View allAll Photos Tagged Bioengineering
Professor Rui L. Reis was chosen as the 2017 recipient of the IET Harvey Engineering Research Prize for his outstanding contributions to research in the field of Medical Engineering, specifically for contributions to bioengineering, biomedical engineering, tissue engineering and biomaterials.
He presented a prize lecture on 20 March 2018, discussing his research and how the prize funding will be used to further it.
Photos courtesy of Trampenau photography - Steve Pearcy.
Site of future bioengineering building at the University of California, Santa Barbara. Taken from the 4th floor of the Davidson Library.
Bioengineers in Prashant Mali's lab have developed a 3D bioprinting technique that works with natural materials and is easy to use, allowing researchers of varying levels of technical expertise to create lifelike tissues, such as blood vessels and a vascularized gut. The goal is to make human organ models that can be studied outside the body or used to test new drugs ex vivo.
Full story: jacobsschool.ucsd.edu/news/news_releases/release.sfe?id=2673
Photo credit: David Baillot/UC San Diego Jacobs School of Engineering
Researchers Daniel Strange and Dr Michelle Oyen at the Department of Engineering making synthetic bone have turned to legendary children’s toy Lego for a helping hand.
Within the Bioengineering subject area, the group is active across a range of applications using modelling and experimental techniques to simulate cell behaviour, for example characterising cell forces and dynamics, cancer development and blood dynamics. Tissue engineering work includes development and characterisation of hydrogels and use of electro-spinning to produce micro-architectured material from a range of materials for use in bioengineering applications.
The Biomechanics group is also active in the area of Biomedical Engineering. Work on fibre-networks aims to exploit magnetic actuation to improve bone tissue growth on prosthetic implants, while biomechanics principles are used to understand the mechanical properties of arteries, placental membranes and skin.
Ishan Patel, OSU bioengineering student, is developing an assay for blood clot risk in collaboration with Dr. Owen J.T. McCarty at the Oregon Health & Science University. (Photo: Jan Sonnenmair)
Bioengineers in Prashant Mali's lab have developed a 3D bioprinting technique that works with natural materials and is easy to use, allowing researchers of varying levels of technical expertise to create lifelike tissues, such as blood vessels and a vascularized gut. The goal is to make human organ models that can be studied outside the body or used to test new drugs ex vivo.
Full story: jacobsschool.ucsd.edu/news/news_releases/release.sfe?id=2673
Photo credit: David Baillot/UC San Diego Jacobs School of Engineering
photo attribution: sean dreilinger durak.org
Todd P. Coleman
Neural Interaction Lab
Todd P. Coleman is an Associate Professor in the Department of Bioengineering at UCSD. His graduate training at MIT was in electrical engineering, while his postdoctoral training at MIT was in neuroscience. Dr. Coleman directs the Neural Interaction Laboratory at UCSD, where his research group builds flexible ?tattoo electronics? for neurological monitoring and brain-computer interfaces applications. Dr. Coleman is a science advisor for the Science & Entertainment Exchange (National Academy of Sciences). His research has been featured in CNN, the New York Times, and Popular Science.
view Todd Coleman - Where Will the Chips of Tomorrow Take Us? - TEDxS on a black background.
Bishan–Ang Mo Kio Park, Singapore
Ramboll Studio Dreiseitl, 2012
Sky Habitat, Singapore
Moshe Safdie, 2016
photo attribution: sean dreilinger durak.org
Todd P. Coleman
Neural Interaction Lab
Todd P. Coleman is an Associate Professor in the Department of Bioengineering at UCSD. His graduate training at MIT was in electrical engineering, while his postdoctoral training at MIT was in neuroscience. Dr. Coleman directs the Neural Interaction Laboratory at UCSD, where his research group builds flexible ?tattoo electronics? for neurological monitoring and brain-computer interfaces applications. Dr. Coleman is a science advisor for the Science & Entertainment Exchange (National Academy of Sciences). His research has been featured in CNN, the New York Times, and Popular Science.
view Todd Coleman - Where Will the Chips of Tomorrow Take Us? - TEDxS on a black background.
