View allAll Photos Tagged Bioengineering
Tavla i byggnaden för life science och bioengineering vid Danmarks Tekniske Universitet (DTU), 2018-09-04..Photo: News Øresund – Anna Palmehag..© News Øresund – Anna Palmehag (CC BY 3.0).Detta verk av News Øresund är licensierat under en Creative Commons Erkännande 3.0 Unported-licens (CC BY 3.0). Bilden får fritt publiceras under förutsättning att källa anges..The picture can be used freely under the prerequisite that the source is given. News Øresund, Malmö, Sweden..www.newsoresund.org.News Øresund är en oberoende regional nyhetsbyrå som är en del av det oberoende dansk-svenska kunskapscentrat Øresundsinstituttet..www.newsoresund.org.www.oresundsinstituttet.org
Researchers at the Wayne State Bioengineering Center work with a crash test dummy.
For more information: engineering.wayne.edu/bme/
Isabella Cabrera plays the violin with a prosthetic left arm designed by a senior design team of Mason bioengineering students from Mason's Volgeneau School. Photo by Evan Cantwell/Creative Services/George Mason University
Tissue from the skeletal muscle of pigs is spun in detergent until only the fibrous extracellular matrix remains.
Dept. of Chemical Engineering & Applied Chemistry - Edwards' Lab, Faculty of Applied Science & Engineering, University of Toronto
Photo by Sara Collaton
Tissue from the skeletal muscle of pigs is spun in detergent until only the fibrous extracellular matrix remains.
Research fellow Dr. Young Joon Seol works on a project to print experimental muscle tissue for reconstructive surgery. (Photo courtesy of Wake Forest Institute for Regenerative Medicine)
Tissue from the skeletal muscle of pigs is spun in detergent until only the fibrous extracellular matrix remains.
This picture was created in a figurative themes class I took in college-- the theme for this particular piece was "forces of nature"
Bioengineering demonstration measures will help to stabilize a part of the cut slope on one side of Road 108 in Phong Lap Commune, which requires protection from erosion caused by flash floods.
Photo by ICEM
Surgeons handle a human acellular vessel during an operation. The off-the-shelf, bioengineered blood vessel is being studied for use in repairing and reconstructing various types of vascular injuries. (Photo courtesy of Humacyte Inc.)
Biologically Inspired Engineering: From Human Organs-on-Chips to Programmable Nanotherapeutics
Dr. Donald Ingber
Professor of Bioengineering, Harvard John. A. Paulson School of Engineering & Applied Sciences
Abstract
The Wyss Institute for Biologically Inspired Engineering at Harvard University that I lead has pioneered a new model for innovation, trans-disciplinary collaboration and technology translation. I will highlight engineering of “Organs-on-Chips” that recapitulate organ-level structure and functions as a way to replace animal testing for drug development, mechanistic discovery, and personalized medicine; nanotherapeutics that target to vascular occlusion sites like artificial platelets; anticoagulant surface coatings for medicine devices inspired by a plant; a ‘biospleen’ device that cleanses blood of pathogens and toxins in septic patients; and self-assembling DNA-based nanorobots that can be programmed to travel to cancer sites and kill tumor cells. This new bioinspired technology wave represents a major paradigm shift in medicine, and the novel organizational structure of the Institute offers an entirely new way to translate discoveries into breakthrough products in the academic setting.
Live Broadcast: coe.miami.edu/speaker/ingber
Dr. Donald Ingber is the Founding Director of the Wyss Institute for Biologically Inspired Engineering at Harvard University the Judah Folkman Professor of Vascular Biology at Harvard Medical School & Boston Children’s Hospital, and Professor of Bioengineering, Harvard John. A. Paulson School of Engineering & Applied Sciences. He is a member of the National Academy of Medicine, National Academy of Inventors, American Institute for Medical and Biological Engineering, and American Academy of Arts and Sciences.
Dept. of Chemical Engineering & Applied Chemistry - Edwards' Lab, Faculty of Applied Science & Engineering, University of Toronto
Photo by Sara Collaton
Han Lim (right)and bioengineering professor Shyni Varghese (left) in 2008. Lim is one of the bioengineering undergraduates who created an artificial environment for stem cells that simultaneously provides the chemical, mechanical and electrical cues necessary for stem cell growth and differentiation.
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.
15 February 2016, Rome, Italy - Chittaranjan Kole, Jacob School of Biotechnology & Bioengineering, Allahabad, India, Facing the challenges of climate change: Adaptation of the crop and forestry sectors - FAO International Symposium on “The Role of Agricultural Biotechnologies in Sustainable Food Systems and Nutrition", FAO headquarters (Sheikh Zayed Centre).
Photo credit must be given: ©FAO/Giuseppe Carotenuto. Editorial use only. Copyright ©FAO.
Dept. of Chemical Engineering & Applied Chemistry - Edwards' Lab, Faculty of Applied Science & Engineering, University of Toronto
Photo by Sara Collaton
PROMES Camp students design micro devices to test pH levels during a microfluidics bioengineering lab experiment on July 9, 2019.
Students in the 7th and 8th grades from throughout the state of Maryland take part in the Easy As PI day event to learn about topics in the fields of Science, Technology, Engineering, and Mathematics (STEM) at the Garrett-Jacobs Mansion in Baltimore, Md., March 30, 2016. (U.S. Army Corps of Engineers photo by Alfredo Barraza)
Coir Green ™(Geotextiles) – CGgeo ™ have been known to reduce soil erosion and is used for bioengineering and slope stabilization applications globally due to the mechanical strength necessary to hold soil together. It is been proven that CGgeo ™(Geotextiles) last for approximately 3 - 5 years depending on the weight, and by the time the product degrades, it converts itself it to humus, which enriches the soil. The following Geotextiles are produced by Coir Green.
CGgeo 400g Hand Woven Coir Netting (CG Geotextiles)
CGgeo 700g Hand Woven Coir Netting (CG Geotextiles)
CGgeo 900g Hand Woven Coir Netting (CG Geotextiles)
The cover of the November 1963 Wayne Engineer student magazine featured a high speed photo of Larry Patrick, former professor and director of the Bioengineering Center, in motion in a vertical linear accelerator. Patrick often volunteered for experiments and, at the time of the photo, was researching vertebrae injury. More information: engineering.wayne.edu/
Bruce Tromberg, PhD, the guest of honor, gives a presentation on the important work being done at the National Institute for Biomedical Imaging and Bioengineering (NIBIB).
A visit to Cellular Bioengineering. Located in Moiliili, the company is a Hawaii based accelerator of disruptive technologies with biomedical and biodefense applications.
On May 30-31, a conference at the Center featured discussion and presentations by physicians and scholars from the U.S., China and throughout the Asia Pacific region, exploring critical topics with a focus on Molecular Mechanisms and Bioengineering for Surgical Diseases. Jack Gilbert, Associate Professor at UChicago's Department of Ecology and Evolution and an Environmental Microbiologist, delivered a keynote speech