Sunday, December 18, 2022

Measuring the stress of moving house

Moving is considered stressful, but just how stressful is it? University of Auckland researchers have developed an original method of investigation.

Peer-Reviewed Publication

UNIVERSITY OF AUCKLAND

University of Auckland Business School researcher Dr William Cheung is analysing micro-level data about people and households to examine the effects of moving house on mental well-being and stress.

His study, co-authored with business analyst Daniel Wong scrutinises stress levels among adults in the Auckland region, namely homeowners and renters, alongside a control group of non-movers. Overall, the results show that the average stress level of homeowners is significantly higher than renters, and those who move more frequently are more stressed than those who don't. The data also suggests that individuals dealing with high stress levels are predisposed to move house.

While acute stresses seem to result in one-off movements, Dr Cheung says chronic stresses result in more frequent movement. The study also shows that stress levels decrease over time when individuals don't move. Cheung says social housing tenants have much higher baseline stress levels than both homeowners and renters.

While research has shown that moving house is detrimental to mental well-being," Dr Cheung says in his paper, "our studies further suggest that frequent relocation and the housing tenure types, especially owner-occupier, is a substantial contributor to stress."

As a result, the study's authors recommend implementing housing strategies that ensure housing can be sustained over time. Dr Cheung says this may include assistance programmes that make housing more attainable for the vulnerable, such as those encountering mental illness. "We need economic programmes that aid individuals at risk of losing their homes and, as well as providing stable housing, mental health services must be available, easily accessible among urban residents, and designed to remain amenable under transient circumstances."

The average stress levels of non-movers, renters, homeowners, and social housing residents aged between 19 and 54 living in urban Auckland between 2013 and 2018 were analysed by Cheung and Wong using the government's Integrated Data Infrastructure, which is based on micro-level individual census data.

This census data enabled them to reconstruct what's known as the Social Readjustment Rating Scale (SRRS), a stress comparison scale developed in the 1960s by two psychiatrists. The original SRRS attributes up to 100 points to different life stressors, ranging from 100 points for a spouse's death to 11 points for minor law violations. Other examples include moving house (20 points), incurring a large mortgage (37) and divorce (73 points).

Dr Cheung says the new method resulted in an instrument that can measure the socioeconomic impact on an individual in any population segment far more cost-effectively than current measures. Using the census data and the SRRS model also proved more efficient than conventional surveys, with better sensitivity and an increased ability to identify influences on the individual.

"We advanced our understanding of the stress of moving homes; the influence of mobility on place experience; and the circumstances, advantages and challenges of moving home over a resident's lifetime." By progressing people's understanding of such stressors, Dr Cheung says researchers can contribute to broader discussions on how an individual's personal history and social mobility influence their social well-being. 

HKU Mechanical Engineering team develops new microscale 3D printer for multi-level anticounterfeiting labels

Peer-Reviewed Publication

THE UNIVERSITY OF HONG KONG

Research team 

IMAGE: DR JI TAE KIM (LEFT) AND DR JIHYUK YANG (RIGHT) view more 

CREDIT: THE UNIVERSITY OF HONG KONG

Counterfeiting threatens the global economy and security. According to the report issued by the United States Patent and Trademark Office (USPTO) in 2020, the value of global counterfeit and pirated products is estimated between US$ 1.7 and 4.5 trillion a year. Despite enormous efforts, conventional anticounterfeiting approaches such as QR codes can be easily fabricated due to limited data encryption capacity on a planar space. How can we increase the encryption density in a limited space?

The team led by Dr Ji Tae Kim from the Department of Mechanical Engineering at the University of Hong Kong (HKU) has developed a high-precision 3D printing method that can produce new polarisation-encoded 3D anticounterfeiting labels. This new 3D label can encrypt more digital information than a traditional 2D label. The work has been published in Nano Letters in an article entitled “Three-Dimensional Printing of Dipeptides with Spatioselective Programming of Crystallinity for Multilevel Anticounterfeiting”.

Diphenylalanine (FF), a species of dipeptides, was chosen as a material for data encryption due to its unique optical properties. Dr Jihyuk Yang from the Department of Mechanical Engineering, HKU, explained: “FF has long attracted great attention to neuroscientists due to its association with Alzheimer's disease. Recently, FF is emerging as a new electronic and photonic device material due to its unique properties – e.g. piezoelectricity and optical birefringence – arising from crystalline nature.” Dr Yang is the first author of the paper.

