to move, so the computer model wasn’t a direct representation.

“We also don’t really have an objective means of deciding what a ‘high density’ really means, in terms of veins in a cricket wing, which is a problem if you start with a new cricket with different wing venation whose wings you have never measured before,” said Mhatre. 

In the new study, Mhatre and her collaborators developed a computer modelling method that adhered more closely to the cricket’s actual physical characteristics and clamped the wings as they should be.

The new model, based on Teleogryllus oceanicus (commonly known as the Australian, Pacific or oceanic field cricket). is now able to predict the precise vibration patterns of cricket forewings without simplifying assumptions. It can even predict the behaviour of new wings that it was not specially designed or tuned for.

The authors then tackled another method used for reconstructing cricket song, which was the use of preserved specimens. They showed that a dry-preserved cricket forewing, such as a museum specimen, would have very similar vibrational pattern as a live cricket but it would resonate at the wrong frequency. This is because the wing material hardens as it dries. They found that the correct frequency could be recovered, however, simply by wetting the wing with water or reducing this stiffness artificially in a computer model.

“We’ve developed a more reliable way of dealing with reconstructing cricket acoustic function from morphology, using computational modelling and preserved specimens,” said Mhatre.

Mhatre collaborated with co-author Nathan Bailey from the University of St. Andrews on this new model, research that dates back to the beginning of the COVID-19 pandemic. The long-time collaborators were joined by three of Mhatre’s then-undergraduate thesis students, Sarah Duke, Ryan Weiner and Gabriella Simonelli, who are all co-authors on the study.

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Journal

Royal Society Open Science

DOI

10.1098/rsos.251005 

Method of Research

Computational simulation/modeling

Subject of Research

Animals

Article Title

Reliable reconstruction of cricket song from biophysical models and preserved specimens

Article Publication Date

30-Jul-2025

 Study reveals mixed impact of state e-cigarette flavor bans on tobacco use

Mass General Brigham

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A new study by investigators from Mass General Brigham examined the effects of policies banning flavored e-cigarettes on adults and young people. Investigators found that e-cigarette use significantly declined among young adults and adults in states that had enacted flavor bans relative to states that did not. However, declines in cigarette smoking also slowed in those states with flavor bans relative to other states—a potential unintended consequence of the bans. Results are published in JAMA Network Open.

“Both e-cigarettes and combustible cigarettes are essentially a source of nicotine for people who may have nicotine dependencies,” said Douglas Levy, PhD, Director of Policy Research at the Tobacco Research & Treatment Center at Massachusetts General Hospital, a founding member of the Mass General Brigham healthcare system. “We're trying to solve the problem of youth vaping, but we need to carefully consider impacts on more harmful combustible cigarette use.”

Flavored e-cigarettes are extremely popular among teens and young adults, raising public health concerns due to the addictive nicotine they contain. To reduce youth vaping, states including Massachusetts, New Jersey, New York, Rhode Island, Maryland and Utah banned the sale of flavored e-cigarettes, with many policies going into place in 2020. Levy, and other researchers at Mass General Brigham evaluated how those laws have influenced e-cigarette and cigarette use in youths and adults.

 

The study, led by first author David Cheng, PhD, used data from large-scale surveys administered in 50 states and D.C. from 2019 to 2023, tracking changes in the prevalence of tobacco use before (2019) and after (2020-2023) six states introduced flavor bans. Significant decreases in e-cigarette use among young adults ages 18–24 and adults over 25 were found in states with flavor bans relative to trends from other states without the bans. However, increases in cigarette smoking were also found among teenagers and young adults in those same states relative to other states.

 

Other key stats from the study:

• Among young adults (ages 18–24), e-cigarette use declined by 6.7 percentage points in policy states relative to other states in 2022.
• Among adults aged 25+, e-cigarette use declined by 1.2 percentage points in policy states relative to other states in 2023.
• From 2019 to 2023, youth e-cigarette use declined from 24.1% to 14.0% in policy states, compared to 24.6% to 17.2% in other states.

