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May 26, 2009: A new center for disease research at the University of Queensland in Australia will focus on the early diagnosis and tailored treatment of diseases like cancer.

Announced in Seattle at the Fred Hutchinson Cancer Research Center by Trade Minister Stephen Robertson, the Centre for Biomarker Research and Development will be formed at the University of Queensland’s Australian Institute for Bioengineering and Nanotechnology (AIBN).

Robertson said the center will unite AIBN’s nanotechnology researchers with leaders in the fields of medicine and molecular biology.

Biomarkers are molecules specifically associated with particular diseases that when present in the body, may indicate the onset and status of the disease. It’s anticipated biomarkers will be used to identify and treat diseases far earlier.

“Such early diagnosis leads to faster, far better treatment and therefore improved health for Queenslanders,” Robertson said. “The new center will focus on discovery, validation and utilization of molecular based biomarkers in medicine.

“It also re-affirms our commitment to the AIBN. The Queensland government invested $20 million into its construction and this has certainly proven to be a worthwhile investment, as the AIBN is now considered a world leader in the fields of bioengineering and nanotechnology.”

May 26, 2009: Agilent Technologies Inc. (NYSE: A) and Anderson Forschung Group LLC (AFG) are collaborating to develop quantitative peptide assays to speed protein biomarker discovery and validation.

The collaboration will combine AFG’s stable isotope standards and capture by anti-peptide antibodies (SISCAPA) technology with Agilent’s 1200 Series HPLC-Chip and 6400 Series triple quadrupole mass spectrometers (MS). The combination will be used to develop methods for measuring the amounts of large numbers of peptides in digests of complex samples such as plasma. The results will benefit both organizations, and financial details were not disclosed.

“We’re proud to be partnering with a thought leader like Dr. (Leigh) Anderson to develop improvements in clinical mass spectrometry,” said Gustavo Salem, Agilent vice president and general manager, Biological Systems Division. “One of the greatest challenges to delivering useful knowledge using the protein biomarker discovery paradigm is achieving effective, reproducible and highly sensitive peptide quantitation.”

“SISCAPA assays for candidate biomarkers can benefit substantially from the reproducibility and sensitivity of Agilent’s platform, and we look forward to optimizing this combination,” said Leigh Anderson, AFG’s chief executive officer.

The SISCAPA method utilizes antibody-coated magnetic beads and a rotary magnetic bead trap device to capture target peptides, which are then measured using a nanoflow LC-MS/MS system. The goal is to accurately measure the quantities of very small amounts of peptides in sample digests, creating a useful research tool with potential uses in advanced diagnostics.

The Agilent 1200 Series HPLC-Chip/MS system is a microfluidic platform that integrates LC columns, connection capillaries, and nanospray emitter in a polymer chip, providing uncompromised chromatographic performance, even with small sample input amounts. The credit card-sized device is inserted into Agilent’s HPLC-Chip Cube to interface with the MS. Chip loading, solvent and sample delivery, high pressure switching of flows, and chip positioning in the MS source are all automated.

The Agilent 6400 Series triple quadrupole LC/MS systems can provide femtogram-level sensitivity across a broad mass range. These instruments have earned a reputation for reliably quantitating trace organic compounds in complex matrices, such as drug metabolites, herbicide levels in food and contaminants in ground water.

May 22, 2009: China-based panel maker Irico Group Electronics plans to invest $74.38 million in its first OLED production fab, which broke ground in Foshan, China on May 12, 2009, according to a report in Digitimes Displays.

Organic light emitting diodes (OLEDs) are screens based on nanostructured polymer films.

Digitimes cited China media reports as saying that construction of the OLED production fab will take about 16 months, with annual capacity to reach 12 million panels.

The reports noted that Irico also plans to build module and low-temperature polysilicon (LTPS) production lines, according to Digitimes.