 “Our new 3D printing method combined with nature-driven molecular self-assembly can print multi-segmented 3D FF micro-pixels with programmed crystallinity for high-density data encryption. By utilising different responses of the amorphous and crystalline segments to polarised light, a tiny single 3D pixel can encrypt a multi-digit binary code consisting of "0" and “1". The information capacity can be increased to 211 with a single eleventh-segmented freestanding pixel on a tiny 4 µm2 area which is 1000 times smaller than a hair strand,” said Dr Ji Tae Kim. He believes that 3D printing technology can be effectively used to customise security labels on-demand anywhere and anytime, contributing to strengthening the information security of individuals and companies.

Link to the journal article: https://pubs.acs.org/doi/abs/10.1021/acs.nanolett.2c01761

Scheme: 3D printing process of polarization-encoded 3D micro-pixels

CREDIT

The University of Hong Kong

Catalyzing ‘net-zero’ green hydrogen from the sun: HKU chemists discover a fundamental catalyst protonation process to promote solar-driven water-splitting for hydrogen production without CO2 emissions

Peer-Reviewed Publication

THE UNIVERSITY OF HONG KONG

Protonation 

IMAGE: CHEMISTS AT HKU DISCOVER A FUNDAMENTAL CATALYST PROTONATION PROCESS TO ENHANCE PRODUCTIVITY OF SOLAR-DRIVEN WATER-SPLITTING FOR HYDROGEN BY EIGHT TIMES, CATALYSING GREEN ENERGY WITHOUT CO2 EMISSIONS. view more 

CREDIT: THE UNIVERSITY OF HONG KONG

Hydrogen is a promising green energy carrier for a sustainable future. However, it is mostly locked in water. Energy is required to liberate it from water for practical use. Solar energy is abundantly renewable, ideal for direct water-splitting to generate hydrogen using a ‘photocatalyst’. However, despite of considerable effort, practical adoption has been slow due to relatively low efficiency and high cost of the catalyst.

A research team led by Professor Zheng-Xiao GUO and Professor David Lee PHILLIPS from the HKU-CAS Joint Laboratory on New Materials and the Department of Chemistry of The University of Hong Kong (HKU), has reported the discovery of an important in-situ protonation process that the photodynamics and separation of charge carriers in a photocatalyst, leading to efficient hydrogen generation from water using visible solar light. The process is enabled in an interstitial phosphorus doped carbon nitride structure, with only earth-abundant non-metallic elements, for its cost-effectiveness and high potential for practical applications. The research findings are recently published online in a top scientific journal, Energy & Environmental Science.

Background and Achievement
Extensive research efforts have been devoted to the development of photocatalysts for solar-driven energy conversion with improved activity, efficiency and durability, mostly via: charge separation, transfer and utilisation. However, the complex multi-electron transfer, proton coupling and intermediate dynamics can all influence the photocatalytic pathway, kinetics and efficiency, which have not been well understood. It is thus highly desirable to foster in-depth investigations integrating innovative synthesis design, microscopic and spectroscopic characterisations and atomic simulations at the molecular level.

With full appreciation of the current efforts and the challenges in photocatalysis, the HKU team examined the fundamental issues from a different angle and proposed a new fundamental process of a proton-mediated photocatalytic mechanism to enhance the photo-dynamics, charge separation and hence the overall efficiency of an interstitial phosphorus-doped carbon-nitride, g-C3N4. The in-situ proton-mediated mechanism points to a new role of the water molecule, not just as a solvent or reactant but as an effective band-structure modifier of the catalyst in the overall design of effective photocatalytic processes.

In essence, the team has developed an effective atomic heterojunction by porosity-stabilised interstitial P-doping and in-situ protonation to induce shallow trap states, which effectively: a) enhance the lifetime of the excited states and b) restrain undesirable deep charge trapping, leading to efficient water decomposition. For the first time, the team has identified that the in-situ protonation of an interstitially anchored phosphorus in a holey g-C3-xNis a very effective structural configuration of the catalyst for highly efficient and stable visible-light hydrogen generation.

‘We expect that our discovery will open up a new line of thinking in the future design of photocatalysts for effective solar energy utilisation, by paying more attention to operando structural dynamism as a viable handle to pump up the conversion efficiency,’ said Professor Zheng-Xiao Guo.