 

However, cigarette use declined less in states with flavor bans relative to other states:

• For example, in 2021:
  • Cigarette use among youths was 1.8 percentage points higher than expected in policy states.
  • Cigarette use among young adults was 3.7 percentage points higher than expected.

 

The associations between flavor bans and e-cigarette and cigarette use varied by state. Massachusetts saw consistent decreases in vaping associated with the bans across age groups, which could be due to the presence earlier local bans and stronger enforcement. Other states, such as Utah and Maryland, allowed certain exemptions (e.g., menthol flavors or specialty shops), which may have modified the impact of their bans.

 

One limitation of the study is that it was observational, meaning no experimental manipulation was involved, and unmeasured factors may have contributed to the findings. Additionally, these results reflect the initial experience of the first states to institute flavor restriction policies. The impact of restrictions may change over time for states with existing restrictions and states that newly institute restrictions.

 

The next step is to identify additional strategies that can curb youth nicotine use without slowing downward trends in cigarette smoking.

 

Authorship: In addition to Levy and Cheng, Mass General Brigham authors of the study include Abra M. Jeffers, Maeve Stover, Lindsay Kephart, Ginny Chadwick, A. Eden Evins, and Nancy A. Rigotti. Additional authors include Gina R. Kruse of the University of Colorado School of Medicine.

Disclosures: Cheng reported having a pending grant from AstraZeneca outside the submitted work. Kruse reported having family equity ownership in Dimagi, Inc and receiving grants from AstraZeneca administered by the National Comprehensive Cancer Network outside the submitted work. Rigotti reported receiving grants from Achieve Life Sciences, Inc paid to Massachusetts General Hospital and personal fees from Achieve Life Sciences, Inc ending in 2022 and UpToDate outside the submitted work.

Funding: This research was supported by the National Institute on Drug Abuse within the National Institutes of Health (grant R01DA054935).

Paper cited: Cheng, D. et al. “State E-Cigarette Flavor Restrictions and Tobacco Product Use in Youths and Adults.”  JAMA Network Open DOI: 10.1001/jamanetworkopen.2025.24184

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About Mass General Brigham

Mass General Brigham is an integrated academic health care system, uniting great minds to solve the hardest problems in medicine for our communities and the world. Mass General Brigham connects a full continuum of care across a system of academic medical centers, community and specialty hospitals, a health insurance plan, physician networks, community health centers, home care, and long-term care services. Mass General Brigham is a nonprofit organization committed to patient care, research, teaching, and service to the community. In addition, Mass General Brigham is one of the nation’s leading biomedical research organizations with several Harvard Medical School teaching hospitals. For more information, please visit massgeneralbrigham.org.

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Journal

JAMA Network Open

DOI

10.1001/jamanetworkopen.2025.24184 

Article Title

State E-Cigarette Flavor Restrictions and Tobacco Product Use in Youths and Adults

Article Publication Date

30-Jul-2025

 

Huge hidden flood bursts through the Greenland ice sheet surface

A huge flood triggered by the rapid draining of a lake beneath the Greenland ice sheet occurred with such force that it fractured the ice above and burst out across its surface.

Lancaster University

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A huge flood triggered by the rapid draining of a lake beneath the Greenland ice sheet occurred with such force that it fractured the ice above and burst out across its surface.

This phenomenon, observed for the first time in Greenland and detailed in research published today in the journal Nature Geoscience, sheds new light on the destructive potential of meltwater stored beneath the ice sheet.

It reveals how, under extreme conditions, water flooding underneath the ice can force its way upwards through the ice and escape at the ice sheet surface.

This phenomenon is not considered by numerical models that aim to predict the future evolution of the Greenland ice sheet, and this new work raises questions about whether this type of mechanism deserves greater attention in the future.

