Researchers Find New Method to Produce Conductive Graphene Material Using Bacteria

In order to create new and more efficient computers, medical devices, and other advanced technologies, researchers are turning to nanomaterials: materials manipulated on the scale of atoms or molecules that exhibit unique properties. 

Graphene—a flake of carbon as thin as a single layer of atoms—is a revolutionary nanomaterial due to its ability to easily conduct electricity, as well as its extraordinary mechanical strength and flexibility. However, a major hurdle in adopting it for everyday applications is producing graphene at a large scale, while still retaining its amazing properties.

Mixing Oxidized Graphite with Bacteria

In a paper published in the journal ChemOpen, Anne S. Meyer, an associate professor of biology at the University of Rochester, and her colleagues at Delft University of Technology in the Netherlands, describe a way to overcome this barrier. The researchers outline their method to produce graphene materials using a novel technique: mixing oxidized graphite with bacteria. Their method is a more cost-efficient, time-saving, and environmentally friendly way of producing graphene materials versus those produced chemically, and could lead to the creation of innovative computer technologies and medical equipment.

Thinnest Yet Strongest

Graphene is extracted from graphite, the material found in an ordinary pencil. At exactly one atom thick, graphene is the thinnest—yet strongest—two-dimensional material known to researchers. Scientists from the University of Manchester in the United Kingdom were awarded the 2010 Nobel Prize in Physics for their discovery of graphene; however, their method of using sticky tape to make graphene yielded only small amounts of the material.

“For real applications you need large amounts,” Meyer says. “Producing these bulk amounts is challenging and typically results in graphene that is thicker and less pure. This is where our work came in.”

Lab Procedure

In order to produce larger quantities of graphene materials, Meyer and her colleagues started with a vial of graphite. They exfoliated the graphite—shedding the layers of material—to produce graphene oxide (GO), which they then mixed with the bacteria Shewanella. They let the beaker of bacteria and precursor materials sit overnight, during which time the bacteria reduced the GO to a graphene material.

“Graphene oxide is easy to produce, but it is not very conductive due to all of the oxygen groups in it,” Meyer says. “The bacteria remove most of the oxygen groups, which turns it into a conductive material.”

While the bacterially-produced graphene material created in Meyer’s lab is conductive, it is also thinner and more stable than graphene produced chemically. It can additionally be stored for longer periods of time, making it well suited for a variety of applications, including field-effect transistor (FET) biosensors and conducting ink. FET biosensors are devices that detect biological molecules and could be used to perform, for example, real-time glucose monitoring for diabetics.

“When biological molecules bind to the device, they change the conductance of the surface, sending a signal that the molecule is present,” Meyer says. “To make a good FET biosensor you want a material that is highly conductive but can also be modified to bind to specific molecules.” Graphene oxide that has been reduced is an ideal material because it is lightweight and very conductive, but it typically retains a small number of oxygen groups that can be used to bind to the molecules of interest.

Bacterially-produced Graphene Material - Applications

The bacterially produced graphene material could also be the basis for conductive inks, which could, in turn, be used to make faster and more efficient computer keyboards, circuit boards, or small wires such as those used to defrost car windshields. Using conductive inks is an “easier, more economical way to produce electrical circuits, compared to traditional techniques,” Meyer says. Conductive inks could also be used to produce electrical circuits on top of nontraditional materials like fabric or paper.

“Our bacterially produced graphene material will lead to far better suitability for product development,” Meyer says. “We were even able to develop a technique of ‘bacterial lithography’ to create graphene materials that were only conductive on one side, which can lead to the development of new, advanced nanocomposite materials.”

Source: University of Rochester

Discovery of a New Class of Enzymes to Convert Plant Waste into Eco-friendly Products

A cross-institutional team of scientists has engineered a new family of enzymes to convert plant waste into sustainable and high-value products, such as nylon, plastics and chemicals.