‘Spectroscopic investigations show a colourful world of nanomaterials, and it will cast more light on the mechanistic insights of science and technologies,’ echoed Professor David Lee Phillips.

About Professor Zheng-Xiao Guo
Professor Zheng-Xiao Guo is a joint-faculty Professor of Chemistry and Mechanical Engineering at HKU, an Honorary Professor at the University College London (UCL), an Elected Member of Academia Europaea (The Academy of Europe), as well as a Fellow of the Royal Society of Chemistry and a Fellow of the Institute of Materials, Minerals and Mining. He was a Professor of Chemistry at UCL (2007-18), and prior to this, a Lecturer (1995-98), Reader (1998-99) and Professor (2000-07) at Queen Mary, the University of London. He was a research fellow at the University of Oxford (1990-95), and of Strathclyde (1988-90), respectively, with a PhD and an MRes from the University of Manchester in 1988 and 1984, and a BEng in Materials Science from the Northeastern University/China in 1983, respectively.

More information about his research group: https://zxguo.hku.hk/

About Professor David Lee Phillips
Professor David Lee Phillips is a Chair Professor at HKU Department of Chemistry. As an internationally recognised chemist, he uses time-resolved spectroscopy experiments and quantum mechanical calculations to study short-lived intermediates in chemical reactions of interest in chemistry, biology and the environment. He has published more than 350 internationally refereed scientific journal articles listed in Science Citation Index.

He serves on the Editorial Advisory Board of the journal Molecules and also on the Advisory Board of the Journal of Physical Organic Chemistry. Professor Phillips graduated with a PhD from the University of California, Irvine.

More information about his research group: https://sites.google.com/view/dlplab/home?pli=1

About the Research Team
Dr Wenchao WANG (Postdoctoral fellow) from Professor Guo’s group is the first author. Professor Lili DU from the Jiangsu University, Professor Hung Kay LEE from the Chinese University of Hong Kong and other HKU researchers (including Miss Ruiqin XIA; Dr Runhui LIANG; Mr Tao ZHOU; Dr Zhiping YAN; Miss Hao LUO; Dr Congxiao SHANG) in the Department of Chemistry contributing to the research.

Supplementary Information
W. Wang, L. Du, R. Xia, R. Liang, T. Zhou, H. K. Lee, Z. Yan, H. Luo, C. Shang, D. L. Phillips,* Z. X. Guo* “In-situ protonated-phosphorus interstitial doping induces long-lived shallow charge trapping in porous C3-xN4 photocatalyst for highly efficient H2 generation” (2022) Energy Environ. Sci. (DOI: https://doi.org/10.1039/D2EE02680E)

The research paper can be accessed here: https://pubs.rsc.org/en/content/articlelanding/2023/ee/d2ee02680e

This work was supported by the Hong Kong RGC-EU Collaborative Programme initiative, the HK Environment and Conservation Fund, RGC-GRF, the Natural Science Foundation of Zhejiang Province, the Key-Area Research and Development Program of Guangdong Province, the Joint Laboratory Funding Scheme, the “Hong Kong Quantum AI Lab Ltd” funded by the AIR@InnoHK, launched by the Innovation and Technology Commission (ITC), the URC Platform Technology Fund, the start-up support from the University of Hong Kong, and HKU Libraries’ Open Access Author Fund.

Image download and caption: https://www.scifac.hku.hk/press

For media enquiries, please contact Ms Casey To, External Relations Officer (tel: 3917 4948; email: caseyto@hku.hk / Ms Cindy Chan, Assistant Director of Communications of HKU, Faculty of Science (tel: 3917 5286; email: cindycst@hku.hk).

Detrimental secondary health effects after disasters and pandemics

Researchers from Osaka University showed an increase in major non-communicable diseases after the Fukushima disaster and COVID-19 outbreak

Peer-Reviewed Publication

OSAKA UNIVERSITY

Fig. 

