Synopsis: Materials:

"We can now study the atomic details of microtubule polymerization and depolymerization to develop a complete description of microtubule dynamics,

but surface tension keeps it from leaking into the side channels, while still allowing the cells to enter. hat the key,

surface tension drives where it goes, so we decided to use surface tension to our advantage. oon,

Kamm was using the device in his lab: In a 2011 study, researchers in his group discovered that breast cancer cells can break free from tumors

But the nanoclews are coated with a positively charged polymer that breaks down the endosome, setting the nanoclew free inside the cell.

while they were initially designing photosensitive polymers for drug delivery applications. Once they came up with a polymer that responded to UV light,

they realized that this did not permeate well through skin and could cause damage to healthy cells. e

How it works The nanoparticles are prepared from molecules (synthetic macromolecules commonly called plastics) that have a protective,

hydrophilic (water-loving) shell and a hydrophobic (water-fearing) spherical core. he polymers are synthetized to ensure that

polymers are released into the water. While the polymer released (polyethylene glycol) is recognized as safe and used in various food, pharmaceutical and cosmetics products,

it would be ideal if no material was released or if it could be used by parts of the ecosystem to further minimize environmental impact.

and is well below limits for metals put in place by the Environmental protection agency and World health organization. Dankovich nonprofit company page Drinking Paper, works together with the nonprofit WATERISLIFE

To circumvent this problem the team developed a simple method to densely coat the nanoparticles with a nonsticky polymer called PEG,

As a next step, Bertrand said it would be interesting to design a system where no polymer is released,

however, remains an open question. hese findings will be exciting to both the materials science and the biochemistry communities, said Quiroz. heyl be able to push the limits of what we know about these kinds of materials

The researchers used a combination of X-ray crystallography techniques and in-vitro analysis to study the bacteria.

Jost performed crystallography to establish the shapes of the structures, while the Spanish researchers, Drennan notes, id all of the control experiments to show that we were really thinking about this right,

which incorporates nanoparticles into polymers through a technique called electrospinning, was developed by a team from the University of North Texas System College of Pharmacy,

"Van der Merwe was assisted by Prof Frank Graewe, head of the Division of Plastic Reconstructive Surgery at SU FMHS, Prof Rafique Moosa, head of the FMHS Department of Medicine, transplant

For example, after the implantation of an artificial ureter, urease crystals often start to grow inside

the David H. Koch (1962) Professor in Engineering in the Department of Materials science and engineering and a Koch Institute investigator who oversaw the sensor development. ather than waiting months to see

The sensor housing, made of a biocompatible plastic, is small enough to fit into the tip of a biopsy needle.

#Powerful Plastic Microscope Brings Better Diagnostic Care for World's Rural Poor, Rice university Reveals You can learn a lot about the state of someone's immune system just by examining their blood under the microscope.

a research team from Rice university has developed recently a plastic, miniature digital fluorescence microscope that can quantify white blood cell levels in patients located in rural parts of the world that are removed far from the modern laboratory."

which consisted of one polystyrene lens and two polymethyl methacrylate aspheric lenses, the researchers used a single-point diamond turning lathe.

reflectors, and USB detectors, combined with the all-plastic housing and lenses will allow for future versions of the prototype to be mass-produced

A spokesperson for Imperial Metals was unavailable for comment. Karina Brino president of the Mining Association of British columbia, said her industry knew the investigation into the dam's collapse would inevitably mean regulatory

At another TCL plant in Hefei, near Shanghai, steel refrigerator frames are bent into shape before being plucked by a blue Yasakawa robot arm that stacks them in neat rows for further assembly.

Scientists Enlist E coli To Make Planet-Saving Plastic Out Of Practically Nothing The Intertubes have buzzing with news of a new way to make plastic without using petroleum or petrochemicals.

Based on artificial photosynthesis, the process uses sunlight and carbon dioxide to make the building blocks for renewable plastics as well as fuels, paints,

and the biodegradable plastic PHB. Moving forward the team will try to figure out how to combine the two bacteria into one integrated step.

In response to this problem the engineers developed a visibly transparent overlay more technically a silica photonic crystal overlay that increases solar cell efficiency by radiating the heat of cells away from them much like how we naturally radiate heat from our bodies to prevent overheating.

