Saturday, April 11, 2020

THE MUSIC OF THE SPHERES (X4)
Researcher unraveling SARS-CoV-2 spike protein through music (Update)

by Kim Martineau, Massachusetts Institute of Technology
MIT Professor Markus Buehler designs new proteins with the help of artificial intelligence. He recently translated the spike protein of the novel coronavirus (SARS-Cov-2) into sound to visualize its vibrational properties, as seen here, which could help in finding ways to stop the virus. Primary colors represent the spike’s three protein chains. Credit: Markus Buehler

The proteins that make up all living things are alive with music. Just ask Markus Buehler: The musician and MIT professor develops artificial intelligence models to design new proteins, sometimes by translating them into sound. His goal is to create new biological materials for sustainable, non-toxic applications. In a project with the MIT-IBM Watson AI Lab, Buehler is searching for a protein to extend the shelf-life of perishable food. In a new study in Extreme Mechanics Letters, he and his colleagues offer a promising candidate: a silk protein made by honeybees for use in hive building.


In another recent study, in APL Bioengineering, he went a step further and used AI discover an entirely new protein. As both studies went to print, the Covid-19 outbreak was surging in the United States, and Buehler turned his attention to the spike protein of SARS-CoV-2, the appendage that makes the novel coronavirus so contagious. He and his colleagues are trying to unpack its vibrational properties through molecular-based sound spectra, which could hold one key to stopping the virus. Buehler recently sat down to discuss the art and science of his work.

Q: Your work focuses on the alpha helix proteins found in skin and hair. Why makes this protein so intriguing?

A: Proteins are the bricks and mortar that make up our cells, organs, and body. Alpha helix proteins are especially important. Their spring-like structure gives them elasticity and resilience, which is why skin, hair, feathers, hooves, and even cell membranes are so durable. But they're not just tough mechanically, they have built-in antimicrobial properties. With IBM, we're trying to harness this biochemical trait to create a protein coating that can slow the spoilage of quick-to-rot foods like strawberries.

Q: How did you enlist AI to produce this silk protein?

A: We trained a deep learning model on the Protein Data Bank, which contains the amino acid sequences and three-dimensional shapes of about 120,000 proteins. We then fed the model a snippet of an amino acid chain for honeybee silk and asked it to predict the protein's shape, atom-by-atom. We validated our work by synthesizing the protein for the first time in a lab—a first step toward developing a thin antimicrobial, structurally-durable coating that can be applied to food. My colleague, Benedetto Marelli, specializes in this part of the process. We also used the platform to predict the structure of proteins that don't yet exist in nature. That's how we designed our entirely new protein in the APL Bioengineering study.


Q: How does your model improve on other protein prediction methods?

A: We use end-to-end prediction. The model builds the protein's structure directly from its sequence, translating amino acid patterns into three-dimensional geometries. It's like translating a set of IKEA instructions into a built bookshelf, minus the frustration. Through this approach, the model effectively learns how to build a protein from the protein itself, via the language of its amino acids. Remarkably, our method can accurately predict protein structure without a template. It outperforms other folding methods and is significantly faster than physics-based modeling. Because the Protein Data Bank is limited to proteins found in nature, we needed a way to visualize new structures to make new proteins from scratch.

Q: How could the model be used to design an actual protein?

A: We can build atom-by-atom models for sequences found in nature that haven't yet been studied, as we did in the APL Bioengineering study using a different method. We can visualize the protein's structure and use other computational methods to assess its function by analyzing its stablity and the other proteins it binds to in cells. Our model could be used in drug design or to interfere with protein-mediated biochemical pathways in infectious disease.
With the MIT-IBM Watson AI Lab, Markus Buehler and his colleagues used artificial intelligence to reproduce the alpha-helical protein that honeybees produce in making silk to build their hives. Credit: Markus Buehler

Q: What's the benefit of translating proteins into sound?

A: Our brains are great at processing sound! In one sweep, our ears pick up all of its hierarchical features: pitch, timbre, volume, melody, rhythm, and chords. We would need a high-powered microscope to see the equivalent detail in an image, and we could never see it all at once. Sound is such an elegant way to access the information stored in a protein.

Typically, sound is made from vibrating a material, like a guitar string, and music is made by arranging sounds in hierarchical patterns. With AI we can combine these concepts, and use molecular vibrations and neural networks to construct new musical forms. We've been working on methods to turn protein structures into audible representations, and translate these representations into new materials.

Q: What can the sonification of SARS-CoV-2's "spike" protein tell us?

A: Its protein spike contains three protein chains folded into an intriguing pattern. These structures are too small for the eye to see, but they can be heard. We represented the physical protein structure, with its entangled chains, as interwoven melodies that form a multi-layered composition. The spike protein's amino acid sequence, its secondary structure patterns, and its intricate three-dimensional folds are all featured. The resulting piece is a form of counterpoint music, in which notes are played against notes. Like a symphony, the musical patterns reflect the protein's intersecting geometry realized by materializing its DNA code.