The international team of researchers led by scientists at Lancaster University’s Centre of Excellence in Environmental Data Science and The UK Centre for Polar Observation and Modelling, studied a previously undetected lake beneath the ice sheet (known as a subglacial lake) in a remote region of northern Greenland, using state-of-the-art satellite data and numerical models.

Using detailed three-dimensional representations of the ice sheet surface from the ArcticDEM project, alongside data from a number of European Space Agency (ESA) and NASA satellite missions, they monitored the sudden drainage of this lake.

The researchers discovered that over a period of 10 days in summer 2014, an 85 metre-deep crater appeared across a 2 km2 area in the ice surface, as 90 million cubic metres of water flooded out of the underlying lake.

This roughly equates to nine hours of water gushing over the Niagara Falls during its peak season, and represents one of the largest Greenland subglacial floods in recorded history.

However, what the researchers found further downstream was even more surprising.

In a region of previously unblemished ice, they observed the sudden appearance of an area the size of around 54 football pitches (385,000 square metres) of fractured and distorted ice; comprising deep cracks and 25 m high uprooted ice blocks, together with a freshly water-scoured ice surface  around twice the size of New York’s Central Park (six square kilometres).

Lead author Dr Jade Bowling, who led this work as part of her PhD at Lancaster University, said: “When we first saw this, because it was so unexpected, we thought there was an issue with our data. However, as we went deeper into our analysis, it became clear that what we were observing was the aftermath of a huge flood of water escaping from underneath the ice.

“The existence of subglacial lakes beneath the Greenland Ice Sheet is still a relatively recent discovery, and – as our study shows – there is still much we don’t know about how they evolve and how they can impact on the ice sheet system.

“Importantly, our work demonstrates the need to better understand how often they drain, and, critically, what the consequences are for the surrounding ice sheet.”

Although it had been previously assumed that meltwater flows from the surface to the base of the ice sheet, and then onwards to the ocean, this research provides clear evidence that water can also travel upwards, in the opposite direction.

It also surprised the scientists to find that the flood occurred in a region where models predicted that the ice was frozen at the bed, leading the researchers to propose a mechanism whereby pressure-driven fracturing of ice along the ice bed created a pathway for the water to then flow.

These mechanisms are not considered by the models that aim to simulate how the ice sheet might evolve in the future, as Earth’s climate warms and the ice sheets experience increasing rates of melting.

As such, these discoveries highlight the complexity of water flow, and the need to better understand how the ice sheet responds to extreme inputs of meltwater; something which is likely to become more common as our climate warms, and surface melting intensifies and expands into new areas.

Prof. Mal McMillan, Co-Director of the Centre of Excellence in Environmental Data Science at Lancaster University, and Co-Director of Science at the UK Centre for Polar Observation and Modelling, said: “This research demonstrates the unique value of long-term satellite measurements of Earth’s polar ice sheets, which – due to their vast size – would otherwise be impossible to monitor.

“Satellites represent an essential tool for monitoring the impacts of climate change, and provide critical information to build realistic models of how our planet may change in the future. “This is something that all of us depend upon for building societal resilience and mitigating the impacts of climate change.”

Dr Amber Leeson, Reader in Glaciology at Lancaster University and an expert in ice sheet hydrology said:

“What we have found in this study surprised us in many ways. It has taught us new and unexpected things about the way that ice sheets can respond to extreme inputs of surface meltwater, and emphasised the need to better understand the ice sheet’s complex hydrological system, both now and in the future.

“Given the control that subglacial hydrology has on the dynamics of the ice sheet, it is critical that we continue to improve our understanding of these hidden, and poorly understood, hydrological processes, and these satellite observations are key to that.”

This research, led by Jade Bowling, Malcolm McMillan and Amber Leeson (Lancaster University) is a collaboration between Lancaster University, the UK Centre for Polar Observation and Modelling (led from Northumbria University), The University of Sheffield, The Geological Survey of Denmark and Greenland, The University of Edinburgh, The University of Liege, Utrecht University, DTU Space (Technical University of Denmark), The University of California, Universite Grenoble, The University of Leeds, The Alfred Wegener Institute and The University of Bremen.