A technical session titled “Think Outside the Chip: MEMS-Based Systems Solutions” will be held at the Sensors Expo Chicago 2009. In the all-day session on Monday June 8, industry analyst (and Small Times contributing editor) Roger Grace will be joined by more than 20 other world recognized leaders in the microelectromechanical (MEMS) area representing North America, Asia and Europe. The group will present information on the partitioning, integrating and creating of MEMS- based systems and their applications. Grace will also make a presentation which will premier his annual MEMS Industry Report Card and will focus on MEMS design for manufacturing, assembly and test. The exhibition and technical conference will take place at the Donald E. Stephens Conference Center in Rosemont, Illinois from June 8-10, 2009.

“I created this all-day session to encourage MEMS developers and users to think outside the chip… i.e. not about the MEMS device(s) exclusively but rather about the system solution which can be enabled by MEMS devices,” Grace said. “It is well documented and well known that the typical MEMS device constitutes approximately 25-35% of the total solution cost of a MEMS-based system. The major cost factors are the other electronic components which make up the system, the packaging and test. The object of the session will be to inform the technical, technical management, and business community about the critical importance of MEMS system integration issues and tradeoffs as well as the numerous examples of their far reaching applications from both a current and future perspective.”

Grace said attendees will be provided with an overview of the issues in creating MEMS-based system solutions especially the tradeoffs on selecting signal conditioning circuits, embedded software, power generation and energy storage, network communications, interconnects, packaging and testing functions. “We expect the attendee to emerge from the session with a broad and excellent knowledge of the important factors associated with the effective selection of system elements and the integration and creation of a MEMS-based system solution to optimally fulfill their application,” he said.

Two internationally recognized experts on the “think outside the chip” philosophy of MEMS system integration will keynote the session. The morning keynote entitled,” Smart System Integration through Micro and Nanotechnologies” will be given by Dr. Thomas Gessner, Director of the Fraunhofer Research Institution for Electronic Nano Systems (ENS) of Chemnitz Germany The afternoon keynote entitled, “Integration Issues and Tradeoffs for Microsystems: Strategies and Applications” will be given by Professor Khalil Najafi who is the Assistant Director of the University of Michigan’s Wireless Integrated Microsystems Research Center (WIMS). “Chip” Spangler of Aspen Technologies will give an invited presentation entitled, “Packaging and Assembly Issues for MEMS, Microsystems and Sensors”. A panel discussion of industry pundits will address the topic of “MEMS Design for Manufacturing, Assembly and Test” will conclude the session.

The Sensors Expo Technical Conference will take place from June 8-10. The three-day conference will offer three intensive full-day tutorials, 18 tracks encompassing 55 conference sessions. Topics include energy harvesting, environmental monitoring, wireless sensor networks, low-power sensing, fiber optics, smart materials, biodetection and applications. The two day technical exhibition runs June 10 and 11.

May 21, 2009: Engineeers from Powercast Corp. and CAP-XX Ltd., which which develops nanostructured supercapacitors have introduced a wireless energy-harvester reference design that creates a battery-free power source for wireless sensors commonly used in security, environmental and condition-monitoring systems.

In operation, the design creates a perpetual power supply for fixed or mobile wireless sensor nodes deployed throughout a building or local area, eliminating the need for batteries or wired power.

The module integrates a power receiving antenna, a Powercast Powerharvester to convert radio waves into low DC power, and a CAP-XX supercapacitor. The supercapacitor stores the harvested energy and provides the peak transmission power a wireless sensor needs to transmit data over wireless networks.


The Powercast RF Energy Harvesting Module, front and back closup of components. (Photos courtesy of CAP-XX)

This reference design uses the 915 MHz band, but can be adapted for other frequencies, or set to harvest environmental radio waves from TV, radio or mobile phone networks.

The companies presented a collaborative paper, “Harvesting RF Energy and Powering a Wireless Sensor Node Using a Supercapacitor,” on May 18 at the Darnell nanoPower Forum in San Jose, Calif.