Lignin – A Main Component of New Enzymes

The newly engineered enzyme is active on lignin – one of the main components of plants, which scientists have been trying for decades to find a way of breaking down efficiently. Lignin acts as scaffolding in plants and is central to water-delivery. It provides strength and defence against pathogens.

Professor McGeehan, Director of the Centre for Enzyme Innovation in the School of Biological Sciences at Portsmouth said, “To protect their sugar-containing cellulose, plants have evolved a fascinatingly complicated material called lignin that only a small selection of fungi and bacteria can tackle. However, lignin represents a vast potential source of sustainable chemicals, so if we can find a way to extract and use those building blocks, we can create great things.”

“Cellulose and lignin are among the most abundant biopolymers on earth. The success of plants is largely due to the clever mixture of these polymers to create lignocellulose, a material that is challenging to digest,” he further added.

Engineering of Naturally Occurring Enzymes

The team’s goal is to discover enzymes from nature, bring them into our laboratories to understand how they work, then engineer them to produce new tools for the biotechnology industry. In this case, the team has taken a naturally occurring enzyme and engineered it to perform a key reaction in the breakdown of one of the toughest natural plant polymers.

Current enzymes tend to work on only one of the building blocks of lignin, making the breakdown process inefficient. Using advanced 3D structural and biochemical techniques the team has been able to alter the shape of the enzyme to accommodate multiple building blocks. The results provide a route to making new materials and chemicals such as nylon, bioplastics, and even carbon fiber, from what has previously been a waste product.

The discovery also offers additional environmental benefits – creating products from lignin reduces our reliance on oil to make everyday products and offers an attractive alternative to burning it, helping to reduce CO2 emissions.

An International Research Team of Specialized Experts

The research team was made up of an international team of experts in structural biology, biochemistry, quantum chemistry and synthetic biology at the Universities of Portsmouth, Montana State, Georgia, Kentucky and California, and two US national laboratories, NREL and Oak Ridge.

Professor McGeehan said, “We now have proof-of-principle that we can successfully engineer this class of enzymes to tackle some of the most challenging lignin-based molecules and we will continue to develop biological tools that can convert waste into valuable and sustainable materials.”

The research was jointly funded by the Biotechnology and Biological Sciences Research Council (BBSRC), National Science Foundation (NSF), and the DOE EERE Bioenergy Technologies Office. The 3D enzyme structures that underpinned this work were solved at the Diamond Light Source, the UK’s national synchrotron science facility in Oxford. 

Source: UoP News

Newly Engineered Thermoplastic Alloy by Polyscope Polymers for Medical Segment

Polyscope Polymers B.V. has introduced a new engineering thermoplastic alloy combining the benefits of styrene maleic anhydride (SMA) and polymethyl methacrylate (PMMA) to meet the needs of the rapidly growing point-of-care (POC) microfluidic medical test device segment. 

Features of XILOY™ Alloy

The injection moldable polymer, called XILOY™ SO2315 SMA/PMMA alloy, offers excellent optical properties, biocompatibility with a variety of proprietary coatings, reagents, and blood and tissue products, and maintains high dimensional stability to assure accurate and reliable immunoassay test results. The material is in use on devices completing their final agency reviews and expected to be commercially available to medical professionals soon.

Use of SMA and PMMA Alloy to Mold Microfluidic Cassettes

The newest material being used to mold microfluidic cassettes is an alloy of SMA and PMMA. The specific reactivity of anhydride groups on the SMA portion of XILOY SO2315 copolymer is especially helpful in microfluidic chip applications for its intrinsic ability to react with the “bioanchor,” which captures and binds to analytes (substances/chemicals of interest, e.g. amino acids, peptides, proteins) in the fluid sample, simplifying the post-mold coating process while, at the same time, making it more robust and cost-effective. 

SMA also provides higher thermal stability than PS for tests requiring heat to process samples, plus it maintains very-high dimensional stability to assure micro channels operate properly and cassettes fit into test devices. SMA is not especially miscible with PS, leading to a copolymer that is more opaque than transparent. Instead, chemists combine it with PMMA, with which it is highly miscible. 

