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CircuLite Awarded NIH Grant To Develop The Synergy(R) Micro-Blood Pump For Children And Infants With Life-Threatening Heart Conditions
CircuLite®, Inc. announced that it has been awarded a Fast-Track Phase I-II Small Business Innovation Research (SBIR) grant from the National Institutes of Health (NIH) to fund the development of a pediatric circulatory assist device based upon CircuLite"s Synergy Pocket Micro-pump. CircuLite, who will collaborate with the University of Maryland School of Medicine on the grant, has received funding from the National Heart, Lung, and Blood Institute at NIH to support the first phase of the grant. The total potential award for Phase I and Phase II could reach up to $3.7 million. Synergy is a micro-blood pump, the size of a AA battery, that can be implanted superficially in a "pacemaker-like" pocket. Synergy is the first and smallest device designed for partial circulatory support (up to 3L/min) and long-term use in adult patients with Class IIIb and early Class IV heart failure. Synergy is currently in a CE Mark clinical trial at multiple centers in Europe.
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Understanding The Process Of Homosexual Identity Formation Among Asian And Pacific Islander Youth
Young American-raised Asian and Pacific Islanders (API), who are in the sexual minority, face psychological and social stresses in dealing with their families" values and ancestral cultures that significantly impact the development of their ethnic and sexual identities.
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Ambulance Diversion Studied
When a hospital"s emergency department is overcrowded with seriously sick and injured patients, it may "go on diversion," re-routing ambulances to other emergency departments. But the benefits of "diversion" are largely unproven. Often those emergency departments are just as crowded, and the greater distance to that other hospital can worsen the condition of some patients.
Diagnostics

Capturing Kinetic Energy To Turn A Soldier's March Into A Charge

Engineers at the University of Leeds (UK) are developing a way to capture the kinetic energy produced when soldiers march and use it to power their equipment. The new system designed to convert foot-power into battery power could help troops reduce the weight of their packs by up to 10kg. The devices will use high tech ceramics and crystals as piezoelectric transducers in order to convert mechanical stress into an electric charge. The project will consider the optimum placement of the "energy harvesting" devices, including the back-pack straps and around the knee to provide active support, capturing energy but also cushioning the impact when legs are bent, joints compressed or their boots strike the ground. Professor Andrew Bell, Director of the Institute for Materials Research at the University of Leeds, who is leading the ÷£1m research project says: "As well as the obvious green issue of using so many batteries, it could also reduce a soldier"s pack weight by around 15 per cent. And this technology could potentially have lots of applications in civvy street too." The project has been designed to address the needs of soldiers serving in Iraq and Afghanistan. Heavy packs can severely limit a soldier"s mobility and also lead to long term health problems. Ground troops typically carry electrical equipment including including torches, personal radios, the Bowman communications system plus kit for electronic counter measures. The typical pack weight of an infantry soldier on a 6 hour patrol is around 75kg, with batteries making up 10kg of the load. Essential kit such as ammunition and water make up much of the rest. A similar energy harvesting idea has been used in cars for some time where braking force is stored and later used to drive the vehicle forward. However harvesting energy from people walking has always proved difficult due to the flexibility and strength of the materials required and the fact that everyone"s walking patterns are different. Professor Bell says his team will succeed where others have failed because they are taking a holistic approach. "By using the latest materials and electronics combined with taking into account personal differences in walking style we are confident we can make this work without adding to the burden or fatigue of the soldier wearing the device," he says. Another key part of the project will be adapting radio equipment to run on a reduced power budget. The new style low power radios will run on "standby", only boosting up to full power when an important message is received or a transmission is required. The 2-year project, due to start in September this year, also involves scientists from Bristol, Essex, Liverpool, Sheffield, Southampton and Cranfield universities. The project is funded by the Engineering and Physical Sciences Research Council (EPSRC) and the Defence Science and Technology Laboratory (DSTL). The Leeds-led kinetic energy project is part of a larger programme of research called the "battery free soldier", commissioned by DSTL and EPSRC, which includes research into converting and storing and other s of energy such as solar power and body heat.. Jo Kelly University of Leeds


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