The complete module, cncluding power receiving antenna. (Photos courtesy of CAP-XX)

May 21, 2009: Washington Technology Center (WTC) has awarded an Entrepreneur’s Access grant to the University of Washington to support an advanced material research collaboration with Modumetal Inc., a Seattle-based developer of nanostructured materials.

The project is titled, “Functionally-Graded Preceramic Polymer Coating for Corrosion Resistant Commercial Sulfuric Acid Pipelines.”

“We are excited about this opportunity to partner with the exceptional researchers at the University of Washington to create this cutting-edge material for new commercial anti-corrosion application,” says Leslie Warren, Modumetal’s Project Manager and senior engineer in this effort. Christina Lomasney, the company’s CEO said that “with support from partners like the WTC and University of Washington, Modumetal is poised to create a new technology that will have broad industrial application and will result in new jobs and economic growth in our region.”

Sulfuric acid is a highly corrosive substance used extensively in industrial processes. Typical anti-corrosion coatings have a weakness — if breached, they leave the metal surface underneath the coating vulnerable to acid attack. Modumetal has a unique production method that eliminates this surface weakness by allowing anti-corrosion materials to be functionally combined with metal.

With this project, the team of Modumetal and UW Professor Rajendra Bordia, Ph.D., plans to modify a preceramic polymer system developed at the University to merge with a functionally graded materials system developed by Modumetal for corrosion protection of commercial sulfuric acid production pipelines for ConocoPhillips.

“This project combines the research that has been done at the University of Washington and at Modumetal to develop a novel solution for a significant problem in the area of corrosion,” said Dr. Bordia. “The short term EA funding from WTC gives us a chance to initiate this joint development and prepares us for long term collaboration with Modumetal. The need for corrosion resistant coatings is widespread and the proposed solution that we will be exploring with Modumetal has the potential to impact a broad range of industries.”

Modumetal expects that successful application of this technology will lead to many opportunities in the $300 million corrosion-prevention market.
The $5,000 award for this project comes from an Entrepreneur’s Access grant from Washington Technology Center (WTC). WTC competitively awards around $1 million in state funding annually for research and technology development projects. State funding enables collaboration between companies and non-profit research institutions on technology projects that show strong potential for commercializing products and creating jobs. Since 1996, the state has funded 330 research and technology development projects.

“This grant is a great example of state government at its best,” said Washington State Representative Jamie Pedersen (D-Seattle). “The seed money from WTC, combined with world-class research facilities at the University of Washington and the innovative entrepreneurs at Modumetal, will create jobs and help the state maintain its lead in technology.”

Modumetal was co-founded in 2006 in Seattle to realize the commercial potential of a unique class of advanced materials. Modumetal is creating nanolaminated and functionally graded materials that will change design and manufacturing by dramatically improving the structural, corrosion and high temperature performance of coatings, bulk materials and parts. Modumetal represents a whole new way of producing parts and is leveraging nanotechnology to achieve this unprecedented performance. Modumetal is made by a “green” electrochemical manufacturing approach, which reduces the carbon footprint of conventional metals manufacturing at the same time that it redefines materials performance.

May 21, 2009: By combining the art of origami with nanotechnology, Dana-Farber Cancer Institute researchers have folded sheets of DNA into multilayered objects with dimensions thousands of times smaller than the thickness of a human hair. These tiny structures could be forerunners of custom-made biomedical nanodevices such as “smart” delivery vehicles that would sneak drugs into patients’ cells, where they would dump their cargo on a specific molecular target.

While creation of structures from single layers of DNA has been reported previously, William Shih, senior author of the study appearing in the May 21 issue of Nature, said the multilayer process he and his colleagues developed should enable scientists to make customized DNA objects approximating almost any three-dimensional shape. Multilayered objects are more rigid and stable, thus better able to withstand the intracellular environment, which “is chaotic and violent, like being in a hurricane,” Shih said. “We think this is a big advance.”