IMAGE: FIG. (A) CHANGE IN PREVALENCE OF DISEASES AFTER THE FUKUSHIMA DISASTER (FUKUSHIMA PREFECTURE); (B) CHANGE IN PREVALENCE OF DISEASES AFTER THE COVID-19 OUTBREAK (THE WHOLE OF JAPAN). ERROR BARS REPRESENT 95% UNCERTAINTY INTERVALS. view more 

CREDIT: MICHIO MURAKAMI, SHUHEI NOMURA: ANNUAL PREVALENCE OF NON-COMMUNICABLE DISEASES AND IDENTIFICATION OF VULNERABLE POPULATIONS FOLLOWING THE FUKUSHIMA DISASTER AND COVID-19 PANDEMIC,INTERNATIONAL JOURNAL OF DISASTER RISK REDUCTION,2022,103471, HTTPS://DOI.ORG/10.1016/J.IJDRR.2022.103471.

Osaka, Japan - Disasters and pandemics can affect the physical and psychological health of the people involved even after the events have occurred. These effects can include non-communicable chronic diseases. Now, researchers at Osaka University have identified the similarities and differences in secondary health effects in people who have experienced disasters and pandemics.

After the devastating Great East Japan Earthquake and the Fukushima Daiichi Nuclear Power Station accident in Japan in 2011, non-communicable diseases have increased since that time. In a seven-year follow-up after the Fukushima disaster, a previous study revealed the age-adjusted prevalence of diabetes in both evacuees and non-evacuees significantly increased. Similar concerns existed regarding the COVID-19 pandemic and its potential impact on chronic illnesses. This meant many restrictions were implemented to ensure the safety and health of the people of Japan. To stop the spread of infection, people were encouraged to stay at home and work from home. Perhaps as a result of this, increased body weight among certain populations and mental disorders were observed.

In this study, the changes in the prevalence of diseases in Japan, including hypertension, hyperlipidemia, diabetes, and mental disorders, before and after the Fukushima disaster and the COVID-19 pandemic were reviewed using a health insurance dataset over a long period of time. First, the changes in the prevalence of hypertension, hyperlipidemia, diabetes, and mental disorders over nine years following the Fukushima disaster were analyzed. Second, the changes in prevalence before and after the COVID-19 pandemic were examined. Results were examined by age and sex to determine the most significantly affected groups.

Results of this study showed that the prevalence of all four diseases increased in Fukushima Prefecture after the Fukushima disaster and in the whole of Japan after the COVID-19 outbreak as well. The increased rates of hypertension, hyperlipidemia, diabetes, and mental disorders were higher in females aged 40-74 years after the Fukushima disaster. However, after the COVID-19 outbreak, the increase in prevalence rates of all four diseases was higher among males aged 0-39 years.

“This study has shed some light on identifying the vulnerable populations involved and assessing the secondary effect of disasters on the mental and physical health of these people” says lead author, Michio Murakami.

The importance of supporting secondary health effects after disasters and pandemics are now being recognized and can lead to improved post-disaster policies and recommendations that focus on health promotion and effective prevention strategies.

###

The article, “Annual prevalence of non-communicable diseases and identification of vulnerable populations following the Fukushima disaster and COVID-19 pandemic,” was published in the International Journal of Disaster Risk Reduction at DOI: https://doi.org/10.1016/j.ijdrr.2022.103471

About Osaka University

Osaka University was founded in 1931 as one of the seven imperial universities of Japan and is now one of Japan's leading comprehensive universities with a broad disciplinary spectrum. This strength is coupled with a singular drive for innovation that extends throughout the scientific process, from fundamental research to the creation of applied technology with positive economic impacts. Its commitment to innovation has been recognized in Japan and around the world, being named Japan's most innovative university in 2015 (Reuters 2015 Top 100) and one of the most innovative institutions in the world in 2017 (Innovative Universities and the Nature Index Innovation 2017). Now, Osaka University is leveraging its role as a Designated National University Corporation selected by the Ministry of Education, Culture, Sports, Science and Technology to contribute to innovation for human welfare, sustainable development of society, and social transformation.

Website: https://resou.osaka-u.ac.jp/en

Scientists release UK roadmap for managing key ingredient behind all the food we eat

As phosphate fertiliser prices remain at very high levels after spiking this year, scientists are calling for urgent measures to manage phosphorus, a vital element essential for food production.

Reports and Proceedings

LANCASTER UNIVERSITY

As phosphate fertiliser prices remain at very high levels after spiking this year, scientists are calling for urgent measures to manage phosphorus, a vital element essential for food production, but which is also behind environmental pollution in our rivers and lakes.

