Developing 100 Percent Biodegradable Plastics from Bacteria

 His idea is to use bacteria to make plastics, specifically employing cyanobacteria, a photosynthesis-happy bug, as one of the starting materials. Weiss recently published a paper in Metabolic Engineering that outlines a new production method that would be powered by cyanobacteria and the naturally occurring Halomonas boliviensis.

Weiss recently joined ASU’s Polytechnic campus, where he will work on scaling up the process at the Arizona Center for Algae Technology and Innovation (AzCATI). Here, Weiss describes his idea for making environmentally friendly bioplastics.

Present Issues with Today’s Plastics

Plastics fall into two very distinct categories:

• Those that can be melted down and reused
• Those that cannot be reused

Recycling some plastics can save energy, but all plastics don’t ultimately degrade like biological materials down to “nothingness” or become metabolized by a living creature. Most plastics degrade like rocks: They just break down into smaller and smaller pieces that accumulate in the environment.

Plastics Produced are 100% Biodegradable. Over what time frame?

Degradation times depend on the object and conditions, but bioplastics typically break down faster than plant celluloses, like wood. With lots of biological activity, like in a compost pile, fibers and films will biodegrade within two months. The human body takes about three months to completely dissolve bioplastic suture threads. Something like plastic utensils in the ocean would take longer, but still be unrecognizable within a year.

Essentially, because the average usage-lifetime of a disposable plastic bag in the U.S. is 12 minutes, yet take hundreds of years to degrade, we're looking to bioplastics to create the benefits of disposability without the long-term negative consequences.

How these Bioplastics are Made

Taylor Weiss said:
“We created a symbiotic partnership between two bacteria, each specializing in a specific task. The cyanobacteria use photosynthesis to create sugar and are engineered to constantly excrete that sugar. A second bacteria (Halomonas boliviensis) then consumes the sugar to alternately grow and produce bioplastics in cycles. Additionally, the cyanobacteria are captured in hydrogel beads (made from seaweed extract) that are submerged in saltwater filled with the bioplastic-producing bacteria.”

Process Advantage

Taylor Weiss said:
“In the big picture, we don’t use resources better spent on food production (fresh water and farmable land) to first grow a crop that can be processed into sugar and then fed to the bacteria to make bioplastics. We’ve done this by efficiently bringing together two bacteria species that are among the best on Earth at making sugar and bioplastics.”

Trapping the cyanobacteria in a hydrogel is also critical — it means that the same cyanobacteria can be reused instead of regrown, and because the trapped cells barely grow at all, energy otherwise spent on growth can be redirected toward even greater sugar production. As a bonus, the system seems to stand up to contamination. Weiss didn’t tightly control the system to keep out contaminating bacteria, or add chemicals to kill them. What contamination was present simply didn’t interfere — for more than five months — because our bioplastic-producing bacteria was simply so good at consuming all of the sugar.

Make Process Industrially Viable

The cyanobacteria, the Halomonas boliviensis bacteria and hydrogel have already been industrialized, so each has a lot of proven potential. Using as little of the hydrogel as possible and for as long as possible needs to be further explored. That will help keep costs down. Bringing all these elements together and in real-world conditions at large scales needs to be done. Fortunately, we have a one-of-a-kind academic test bed facility here at AzCATI that is uniquely suited to answer the remaining production questions and push development of the technology.

Source: University of Arizona

Aerion and Lockheed Martin join forces to develop a supersonic business jet

Two leaders in supersonic technology, Aerion and Lockheed Martin announced a Memorandum of Understanding (MOU) to define a formal and gated process to explore the feasibility of a joint development of the world's first supersonic business jet, the Aerion AS2. Over the next 12 months, the companies will work together to develop a framework on all phases of the program, including engineering, certification and production.

Aerion Chairman Robert M. Bass stated, "This relationship is absolutely key to creating a supersonic renaissance. When it comes to supersonic know-how, Lockheed Martin's capabilities are well known, and, in fact, legendary. We share with Lockheed Martin a commitment to the long-term development of efficient civil supersonic aircraft."

Lockheed Martin, known for developing the world's leading supersonic combat aircraft, the F-16, the F-35, and F-22, as well as the Mach 3+ SR-71 reconnaissance aircraft, is committed to fostering new innovations and developing supersonic technologies with civil and commercial applications.
During the last two and a half years, Aerion advanced the aerodynamics and structural design of the AS2 through a previous engineering collaboration agreement with Airbus. Through that effort, the two companies developed a preliminary design of wing and airframe structures, systems layout, and preliminary concepts for a fly-by-wire flight control system.