The PMMA portion of the copolymer provides excellent transparency for optical detection test methods and has good biological compatibility with human tissue and fluids. The resulting copolymer is chemically compatible with the proprietary coatings and reagents typically used on microfluidic cassettes. It also processes easily and maintains consistent tight dimensions for intricate molded micro patterns that are critical to accurate and reliable rest results. 

Use of XILOY SO2315 Copolymer in Further Applications

In addition to use for disposable microfluidic cassettes for POC medical diagnostic devices, XILOY SO2315 copolymer is also appropriate for use in a variety of demanding applications in lighting, display, housewares, and consumer disposable applications. 

 

Source: Polyscope Polymers BV

Covestro Joins Carbon to Upscale 3D Printing for Digital Mass Production

Covestro has partnered Silicon Valley based tech company Carbon to upscale 3D Printing process 

to meet industrial demand of mass production. 

Joint Forces to Prove Mass Production Viability

Silicon Valley based company Carbon has developed Digital Light Synthesis™ (DLS™) technology, 

which can accelerate the production of parts up to a hundredfold compared to previous processes. 

After years of R&D, Carbon developed a novel polyurethane liquid resin suitable for production parts.

Covestro is a key partner in the scale-up and high-volume production of this material.

 The company invested a significant sum to enable the production in commercial quantity. 

As a result, joint forces proving mass production viability of the 3D-printing process and the 

respective material. 

"Our biggest challenge in the upscaling of additive manufacturing until series production lies in the supply of suitable materials in the required quality and quantity," explains Patrick Rosso, global head of additive manufacturing at Covestro. "By partnering with companies like Carbon, we are pushing existing scale boundaries and supporting various industries along the value chain on their way to digital mass production.” 

Production Using DLS™ Technology on a Large Scale

Efficient manufacturing process DLS™ technology developed by Carbon, is now being used for the 

first time on a large scale. Like stereolithography, the workpiece is created in a vat of liquid plastic

 resin that is cured by means of UV radiation. 

At Carbon’s DLS™ technology, oxygen is supplied from below to counteract the curing and thus 

creating a liquid dead zone. For this purpose, the bottom of the vessel is made of a light- and 

air-permeable membrane, like a contact lens. Due to this dead zone, the printed part can be 

pulled continuously upward without the formation of individual layers. 

Production using DLS™ technology is up to 100 times faster than with stereolithography – another

 important prerequisite for industrial mass production. In that context, a proprietary process combines 

software, hardware and materials. It imparts the desired technical and mechanical properties to the 

finished parts. 

Rising Demand of 3D Printing in Industrial Mass 

Production

3D printing offers unique opportunities to produce three-dimensional, often complex shaped parts 

in one single step. While predominantly prototypes and sample parts have been produced in small 

numbers so far, many industries are increasingly interested in industrial mass production. 

Covestro is currently researching materials to enable an extended range of industrial applications. 

To this end, the company is upgrading laboratories for 3D printing at its Leverkusen, Pittsburgh and 

Shanghai sites, where it develops and tests material solutions for serial additive manufacturing in 

collaboration with different customers. 
 

Source: Covestro

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Hemp fiber-reinforced plastic wins product of the year

An audience at the 16th EIHA Hemp Conference, which took place in Germany in June, has voted for a hemp fiber reinforced plastic material as one of its hemp products of the year.

BioLite, a polypropylene (PP) reinforced with 30% hemp fibers benefits from the strength of the fibers, making it strong, light and durable, its manufacturer, Trifilon, says. The new material is suitable for lightweight automotive construction and consumer goods and was used in this instance to make a trolley case.

Michelin & GM Develop New Generation of Airless Wheel Technology

Michelin and General Motors presented a new generation of airless wheel technology, the MICHELIN Uptis Prototype (or “Unique Puncture-proof Tire System”), at the Movin’On Summit for sustainable mobility. GM intends to develop this airless wheel assembly with Michelin and aims to introduce it on passenger vehicles as early as 2024.