 

In launching the UK’s first comprehensive national transformation strategy into phosphorus, researchers say they are providing a roadmap for how the nation can better manage this important resource.

 

The strategy outlines a pressing need for new solutions and scaling-up of existing phosphorus innovations to prevent future damage to aquatic biodiversity and habitat, reduce reliance on risky import markets and to unlock new opportunities for agriculture.

 

Phosphorus is a lynchpin of our food system – plants cannot grow without it and has no substitute.

 

Crop and livestock production in the UK is almost entirely dependent on imported phosphorus in feeds and fertilisers – the UK imports around 174,000 tonnes of phosphorus annually.  Much of these imports derive from phosphate rock from countries including Russia, Morocco and China. The price of phosphate fertiliser quadroupled between mid 2020 and mid 2022 due to supply disruptions and market concentration in China. The ongoing war in Ukraine is serving to highlight the food security risks associated with reliance on imports of critical farm inputs like phosphorus.

 

Despite volatile prices and supply disruptions, phosphorus use in the UK is still highly inefficient, with less than half of imported phosphorus used productively to grow food. Mismanagement of phosphorus over decades has led to it being a major contributor to environmental problems. Wastewater discharges, along with excess phosphorus accumulating in agricultural soils and leaching into our rivers, lakes and other waterways, are contributing to issues such as algal blooms.

 

The ‘UK Phosphorus Transformation Strategy’ – a major output from the RePhoKUs project, led by Lancaster University and involving the University of Technology Sydney, University of Leeds, AFBI, UK CEH and funded under the UK’s Global Food Security research programme – sets out the challenges and key steps needed for the UK to adopt resilient, efficient and sustainable management of phosphorus.

 

Professor Paul Withers, of Lancaster University and lead investigator of the RePhoKUs project, said: “At present the UK does not have a coherent plan for managing phosphorus across the food system, either nationally, regionally or within catchments. This needs to change urgently.

 

“Transforming the way phosphorus is used in the UK food system is essential. Getting it right provides huge benefits to food and water security, tourism opportunities, and to maintain a clean healthy environment to boost biodiversity and the natural world for generations to come – but it requires all sectors to come on board.”

 

The strategy’s recommendations, co-developed with national stakeholders through extensive consultation with farmers, regulators, policy-makers, food producers, wastewater companies, and environmental managers, highlight a number of priorities to enable the UK to transition towards using phosphorus more sustainably:

 

  • Develop and deploy at scale new technologies and innovations that can recover phosphorus from animal manure, wastewater and food waste, and redistribute as viable, cost-effective and renewable fertilisers.
  • Provide incentives that encourage investment in technologies and lower barriers to create new markets for a renewable phosphorus fertiliser sector.
  • Improve, align and make coherent policies and governance that recognise and manage phosphorus as a scare resource, as well as a pollutant.
  • Provide tailored knowledge, research and advice for farmers on tapping soil legacy phosphorus, and using recycled phosphorus.
  • Better engage stakeholders across the whole phosphorus value chain to set strategic direction and support implementation via bespoke and diverse local phosphorus solutions.
  • The creation of nutrient stakeholder platform and UK nutrient data sharing dashboards to help inform phosphorus management

 

Aside from the phosphorus sources in wastewater treatment plants servicing towns and cities, the report highlights that phosphorus is unevenly concentrated across the UK. Where livestock farming is most intensive, predominantly in the west of England and Northern Ireland, then surpluses of phosphorus (largely in manure) are higher. The excess phosphorus applied in England’s North West region alone is equivalent to nearly £30 million of fertiliser.

 

In areas where arable crops are grown, which tends to be predominantly in the east of the country, there is a deficit and the need to use phosphorus-based fertilisers because crops are taking up more than is applied.

 

However, the logistics of moving bulky manure from one part of the country to another are impractical. Finding new innovative ways to extract and relocate phosphorus from manure will be key in addressing these regional imbalances.

 

There is currently billions of pounds of phosphorus locked in UK top soil from decades of applications of fertiliser and manure – accessing and managing this legacy phosphorus ‘bank’ is central to improving efficiency and reducing imports, the team of scientists behind the new strategy argue.

 

One of the report’s lead authors, Associate Professor Brent Jacobs said: “The good news is there are many pockets of innovation and initiatives already under way in different sectors in the UK. These can be learned from, scaled-up and integrated to help overcome some of the challenges associated with phosphorus use.