The overlay itself was made from patterned silica, fashioned into a thin, transparent material. This design means that the overlay can be laid on top of an unaltered solar cell this is important

The critical feature of the silica overlay is found in its micron-scale pattern, which is designed to maximise the radiating of heat, in the form of infrared light, out and away from the cell into space.

amples from left to right are the solar absorber structure with the planar silica layer on top, the absorber structure with verlayon top,

In this regard they point toward employing nanoprint lithography a common technique for producing nanometer scale patterns in larger quantities to produce silica overlays.

The micromotors have an outer polymer surface that holds the enzyme carbonic anhydrase, which speeds up the reaction between carbon dioxide and water to form bicarbonate.

#The metal that could lead to'indestructable'warships and ultralight cars Researchers have demonstrated a new type of metal

The radical new material, called a metal matrix composite, was developed with the US ARMY. A boat made of such lightweight composites will not sink

despite damage to its structure. The new material also promises to improve automotive fuel economy because it combines light weight with heat resistancealthough syntactic foams have been around for many years,

this is the first development of a lightweight metal matrix syntactic foam.''This new development of very light metal matrix composites can swing the pendulum back in favor of metallic materials,

'said Nikhil Gupta, an NYU School of engineering professor in the Department of Mechanical and Aerospace engineering and the study's co-author.

It was created by Deep Springs Technology and the New york University Polytechnic School of engineering.''The ability of metals to withstand higher temperatures can be a huge advantage for these composites in engine and exhaust components, quite apart from structural parts.'

'The magnesium alloy matrix composite is reinforced with silicon carbide hollow particles and has a density of only 0. 92 grams per cubic centimeter compared to 1. 0 g/cc of water.

Not only does it have a density lower than that of water, it is strong enough to withstand the rigorous conditions faced in the marine environment.

Significant efforts in recent years have focused on developing lightweight polymer matrix composites to replace heavier metal-based components in automobiles and marine vessels.

The technology for the new composite is very close to maturation and could be put into prototypes for testing within three years.

and high buoyancy offered by the new syntactic foams, the researchers explained. The syntactic foam made by DST

and NYU captures the lightness of foams, but adds substantial strength. The secret of this syntactic foam starts with a matrix made of a magnesium alloy,

which is turned then into foam by adding strong, lightweight silicon carbide hollow spheres developed and manufactured by DST.

A single sphere's shell can withstand pressure of over 25,000 pounds per square inch (PSI) before it rupturesne hundred times the maximum pressure in a fire hose.

The hollow particles also offer impact protection to the syntactic foam because each shell acts like an energy absorber during its fracture.

The composite can be customized for density and other properties by adding more or fewer shells into the metal matrix to fit the requirements of the application.

This concept can also be used with other magnesium alloys that are nonflammable. The new composite has potential applications in boat flooring, automobile parts,

and buoyancy modules as well as vehicle armour. h

#The material with the MIDAS touch: New supercooled liquid instantly glows gold when it's touched By Jonathan O'Callaghan for Mailonline Published:

a video captures the moment the material becomes extremely bright after being rubbed by a crystal.

When rubbed by another crystal it suddenly begins to crystallise (shown. Credit: American Chemical Societythe research, reported by the American Chemical Society, was carried out by Kyeongwoon Chung and Dr Jinsang Kim from the University of Michigan.

to scrawl messages such as hear-triggered crystal. he researchers said the molecule may be useful in biosensors,

Water penetrates the steel in the concrete which starts to rust and becomes brittle. Using a type of bacteria that is typically found near active volcanoes,

Metals like lithium can store 10 times as much energy but are unstable and can often catch fire or short circuit.

The bullet's energy is transferred simultaneously to the alloy ball, propelling it towards the target.'

In 2014, physicists at the University of Geneva teleported the quantum state of a photon to a crystal over 15 miles (25km) of optical fibre.

Now a team of geologists have developed a new'geospeedometer'that they argue can help resolve this controversy by providing direct measurements of how long the most explosive types of magma existed as melt-rich bodies of crystal-poor magma before they erupted.

The researchers'geospeedometer is sized based on millimeter quartz crystals that grew within the magma bodies that produced these giant eruptions.

Quartz crystals are typically found in magmas that have a high percentage of silica. This type of magma is very viscous

When the crystals form they often capture small blobs of molten magma known as blebs or melt inclusions.

While the crystal is floating in hot magma, diffusion causes them to gradually acquire the polygonal shape of the crystal void that they occupy.

to calculate how long the crystal existed in the magma before the eruption, 'said Pamukcu. In addition, the researchers compared the results obtained with faceting with results obtained using other techniques.