The research was primarily funded by the UK Natural Environment Research Council (NERC), the European Space Agency (ESA), and UK Research and Innovation (UKRI).

The research is detailed in the paper: 'Outburst of a subglacial flood from the surface of the Greenland Ice Sheet'.

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Journal

Nature Geoscience

DOI

10.1038/s41561-025-01746-9 

Method of Research

Data/statistical analysis

Subject of Research

Not applicable

Article Title

'Outburst of a subglacial flood from the surface of the Greenland Ice Sheet

Article Publication Date

30-Jul-2025

Scientists unlock nature’s 500-million-year-old colour secrets with nano-tech breakthrough

Trinity College Dublin

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Microscopic pixels can be fabricated using direct laser writing, demonstrating the ability to achieve wide gamut structural colours, and these can be combined into microscopic works of art (e.g. as in the hummingbird art example shown here).

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Credit: Prof. Colm Delaney, Trinity College Dublin and the AMBER Research Ireland Centre for Advanced Materials and BioEngineering Research.

Over 500 million years ago, nature evolved a remarkable trick: generating vibrant, shimmering colours via intricate, microscopic structures in feathers, wings and shells that reflect light in precise ways. This “structural colour” has continued to fascinate and perplex scientists—but now, researchers from Trinity College Dublin have taken a major step forward in harnessing it for advanced materials science.

A team, led by Professor Colm Delaney from Trinity’s School of Chemistry and AMBER, the Research Ireland Centre for Advanced Materials and BioEngineering Research, has developed a pioneering method, inspired by nature, to create and programme structural colours using a cutting-edge microfabrication technique. 

The work, which has been funded by a prestigious European Research Council (ERC) Starting Grant, could have major implications for environmental sensing, biomedical diagnostics, and photonic materials.

At the heart of the breakthrough is the precise control of nanosphere self-assembly—a notoriously difficult challenge in materials science. Teodora Faraone, a PhD Candidate at Trinity, used a specialised high-resolution 3D-printing technique to control the order and arrangement of nanospheres, allowing them to interact with light in ways that produce all the colours of the rainbow in a controlled manner.

“This was the central challenge of the ERC project,” said Prof. Delaney, who is en route to Purdue University to present the landmark findings at the MARSS conference on microscale and nanoscale manipulation. “We now have a way to fine-tune nanostructures to reflect brilliant, programmable colours.”

One of the most exciting aspects of the newly developed material is its extreme sensitivity: the structural colours shift in response to minute changes in their environment, which opens up new opportunities for chemical and biological sensing applications.

Dr Jing Qian, a postdoctoral researcher and computational specialist on the team, helped confirm the experimental results through detailed simulations, providing deeper insights into how the nanospheres organise themselves.

The team is already combining the colour-programming technique with responsive materials to develop tiny microsensors that change colour in real time. These sensors are being developed as part of the IV-Lab Project, a European Innovation Council Pathfinder Challenge led by the Italian Institute of Technology, with a key goal being the development of implantable devices capable of tracking biochemical changes inside the human body.

“Collaboration has been key to this discovery, as it has been the combination of chemistry, materials science, and physics that has ultimately enabled us to harness an ability that nature and its weird and wonderful creations have been perfecting for millions of years,” said Prof. Delaney, noting the contributions of fellow principal investigators at Trinity, Prof. Larisa Florea (School of Chemistry) and Prof. Louise Bradley (School of Physics).

“From ancient feathers to next-generation medical sensors, the future of colour is brighter—and smaller—than ever.”