In May 2017, GE Aviation announced an agreement with Aerion to define a supersonic engine for the AS2. The latest announcement with Lockheed Martin further positions Aerion as the leader in the nascent sector of civil supersonic aviation.

Source:Lockheedmartin

Teijin Limited to Integrate its Carbon Fiber Business in 2018

Teijin Limited has recently announced that it will integrate its subsidiary Toho Tenax Co., Ltd., the core company of Teijin’s carbon fibers business, on April 1, 2018.

Maximizing Corporate Value

Integrating Toho Tenax within Teijin Limited will help maximize corporate value, specifically by expanding comprehensive capabilities through greater sharing of information, technologies and the optimized deployment of human resources throughout the Teijin Group. Teijin expects to strengthen its upstream-to-downstream global business by better leveraging its group synergies in high-performance materials and technology development and know-how.

Growth & Transformation Strategies

Teijin’s current growth and transformation strategies are focusing on core strengths in materials and healthcare business fields as the pillars of its operations, as expressed in its medium-term management plan for 2017-2019 “ALWAYS EVOLVING”. The company is increasingly emphasizing its development of strong, lightweight high-performance materials that offer environmental value solutions to meet demands for higher fuel efficiency in line with intensifying environmental regulations, and businesses focused on the aircraft and automotive fields.

In accordance with the integration, Toho Tenax Europe GmbH, Toho Tenax America, Inc. and Toho Tenax Singapore Pte. Ltd will be renamed Teijin Carbon Europe GmbH, Teijin Carbon America, Inc., and Teijin Carbon Singapore Pte. Ltd., respectively.

Source: Teijin Limited

Breakthrough Technique to 3D Print Fully Functional Electronic Circuits from Plastics

Researchers at the University of Nottingham have pioneered a breakthrough method to rapidly 3D print fully functional electronic circuits. 

Single Step Printing Process

The circuits, which contain electrically-conductive metallic inks and insulating polymeric inks, can now be produced in a single inkjet printing process where a UV light rapidly solidifies the inks.

The breakthrough technique paves the way for the electronics manufacturing industry to produce fully functional components such as 3D antennae and fully printed sensors from multiple materials including metals and plastics.

Combining 2D with 3D Printing

The new method combines 2D printed electronics with Additive Manufacturing (AM) or 3D printing - which is based on layer-by-layer deposition of materials to create 3D products. This expands the impact of Multifunctional Additive Manufacturing (MFAM), which involves printing multiple materials in a single additive manufacturing system to create components that have broader functionalities.

Overcoming Manufacturing Challenges

The new method overcomes some of the challenges in manufacturing fully functional devices that contain plastic and metal components in complex structures, where different methods are required to solidify each material.

Existing systems typically use just one material which limits the functionality of the printed structures. Having two materials like a conductor and an insulator expands the range of functions in electronics. For example, a wristband which includes a pressure sensor and wireless communication circuitry could be 3D printed and customized for the wearer in a single process.

The breakthrough speeds up the solidification process of the conductive inks to less than a minute per layer. Previously, this process took much longer to be completed using conventional heat sources such as ovens and hot plates, making it impractical when hundreds of layers are needed to form an object. In addition, the production of electronic circuits and devices is limited by current manufacturing methods that restrict both the form and potentially the performance of these systems.

Professor Chris Tuck, Professor of Materials Engineering and lead investigator of the study, highlighted the potential of the breakthrough:
“Being able to 3D print conductive and dielectric materials (electrical insulators) in a single structure with the high precision that inkjet printing offers will enable the fabrication of fully customized electronic components. You don’t have to select standard values for capacitors when you design a circuit, you just set the value and the printer will produce the component for you.”

Professor Richard Hague, Director of the Centre for Additive Manufacturing (CfAM) added:
“Printing fully functional devices that contain multiple materials in complex, 3D structures are now a reality. This breakthrough has significant potential to be the enabling manufacturing technique for 21st century products and devices that will have the potential to create a significant impact on both the industry and the public.”

How it Works

Dr Ehab Saleh and members of the team from CfAM found that silver nanoparticles in conductive inks are capable of absorbing UV light efficiently. The absorbed UV energy is converted into heat, which evaporates the solvents of the conductive ink and fuses the silver nanoparticles. This process affects only the conductive ink and thus, does not damage any adjacent printed polymers. The researchers used the same compact, low cost LED-based UV light to convert polymeric inks into solids in the same printing process to form multi-material 3D structures.