Dr. George Pantalos, bioengineering and cardiovascular and thoracic surgery professor with the UofL Cardiovascular Innovation Institute, in September took four UofL students to Houston where they conducted more tests in zero-gravity on the astrosurgery device he is developing with researchers at Carnegie Melon. This was the third time since 2012 that Dr. Pantalos and his research team tested the device in zero-G. The device is the Aqueous Immersion Surgical System – a water- and airtight-device that isolates surgical incisions and controls bleeding in a zero-gravity environment. The device seeks to control the escape of blood and bodily fluids in this environment, currently impossible to do. The ultimate goal is to develop a system that long-range space flights (such as to Mars) could use if surgery is needed onboard the spacecraft. However, applications on Earth for the device would be when sterile conditions are hard to come by, such as in war zones or areas where medical facilities are not present.
San Luis Valley National Wildlife Refuge Complex Youth Conservation Corps (YCC) crew members work on the Kerber Creek Restoration Project, aimed to restore over 20 miles of stream and 1,000 acres of floodplain. YCC crews were used to transplant vegetation and repair eroding banks.
Credit: USFWS
Originally published in:
Liebschner M., Wettergreen M.: "Optimization of Bone Scaffold Engineering for Load Bearing Applications." In Ferretti P., Ashammakhi N.: Topics in Tissue Engineering, e-book on tissue engineering, T. Waris & N. Ashammakhi, Chapter 22, www.tissue-engineering-oc.com, 2003.
Cellular Bioengineering Inc. hosted September's Bytemarks lunch. They let us into their lab to see their secret sauce.
The photo above shows a bioengineered blood vessel developed by the Duke University team.
Credit: Duke University
Bioengineers in Prashant Mali's lab have developed a 3D bioprinting technique that works with natural materials and is easy to use, allowing researchers of varying levels of technical expertise to create lifelike tissues, such as blood vessels and a vascularized gut. The goal is to make human organ models that can be studied outside the body or used to test new drugs ex vivo.
Full story: jacobsschool.ucsd.edu/news/news_releases/release.sfe?id=2673
Photo credit: David Baillot/UC San Diego Jacobs School of Engineering
Professor Rui L. Reis was chosen as the 2017 recipient of the IET Harvey Engineering Research Prize for his outstanding contributions to research in the field of Medical Engineering, specifically for contributions to bioengineering, biomedical engineering, tissue engineering and biomaterials.
He presented a prize lecture on 20 March 2018, discussing his research and how the prize funding will be used to further it.
Photos courtesy of Trampenau photography - Steve Pearcy.
photo attribution: sean dreilinger durak.org
Todd P. Coleman
Neural Interaction Lab
Todd P. Coleman is an Associate Professor in the Department of Bioengineering at UCSD. His graduate training at MIT was in electrical engineering, while his postdoctoral training at MIT was in neuroscience. Dr. Coleman directs the Neural Interaction Laboratory at UCSD, where his research group builds flexible ?tattoo electronics? for neurological monitoring and brain-computer interfaces applications. Dr. Coleman is a science advisor for the Science & Entertainment Exchange (National Academy of Sciences). His research has been featured in CNN, the New York Times, and Popular Science.
They used commercially available software to process CT scans of the patients’ pelvis and create a computerized model of bone and growth plate for 3D printing. The models allowed surgeons to practice and visualize the surgery before they operated in the real world.
Some jokers here in flickr-land think that I write engineering books just so I can put my photography on the cover... okay they may be right...
Coming in October 2010... pre-order your copy today!
photo attribution: sean dreilinger durak.org
Todd P. Coleman
Neural Interaction Lab
Todd P. Coleman is an Associate Professor in the Department of Bioengineering at UCSD. His graduate training at MIT was in electrical engineering, while his postdoctoral training at MIT was in neuroscience. Dr. Coleman directs the Neural Interaction Laboratory at UCSD, where his research group builds flexible ?tattoo electronics? for neurological monitoring and brain-computer interfaces applications. Dr. Coleman is a science advisor for the Science & Entertainment Exchange (National Academy of Sciences). His research has been featured in CNN, the New York Times, and Popular Science.