In quartz, the element titanium can vary sharply between different zones or layers within the crystal.

so the shallower the slope of titanium concentrations across these boundaries today, the longer the crystal spent in magmatic conditions.

so the researchers could use these measurements to provide an independent estimate of how long a crystal spent floating around in the melt.

as long as they erupt magmas that contain quartz crystals, 'said Pamukcu.''We are also confident that we can adapt these techniques to work with other minerals,

like the low-silica basalts commonly erupted from Hawaiian volcanoes.''VOLCANO'S GLOBAL DEVASTATION A volcanic eruption of a similar size to Laki eruption that hit Iceland in 1783 could have global impacts according to the new report.

the team first had to solve the problem of surface tension. The Robobee is so small and light it couldn't break the surface tension of the water at first.

But the researchers worked out a way of making it hover over the water at a certain angle,

'Robert Wood, the Charles river Professor of Engineering and Applied sciences At seas added:''Bioinspired robots, such as the Robobee, are invaluable tools for a host of interesting experiments--in this case on the fluid mechanics of flapping foils in different fluids.''

Conductive Composites has created a method to layer nickel on carbon to form a material that's light

and manufacturing performance advantages of composites and plastics,'the firm says. Using the wallpaper would allow people to easily turn entire rooms into Faraday cages.

By adding composites made of a polymer and reduced graphene oxide, the films are able to detect touch

The secret of its design is a scattering of billions of carbon'nanotubes'-microscopic hollow carbon rods.

and is covered by a scratch resistant hardened glass. the dial has a rechargeable lithium polymer battery,

and the enamel that defends your teeth from decay is protected. Same old circular brushing pattern.

which proved to be tricky in our brass brush test video after the break. So what's the secret sauce behind this new coating?

For those who care about benchmarks, these can apparently resist brass brush weight of up to 2kg

Recent test samples have achieved compressive strengths of 7, 000psi twice the strength of ordinary concrete and have demonstrated resistance to water and chemical erosion.

Plumestop is composed of very fine particles of activated carbon (1-2 m) suspended in water through the use of unique organic polymer dispersion chemistry.

and encapsulates it in a netlike cage made of 3d-printed elastomer that forms to the body.

it changes the membrane's surface tension.""That change is very tiny--as small as a few nanometers or less,

#Wood instead of petroleum: Producing chemical substances solely from renewable resources Petroleum might well be replaced by wood soon

when it comes to manufacturing chemical substances. Research has made now significant progress towards using sustainable biomass, like wood, as an alternative raw material for chemical production.

Scientists at Johannes Gutenberg University Mainz (JGU) in Germany and at the University of Alabama in Tuscaloosa in the USA recently managed to synthesize two complex chemical substances from wood-based starting materials.

The process can be as cost-effective as the conventional petroleum product-based process and is less damaging to the environment."

substances used to produce automotive coatings, plastics, adhesives, and other commodity materials. At a conference in Goslar in Germany about two years ago, the two researchers realized that their experience

This new work shows that the relevant carbon skeletons can be created solely from wood-based starting materials.

"This shows that the implementation of a wood-based chemical economy is associated not necessarily with decreased cost-efficiency,"added Daniel Stubba, JGU first author of the publication."

like Canada, have extensive available wood resources s

#A'profound'success in treating children and young adults with rare blood disorders Hematology researchers have safely and effectively treated children and young adults for autoimmune blood disorders in a multicenter clinical trial.

Chiang and his colleagues plan next to use X-ray crystallography to create a three-dimensional image of Notch

The groups created brush-shaped polymers with side chains that resemble bristles. From there they attached DNA to the tips of these bristles

A leading neuroscientist at Florida Atlantic University has developed the"Lewy Body Composite Risk Score"(LBCRS) to quickly

The LBCRS study,"Improving the Clinical Detection of Lewy Body Dementia with the Lewy Body Composite Risk Score,

and transition metal dichalcogenides,"said Awschalom.""It's not just that it's faster and easier.

called a solenoid, outside near the tumor. Electricity passed through the solenoid creates a weak radiofrequency field.

The field causes the magnetic tails of the chain to vibrate bursting the liposome spheres,

Through the use of this new ink, more versatile devices on paper or plastic can be made at a rate of 300 per minute, at a very low cost.

designing the first on-chip metamaterial with a refractive index of zero, meaning that the phase of light can travel infinitely fast.

"The metamaterial consists of silicon pillar arrays embedded in a polymer matrix and clad in gold film.

