New Englands favorite summertime delicacy, the chowder clam, has just been elevated to a whole new status. An international team of scientists-who credit studying surf clam (Spisula solidissima) cells with important research breakthroughs in the study of diseases such as cancer, premature aging, and muscular dystrophy-has convened at the Marine Biological Laboratory to begin sequencing some of the clams active genes.
The effort, called the Clam Project, is the first step toward sequencing the entire clam genome, and its goal is to provide scientists with better knowledge of the clams active DNA. Such information is crucial to the study of the basic cellular processes involved in many diseases. The scientists plan to use the new genetic information to create antibodies. And they hope to begin experiments impossible without those antibodies as soon as the project is complete.
The research team includes: Avram Hershko of Technion-Israel Institute of Technology, Yosef Gruenbaum of Hebrew University of Jerusalem, Robert Palazzo of Rensselaer Polytechnic Institute, and Robert Goldman of Northwestern University, all visiting summer investigators at the Marine Biological Laboratory.
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25.10.2016 | Institut für Pflanzenbiochemie
Ultrafast lasers have introduced new possibilities in engraving ultrafine structures, and scientists are now also investigating how to use them to etch microstructures into thin glass. There are possible applications in analytics (lab on a chip) and especially in electronics and the consumer sector, where great interest has been shown.
This new method was born of a surprising phenomenon: irradiating glass in a particular way with an ultrafast laser has the effect of making the glass up to a...
Terahertz excitation of selected crystal vibrations leads to an effective magnetic field that drives coherent spin motion
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Researchers from the Institute for Quantum Computing (IQC) at the University of Waterloo led the development of a new extensible wiring technique capable of controlling superconducting quantum bits, representing a significant step towards to the realization of a scalable quantum computer.
"The quantum socket is a wiring method that uses three-dimensional wires based on spring-loaded pins to address individual qubits," said Jeremy Béjanin, a PhD...
In a paper in Scientific Reports, a research team at Worcester Polytechnic Institute describes a novel light-activated phenomenon that could become the basis for applications as diverse as microscopic robotic grippers and more efficient solar cells.
A research team at Worcester Polytechnic Institute (WPI) has developed a revolutionary, light-activated semiconductor nanocomposite material that can be used...
By forcefully embedding two silicon atoms in a diamond matrix, Sandia researchers have demonstrated for the first time on a single chip all the components needed to create a quantum bridge to link quantum computers together.
"People have already built small quantum computers," says Sandia researcher Ryan Camacho. "Maybe the first useful one won't be a single giant quantum computer...
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14.10.2016 | Event News
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