Posted on

Zika makes your skin more attractive
to mosquitoes

The Zika virus manipulates human skin cells to increase the release of mosquito-attracting odors, making infected individuals more likely to be bitten, according to a new study published in Communications Biology.

Researchers from Liverpool School of Tropical Medicine found that the virus alters gene and protein activity in dermal fibroblasts, changing their metabolism to produce higher levels of the compounds that attract mosquitoes.

This improves the chances of the virus spreading. The research highlights how Zika has evolved to boost its own transmission and suggests that controlling these changes could be a potential strategy for limiting its spread.

Posted on

A golden opportunity for medical
devices

A new way to embed gold nanoparticles into 3D-printed hydrogels could improve medical implants, optical devices and even contact lenses for colorblindness.

Scientists at Khalifa University published their research in Materials & Design. It introduces an eco-friendly method that places nanoparticles exactly where they are needed, without waste or extra chemicals.

3D-printed materials with nanoparticles are not new: The particles have previously been mixed into the printing material or applied as a coating afterwards. Both approaches limit device performance.

This new approach allows for better control over nanoparticle placement, making it useful for drug delivery, biosensors and light-based medical treatments.

Posted on

How Coldplay takes sustainability on tour

With 45,000 other fans, I went to a Coldplay concert last month. It had been 20 years since my last one and this time was a very different experience. The technology wasn’t just a flashy addition, it was an essential part of the sustainable show.

Concert-related CO2 emissions come from a wide range of sources — travel, ticketing, audience electronics, energy consumption for staging, lighting, sound, ventilation, hotel stays for attendees, band members, and crew, as well as waste from packaging and plastics.

After launching “Everyday Life” in 2019, Coldplay told the BBC that they would stop touring until they could ensure it could be done sustainably.

“We’re taking time over the next year or two to work out how our tour can not only be sustainable but how it can be actively beneficial,” frontman Chris Martin said.

Fast forward to 2021 and the announcement of their Music of the Spheres Tour, where the band vowed to cut direct carbon emissions by 50 percent, covering every aspect of production and travel.

Among the innovations used to cut their carbon emissions: Energy centers placed around each venue consist of 44 sustainable tiles for fans to dance on and 15 kinetic bikes that generate energy to help power the show. Data collected from these centers records the amount of energy produced during specific songs, shows and across tours.

“From collecting unprecedented amounts of data to taking specific actions today based on rigorous analysis, Coldplay is modelling a trajectory toward a low-carbon, biodiverse and equitable future.”

John E. Fernández, director of the MIT Environmental Solutions Initiative

On average, these installations — along with solar panels set up around the stadium — generate about 17 kWh each night, enough to power the center stage.

The band also encourages concertgoers to use public transportation and shuttle buses organized for the event; set up water stations around the venue; and requests that fans bring refillable bottles.

Every flight, including freight and charter, uses sustainable aviation fuel, and the stage is built with reusable and recycled lightweight materials.

In 2023, the band reported powering 18 shows from a portable battery system made from recycled BMW i3 batteries. Over 2022–2023, they also achieved a 59 percent reduction in CO2 emissions compared to their 2016 tour.

But it’s not all about direct emissions and energy consumption.

Coldplay also focuses on food and waste management. So far, 72 percent of all tour waste has been sent for reuse, recycling or composting. They’ve also donated nearly 10,000 meals from tour catering to the homeless over the same two-year period.

For each ticket sold, a tree is planted, and the band partners with several sustainability-focused organizations, including ClientEarth and One Tree Planted. To top it all off, Coldplay’s tour merchandise is made from organic and recycled materials.

It seems like they’ve got the bases covered. But is it enough?

Carbon Market Watch praises the band’s efforts but points out that some information is missing from their data — such as emissions from fan travel. They also suggest the numbers could be reduced by playing fewer concerts.

The data and sustainability claims have been audited and verified by the MIT Environmental Solutions Initiative.

“For some time now, Coldplay has been leading by example in taking seriously and acting on the various interrelated environmental and social challenges facing humanity; climate change, biodiversity loss, air and water pollution, environmental injustice and more,” says John E. Fernández, director of the MIT Environmental Solutions Initiative.

“With each subsequent year of their tour they demonstrate an evolving vision and expanded commitment to move the entire music industry toward true and humane sustainability and planetary resilience. From collecting unprecedented amounts of data to taking specific actions today based on rigorous analysis, Coldplay is modelling a trajectory toward a low-carbon, biodiverse and equitable future,” he adds.

After all, they’re one of only a few taking such measures.

Comprehensive industry-wide data is scarce. That’s why MIT is conducting its own research, led by Fernández and MIT research scientist Norhan Bayomi of The Climate Machine, an MIT Environmental Solutions Initiative research group.

“This latest analysis of Coldplay’s impact on the environment from touring is again setting a new standard for the entire music industry. The data and the methods of analysis support the conclusion that substantial progress has been made to reduce emissions in touring,” Fernández says.

