Researchers discover new self-assembled crystal structures

 Conceptual image showcasing several interaction potential shapes, represented by stems, that will lead to the self-assembly of new low-coordinated crystal structures, represented by flowers. 
Image Credit: Hillary Pan

Using a targeted computational approach, researchers in the Department of Materials Science and Engineering at Cornell have found more than 20 new self-assembled crystal structures, none of which had been observed previously.

The research, published in the journal ACS Nano under the title “Targeted Discovery of Low-Coordinated Crystal Structures via Tunable Particle Interactions,” is authored by Ph.D. student Hillary Pan and her advisor Julia Dshemuchadse, assistant professor of materials science and engineering.

“Essentially we were trying to figure out what kinds of new crystal structure configurations we can self-assemble in simulation,” Pan said. “The most exciting thing was that we found new structures that weren’t previously listed in any crystal structure database; these particles are actually assembling into something that nobody had ever seen before.”

The team conducted a targeted search for previously unknown low-coordinated assemblies within a vast parameter space spanned by particles interacting via isotropic pair potentials, the paper states. “Low-coordinated structures have anisotropic local environments, meaning that the geometries are highly directional, so it’s incredible that we’re able to see such a variety of these types of structures using purely non-directional interactions,” said Pan.

New insights on the risk of atrial fibrillation in children and adolescents

Image Credit: PublicDomainPictures

Researchers at Karolinska Institutet have investigated the relationship between premature birth and fetal growth and the risk of developing atrial fibrillation up to middle age. The study, published in JAMA Pediatrics, shows a slightly increased risk, especially in people who were born prematurely or who were large at birth. Low fetal growth was associated with an increased risk of atrial fibrillation only up to the age of 18.

For a few decades, the prevalence of atrial fibrillation at a young age has increased slightly, albeit from low levels.

"Atrial fibrillation at a young age can impose a heavy socio-economic burden on the individual, and more knowledge is needed about the underlying causes of the disease. Our findings can highlight the need to monitor and prevent the disease in more groups with an increased risk of cardiovascular disease", said the study's first author Fen Yang, doctoral student at Department of Global Public Health, Karolinska Institutet.

Vaccine printer could help vaccines reach more people

MIT researchers have designed a mobile vaccine printer that could be scaled up to produce hundreds of vaccine doses in a day. This kind of printer, which can fit on a tabletop, could be deployed anywhere vaccines are needed. Pictured is an artist’s interpretation of the printer.
Illustration Credit: Ryan Allen from Second Bay Studios
(CC BY-NC-ND 3.0)

Getting vaccines to people who need them isn’t always easy. Many vaccines require cold storage, making it difficult to ship them to remote areas that don’t have the necessary infrastructure.

MIT researchers have come up with a possible solution to this problem: a mobile vaccine printer that could be scaled up to produce hundreds of vaccine doses in a day. This kind of printer, which can fit on a tabletop, could be deployed anywhere vaccines are needed, the researchers say.

“We could someday have on-demand vaccine production,” says Ana Jaklenec, a research scientist at MIT’s Koch Institute for Integrative Cancer Research. “If, for example, there was an Ebola outbreak in a particular region, one could ship a few of these printers there and vaccinate the people in that location.”

The printer produces patches with hundreds of microneedles containing vaccine. The patch can be attached to the skin, allowing the vaccine to dissolve without the need for a traditional injection. Once printed, the vaccine patches can be stored for months at room temperature.

Effects of brain stimulation can be conditioned

Brain activity can be stimulated with transcranial magnetic stimulation.
Photo Credit: © RUB, Marquard

What worked with Pavlov's dog also works with an artificially induced change in nerve cell activity.

Researchers at the Ruhr University Bochum have succeeded in a special form of classic conditioning. In a group of 75 people, they showed that effects of transcranial magnetic stimulation, or TMS for short, can only be triggered by hearing a sound. Prof. Dr. Burkhard Pleger from the neurology of the Bergmannsheil University Hospital describes the results together with doctoral students Stefan Ewers and Timo Dreier as well as other colleagues in the journal Scientific Reports.