"said Roman Engel-Herbert, assistant professor of materials science and engineering.""But there are some materials, like vanadium oxide, that you can add to existing devices to make them perform even better."

and oxygen, had an unusual property called the metal-to-insulator transition. In the metal state, electrons move freely,

In order to create a sharp metal-to-insulator transition, the ratio of vanadium to oxygen needs to be controlled precisely.

"The metal-to-insulator property of vanadium dioxide can ideally enhance state-of-the-art nonvolatile memories by using the material as an augmentation device,

#Powerful plastic microscope brings better diagnostic care for world's rural poor You can learn a lot about the state of someone's immune system just by examining their blood under the microscope.

a research team from Rice university has developed recently a plastic, miniature digital fluorescence microscope that can quantify white blood cell levels in patients located in rural parts of the world that are removed far from the modern laboratory."

which consisted of one polystyrene lens and two polymethyl methacrylate aspheric lenses, the researchers used a single-point diamond turning lathe.

reflectors, and USB detectors, combined with the all-plastic housing and lenses will allow for future versions of the prototype to be mass-produced d

#Gene on-off switch works like backpack strap A research team based in Houston's Texas Medical center has found that the proteins that turn genes on by forming loops in human chromosomes work like the sliding plastic adjusters on a grade-schooler

#Cyclic healing removes defects in metals while maintaining strength When designing a new material, whether for an airplane, car, bridge, mobile device,

gentle stretching to eliminate preexisting defects in metal crystals. Their results have been published online today (Monday, Oct 19) in the Proceedings of the National Academy of Sciences.

Most materials are made of crystals. When materials fail, it is usually the result of defects in the crystal or in the arrangement of multiple crystals in a polycrystalline structure.

While much research has been done on metal fatigue at larger scales, new technologies are just now allowing researchers to see how atomic-scale defects nucleate,

In this study, the researchers used transmission electron microscopy to look inside sub-micrometer-sized specimens of aluminum crystals as they subjected the samples to stressors like repeated, small-amplitude deformation or fatigue loading.

a process that repetitively stretches the crystal, helps to unpin or shakedown rows of atomic defects known as dislocations in the metal and move these dislocations closer to free surfaces in the sample.

Image forces, which act to minimize the energy of the defects, attract the dislocations closer to the free surfaces and force them out of the crystal.

As a result, the crystal"heals,"becoming essentially free of preexisting dislocations, thereby significantly increasing its strength.

because cyclic deformation has an opposite effect in micro-and macro-scale metal crystals. In these larger samples, repeated stretching generally leads to the creation, accumulation and interaction of defects,

under certain controlled conditions, can lead to the removal of defects from crystals of small volume,

#From good to bad with a copper switch At the molecular level, the difference between Doctor Jekyll and Mr Hyde lies in a metal, copper.

According to a new SISSA study, the mechanism underlying this change is a metal, copper, or rather a particular region of the protein to which the metal binds,

#Super-slick material makes steel better, stronger, cleaner Steel is ubiquitous in our daily lives.

We cook in stainless steel skillets, ride steel subway cars over steel rails to our offices in steel-framed building.

Steel screws hold together broken bones, steel braces straighten crooked teeth, steel scalpels remove tumors.

Most of the goods we consume are delivered by ships and trucks mostly built of steel.

While various grades of steel have been developed over the past 50 years, steel surfaces have remained largely unchanged--and unimproved.

The steel of today is as prone as ever to the corrosive effects of water and salt and abrasive materials such as sand.

Steel surgical tools can still carry microorganisms that cause deadly infections. Now researchers at the Harvard John A. Paulson School of engineering and Applied sciences (SEAS) have demonstrated a way to make steel stronger, safer and more durable.

Their new surface coating, made from rough nanoporous tungsten oxide, is the most durable antifouling and anti-corrosive material to date,

capable of repelling any kind of liquid even after sustaining intense structural abuse. The new material joins the portfolio of other nonstick,

antifouling materials developed in the lab of Joanna Aizenberg, the Amy Smith Berylson Professor of Materials science and core faculty member of the Wyss Institute for Biologically Inspired Engineering at Harvard university.

Aizenberg's team developed Slippery Liquid-Infused Porous Surfaces in 2011 and since then has demonstrated a broad range of applications for the super-slick coating, known as SLIPS.

The new SLIPS-enhanced steel is described in Nature Communications.""Our slippery steel is orders of magnitude more durable than any antifouling material that has been developed before,

"said Aizenberg.""So far, these two concepts-mechanical durability and antifouling-were at odds with each other.