 

“Theoretically there is enough phosphorus circulating in the food system and in our soils. One of the pathways to achieving sustainable phosphorus use will involve developing and deploying new technologies that can extract legacy phosphorus from soils and manures and develop new renewable fertiliser markets.”

 

The authors highlight the need for all of the different actors and sectors involved in food production, across catchment areas and government departments, which are currently operating in a fragmented manner, to work more closely and to adopt innovative solutions to transition towards using phosphorus more sustainably.

 

Professor Julia Martin-Ortega of the University of Leeds and co-author of the report said: “As the UK food system is undergoing fundamental policy change, our report provides a timely opportunity to integrate urgently needed actions across all sectors of the food chain into regional and national policy and governance, tapping into huge potential wins for the environment and the economy.”

 

For the full UK Phosphorus Transformation Strategy report please visit: http://wp.lancs.ac.uk/rephokus/publications/

 

The report was produced as part of the RePhoKUs project (The role of phosphorus in the sustainability and resilience of the UK food system) funded by BBSRC, ESRC, NERC, and the Scottish Government under the UK Global Food Security research programme (Grant No. BB/R005842/1).


The value of people’s values: Study shows how relational values contribute towards sustainability

New study underscores the significance of relational values in improving people’s participation in the sustainable management of social-ecological systems

Peer-Reviewed Publication

RITSUMEIKAN UNIVERSITY

New study shows how relational values can play a role in making socio-ecological systems (SESs) sustainable 

IMAGE: THE STUDY HIGHLIGHTS THE IMPORTANCE OF RELATIONAL VALUES IN GAINING PEOPLE’S SUPPORT FOR SUSTAINABLE MANAGEMENT STRATEGIES IN SESS. THESE RELATIONAL VALUES WERE ALSO FOUND TO BE ASSOCIATED WITH PRO-SES BEHAVIOR, WHICH CAN HELP MAKE SES MANAGEMENT PLANS SUCCESSFUL. view more 

CREDIT: TAKURO UEHARA FROM RITSUMEIKAN UNIVERSITY

In today’s world of excess, human-nature dynamics have become quite distorted and exploitative. Therefore, sustainable and mindful coexistence within our natural ecosystems has become the need of the hour. This is where sustainable social-ecological systems (SESs) come into play. SESs are complex adaptive systems that envelope the intricate interactions between people and their surroundings. Effectual SES management requires balancing the improvement of human well-being along with conservation of ecosystem integrity. However, the success of an SES management plan rests upon the understanding, support, and participation of the people of the SES. To ensure this support and involvement, it is integral that management decisions align with people’s wishes and the values they place on their natural environment.

Earlier studies have mainly focused on the instrumental and intrinsic values of nature. Instrumental value pertains to the necessity of something in achieving a particular end, whereas intrinsic value is when the thing is desirable in itself. However, few studies have looked into the significance of relational values of nature. These are values that arise from human–nature connectedness and encompass a sense of place, identity, and well-being that can motivate environmental stewardship. Overcoming this paucity of research, a new study from Japan, which was published in Frontiers in Marine Science on December 8, 2022, has become the first to quantitatively reveal the essential role of relational values in people’s readiness to participate in and support SES management. “Relational values are preferences associated with positive human-nature relationships that are valued by people. Our research shows that by managing SESs that respect these relationships, SESs can become a more desirable state,” says Prof. Takuro Uehara, a professor at Ritsumeikan University, Japan, and the lead researcher of the study.

Residents from three SESs surrounding the Seto Inland Sea in Japan were surveyed for the study. These included people from Kobe-Hanshin (N=1136), Harima (N=864), and Kagawa (N=1000). The study evaluated how relational values affect people’s proclivity towards sustaining their SES. This was measured by pro-SES behavior scales that were specifically designed for the studied SESs. These one-of-a-kind behavior-measuring scales included factors related to the sustainable utilization of natural resources and active human interaction with nature. These scales were created to be in line with the local conservation policies and the Japanese concept of ‘satoumi’ — human–nature interactions that enhance ecosystem services while conserving nature.