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Journal

Advanced Materials

DOI

10.1002/adma.202504116 

 

Economic evaluation of wastewater surveillance for COVID-19 testing in long-term care settings

Early detection through wastewater surveillance could generate net benefits of $41 million in 4 weeks

Waseda University

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Researchers have proposed a warning system based on wastewater surveillance with incremental the economic and financial benefits

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Credit: Byung-Kwang Yoo, Waseda University and Kanagawa University of Human Services

The COVID-19 pandemic has placed enormous pressure on healthcare systems and economies around the world, with particularly severe impacts on vulnerable groups like residents of long-term care facilities (LTCFs). One key lesson from the pandemic is that early detection and treatment can lower hospitalization and death rates while also cutting medical costs. Wastewater surveillance at treatment plants (WSTPs) has emerged as a low-cost and innovative method to detect outbreaks early. Many developed countries have adopted this approach, but Japan has been slow to do so.

To promote the adoption of the WSTP system in Japan, a group of researchers led by Professor Byung-Kwang Yoo, Faculty of Human Sciences, Waseda University, Japan, and Professor Masaaki Kitajima, Research Center for Water Environment Technology, The University of Tokyo, conducted an economic evaluation of a city-level warning system based on wastewater data. Their findings were made available online on June 18, 2025, and will be published in Volume 990 of the journal Science of The Total Environment on August 15, 2025.

“Our proposed warning system seems reasonably feasible when compared to a similar ongoing successful wastewater surveillance system for polio in the UK. This UK system actually detected poliovirus at an earlier time, enabling a rapid public health response such as enhanced clinical tests and vaccine campaigns among a high-risk subpopulation,” explains Yoo.

According to their proposed system, when the number of newly reported COVID-19 cases exceeds a threshold of 90 newly reported clinically positive cases per million residents per day in a city where an LTCF is located, a warning will be issued by the city government recommending weekly clinical screening tests at LTCFs. Yoo notes, “Early detection and treatment of infected individuals contribute to lower hospitalization rates, lower mortality rates, and reduced medical expenses.”

The researchers used simulations to estimate how much financial benefit this system could offer. “Wastewater surveillance conducted at treatment plants was simulated to generate net benefits of around $5,000–$49,000 at a single LTCF, which encompasses 100 residents and 60 staff members, and around $3.5-$41 million at the national level in Japan during 4 weeks with a high incidence of COVID-19 infection,” says Yoo. “We hope these findings increase the support for WSTPs as well as the proposed warning system in Japan. This is because another study of ours reported that the general adult population in Japan is willing to pay $497 million annually for hypothetical WSTPs targeting COVID-19 and other diseases.”

Compared to clinical surveillance—which requires collecting individual patient samples—wastewater surveillance offers broader coverage, earlier outbreak detection, and lower costs. Yoo adds, “Since one wastewater sample easily allows us to test multiple pathogens together, an additional implication is to expand the scope of target pathogens, which will decrease the test cost per pathogen as well as increase the benefit per sample. Such target candidates include polio and influenza, which were already implemented in Japan on a small scale.”

As the world prepares for future public health challenges, cost-effective and scalable solutions like wastewater surveillance are essential. The present research is a crucial step toward evidence-based policy decisions and encourages a broader adoption of this approach in Japan and beyond.

 

***

 

Reference

 

DOI: 10.1016/j.scitotenv.2025.179645

 

Authors: Byung-Kwang Yooa, b, Ryo Iwamotoc, d, Ungil Chungb, e, Tomoko Sasakif, Peter G. Szilagyig, and Masaaki Kitajimah

 

Affiliations:

aFaculty of Human Sciences, School of Human Sciences, Waseda University

bSchool of Health Innovation, Kanagawa University of Human Services

cSHIONOGI & Co., Ltd.

dAdvanSentinel Inc.

eGraduate Schools of Engineering and Medicine, The University of Tokyo

fKanagawa University of Human Services

gDepartment of Pediatrics, David Geffen School of Medicine, University of California, Los Angeles

hResearch Center for Water Environment Technology, School of Engineering, The University of Tokyo

 

About Waseda University
Located in the heart of Tokyo, Waseda University is a leading private research university that has long been dedicated to academic excellence, innovative research, and civic engagement at both the local and global levels since 1882. The University has produced many changemakers in its history, including eight prime ministers and many leaders in business, science and technology, literature, sports, and film. Waseda has strong collaborations with overseas research institutions and is committed to advancing cutting-edge research and developing leaders who can contribute to the resolution of complex, global social issues. The University has set a target of achieving a zero-carbon campus by 2032, in line with the Sustainable Development Goals (SDGs) adopted by the United Nations in 2015. 