Posted on

From Nobel-winning breakthroughs to
local innovation

Advances in protein design and the use of AI for predicting protein structures made the headlines with the 2024 Nobel Prize in Chemistry. But closer to home, researchers at Khalifa University in Abu Dhabi are leading the way in using computational methods to predict the crystal structures and properties of materials.

This foundational work is driving progress in energy storage, drug development and the creation of components for advanced optoelectronic devices.

Listen to the Deep Dive

“The basic idea is to use computers to predict the atomic arrangement of solids before we synthesize them in the lab,” says Sharmarke Mohamed, head of the Chemical Crystallography Laboratory (CCL) at Khalifa University. “If we can do this accurately for all target molecules of interest, then this gets us one step closer to answering the scientifically interesting question of what experimental conditions are necessary to target the crystallization of a material with this particular structure.”

Using computers is time-saving, cost-effective and minimizes trial-and-error experiments. But why is this important?

Today, the challenge is not whether we can use computers to predict crystal structures, but how the predicted crystal structures can be used to guide experiments in the synthesis and discovery of functional materials.

Sharmarke Mohamed, head of the Chemical Crystallography Laboratory (CCL) at Khalifa University

Crystallizing proteins allows scientists to understand their structure in detail.

Proteins are complex macromolecules, and their shape determines how they function in the body. By creating crystals of proteins, researchers can use techniques like X-ray crystallography to study their 3D structure. This helps in designing medicines that fit a protein perfectly to treat diseases. It also advances understanding of conditions like cancer and Alzheimer’s by revealing malfunctions in the protein structure.

CAPTION: Sharmarke Mohamed (from left), Praveen Managutti and Thomas Delclos

“Fifteen years ago, when I was doing my Ph.D. in chemical crystallography and computational structure prediction, the question of whether computers can predict crystal structures was still an open question. The problem was also somewhat niche and confined to the academic community because very few industrial researchers were engaged in method development and testing. Today, most pharmaceutical companies around the world have some sort of computational crystal structure prediction research program in-house,” Mohamed says.

But the field has developed immensely over the past couple of decades thanks to a little healthy competition.

Critical Assessment of Structure Prediction (CASP) is a biennial event where researchers assess the performance of methods used to predict protein structures. Scientists worldwide participate in testing algorithms that aim to determine how proteins fold into their 3D shapes based solely on their amino acid sequences. Given the importance of protein structure in areas like drug development and disease research, CASP plays a critical role in advancing computer-based biology research and guiding improvements in prediction methods.

A similar blind test has been ongoing since 1999 for assessing progress in using computers to predict the crystal structures of small molecules.

The Crystal Structure Prediction (CSP) Blind Tests, organized by the Cambridge Crystallographic Data Centre, bring together scientists from academia and industry to evaluate their methods on real-world examples in a controlled setting. These tests also foster collaboration within the CSP community.

Mohamed and his team — including M.Sc. student Mubarak Almehairbi, Ph.D. student Zeinab Saeed and postdoctoral research fellows Tamador Alkhadir and Bhausaheb Dhokale — participated in the most recent CSP blind test.

“This seventh blind test featured the most challenging target molecules to date,” Mohamed tells KUST Review. “The results show that the field has progressed significantly since the first blind test in 1999, as reflected in the success rate in both structure generation and ranking. But as with all advancements in science, when we make progress in one area, new questions and challenges arise.

“Today, the challenge is not whether we can use computers to predict crystal structures, but how the predicted crystal structures can be used to guide experiments in the synthesis and discovery of functional materials,” Mohamed says. “This is now the focus of many researchers in the field, including our group in the Chemistry Department of Khalifa University.”

For example, machine learning has improved how we rank predicted crystal structures, helping researchers identify which ones are likely to form successfully under normal temperature and pressure conditions.

Ranking crystal structures helps researchers figure out which ones are most likely to be observed under real-life conditions. This saves time and effort by focusing on the best options for experiments.

Mohamed’s group is developing new methods and codes to help experiments target new materials with desirable solid-state properties. For example, the team recently created the MechaPredict code, which is able to predict the mechanical properties of crystals on any surface of interest without the need for sensitive nanoindentation experiments.

CAPTION: MechaPredict code summary IMAGE: Khalifa University

This code is already being used by academics around the world and has attracted interest from pharmaceutical companies for its potential to extend the shelf life and improve the solubility and stability of drug products. Additionally, the code can be applied in designing new materials like hole-transport layers for solar cells, which can lead to more efficient, versatile, cost-effective and longer-lasting solar panels.

But with all the advances made in computational CSP methods, a well-equipped crystallography laboratory is necessary to validate the accuracy of the computational predictions.

“The Chemical Crystallography Laboratory (CCL) is the best-equipped crystallography lab in the UAE for performing single-crystal X-ray diffraction, the gold standard for determining the crystal structures of materials,” Mohamed says. “The CCL provides experimental crystallographic services to Khalifa University researchers as well as to collaborators in the UAE and around the world. The synergy between experimental chemical crystallography and computational CSP methods is the key to seeing further advances such as those recognized in the 2024 Nobel Prize in Chemistry.”