The study found that while relational values correlate and overlap with instrumental and intrinsic values to some degree, they are also non-substitutable and important in their own right for the successful management of SESs. The study shows that integrating relational values — either as a single value class or as part of pooled values — is crucial for gaining the public’s support for SES management. It also demonstrates that fostering such relational values can promote pro-SES behavior among people. This can be achieved by improving environmental education, encouraging the consumption of locally sourced foods, and increasing opportunities for more nature-based leisure activities for the community. These results resonated across the three SESs, despite their social, demographic, cultural, and environmental differences.

Overall, this study makes a strong case for incorporating relational values into SES management plans in order to achieve a desirable state of SESs, which is both human- and ecosystem-centric. “Relational values are typically place-based, and our study shows that these values can uniquely and meaningfully contribute towards understanding pro-SES behavior, which could have important management implications for individual SESs. In order to create a systemic change towards sustainability, relational values can be a deep leverage point since people are generally more willing to be involved in activities that support what they value,” comments Prof. Uehara.

Perhaps it is high time that relational values are given due credit in helping make SESs and the world more sustainable.

***

Reference

DOI: https://doi.org/10.3389/fmars.2022.1001180  

 

About Ritsumeikan University, Japan

Ritsumeikan University is one of the most prestigious private universities in Japan. Its main campus is in Kyoto, where inspiring settings await researchers. With an unwavering objective to generate social symbiotic values and emergent talents, it aims to emerge as a next-generation research university. It will enhance researcher potential by providing support best suited to the needs of young and leading researchers, according to their career stage. Ritsumeikan University also endeavors to build a global research network as a “knowledge node” and disseminate achievements internationally, thereby contributing to the resolution of social/humanistic issues through interdisciplinary research and social implementation.

Website: http://en.ritsumei.ac.jp/

 

About Professor Takuro Uehara from Ritsumeikan University, Japan

Dr. Takuro Uehara is a Professor at the College of Policy Science, Ritsumeikan University in Osaka, Japan. He has a Ph.D. in Systems Science with a focus on Economics from Portland State University, USA. He currently works on issues related to social-ecological systems, primarily using systems science and economics. His current research topics include social-ecological modeling, the economic valuation of nature, sustainability, resilience, satoumi, relational values, and marine plastic pollution. Prof. Uehara has also authored research papers published in leading journals in the field, including Ecological EconomicsEcology and SocietyEcosystem ServicesJournal of Environmental ManagementPeople and Nature, and Sustainability Science.

 

Funding information

This study was supported by the Japan Society for The Promotion of Science [Grant/Award Number: 18H03432].

Scientists' use of hydrogel materials leads to stem cells developing like human embryos

Peer-Reviewed Publication

UNIVERSITY OF NEW SOUTH WALES

Materials scientists at UNSW Sydney have shown that human pluripotent stem cells in a lab can initiate a process resembling the gastrulation phase – where cells begin differentiating into new cell types – much earlier than occurs in mother nature.

For an embryo developing in the womb, gastrulation occurs at day 14. But in a dish in a lab at UNSW’s Kensington campus, Scientia Associate Professor Kris Kilian oversaw an experiment where a gastrulation-like event was triggered within two days of culturing human stem cells in a unique biomaterial that, as it turned out, set the conditions to mimic this stage of embryo development.

“Gastrulation is the key step that leads to the human body plan,” says A/Prof. Kilian.

“It is the start of the process where a simple sheet of cells transforms to make up all the tissues of the body – nerves, cardiovascular and blood tissue and structural tissue like muscle and bone. But we haven’t really been able to study the process in humans because you can’t study this in the lab without taking  developing embryonic tissue.”

“So it’s really exciting that we were able to see this happening in vitro.”

The achievement, which was reported today in the journal Advanced Science, has not only implications for our understanding of human embryonic development, but also new treatments in medicine including cell therapy, targeted drug development and CRISPR gene-editing technologies.

The most important time in your life

Developmental biologist Lewis Wolpert once said: “It is not birth, marriage or death, but gastrulation which is truly the most important time in your life.” Gastrulation is the key event in an embryo’s development when a mass of undifferentiated cells begin the first steps of a long journey in the womb towards formation of a human being. This is one of the reasons that work on embryos left over from IVF is forbidden beyond 14 days, when gastrulation occurs.

A/Prof Kilian says that up until now, it has been difficult to study this process in humans because of obvious ethical constraints.

“Controlling gastrulation using materials alone will provide an entirely new way for studying human development,” he says.