Q: What did you learn?

A: The virus has an uncanny ability to deceive and exploit the host for its own multiplication. Its genome hijacks the host cell's protein manufacturing machinery, and forces it to replicate the viral genome and produce viral proteins to make new viruses. As you listen, you may be surprised by the pleasant, even relaxing, tone of the music. But it tricks our ear in the same way the virus tricks our cells. It's an invader disguised as a friendly visitor. Through music, we can see the SARS-CoV-2 spike from a new angle, and appreciate the urgent need to learn the language of proteins.

Q: Can any of this address Covid-19, and the virus that causes it?

A: In the longer term, yes. Translating proteins into sound gives scientists another tool to understand and design proteins. Even a small mutation can limit or enhance the pathogenic power of SARS-CoV-2. Through sonification, we can also compare the biochemical processes of its spike protein with previous coronaviruses, like SARS or MERS.

In the music we created, we analyzed the vibrational structure of the spike protein that infects the host. Understanding these vibrational patterns is critical for drug design and much more. Vibrations may change as temperatures warm, for example, and they may also tell us why the SARS-CoV-2 spike gravitates toward human cells more than other viruses. We're exploring these questions in current, ongoing research with my graduate students.

We might also use a compositional approach to design drugs to attack the virus. We could search for a new protein that matches the melody and rhythm of an antibody capable of binding to the spike protein, interfering with its ability to infect.

Q: How can music aid protein design?

A: You can think of music as an algorithmic reflection of structure. Bach's Goldberg Variations, for example, are a brilliant realization of counterpoint, a principle we've also found in proteins. We can now hear this concept as nature composed it, and compare it to ideas in our imagination, or use AI to speak the language of protein design and let it imagine new structures. We believe that the analysis of sound and music can help us understand the material world better. Artistic expression is, after all, just a model of the world within us and around us.

Viral Counterpoint of the Coronavirus Spike Protein (2019-nCoV): soundcloud.com/user-275864738/viral-counterpoint-of-the-coronavirus-spike-protein-2019-ncov>

Composing new proteins with artificial intelligence
More information: Zhao Qin et al. Artificial intelligence method to design and fold alpha-helical structural proteins from the primary amino acid sequence, Extreme Mechanics Letters (2020). DOI: 10.1016/j.eml.2020.100652

This story is republished courtesy of MIT News (web.mit.edu/newsoffice/), a popular site that covers news about MIT research, innovation and teaching.
POSTMODERN ALCHEMY

World's most complex microparticle: A synthetic that outdoes nature's intricacy (Update)

by University of Michigan
Made from curved gold-cysteine nanosheets that all twist in the same direction, the spiky nanoparticle achieved the highest complexity measured. It absorbs UV light and emits twisted light in the visible part of the spectrum. Credit: Wenfeng Jiang, Kotov Lab, University of Michigan

Synthetic microparticles more intricate than some of the most complicated ones found in nature have been produced by a University of Michigan-led international team. They also investigated how that intricacy arises and devised a way to measure it.


The findings pave the way for more stable fluid-and-particle mixes, such as paints, and new ways to twist light—a prerequisite for holographic projectors.

The particles are composed of twisted spikes arranged into a ball a few microns, or millionths of a meter, across.

Biology is a great creator of complexity on the nano- and microscales, with spiky structures such as plant pollen, immune cells and some viruses. Among the most complex natural particles on the scale of the new synthetic particles are spiky coccolithophores. A few microns in diameter, this type of algae is known for building intricate limestone shells around themselves. To better understand the rules that govern how particles like these grow, scientists and engineers try to make them in the lab. But until now, there was no formalized way to measure the complexity of the results.

"Numbers rule the world, and being able to rigorously describe spiky shapes and put a number on complexity enables us to use new tools like artificial intelligence and machine learning in designing nanoparticles," said Nicholas Kotov, the Joseph B. and Florence V. Cejka Professor of Engineering at U-M, who led the project.
If the gold-cysteine nanosheets are designed to remain flat, the result is a moderately complex design that the researchers called a “kayak” particle. Credit: Wenfeng Jiang, Kotov Lab, University of Michigan

The team—which includes researchers at the Federal University of São Carlos and the University of São Paulo in Brazil, as well as the California Institute of Technology and the University of Pennsylvania—used the new framework to demonstrate that their particles were even more complicated than coccolithophores.

The computational arm of the team, led by André Farias de Moura, professor of chemistry at the Federal University, investigated the quantum properties of the particles and the forces acting on the nanoscale building blocks.