Shih is a researcher in Dana-Farber’s Cancer Biology program. He is also an assistant professor in the Department of Biological Chemistry and Molecular Pharmacology at Harvard Medical School, and a Core Faculty member of the Wyss Institute for Biologically Inspired Engineering at Harvard.

Masters of the ancient Japanese art of origami make a series of folds in a single piece of paper to form stunningly intricate models of animals and other shapes. “We focus on doing this with DNA,” explained Shih. While DNA is best known as the stuff of which genes are made, here the scientists use long DNA molecules strictly as a building component, not a blueprint for making proteins. Shih and his colleagues reported in the Nature paper that they were able to construct a number of DNA objects, including a genie bottle, two kinds of crosses, a square nut, and a railed bridge.

DNA origami is an outgrowth of research in nanotechnology – using atoms and molecules as building blocks for new devices that can be deployed in medicine, electronics, and other fields. Scientists envision using the minuscule structures — which are about the size of small viruses — to mimic some of the “machines” within cells that carry out essential functions, like forming containers for molecular cargos and transporting them from one place to another.

“This is something that nature is very good at — making many complex machines with great control. Nature optimizes cellular technology through millions of years of evolution; we don’t have that much time, so we need to come up with other design approaches,” Shih said.

DNA origami are built as a sheet of parallel double-helices, each consisting of two intertwined strands made up of units called nucleotides. Long strands of DNA serving as a “scaffold” are folded back and forth by short strands of DNA serving as “staples” that knit together segments of the scaffold. The DNA sheet, which Shih likens to the thin bamboo mat that sushi chefs use to prepare maki rolls with filling, is then programmed to curl on itself into a series of layers that are locked in place by staples that traverse multiple layers.

With the design in hand, the scientists then order the DNA staple strands from a company, which take about three days to be synthesized and shipped. Fabricating the desired structure involves mixing the DNA scaffold and staple strands, quickly heating the mixture, and then slowly cooling the sample. This process coaxes the DNA to “self-assemble” and make billions of copies of the desired object. The process takes about a week, though the researchers intend to improve this rate. Finally, the researchers can check the finished product using an electron microscope.

The tiny machines the researchers are aiming for could, for example, act as navigation aids to guide bubble-like sacs filled with medicines. “These machines could be placed on the outside of the drug-delivery vehicles to help them cross biological barriers, or help them outwit mechanisms that are trying to remove things from the bloodstream, so they can reach their target,” suggested Shih.

The technology could also be useful in diagnostics of the future. While current lab tests can measure the concentration of different substances in the body, it may be possible with DNA “to measure the concentration of something within a single cell,” said Shih.

May 18, 2009: Altair Nanotechnologies Inc. (Altairnano), a provider of energy storage systems for clean, efficient power and energy management, and Amperex Technology Ltd. (ATL), which designs and manufactures of lithium-ion battery cells for mobile devices, have entered into a joint development agreement to accelerate the commercialization of next-generation high-performance lithium-titanate battery cells.

Under terms of the agreement, Altairnano and ATL will provide respective technical resources to focus on the engineering, design and testing of the next-generation of rechargeable cells, according to a news release.

The cells are the core technology supporting Altairnano’s energy storage and battery systems designed for electrical grid stability, renewable energy integration, and transportation applications.

The joint development agreement is an integral component of Altairnano’s product roadmap and accelerated commercialization strategy for the company’s advanced energy storage solutions. This initiative seeks to improve cell performance by increasing cell energy and power density.
Increased density, coupled with Altairnano’s distinctive performance capabilities, will further enhance the value and market adoption of the company’s energy storage systems, the company said.

“ATL, utilizing world-class manufacturing techniques and industry-leading expertise in battery cell development, views its association with Altairnano as furthering its goal of working with key companies in the energy storage system market to take advantage of the resulting synergies,”
said Dr. Robin Zeng, president and CEO at ATL, in a prepared statement.

“We are very pleased to be working with Altairnano to accelerate commercialization of next-generation lithium-titanate batteries. The association with Altairnano will provide additional inroads to the global market in energy storage.”