With advancements in technology, inkjet printing can deposit of a wide range of functional inks with a spectrum of properties. It is used in biology, tissue bioprinting, multi-enzyme inkjet printing and various types of cell printing, where the ‘ink’ can comprise of living cells.

The breakthrough has established an underpinning technology which has potential for growth in academia and industry. The project has led to several collaborations to develop medical devices, radio frequency shielding surfaces and novel structures for harvesting solar energy.

Source: University of Nottingham

Plastics from Waste Derived BioChemicals & Recycling: 2018 Events

Join us to witness how the field of Polymers & Chemicals is being rejuvenated via Non-Fossil “WASTE” Raw-Materials that are (1) Biobased-Sustainable or (2) Air-Land-Ocean Pollutants”; thereby leading to preservation of petroleum resources, reduction of air-land-ocean pollution, and utilization of free/undesirable raw materials.

June 25-27: BioPlastics: Biobased Re-Invention of Plastics: New York City area

June 28: Plastics Waste: Value-Creation/Healthier Planet: New York City area

Register for the Conference before DECEMBER 31 and get free admission to Bioplastics-2018 course; further details @

http://innoplastsolutions.com/bio.html

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Upcoming Events: 2018

Polyolefins Workshop, Atlanta, GA, March 13-14
Polymers/Bioplastics Failure & Defects, Amsterdam, April 25-26

Perstorp Introduces Line of Renewable Polyols

Perstorp is announcing world’s first portfolio of renewable alternatives to the essential polyols Pentaerythritol (Penta), Trimethylolpropane (TMP), and Neopentyl glycol (Neo).

Low Carbon Footprint Products

The launch is a response to the fast growing global need for more sustainable Coatings, Resins and Synthetic Lubricants to mention a few. This means that Perstorp is the only chemical company in the world to offer all three essential polyols Penta, TMP and Neo in both traditional and renewable forms.

World’s first renewable Penta, known as Voxtar™, was launched in 2010. It can reduce carbon footprint by up to 80% compared to fossil alternatives. The addition of two new innovative products; Evyron™ (partly renewable TMP) and Neeture™ (partly renewable Neo) will give Perstorp’s customers a clear market advantage in creating pro-environmental low carbon footprint products.

Anna Berggren, Global Market Segment Manager for Resins at Perstorp commented: “The time is right to add two new renewable polyols. The market demand for bio-based material is rapidly increasing due to a strong focus on sustainable chemistry and renewable raw materials. We are committed to our environmental responsibility as well as to helping our customers in their sustainable development. We are dedicated to our pro-environment products, giving prioritized supply for pro-environmental partners at all times.”

Committed to the Pro-environmental Walk

Perstorp’s commitment to sustainability runs deep in the company led by CEO, Jan Secher. “This launch is a great achievement and I’m very proud of the engagement from our employees. It’s clear that we are looking to make a difference. Sustainability is in the core of everything we do which also makes it a perfect strategic fit.”

Perstorp’s new pro-environment portfolio is a great example of how they intend to work towards their 2030 ambition to become Finite Material Neutral. “It is a tough ambition but we have to do it. There is no plan B, because we only have one planet,” Jan continues.

Currently Perstorp is devoting 80% of its R&D resources to finding new sustainable solutions and in addition, all Perstorp Swedish plants will switch to using only renewable electricity in 2018. “With the new pro-environment products we are launching at China Coat, we are reaffirming that we believe our molecules can change things for the better”, Jan concludes.

Good for Business and Good for the Environment:

The two new Pro-Environment Polyols – Evyron™ and Neeture™ - complete the portfolio of the three essential polyols in renewable options. The new portfolio is based on a certified mass balance concept. Mass balance is about mixing fossil and renewable in the same existing systems but keeping track of their quantities and allocating them to specific products. This ensures that the quality and performance of the molecules are exactly the same giving customers a real go-pro-environmental choice.

Perstorp’s Pro-Environment Polyols are all ISCC certified which among other things ensures a traceability of the bio-based raw material back to its country of origin. Anna Berggren highlights: “The bio-based material in our products is sustainably sourced and I am proud to say that Perstorp launches world´s first portfolio of renewable polyols. And even better, they will also be the first to become ISCC certified.”

Voxtar™, Evyron™ & Neeture™ is the property of the Perstorp Group and can be subject to registration in many countries.

Source: Perstorp
 

Creation of Mussel-based Adhesive from Intestinal Bacteria

UniCat scientists have reprogrammed strains of the intestinal bacteria Escherichia Coli in such a way, that the biological underwater adhesive of mussels can be created with help of the bacteria. The special feature of the new biogenic super glue is that its adhesive properties can be switched on by irradiation with light. This results in long-awaited possibilities for bonding broken bones or teeth that can be fused together again through this bio-adhesive. These findings will be applied in a spin-off.