One of the key players in producing complexity can be chirality—in this context, the tendency to follow a clockwise or counterclockwise twist. They introduced chirality by coating nanoscale gold sulfide sheets, which served as their particle building blocks, with an amino acid called cysteine. Cysteine comes in two mirror-image forms, one driving the gold sheets to stack with a clockwise twist, and the other tending toward a counterclockwise twist. In the case of the most complex particle, a spiky ball with twisted spines, each gold sheet was coated with the same form of cysteine.


The team also controlled other interactions. By using flat nanoparticles, they created spikes that were flat rather than round. They also used electrically charged molecules to ensure that the nanoscale components built themselves into larger particles, bigger than a few hundred nanometers across, due to repulsion.
These relatively simple particles arise when flat gold nanosheets attach to one another without several conflicting restrictions. Credit: Wenfeng Jiang, Kotov Lab, University of Michigan

"These laws often conflict with each other, and the complexity emerges because these communities of nanoparticles have to satisfy all of them," said Kotov, professor of materials science and engineering and macromolecular science and engineering.

And that complexity can be useful. Nanoscale spikes on particles like pollen keep them from clumping together. Similarly, the spikes on these particles made by the research team help them disperse in virtually any liquid, a property that is useful for stabilizing solid/liquid mixtures such as paints.

The microparticles with twisted spikes also take in UV light and emit twisted—or circularly polarized—visible light in response.

"The understanding of these emissions was one of the hardest parts of the investigation," de Moura said.

From the results of the experiments and simulations, it appears that UV energy was absorbed into the hearts of the particles and transformed through quantum mechanical interactions, becoming circularly polarized visible light by the time it left through the curved spikes.
The limestone shell produced by the coccolithophore Syracosphaera anthos, one of the most complex particles on this scale found in nature, is more intricate than kayak particles but less intricate than the spiky synthetic particle. Courtesy of mikrotax.org

The researchers believe that the tactics they have uncovered can help scientists engineer particles that improve biosensors, electronics and the efficiency of chemical reactions.

The study is titled, "Emergence of Complexity in Hierarchically Organized Chiral Particles," and is published in the journal Science.

Explore further
Making twisted semiconductors for 3-D projection
More information: "Emergence of complexity in hierarchically organized chiral particles" Science (2020). science.sciencemag.org/lookup/ … 1126/science.aaz7949

Coronavirus highlights the painful political truth about health inequality


medical cost
Credit: CC0 Public Domain
Health inequality was a major concern of 20th century social democrats in countries ranging from Britain to Sweden.
During the current coronavirus crisis, it has once again become one of the most crucial issues that social democrats need to address.
Coronavirus itself does not discriminate in terms of class. Indeed, those with the financial means to travel have often been among the first victims. More men than women appear to be dying of it.
Nonetheless, what a difference your position in the  can make.
Access to excellent and  obviously remains a key issue, even allowing for the fact the wealthy may also fail to have access to ventilators in the current crisis. Years of neoliberal cutbacks have undermined the formerly good public health systems that social democrats established from the 1940s.
Significantly, the struggling Italian health care system has suffered from privatisation and substantial budget cuts.
Years of wage stagnation and the growth of precarious work have also resulted in rising economic inequality. This has made it impossible for many workers to build up a financial buffer for hard times and seriously limited their ability to stock up with food and medicines.
Some poorly paid workers cannot afford not to turn up to work even when they have possible symptoms. Others are continuing to work in jobs that put them at risk.
The economically vulnerable are also less likely to be able to afford the technology to enable people to work from home or help children study while schools are closed. Similarly, it is harder for them to buy in food or other services.
Women are disproportionately affected, too
Women may have a lower mortality rate than men, but have often been in a weaker financial position due to wage disparities and precarious and part-time work. In many countries, these factors can also reduce the payments women are entitled to if they become unemployed due to the pandemic.
At the same time, women's (gendered) carer responsibilities will have massively increased. Many are working in industries, such as aged care or health care, with an increased exposure risk. Some are now restricted to home with abusive partners.
Consequently, health professionals have emphasised the importance of having a gendered analysis of the impacts of the pandemic. Similar calls have been made in countries ranging from the US to India.
Bizarrely, conspiracy theories are now appearing suggesting the  is divine punishment for increased gender and same-sex equality. It is apparently all the fault of "gender theory".
The perils of globalisation
The list of COVID-19 scapegoats is a long one. Various racial and  were among the first to experience virus-related discrimination.
Many racial and ethnic groups are also often in an economically vulnerable position, which then exacerbates their existing problems during a pandemic. Remote Indigenous communities are particularly at risk.
Doctors are having to make difficult choices about who gets access to scarce medical equipment. The elderly are at particular risk of being denied treatment in some countries. Older citizens are more prone to dying as a result of the virus, but there are suggestions ageism could be a factor, too.
Meanwhile, the perils of globalisation are becoming clear as global supply chains of crucial medical equipment, chemicals and food are disrupted. Countries are discovering they can no longer manufacture the essential products they need, including medical ones.
Major pharmaceutical and other companies are among those racing to develop treatments and vaccines. But will cheap, generic versions be publicly available or will they be subject to restrictive patents and price gouging?
After all, there are claims the shortage of ventilators in countries such as the US is partly due to firms prioritising producing more expensive and highly profitable models over cheaper, basic ones. Bidding wars for scarce ventilators are already breaking out.
A return to social democracy?
Given the market is not coping and the need for government to intervene is more apparent than ever, one might think the time for social democracy has come again.
Some countries, such as Sweden, are indeed evoking social democratic values of solidarity and caring for others. Controversially, the Swedish government may believe those values are so strong that stricter lockdown provisions are not required to enforce community compliance.
Other social democratic countries such as Denmark were among the first to introduce forms of wage support for those thrown out of work.
However, in a time when even conservative governments in countries such as Germany, Britain and Australia are abandoning neoliberal strictures on fiscal restraint to throw billions at the pandemic and their collapsing economies, the need for social democratic governments may not be as apparent as before.
Furthermore, social democratic governments face the same impossible challenges as conservative ones.
In my recent book on social democracy and equality, I argued that one of the main aims of social democratic governments was to make citizens feel secure and less fearful. Providing good publicly available health services and income support for the sick and unemployed was an important part of this.
But how can any government or political party make people feel secure or less fearful in a pandemic and economic disaster of this scale? This is a once-in-a-hundred-year crisis that could exacerbate xenophobia, as well as existing domestic social and economic divisions.
Consequently, the challenge for social democrats is that issues they would normally address may instead be taken up by their mainstream conservative opponents or those on the far right.
No work, no money: Self-isolation due to COVID-19 pandemic punishes the poor