To learn more about Waseda University, visit https://www.waseda.jp/top/en  

 

About Professor Byung-Kwang Yoo
Dr. Byung-Kwang Yoo is a Professor at the Faculty of Human Sciences, School of Human Sciences, Waseda University, and also affiliated with the School of Health Innovation, Kanagawa University of Human Services. He holds a PhD in Health Policy and Management (Health Economics) from Johns Hopkins University, an M.Sc. from Harvard University, and an MD from Hokkaido University. With over 20 years of academic experience, his research focuses on health economics, public health responses to pandemics, and health promotion education with theater techniques. He is also the author of several widely recognized health policy books in Japan.

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Journal

Science of The Total Environment

DOI

10.1016/j.scitotenv.2025.179645 

Method of Research

Computational simulation/modeling

Subject of Research

People

Article Title

Economic evaluation of the city-level warning system based on surveillance at wastewater treatment plants to recommend optimal clinical COVID-19 screening tests at long-term care facilities, Japan

Article Publication Date

15-Aug-2025

COI Statement

Mr. Iwamoto reported being employed by SHIONOGI & Co., Ltd., a for-profit laboratory company in Japan. Dr. Kitajima reported receiving collaborative research grants from SHIONOGI & Co., Ltd., AdvanSentinel, Inc., and WOTA Corp. Dr. Kitajima reported having patent royalty with SHIONOGI & Co., Ltd. Dr. Kitajima reported receiving an academic consulting fee from Nissui Corporation. Dr. Kitajima reported receiving an honorarium for a lecture from AdvanSentinel, Inc. and Nissui Corporation. Dr. Kitajima reported receiving an honorarium for a presentation from Bio-Rad Laboratories, Inc. and Qiagen. Dr. Kitajima reported having a pending patent with SHIONOGI & Co., Ltd. All other authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

 

Nanotech advances offer sustainable breakthroughs in wastewater treatment

Bentham Science Publishers

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The latest title from Bentham Science Nanotechnology for Wastewater Treatment, explores how innovative nanomaterials are transforming the landscape of water purification and environmental sustainability.

By integrating cutting-edge nanotechnological approaches, the book presents efficient, cost-effective, and eco-friendly solutions to modern wastewater treatment challenges. Each chapter focuses on the latest research on nanomaterials such as zero-valent metals and graphene-based compounds and their specific roles in removing pollutants from wastewater.

Designed for researchers, professionals, and academics, the book offers practical insights into how nanotechnology can improve treatment outcomes while reducing energy and resource consumption. It also provides a forward-looking view of emerging trends and future directions in the field.

Key Features:

• In-depth coverage of nanomaterials used in pollutant removal
   

• Focus on efficiency, sustainability, and cost reduction in wastewater treatment
   

• Exploration of current challenges and innovative solutions in nanotech-based purification 

 

Learn more about this book here: http://bit.ly/3Hcjv73 

For media inquiries, review copies, or interviews, please contact Bentham Science Publishers.
 

About the Editor:

 Dr. Bendi is an Associate Professor (Research) at the Innovation and Translational Research Hub (iTRH) and the Department of Chemistry, Presidency University, Bangalore, India. With a Ph.D. in Organic Chemistry and extensive experience in catalysis, nanocatalysis, and environmental remediation, he has authored over 65 research papers, one book, 17 book chapters, and holds five patents. Bendi has more than 17 years of experience in teaching and research and is actively engaged in national and international scientific collaborations.

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DOI

10.2174/97898153228281250101