“We currently can’t do this because embryo research beyond 14 days is often viewed as unethical, and it’s currently impossible in vivo because you’d need to observe an embryo in a pregnant human mother.”

But while there are animal models to study – such as mice and zebrafish – and other researchers have induced gastrulation-like events in the lab using chemicals including growth factors, this is the first time culture conditions alone have initiated gastrulation outside of a human body.

“Our method could lead to a new approach to mimic human embryogenesis outside of a person,” A/Prof Kilian says.

Miniature organs and CRISPR gene splicing

In the medical sciences, the ability to induce gastrulation in ‘synthetic’ embryos like those created by the UNSW team could also help in creating body tissue or even miniature organs based on a patient’s own genetic code. These so-called ‘organoids’, which are barely visible to the naked eye, are already being developed using stem cells for medical research, such as testing the effectiveness of certain drugs. But the process requires chemicals to stimulate the cells into forming differentiated organ tissue which is time consuming and expensive.

A/Prof. Kilian says controlling gastrulation by using only hydrogel materials to stimulate what happens naturally could be a quicker and more cost-effective solution.

“The thing that really excites us about this is the potential to make therapeutically useful cells much faster and more reproducible,” says A/Prof. Kilian.

“Our method could provide a way to initiate ‘organogenesis’ – with an array of hundreds of well-defined cell aggregates in a single well – leading to faster and more well-defined structures that could then be turned into brain, liver, gut, potentially any solid organ tissue.

“This approach could also revolutionise drug development including RNA and CRISPR/Cas9 approaches by providing a more reproducible way to mimic human tissue in a lab. For instance, you could make an organoid from a patient’s cells, then test therapies aimed at correcting mutations or restoring function.”

A hydrogel home is just right

The secret to the success of the UNSW team’s work in the lab is in the structure of the culture that the stem cells were seeded into. Using a technique adapted from the semiconductor industry, defined regions are fabricated across a hydrogel for cells to stick to. This combination of geometric confinement and the soft gel that mimics the surface of a human uterus coaxes the cells to start gastrulation-like processes.

“We discovered that if you take pluripotent stem cells and you put them in a very confined and soft environment, it’s akin to what the cells might experience in a mother's uterus,” says A/Prof. Kilian.

“That viscoelastic, soft, squishy material gives them just enough cues that they initiate this gastrulation-like process all on their own.”

This contrasts greatly with the standard practice that’s been used in labs more recently that forces a type of gastrulation process using growth factors and chemical supplements on hard plastic or glass dishes.

“Unsurprisingly, previous research culturing stem cells on glass or plastic have failed to recapitulate the signals that happen in a body. But using our soft substrates mimicking embryonic tissue, we can coax the cells to spatially organise and begin the early morphogenesis that could ultimately create a person.”

But, A/Prof. Kilian cautions, while the team has discovered the conditions that emulate the first stage of gastrulation, it doesn’t appear to go any further.

“We can’t make a person this way,” he says.

“This method only demonstrates the early, but very crucial stage in development. The impact lies in being able to study this all-important stage of human development, and to use the generated structures for developing therapies.”

Serendipity can be a big part of discovery

As with most great discoveries in science, serendipity played a role. The team weren’t actively looking to bring on gastrulation when they dropped some stem cells onto the hydrogel substrate.

Lead author Dr Pallavi Srivastava was surprised by what she observed.

“Initially I was trying to get stem cells to attach to our hydrogels and planned to differentiate them in the conventional way,” she says.

“The difference between cells cultured on glass and those on our gels was very striking. I remember thinking, ‘wow, something is going on here. I need to investigate’. This led to a big shift in my project, and ultimately this exciting discovery.”

The researchers are hopeful they can continue exploring the benefits of their discovery by understanding how materials can guide embryogenesis and beyond. A/Prof. Kilian says that while this finding is exciting, more work is needed to guide the gastrulation-like processes to form useful tissues.

“This is really the first step in what we hope is a platform technology for producing useful tissue models. Triggering gastrulation is not enough – now we need to provide other signals to keep differentiation going.”

Discovering the next set of materials signals may allow creation of virtually any solid tissue for research purposes, A/Prof. Kilian says, and for generating useful cell types for regenerative medicine.

“Considering pluripotent stem cells can now be generated from blood or tissue samples, the future is wide open for regenerating tissues and organs from a patient’s own cells.”