Provided by The Conversation 

The cold eyes of DUNE: 

International Deep Underground Neutrino Experiment

The cold eyes of DUNE
Analog-to-digital convertors built to work at cryogenic temperatures, such as the prototype
 pictured here, will operate inside of liquid-argon chambers in the Deep Underground 
Neutrino Experiment. Credit: Alber Dyer, Fermilab
How do you detect a particle that has almost no mass, feels only two of the four fundamental forces, and can travel unhindered through solid lead for an entire light-year without ever interacting with matter? This is the problem posed by neutrinos, ghostly particles that are generated in the trillions by nuclear reactions in stars, including our sun, and on Earth. Scientists can also produce neutrinos to study in controlled experiments using particle accelerators. One of the ways neutrinos can be detected is with large vats filled with liquid argon and wrapped with a complex web of integrated circuitry that can operate in temperatures colder than the average day on Neptune.
Industry does not typically use electronics that operate at , so particle physicists have had to engineer their own. A collaboration of several Department of Energy national labs, including Fermilab, has been developing prototypes of the electronics that will ultimately be used in the international Deep Underground Neutrino Experiment, called DUNE, hosted by Fermilab. 
DUNE will generate an intense beam of  at Fermilab in Illinois and send it 800 miles through the Earth's crust to detectors in South Dakota. Results from the experiment may help scientists understand why there is more matter than antimatter, an imbalance that led to the formation of our universe.
Physics and chill
DUNE's neutrino detectors will be massive: a total of four tanks, each as high as a four-story building, will contain a combined 70,000 tons of liquid argon and be situated in a cavern a mile beneath Earth's surface.
Argon occurs naturally as a gas in our atmosphere, and turning it into a liquid entails chilling it to extremely cold temperatures. The atomic nuclei of liquid argon are so densely packed together that some of the famously elusive neutrinos traveling from Fermilab will interact with them, leaving behind tell-tale signs of their passing. The resulting collision produces different particles that scatter in all directions, including electrons, which physicists use to reconstruct the path of the otherwise invisible neutrino.
A strong electric field maintained within the detector causes the  to drift toward wires attached to sensitive electronics. As the electrons travel past the wires, they generate small voltage pulses that are recorded by electronics in the liquid-argon chamber. Amplifiers in the chamber then boost the signal by increasing the voltage, after which they are converted to . Finally, the signals collected and digitized across the entire chamber are merged together and sent to computers outside the detector for storage and analysis.
Challenges for chilled electronics
The electronics in neutrino detectors work the same way as the technology we use in our everyday lives, with one major exception. The integrated circuitry in our phones, computers, cameras, cars, microwaves and other devices has been developed to operate at or around room temperature, down to about minus 40 degrees Celsius. The liquid argon in neutrino detectors, however, is cooled to around minus 200 degrees.
"If you use electronics designed to work at room temperature, rarely do you find that they work anywhere nearly as well as those designed to operate at cryogenic temperatures," said Fermilab scientist David Christian.
In the past, this issue was sidestepped altogether by placing the electronic circuitry outside of the argon tanks. But when you're measuring a limited number of electrons, even the slightest amount of electronics noise can mask the signal you're looking for.
The easiest way to mitigate the problem involves the same tactic you use to keep food from spoiling: Keep it cold. If all the electronics are submerged in the liquid argon, there are fewer thermal vibrations from atoms and a larger signal-to-noise ratio. Placing the electronics in the liquid-argon tank has the added benefit of decreasing the amount of wire you have to use to deliver signals to the amplifiers. If, for example, amplifiers and analog-to-digital converters are kept outside the chamber (as they are in some neutrino detectors), long wires have to connect them to the detectors on the inside.