Initial availability of these cells and advanced energy storage systems and batteries featuring the company’s next generation of advanced lithium-titanate cells is anticipated by the end of 2009.

“We’re excited to partner with a recognized world leader in advanced cell design and manufacturing,” said Dr. Terry Copeland, president and CEO, Altairnano, in a prepared statement. “Strategic alignment with ATL strengthens Altairnano’s position to meet growing global market demands for utility-scale energy storage systems and for EV, HEV and PHEV battery applications.”

May 18, 2009: PolyOne Corp. (NYSE: POL) and Zyvex Performance Materials have received a $4.9 million grant from the Ohio Third Frontier Commission that will fund further development and production of carbon-nanotube composites. The highly-competitive Third Frontier grant program was created to increase Ohio’s high-tech research capabilities by promoting collaborative innovation.

Cecil Chappelow, vice president, innovation, sustainability and chief innovation officer at PolyOne said, “We are honored by this award and confident that our development efforts will yield a significant portfolio of next-generation thermoplastic materials based on carbon nanotubes.”

Funding will be used to support ongoing development work initiated several months ago under a joint development agreement between PolyOne and Zyvex Performance Materials to produce carbon nanotube-filled thermoplastics for structural and electrically conductive applications.

Lance Criscuolo, president of Zyvex Performance Materials explained, “This grant underscores both companies’ commitment to the technology and our certainty that Zyvex Performance Materials and PolyOne have the expertise needed to drive thermoplastic nanocomposites to the next level of performance. It will also allow us to accelerate our hiring plans and more rapidly introduce our technology commercially.”

May 15, 2009: Life Technologies Corp. (Nasdaq: LIFE) and Zymera Inc., have announced a licensing and supply agreement that gives Zymera rights to Life Technologies’ extensive intellectual property estate related to quantum dots.

Zymera will use Life Technologies’ Qdot nanocrystals to create new, self-illuminating quantum dot products to improve in-vivo imaging, biomarker discovery and a growing number of biosensing applications.

Pharmaceutical and biotechnology companies, as well as academic researchers, use Life Technologies’ Qdot nanocrystals for studies of the underlying basis of disease and for detecting targets in complex mixtures. These nanocrystals are nanometer-size, fluorescent particles made of semiconductor materials, which are invisible to the naked eye. These tiny particles emit intensely bright light when exposed to low-cost violet or ultraviolet light sources, displaying unique colors due to differences in size and composition.

Zymera’s novel self-illumination technology uses Bioluminescence Resonance Energy Transfer, also referred to as BRET, to transfer light from a bioluminescent protein — such as luciferase — directly to quantum dots. The resulting BRET dots produce light without an external source of illumination, eliminating autofluorescence background and the need for external light sources, such as lasers.


This image shows the tuneability of Qdot nanocrystals. Five different nanocrystal solutions are shown excited with the same long-wavelength UV lamp; the size of the nanocrystal determines the color. (Image courtesy of Life Technologies)

As a result, it is possible to visualize targets deeper in tissue sections or living animals, and to identify multiple targets at the same time with a wider variety of detection devices. Zymera expects to combine the technologies to develop new products for tracing blood and lymphatic fluid flow, tracking cells, and detecting biomarkers for use across a range of life science applications.

“This agreement enables Life Technologies to work with Zymera to expand the applications of our quantum dot technology portfolio beyond fluorescence into bioluminescence, which will enable our entry into new markets,” said Mark Stevenson, president and chief operating officer at Life Technologies

“The combination of Zymera’s technology with our fluorescent nanocrystals has the potential to create powerful solutions for the applied markets and other applications.”

“Quantum dot technology is one of the fastest-evolving technologies in life science,” said Steve Miller, vice president of commercialization at Zymera. “By licensing intellectual property from the market leader in fluorescence-based applications, we are able to advance our Zymera solutions to further unleash the potential of self-illuminating quantum dot products for more scientists to apply this technology to get a clearer picture of complex samples.”