New generation of full sized fingerprint sensors has been unveiled by NEXT Biometrics Group. The low-power fingerprint sensors are not only cost-effective but are also robust.
In minuscule amounts, it works in cells as an essential catalyst called a cofactor and as a signaling molecule to trigger other processes. Now, for the first known time, researchers have tracked those activities inside of cells.
Profusa, Inc. announced today that it was selected by Pioneers, the global business relationship builder, to showcase the company's "wear-and-forget" Lumee™ biosensor technology at the Pioneers Festival held at the prestigious Hofburg Imperial Palace in Vienna, Austria, May 24th-25th.
Many cancers could be successfully treated if the patient consulted the doctor sufficiently early. But how can a developing cancer be detected if it doesn't give rise to any symptoms? In the near future, suitably early diagnosis could be provided by simple and cheap chemical sensors - thanks to special recognizing polymer films developed at the Institute of Physical Chemistry of the Polish Academy of Sciences in Warsaw.
Profusa, Inc., a leading developer of tissue-integrated biosensors, today announced that the National Institutes of Health has awarded it a $1.75 million grant under the Small Business Innovation Research (SBIR) program. Administered by the National Heart, Lung, and Blood Institute (NHLBI), the funding will support Fast-tracked Phase I and Phase II studies of the company's Lumee™ tissue-integrated biosensors for continuous monitoring of oxygen toward improving the clinical outcomes of patients suffering from peripheral artery disease (PAD).
Rice University synthetic biologist Jeffrey Tabor is intent upon making the gut check standard operating procedure.
Mitochondrial dysfunction plays a critical role in the development of chemical and pharmaceutical toxicity. However, current methods to evaluate mitochondrial activity still rely on traditional tests called end-point assays, which provide limited prognostic information.
Scientists of the Research Center caesar in Bonn, an Institute of the Max Planck Society, developed a new biosensor, which allows to measure nanomolar levels of the second messenger cAMP. The sensor makes it possible to study cAMP signaling with high precision, even in subcellular compartments. Using this new biosensor, the scientists of the Minerva Max Planck Research Group “Molecular Physiology“ headed by Dagmar Wachten and of the Department “Molecular Sensory Systems” headed by Benjamin Kaupp revealed how the production of cAMP is regulated in the flagella of sperm cells from mice.
Yissum Research Development Company of the Hebrew University of Jerusalem, the technology-transfer company of the Hebrew University, announced today the formation of Neteera Technologies, developer of remote sensing technology of various human biological indicators. Neteera Technologies has completed its first round of funding, raising $2.0 million from private investors.
Researchers from the University of Illinois at Urbana-Champaign have developed a highly sensitive biosensor based on a differential immuno-capture technology that can detect sub-populations of white blood cells. As part of a small, disposable biochip, the microfluidic biosensor can count CD4+/CD8+ T cells quickly and accurately for AIDS diagnosis in the field. This is a follow-up of the work earlier published by the group in Science Translational Medicine.
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