"If you put the electronics inside the cold chamber, you have much shorter wires and therefore lower noise," said Carl Grace, an engineer at Lawrence Berkeley National Laboratory. "You amplify the signal and digitize it in the argon chamber. You then have a digital interface to the outside world in which noise is no longer a concern."
There are several design challenges these teams have had to overcome during development, not the least of which was determining how to test the durability of the devices.
"These chips will have to operate for a minimum of 20-odd years, hopefully longer," Grace said. "And because of the nature of the argon chambers, the electronics that get put inside of them can't cannot be changed. They cannot be swapped out or repaired in any way."
Since Grace and his team don't have 20 years in which to test their prototypes, they've approximated the effects of aging by increasing the amount of voltage powering the chips to simulate the wear and tear of regular, long-term operation.
"We take the electronics, cool them down and then elevate their voltage to accelerate their aging," Grace said. "By observing their behavior over a relatively short period of time, we can we can then estimate how long the electronics would last if they were operated at the voltages for which they were designed."
Resistance in circuits
Not only do these circuits need to be built to last for decades, they also need to be made more durable in another way.
Electronic circuitry has a certain amount of resistance to the electric current flowing through it. As electrons pass through a circuit, they interact with the vibrating atoms within the conducting material, which slows them down. But these interactions are reduced when the electronics are cooled to cryogenic temperatures, and the electrons that constitute the signal move more quickly on average.
This is a good thing in terms of output; the integrated circuits being built for DUNE will work more efficiently when placed in the . But, as the electrons travel faster through the circuits as temperatures drop, they can begin to do damage to the circuitry itself.
"If electrons have a high enough kinetic energy, they can actually start ripping atoms from the crystal structure of the conducting material," Grace said. "It's like bullets hitting a wall. The wall starts to lose integrity over time."
DUNE chips are designed to mitigate this effect. The chips are fabricated using large constituent devices to minimize the amount of damage accrued, and they are used at lower voltages than normally used at room temperature. Scientists can also adjust operating parameters over time to compensate for any damage that occurs during their many years of use.
Timeline to completion
With preparations for the DUNE well under way and the experiment slated to begin generating data by 2027, scientists from many institutions have been hard at work developing electronic prototypes.
Scientists at Brookhaven National Laboratory are working on perfecting the amplifier, while teams from Fermilab, Brookhaven and Berkeley labs are collaborating on the analog-to-digital converter design. Fermilab has also teamed up with Southern Methodist University to develop the electronic component that merges all of the data within an argon tank before it's transmitted to electronics located outside the cold detector. Finally, researchers working on a competing design at SLAC National Accelerator Laboratory are trying to find a way to efficiently combine all three components into one integrated circuit.
The various teams plan to submit their circuit designs this summer for review. The selected designs will be built and ultimately installed in the DUNE neutrino detectors at the Sanford Underground Neutrino Facility in South Dakota.

Bangladesh's waters reeking with drugs, chemicals

by Saleem Shaikh, SciDev.Net

Antibiotic residues can also make their way to farmlands. 
Credit: Balaram Mahalder (CC BY-SA 3.0)

High levels of antibiotic residues, other medicines and chemicals present in Bangladesh's ponds, canals, lakes, rivers and other surface waters are contributing to a spike in antibiotic resistance in the country, says a new study.

Antibiotic resistance results from microorganisms (such as bacteria, fungi, viruses and parasites) mutating when exposed to antimicrobial drugs that become ineffective in the prevention, treatment and spread of infectious diseases, according to the WHO.

Factors that make low- and middle-income countries like Bangladesh vulnerable to increased emergence and spread of anti-microbial resistance in the environment include poor regulation of antimicrobial drug use, high volume of antimicrobials used in human medicine and agricultural production and poor wastewater management, the study noted.