We need surfaces to be textured and porous to impart fouling resistance but rough nanostructured coatings are intrinsically weaker than their bulk analogs.

This research shows that careful surface engineering allows the design of a material capable of performing multiple, even conflicting, functions, without performance degradation."

The biggest challenge in the development of this surface was to figure out how to structure steel to ensure its antifouling capability without mechanical degradation.

The team solved this by using an electrochemical technique to grow an ultrathin film of hundreds of thousands of small and rough tungsten-oxide islands directly onto a steel surface."

"Electrochemical deposition is already a widely used technique in steel manufacturing, said Aizenberg.""I don't want to create another line that would cost millions

The team tested the material by scratching it with stainless steel tweezers, screwdrivers, diamond-tipped scribers,

and show anti-biofouling behavior but the tungsten oxide actually made the steel stronger than steel without the coating.

Medical steel devices are one of the material's most promising applications, said Philseok Kim,

Due to the high refractive index (2. 4) of diamond, the photon collection efficiency from the nitrogen vacancy centers in bulk diamond is low."

which is a theoretical model that describes the normal state of most metals at sufficiently low temperatures."

#Single atom alloy platinum-copper catalysts cut costs, boost green technology A new generation of platinum-copper catalysts that require very low concentrations of platinum in the form of individual atoms to cleanly

which"poisons"the desired reactions, for example in polymer electrolyte membrane (PEM) fuel cells, which are the leading contenders for small-scale and mobile power generation not based on batteries or combustion engines.

in order to facilitate downstream polymer production. The current industrial catalyst for butadiene hydrogenation uses palladium and silver.

while a relatively cheap metal, is not nearly as catalytically powerful as platinum, noted Professor of Chemistry Charles Sykes, Ph d.,one of the senior authors on the paper."

"The researchers first conducted surface science experiments to study precisely how platinum and copper metals mix."

"We were excited to find that the platinum metal dissolved in copper, just like sugar in hot coffee, all the way down to single atoms.

We call such materials single atom alloys, "said Sykes. The Tufts chemists used a specialized low temperature scanning tunneling microscope to visualize the single platinum atoms and their interaction with hydrogen."

such as platinum-copper single atom alloy nanoparticles supported on an alumina substrate, and then tested them under industrial pressure and temperatures."

We believe this approach is also applicable to other precious metals if added as minority components in copper."

In the early 2000s, Maria's group had pioneered the single-atom approach for metals anchored on oxide supports as the exclusive active sites for the water-gas shift reaction to upgrade hydrogen streams for fuel cell use.

Together we embarked on a new direction involving single atom alloys as catalysts for selective hydrogenation reactions.

"Sykes and Flytzani-Stephanopoulos have used this approach to design a variety of single atom alloy catalysts that have,

and properties of single atom alloy surfaces and then applied this knowledge to develop a working catalyst.

#Controllable protein gates deliver on-demand permeability in artificial nanovesicles Researchers at the University of Basel have succeeded in building protein gates for artificial nano-vesicles that become transparent only under specific conditions.

Until now, permeability in nanovesicles has been achieved using natural proteins that operate as pores in the protective membrane,

and transition metal dichalcogenides,"said Awschalom.""It's not just that it's faster and easier.

"UW researchers used chemical vapor deposition to grow graphene nanoribbons on germanium crystals. This technique flows a mixture of methane, hydrogen and argon gases into a tube furnace.

armchair edges,"said Michael Arnold, an associate professor of materials science and engineering at UW-Madison.""The widths can be very,

"Not only are designed our facilities to work with all different sorts of materials from metals to oxides,

"What's even more interesting is that these nanoribbons can be made to grow in certain directions on one side of the germanium crystal,

each face of a crystal (1, 1, 1) will have axes that differ from one (1, 1, 0) to the other (1, 0,

At that point, a reflective metal layer is on the bottom.""In this structure--unlike other photodetectors--light absorption in an ultrathin silicon layer can be much more efficient

the researchers designed lenses no larger than the head of a pin and embedded them within flexible plastic.

Then they seeped a polymer between the silicon nanowire pillars. After the plastic support solidified they etched away the silicon backing, leaving bull's-eye patterned black silicon embedded in supple plastic.

This approach gave their lenses unprecedented crisp focusing capabilities, as well as the flexibility that enables them to capture a large field of view.

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