Ben Almquist, Lecturer, Department of Bioengineering, Imperial College London, United Kingdom during the Session on “Unpacking New Medical Paradigms with Imperial College London”. At the World Economic Forum - Annual Meeting of the New Champions in Dalian, People's Republic of China 2017. Copyright by World Economic Forum / Faruk Pinjo
Congratultions to @ucsandiego bioengineers and alumni, whose work on a new neuromorphic chip was published today in @nature_the_journal! You can learn more here: bit.ly/NeuRRAMchipNature
@ucsdalumni
#bioengineering #electricalengineering #AI #neuralnetworks #neuromorphiccomputing #semiconductors Pictures by David Baillot
Bioengineers in Prashant Mali's lab have developed a 3D bioprinting technique that works with natural materials and is easy to use, allowing researchers of varying levels of technical expertise to create lifelike tissues, such as blood vessels and a vascularized gut. The goal is to make human organ models that can be studied outside the body or used to test new drugs ex vivo.
Full story: jacobsschool.ucsd.edu/news/news_releases/release.sfe?id=2673
Photo credit: David Baillot/UC San Diego Jacobs School of Engineering
photo attribution: sean dreilinger durak.org
Todd P. Coleman
Neural Interaction Lab
Todd P. Coleman is an Associate Professor in the Department of Bioengineering at UCSD. His graduate training at MIT was in electrical engineering, while his postdoctoral training at MIT was in neuroscience. Dr. Coleman directs the Neural Interaction Laboratory at UCSD, where his research group builds flexible ?tattoo electronics? for neurological monitoring and brain-computer interfaces applications. Dr. Coleman is a science advisor for the Science & Entertainment Exchange (National Academy of Sciences). His research has been featured in CNN, the New York Times, and Popular Science.
photo attribution: sean dreilinger durak.org
Todd P. Coleman
Neural Interaction Lab
Todd P. Coleman is an Associate Professor in the Department of Bioengineering at UCSD. His graduate training at MIT was in electrical engineering, while his postdoctoral training at MIT was in neuroscience. Dr. Coleman directs the Neural Interaction Laboratory at UCSD, where his research group builds flexible ?tattoo electronics? for neurological monitoring and brain-computer interfaces applications. Dr. Coleman is a science advisor for the Science & Entertainment Exchange (National Academy of Sciences). His research has been featured in CNN, the New York Times, and Popular Science.
Concrete pumping at the new 210,000 square ft. Bio-engineering and Chemical Engineering Building.
Taken with Iphone
Dr. George Pantalos, bioengineering and cardiovascular and thoracic surgery professor with the UofL Cardiovascular Innovation Institute, in September took four UofL students to Houston where they conducted more tests in zero-gravity on the astrosurgery device he is developing with researchers at Carnegie Melon. This was the third time since 2012 that Dr. Pantalos and his research team tested the device in zero-G. The device is the Aqueous Immersion Surgical System – a water- and airtight-device that isolates surgical incisions and controls bleeding in a zero-gravity environment. The device seeks to control the escape of blood and bodily fluids in this environment, currently impossible to do. The ultimate goal is to develop a system that long-range space flights (such as to Mars) could use if surgery is needed onboard the spacecraft. However, applications on Earth for the device would be when sterile conditions are hard to come by, such as in war zones or areas where medical facilities are not present.
Grad students Donghwan Jeon and Saturnino Garcia took top honors in the Computer Science and Engineering category at Research Expo for their poster "Kremlin: Like Gprof, but for Parallelization."
Professor Rui L. Reis was chosen as the 2017 recipient of the IET Harvey Engineering Research Prize for his outstanding contributions to research in the field of Medical Engineering, specifically for contributions to bioengineering, biomedical engineering, tissue engineering and biomaterials.
He presented a prize lecture on 20 March 2018, discussing his research and how the prize funding will be used to further it.
Photos courtesy of Trampenau photography - Steve Pearcy.
Cellular Bioengineering Inc. hosted September's Bytemarks lunch. They let us into their lab to see their secret sauce.
Cellular Bioengineering Inc. hosted September's Bytemarks lunch. They let us into their lab to see their secret sauce.
photo attribution: sean dreilinger durak.org
Todd P. Coleman
Neural Interaction Lab
Todd P. Coleman is an Associate Professor in the Department of Bioengineering at UCSD. His graduate training at MIT was in electrical engineering, while his postdoctoral training at MIT was in neuroscience. Dr. Coleman directs the Neural Interaction Laboratory at UCSD, where his research group builds flexible ?tattoo electronics? for neurological monitoring and brain-computer interfaces applications. Dr. Coleman is a science advisor for the Science & Entertainment Exchange (National Academy of Sciences). His research has been featured in CNN, the New York Times, and Popular Science.
view Todd Coleman - Where Will the Chips of Tomorrow Take Us? - TEDxS on a black background.