Published 10 April in Science of the Total Environment, the study found concentrations of ciprofloxacin and clarithromycin to be the highest. Other antibiotics found in the surface waters of rural and urban Bangladesh include amoxicillin,clindamycin, lincomycin, linezolid, metronidazole, moxifloxacin, nalidixic acid and sulfapyridine.
The study findings were based on an analytical technique (chromatography-mass spectrometric analysis) that measures the mass-to-charge ratio of ions. A total of 17 water samples were taken from ponds, canals, lakes, rivers, household hand pumps and sites near submersible pumps and wastewater treatment plants from April to May 2019.

"Because these waters are key sources of consumption for humans, animals and irrigation purposes, dumping of antibiotic residues has become a leading cause for enhanced multi-drug resistance in bacteria that cause diseases in humans, animals and agriculture crops," says Luisa Angeles, lead study author and research scholar at the State University of New York.

According to Angeles, antibiotic residues are continuously released into the natural aquatic environment from hospital wastewater outlet pipes and wastewater treatment plants.

Non-antibiotic drugs and other micro-pollutants are adding to antibiotic-resistance, the study found. For example, the anti-depressant fluoxetine has been found to promote bacterial mutation, which leads to multiple resistance of Escherichia coli to antibiotics such as fluoroquinolones, β–lactams, aminoglycosides, tetracycline, and chloramphenicol.


"The assessment led to the discovery that five agricultural fungicide compounds—namely hexaconazole, imidacloprid, propiconazol, tebuconazole and tricyclazole—were prominently present in the water samples, showing their largescale use to kill farm pests," Angeles tells SciDev.Net.

"Ubiquity of antifungal agents in urban and rural waters is of grave worry, as it may be contributing to the alarming rise of multi-drug resistant fungal diseases (such as Candida auris) recently seen in humans throughout the world," the study said.

Despite elevated risks and growing cases of antibiotic resistance in the country, there is a lack of information about the types, quantity and scale of antibiotics prevalence in surface waters that hampers action to mitigate the risks, says Hanan Balkhy, assistant director-general for antimicrobial resistance at WHO, Geneva.

"The study findings could significantly help plug the information gap and tap official action to address the risks," Balkhy tells SciDev.Net.

He suggests that Bangladesh build a system-wide health-care strategy to promote sane and responsible use of antibiotics in humans, farm animals and crops through evidence-based interventions and actions at the individual and national levels.

More information: Luisa F. Angeles et al. Retrospective suspect screening reveals previously ignored antibiotics, antifungal compounds, and metabolites in Bangladesh surface waters, Science of The Total Environment (2019). DOI: 10.1016/j.scitotenv.2019.136285

Journal information: Science of the Total Environment 

Provided by SciDev.Net

Hacker brings video to audio cassette tape



cassette tape
Credit: CC0 Public Domain
Admit it. Somewhere in your basement or attic are dust-covered boxes filled with your Dad's old cassette tape music collection (your Mom is likely tidier and disposed of hers years ago.) Although last year there was an uptick in sales for audio cassettes at levels not achieved since the early 2000s, the format generally has been considered a useless relic of a long-gone era.
But one YouTube hacker begs to disagree.
Perhaps taking advantage of newfound free time afforded by self-isolation that has been imposed worldwide due to COVID-19, hacker Kris Slyka thought to himself: How can I put old audio  tapes from the Eighties to better use today?
So he applied his knowledge of Python and Java and found a new use for those 4.25" x 2.75" plastic cases packing up to 300 feet of magnetic tape. He repurposed them to record .
It was no small feat. And while the  is not exactly high-def—in fact, it's quite low-def— the accomplishment remains impressive.
Today's high resolution video formats contain 8.3 million pixels and display 240 frames per second. Working with a format—magnetic audio cassette tape—bearing far greater constraints, Slyka was limited to a display of merely 100x75 pixels, a total of 7,500 pixels, and a speed of 5 frames per second. No one will be watching "The Avengers" or "Black Panther" on this format any time soon.
As one headline referred to the invention: "Hacker Figures Out How to Capture Horrible-Quality Video on Audio Cassettes."
Jokes aside, the accomplishment shows that with drive, determination and ingenuity, a spirited developer can make inroads in technology that were considered near impossible in earlier times. And we don't yet know what improvements or practical uses may lie ahead.