Magnetic stimulation causes the thumb muscle to contract

For the TMS, a magnetic coil is placed from the outside over a specific part of the brain. The strong magnetic field stimulates the underlying nerve cells to act. If you stimulate a certain area of the motor cortex in this way, the index finger or the thumb moves, for example. The Bochum team used the so-called paired pulse TMS stimulation for its work. Two TMS stimuli followed each other every twelve milliseconds, which leads to a stronger contraction of a muscle on the thumb than a TMS individual stimulation. In the conditioning phase, the researchers always combined these paired pulses TMS with a tone that the participants were presented via headphones parallel to the TMS stimulus.

Rare variants of an inflammation 'brake' gene may help reveal outcomes of kidney disease

Paradoxically, a gene variant that increases inflammation also has a protective effect on the kidneys. Seen here, kidney cells nuclei (blue) and an influx of immune regulatory cells (pink) that prevent damage in an injured kidney.
Photo Credit: Garvan Institute of Medical Research

A gene that controls inflammation could pave the way for more precise disease diagnostics and personalized treatments for kidney disease. 

The discovery of variants of an inflammation ‘brake’ gene brings scientists a step closer to personalized treatment for people at risk of kidney disease and kidney failure. 

Researchers at UNSW Sydney, the Garvan Institute of Medical Research, and Westmead Hospital, found that common genetic variants of TNFAIP3, which increase inflammation in the body, can paradoxically protect the kidneys from damage in the short term.  

“We wanted to investigate whether inherited differences in how people regulate inflammation could lead to better or worse kidney health outcomes,” says Professor Shane Grey, senior author of the paper and Head of the School of Biotechnology and Biological Sciences (BABS) at UNSW. 

The findings, published today in the journal Kidney International, could be used to help determine how well people will recover from kidney injury.  

“Our discovery that some genetic variants can be protective against inflammation could lead to a simple genetic test that helps predict the risk of kidney disease for patients,” says Prof. Grey.   

Study Finds Significant Variation in Anatomy of Human Guts

Photo Credit: Lauren Nichols.

New research finds there is significant variation in the anatomy of the human digestive system, with pronounced differences possible between healthy individuals. The finding has implications for understanding the role that the digestive tracts anatomy can play in affecting human health, as well as providing potential insights into medical diagnoses and the microbial ecosystem of the gut.

“There was research more than a century ago that found variability in the relative lengths of human intestines, but this area has largely been ignored since then,” says Amanda Hale, co-first author of the study and a Ph.D. candidate at North Carolina State University. “When we began exploring this issue, we were astonished at the extent of the variability we found.”

“If you’re talking to four different people, odds are good that all of them have different guts, in terms of the relative sizes of the organs that make up that system,” says Erin McKenney, corresponding author of the study and an assistant professor of applied ecology at NC State. “For example, the cecum is an organ that’s found at the nexus of the large and small intestine. One person may have a cecum that is only a few centimeters long, while another may have a cecum the size of a coin purse. And we found similar variability for many digestive organs.”

Increased risk of testicular cancer in people with neuropsychiatric disabilities

Left: Ingrid Glimelius, professor at the Department of Immunology, Genetics and Pathology, Uppsala University
Right: Anna Jansson, PhD student at the Department of Immunology, Genetics and Pathology, Uppsala University
Photo Credit: Ewa Ahlin

A new study from researchers at Uppsala University and the Academic Hospital shows that men who have a neuropsychiatric disability, such as autism and ADHD, also have a slightly increased risk of suffering from the testicular cancer form seminoma. This is the first study to show such a relationship and the results are published in the scientific journal British Journal of Cancer.

Testicular cancer is the most common cancer disease in young men and the underlying causes are still very unknown.