Michelin Uptis Prototype

Later this year, GM will initiate real-world testing and validation of the Uptis Prototype on a Michigan test fleet of Chevrolet Bolt EVs.

“General Motors is excited about the possibilities that Uptis presents, and we are thrilled to collaborate with Michelin on this breakthrough technology,” said Steve Kiefer, senior vice president, Global Purchasing and Supply Chain, General Motors. “Uptis is an ideal fit for propelling the automotive industry into the future and a great example of how our customers benefit when we collaborate and innovate with our supplier partners.”

Airless Technology

Airless technology makes the Uptis Prototype eliminate flats and blowouts. This means Uptis offers significant potential for reducing the use of raw materials and waste, contributing to GM’s vision for a world with zero crashes, zero emissions and zero congestion as it:

• Reduces the number of punctured or damaged tires that are scrapped before reaching the end of their life cycle.
• Reduces the use of raw materials, energy for production and emissions linked to the manufacture of spare tires and replacement tires that are no longer required.
• Lasts longer by eliminating irregular wear and tear caused by over- or under-inflation.
• Reduces dangers related to flats and blowouts. 

Source: General Motors

New Industrial Process to Develop CO2-based Elastic Textile Fibers - Covestro & RWTH

Dress with CO2: Two research projects have succeeded in making elastic textile fibers based on CO2 and so partly replacing crude oil as a raw material. Covestro and its partners, foremost the Institute of Textile Technology at RWTH Aachen University and various textile manufacturers, are developing the production process on an industrial scale and aim to make the innovative fibers ready for the market. They can be used for stockings and medical textiles, for example, and might replace conventional elastic fibers based on crude oil. .

Further Milestone in the Use of CO2 as an Alternative Raw Material

The elastic fibers are made with a chemical component that consists in part of CO2 instead of oil. This precursor called cardyon® is already used for foam in mattresses and sports floorings. And now it is being applied to the textile industry.

“That’s a further, highly promising approach to enable ever broader use of carbon dioxide as an alternative raw material in the chemical industry and expand the raw materials base,” says Dr. Markus Steilemann, CEO of Covestro. “Our goal is to use CO2 in more and more applications in a circular economy process and save crude oil.” 

Sustainable Production Process

The fibers are made from CO2-based thermoplastic polyurethane (TPU) using a technique called melt spinning, in which the TPU is melted, pressed into very fine threads and finally processed into a yarn of endless fibers. Unlike dry spinning, which is used to produce conventional elastic synthetic fibers such as Elastane or Spandex, melt spinning eliminates the need for environmentally harmful solvents. A new chemical method enables carbon dioxide to be incorporated in the base material, which also has a better CO2 footprint than traditional elastic fibers. 

“The CO2-based material could be a sustainable alternative to conventional elastic fibers in the near future,” states Professor Thomas Gries, Director of the Institute of Textile Technology at RWTH Aachen University. “Thanks to our expertise in industrial development and processing, we can jointly drive establishment of a new raw materials base for the textile industry.” 

Development of the method of producing fibers from CO2-based thermoplastic polyurethane has been funded by the European Institute of Innovation and Technology (EIT). It will now be optimized as part of the “CO2Tex” project, which is to be funded by the German Federal Ministry of Education and Research (BMBF) so as to enable industrial production in the future. “CO2Tex” is part of “BioTex Future,” a project initiative of RWTH Aachen University. The initiative is devoted to developing production and processing technologies to facilitate the future market launch of textile systems from bio-based polymeric materials.

Development Partners Display Interest

What makes the CO2-based TPU fibers so special is their properties: They are elastic and tear-proof and so can be used in textile fabrics. Initial companies from the textile and medical engineering sectors have already tested the CO2-based fibers and processed them into yarns, socks, compression tubes and tapes. 

The aim of launching CO2-based textiles on the market is to promote a material cycle in the textile and clothing industry based on sustainable resources.

Source: Covestro