In fact, at least one earlier commercial effort to utilize audio tapes for video was made in the 1980s with the Fisher-Price PXL 2000 PixelVision camcorder designed especially for children. The toy proved to be a loser as video quality was abominable, even for audiences of five-year-olds.
Slyka's project accomplished higher-quality results. He was able to double the frame rate by interlacing images. He also was able to make use of the two tracks assigned to audio on cassette tapes by using one of the tracks to encode color instructions. The Fisher-Price camcorder was limited to black-and-white recordings.
Audio cassettes enjoyed immense popularity in the Eighties, propelled largely by the introduction of the Sony Walkman. For the first time, folks could listen to their favorite music outside their homes; unlike transistor radios, the Walkman allowed them to choose their own songs. Cassette players also contributed to the aerobic craze of the Eighties as physical fitness buffs discovered that listening to personal music compilations through stereo earphones made strenuous workouts more pleasurable. By 1989, 83 million cassette tapes were sold.
Fittingly, Slyka used a Sony  recorder for his project. Last summer marked the 40th anniversary of the release of the first Sony Walkman.
While Slyka's creation has room for improvement, it at least gives us some consolation that those old, dusty cassette tapes may yet have a second life. And if not, they make great door st
End of an era: Sony to stop making Betamax tapes

More information: amplifoxed.bandcamp.com/album/side-a-one-day

Zoom security feature let unapproved users view meetings, researchers find


zoom meeting
Credit: CC0 Public Domain
Zoom, the videoconferencing service that has exploded into the vacuum created by the COVID-19 outbreak, has endured the revelation of a string of privacy and security flaws in recent days. Now researchers have identified just such a flaw in a feature marketed specifically as a way to make meetings more secure.
Zoom said Wednesday it had fixed a vulnerability with its Waiting Room feature.
The feature allows meeting hosts to keep would-be participants in a digital queue pending approval. Medical professionals could use it to host multiple telehealth appointments in a row, and hiring managers could conduct stacked  interviews, the company suggested in a February blog post.
As users have encountered problems with "zoombombing"—whereby participants interrupt and derail meetings, often by using offensive imagery or racist slurs—the company has pointed to the waiting room feature as a way to protect from this type of intrusion.
But security researchers examining the desktop client for vulnerabilities found that Zoom servers would automatically send a live video data to users in the meeting's waiting room, even if they had not yet been approved to join by the person holding the meeting. These users were also sent the meeting's decryption key—the code needed to unlock secure communications. Users could hypothetically extract the video , researchers said.
"If you were moderately technically sophisticated, you could watch what was going on while in the waiting room," said Bill Marczak, a fellow at the Citizen Lab and a postdoctoral researcher at UC Berkeley who found the vulnerability. An audio stream of the call, however, was not accessible.
Marczak said he and John Scott-Railton of the Citizen Lab notified Zoom last week. They detailed their findings in a report published Wednesday, after they receive an email from the company saying the issue had been fixed.
On Wednesday, Zoom Chief Executive Eric Yuan mentioned during a webinar held to address  that Zoom had fixed an issue with its waiting room feature.
"We updated our server. Our waiting room  is already fixed," Yuan said on the webinar. "From a server side, we did not send audio and video data to the  client. However, we did send the session key ... . We did not think that was safe, so we changed our server."
Yuan's comment did not align with what Marczak and Scott-Railton found, they wrote. The  was previously accessible, though the issue has since been fixed, Marczak said.
Zoom did not immediately respond to a request for comment about this discrepancy.
Zoom to focus on security, privacy, CEO says, as usage booms during coronavirus crisis

A model for better predicting the unpredictable byproducts of genetic modification

gene
Credit: CC0 Public Domain
Researchers are interested in genetically modifying trees for a variety of applications, from biofuels to paper production. They also want to steer clear of modifications with unintended consequences. These consequences can arise when intended modifications to one gene results in unexpected changes to other genes. A new model aims to predict these changes, helping to avoid unintended consequences, and hopefully paving the way for more efficient research in the fields of genetic modification and forestry.
The research at issue focuses on lignin, a complex material found in trees that helps to give trees their structure. It is, in effect, what makes wood feel like wood.
"Whether you want to use wood as a biofuel source or to create pulp and paper products, there is a desire to modify the chemical structure of lignin by manipulating lignin-specific , resulting in lignin that is easier to break down," says Cranos Williams, corresponding author of a paper on the work and an associate professor of electrical and computer engineering at NC State. "However, you don't want to make changes to a tree's genome that compromise its ability to grow or thrive."
The researchers focused on a tree called Populus trichocarpa, which is a widely used —meaning that scientists who study genetics and tree biology spend a lot of time studying P. trichocarpa.
"Previous research generated models that predict how independent changes to the expression of lignin genes impacted lignin characteristics," says Megan Matthews, first author of the paper, a former Ph.D. student at NC State and a current postdoc at the University of Illinois. "These models, however, do not account for cross-regulatory influences between the genes. So, when we modify a targeted gene, the existing models do not accurately predict the changes we see in how non-targeted genes are being expressed. Not capturing these changes in expression of non-targeted genes hinders our ability to develop accurate gene-modification strategies, increasing the possibility of unintended outcomes in lignin and wood traits.
"To address this challenge, we developed a  that was able to predict the direct and indirect changes across all of the lignin genes, capturing the effects of multiple types of regulation. This allows us to predict how the expression of the non-targeted genes is impacted, as well as the expression of the targeted genes," Matthews says.
"Another of the key merits of this work, versus other models of gene regulation, is that previous models only looked at how the RNA is impacted when genes are modified," Matthews says. "Those models assume the proteins will be impacted in the same way, but that's not always the case. Our model is able to capture some of the changes to proteins that aren't seen in the RNA, or vice versa.
"This model could be incorporated into larger, multi-scale models, providing a computational tool for exploring new approaches to genetically modifying tree species to improve  traits for use in a variety of industry sectors."
In other words, by changing one gene, researchers can accidentally mess things up with other genes, creating  that aren't what they want. The new model can help researchers figure out how to avoid that.
The paper, "Modeling cross-regulatory influences on monolignol transcripts and proteins under single and combinatorial gene knockdowns in Populus trichocarpa," is published in the journal PLOS Computational Biology
Wood formation model to fuel progress in bioenergy, paper, new applications