"Since you can have a testicular cancer removed and thus cure the disease, it is important to seek care on time if you feel a lump in the testicle", says Ingrid Glimelius, chief physicist at the oncology clinic, Academic Hospital, and professor at Uppsala University.

The new study has focused on patients who have had testicular cancer in Sweden. A total of 6,166 patients have been included and compared with 61,660 age-matched but without testicular cancer. Registry data have been invested where psychiatric diagnoses prior to cancer diagnosis were more common in patients affected by testicular cancer than in the control group.

Scientists Develop Effective Silicon Surface Processing Technology

The technology will be useful in the creation of solar cells, as well as in biomedicine, chemistry, and IT.
 Photo Credit: Ilya Safarov

A team of scientists from Ekaterinburg (UrFU), Moscow, and St. Petersburg has developed a new technology for processing silicon wafers. It is a hybrid chemical and laser texturing, in which the wafer is treated with a femtosecond laser beam after chemical exposure to various reagents. Pre-chemical etching allows for five times faster laser treatment and improves light absorption over a broad spectral range. The technology will be useful in making solar cells. It could also be used in biomedicine for highly sensitive sensors for DNA analysis and detection of viruses and bacteria. It is also used in chemistry and in information and communication technologies. A description of the new technology has been published in the journal Materials.

"Currently, the formation of light-absorbing micro-reliefs on the surface of silicon wafers is achieved by a chemical process that is relatively inexpensive and used on an industrial scale. However, after chemical treatment, the wafers have a significant reflection coefficient, which reduces the efficiency of solar cells. An alternative method is laser treatment of the wafers. It reduces the reflection, but requires a significant amount of time using a femtosecond laser. Our proposed laser treatment after chemical etching reduces the processing time by a factor of five. At the same time, the reflection coefficient of wafers processed by the hybrid method is 7-10% lower than after chemical treatment," says Vladimir Shur, Director of the Ural Multiple Access Center "Modern Nanotechnologies" of the UrFU.

Algae in Swedish lakes provide insights to how complex life on Earth developed

Lönsboda, Sweden
Photo Credit: Johanna Nilsson

By studying green algae in Swedish lakes, a research team, led by Lund University in Sweden, has succeeded in identifying which environmental conditions promote multicellularity. The results give us new clues to the amazing paths of evolution.

The evolution of multicellular life has played a pivotal role in shaping biological diversity. However, we have up until now known surprisingly little about the natural environmental conditions that favor the formation of multicellular groups.

The cooperation between cells within multicellular organisms has enabled eyes, wings and leaves to evolve. The predominant explanation for why multicellularity evolves is that being in a group enables species to better cope with environmental challenges – where being in a large group can, for instance, protect cells against being eaten.

"Our results challenge this idea, showing that multicellular groups form, not because they are inherently beneficial, but rather as a by-product of single-celled strategies to reduce environmental stress. In particular, cells produce a range of substances to protect themselves from the environment and these substances appear to prevent daughter cells from dispersing away from their mother cell", says Charlie Cornwallis, biology researcher at Lund University.

UC Irvine biologists discover bees to be brew masters of the insect world

The UCI study found that the cellophane bee (pictured) ‘brew’ a liquid food for their offspring.
Photo Credit: Tobin Hammer

Scientists at the University of California, Irvine have made a remarkable discovery about cellophane bees – their microbiomes are some of the most fermentative known from the insect world. These bees, which are named for their use of cellophane-like materials to line their subterranean nests, are known for their fascinating behaviors and their important ecological roles as pollinators. Now, researchers have uncovered another aspect of their biology that makes them even more intriguing.

According to a study published in Frontiers in Microbiology, cellophane bees “brew” a liquid food for their offspring, held in chambers called brood cells. The microbiome of these brood cells is dominated by lactobacilli bacteria, which are known for their role in fermenting foods like yogurt, sauerkraut and sourdough bread. The researchers found that these bacteria are highly active in the food provisions of cellophane bees, where they likely play an important role as a source of nutrients for developing larvae.