Bioengineers in Prashant Mali's lab have developed a 3D bioprinting technique that works with natural materials and is easy to use, allowing researchers of varying levels of technical expertise to create lifelike tissues, such as blood vessels and a vascularized gut. The goal is to make human organ models that can be studied outside the body or used to test new drugs ex vivo.
Full story: jacobsschool.ucsd.edu/news/news_releases/release.sfe?id=2673
Photo credit: David Baillot/UC San Diego Jacobs School of Engineering
Cellular Bioengineering Inc. hosted September's Bytemarks lunch. They let us into their lab to see their secret sauce.
Cellular Bioengineering Inc. hosted September's Bytemarks lunch. They let us into their lab to see their secret sauce.
photo attribution: sean dreilinger durak.org
Todd P. Coleman
Neural Interaction Lab
Todd P. Coleman is an Associate Professor in the Department of Bioengineering at UCSD. His graduate training at MIT was in electrical engineering, while his postdoctoral training at MIT was in neuroscience. Dr. Coleman directs the Neural Interaction Laboratory at UCSD, where his research group builds flexible ?tattoo electronics? for neurological monitoring and brain-computer interfaces applications. Dr. Coleman is a science advisor for the Science & Entertainment Exchange (National Academy of Sciences). His research has been featured in CNN, the New York Times, and Popular Science.
view Todd Coleman - Where Will the Chips of Tomorrow Take Us? - TEDxS on a black background.
Dr. George Pantalos, bioengineering and cardiovascular and thoracic surgery professor with the UofL Cardiovascular Innovation Institute, in September took four UofL students to Houston where they conducted more tests in zero-gravity on the astrosurgery device he is developing with researchers at Carnegie Melon. This was the third time since 2012 that Dr. Pantalos and his research team tested the device in zero-G. The device is the Aqueous Immersion Surgical System – a water- and airtight-device that isolates surgical incisions and controls bleeding in a zero-gravity environment. The device seeks to control the escape of blood and bodily fluids in this environment, currently impossible to do. The ultimate goal is to develop a system that long-range space flights (such as to Mars) could use if surgery is needed onboard the spacecraft. However, applications on Earth for the device would be when sterile conditions are hard to come by, such as in war zones or areas where medical facilities are not present.
They used commercially available software to process CT scans of the patients’ pelvis and create a computerized model of bone and growth plate for 3D printing. The models allowed surgeons to practice and visualize the surgery before they operated in the real world.
They used commercially available software to process CT scans of the patients’ pelvis and create a computerized model of bone and growth plate for 3D printing. The models allowed surgeons to practice and visualize the surgery before they operated in the real world.
photo attribution: sean dreilinger durak.org
Todd P. Coleman
Neural Interaction Lab
Todd P. Coleman is an Associate Professor in the Department of Bioengineering at UCSD. His graduate training at MIT was in electrical engineering, while his postdoctoral training at MIT was in neuroscience. Dr. Coleman directs the Neural Interaction Laboratory at UCSD, where his research group builds flexible ?tattoo electronics? for neurological monitoring and brain-computer interfaces applications. Dr. Coleman is a science advisor for the Science & Entertainment Exchange (National Academy of Sciences). His research has been featured in CNN, the New York Times, and Popular Science.
Dr. George Pantalos, bioengineering and cardiovascular and thoracic surgery professor with the UofL Cardiovascular Innovation Institute, in September took four UofL students to Houston where they conducted more tests in zero-gravity on the astrosurgery device he is developing with researchers at Carnegie Melon. This was the third time since 2012 that Dr. Pantalos and his research team tested the device in zero-G. The device is the Aqueous Immersion Surgical System – a water- and airtight-device that isolates surgical incisions and controls bleeding in a zero-gravity environment. The device seeks to control the escape of blood and bodily fluids in this environment, currently impossible to do. The ultimate goal is to develop a system that long-range space flights (such as to Mars) could use if surgery is needed onboard the spacecraft. However, applications on Earth for the device would be when sterile conditions are hard to come by, such as in war zones or areas where medical facilities are not present.