Biological Adhesive Proteins

• Regenerative medicine urgently needs powerful adhesives that are biocompatible – well tolerated by the organism in which they are to be used.
• Such adhesives could treat superficial wounds, and could replace plates and screws which are commonly used to treat bone fractures.
• Biological adhesive proteins could not only allow the bonding of bone fragments, but also the fusion of the bone itself.

Biotechnological Process:

• The UniCat members Prof. Dr. Nediljko Budisa from the TU Berlin, Prof. Dr. Holger Dobbek from the HU Berlin and Prof. Dr. Andreas Möglich, now at the University of Bayreuth, have discovered a biotechnological process, through which the biological underwater adhesive of mussels can be produced.
• Mussels mainly live in the tidal and shelf areas of the oceans. There, they must withstand strong currents and salt water. Mussels use a super adhesive to be able to hold on to the seabed. Even in low tides, when mussel beds are no longer covered by water, the adhesive still has to work.
• Using this adhesive, the living mussels can adhere to almost any surface. The mussel releases threads from its foot, consisting of a protein glue. The most important component of this protein glue is the amino acid 3,4-dihydroxy-phenylalanine, known as "DOPA."

How do scientists produce this super adhesive?

Nediljko Budisa:
"To create these mussel proteins, we use intestinal bacteria, which we reprogrammed. They are like our chemical factory through which we produce the super glue."
For this purpose, a special enzyme, that is obtained from the bacterium Methanocaldococcus jannaschii, was altered by the researchers and introduced into Escherichia coli. Subsequently, the modified intestinal bacteria are fed with the amino acid ONB-DOPA (ortho-nitrobenzyl DOPA). Within the ONB-DOPA molecule, the dihydroxyphenyl groups that are responsible for the strong adhesion, are protected. This is similar to a sticker that has its self-adhesive surface covered by a protective film.
The reprogrammed bacterium now builds these amino acids ‘wrapped in protective film’ into proteins, and a bonding protein is obtained, whose adhesive sites are still protected. It is only after the protected adhesive protein has been separated from the bacteria and purified, that the protective groups are removed by means of light of a specific wavelength (365 nm). Through this, the adhesive protein loses its – figuratively spoken – protective film. Its adhesive points are activated and the protein can be targetedly used as a glue.

From research to market - Spin-off planned

The production or enrichment of Mussel Adhesion Proteins (MAPs) had not yet been satisfactorily resolved: the isolation of these organic glues from mussels and other natural sources is inefficient and expensive. Thus, only 1 to 2 grams of this super adhesive can be obtained from 10,000 mussels. Furthermore, the glue-protein from mussels cannot be obtained homogeneously; that is, each batch is different. An additional disadvantage is that the adhesive protein of the mussel must be used almost immediately due to its good adhesive properties. This new procedure from the UniCat scientists can lead to considerable improvements: an increased yield, the avoidance of animal suffering, and a more homogeneous product with adhesive properties that can be switched on.
Two scientists from Budisa’s working group are planning to establish a spin-off based on this idea that is both environmentally friendly and useful for humanity. "This strategy offers new ways to produce DOPA-based wet adhesives for use in industry and biomedicine with the potential to revolutionize bone surgery and wound healing," assert Christian Schipp and Dr. Matthias Hauf. In order to bring their business idea to life, they plan to use the Inkulab, the spin-off laboratory of the Excellence Cluster UniCat at the TU Berlin, and participate in its incubation program.
Prof. Reinhard Schomäcker, who initiated the start-up Inkulab is delighted: "Precisely for innovative ideas such as this, we founded Inkulab together with the Berlin economy. The science and business hub Berlin is greatly enriched by founding such companies. Germany benefits from this entrepreneurial spirit."

Mussel Proteins:
The strong adhesive properties of these organic glues are due to the presence of 1,2-dihydroxyphenyl groups in the side chain of the amino acid L-3,4-dihydroxyphenylalanine (L-DOPA). L-DOPA is a non-proteinogenic amino acid. Thus, it is not one of the 21 amino acids used as building blocks for the formation of proteins in living cells. L-Dopa is produced by hydroxylation of the proteinogenic amino acid tyrosine (post-translational production) and is particularly well suited for surface adhesion.
The research work on photoactivatable mussel-based underwater detachment proteins is a collaborative effort between three UniCat working groups, and has been published in the journal ChemBioChem.

Source: UniCat