Journal information: PLoS Computational Biology 

New paper points out flaw in Rubber Hand Illusion raising tough questions for psychology

New paper points out flaw in Rubber Hand Illusion raising tough questions for psychology
A demonstration of the Rubber Hand Illusion. Credit: University of Sussex
A world-famous psychological experiment used to help explain the brain's understanding of the body, as well as scores of clinical disorders, has been dismissed as not fit-for-purpose in a new academic paper from the University of Sussex.
The Rubber Hand Illusion, where synchronous brush strokes on a participant's concealed  and a visible fake hand can give the impression of illusory sensations of touch and of ownership of the fake hand, has been cited in more than 5,000 articles since it was first documented more than 20 years ago.
In a new research paper Dr. Peter Lush, Research Fellow at the Sackler Centre for Consciousness Science at the University of Sussex, demonstrates that the control conditions typically used in the Rubber Hand Illusion do not do they job they need to do.
His results show that the commonly reported effects of the Rubber Hand Illusion can be attributed to imaginative suggestion'—otherwise known as 'hypnosis'.
Dr. Lush is calling for the development of valid control methods for the Rubber Hand Illusion while raising the prospect that suggestion effects could confound many other effects throughout psychological science.
He said: "The Rubber Hand Illusion is a cornerstone of contemporary consciousness science. It has been extended to almost any body part imaginable and investigated in just about any clinical disorder you can imagine.
"This paper prompts the reinterpretation of all this work, and other work which uses the same control methods, such as the full body illusion, the out of body illusion and the enfacement illusion. Existing claims that the  hand illusion is not a suggestion effect are invalid, and therefore it is possible that existing reports of the rubber hand illusion are entirely attributable to suggestion effects."
Last year Dr. Lush and colleagues reported in a paper, currently under  but available as a preprint on PsyArxiv, substantial correlations between response to the Rubber Hand Illusion and response to imaginative suggestion , or phenomenological control, in a large sample of 353 participants. This study shows that response to the Rubber Hand Illusion is, partially or entirely a suggestion effect.
Psychologists have long been aware of the dangers of 'demand characteristics'—in which subjects, often without realising it, say what they implicitly think they ought to say.
Dr. Lush's work takes these concerns much further by showing that how suggestible someone is can dramatically influence what people report in the Rubber Hand Illusion—and potentially in many other experiments too.
Dr. Lush said: "The extent to which phenomenological control confounds psychological science is currently unknown, but may be substantial. If the effects are widespread—and they may well be—psychology will be faced with a new crisis of generalisability."
In the new study, published this week in Collabra: Psychology, an innovative design was employed to test imaginative suggestion in  reports.
Participants were provided with information about the Rubber Hand Illusion procedure (including a text description and a minute-long video demonstration of the illusion) and then asked to fill out a standard questionnaire on what they would expect to happen if they were a participant in the procedure.
Strikingly, people expect the same pattern of results that is typically found in Rubber Hand Illusion studies, both for the 'experimental' conditions and the 'control' conditions.
According to Dr. Lush, this means the control methods that have been used for 22 years of Rubber Hand Iillusion studies, are not fit for purpose because demand characteristics have not been adequately controlled, meaning the  may be, partially or entirely, a suggestion effect.
He added: "Few contemporary scientists seem to be aware of the extent to which imaginative suggestion can drive experience, and so haven't been able to control for  effects in the Rubber Hand Illusion.
"Future studies of the Rubber Hand Illusion—and many other similar effects—will need to take  in suggestibility properly into account, if they are to make justifiable claims about how people experience their bodies."
Study shows expectation important component of rubber-hand illusion

More information: Peter Lush, Demand Characteristics Confound the Rubber Hand Illusion, Collabra: Psychology (2020). DOI: 10.1525/collabra.325