View allAll Photos Tagged Bioengineering
Dept. of Chemical Engineering & Applied Chemistry - Edwards' Lab, Faculty of Applied Science & Engineering, University of Toronto
Photo by Sara Collaton
Young woman biologist holding flower pot with sprout and checking it growth in greenhaouse. Plant protection concept
PROMES Camp students design micro devices to test pH levels during a microfluidics bioengineering lab experiment on July 9, 2019.
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.
Studenter 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
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.
Moderator: Prof James McLaughin, Director of the Nanotechnology and Integrated Bioengineering Centre & Director of the Engineering Research Institute, University of Ulster - Northern Ireland
Dr. Loukianos Gatzoulis, Policy Officer, Digital Social Platforms, DG CONNECT, European Commission
Wojciech Dziworski, Head of Sector "Innovation and healthy ageing" DG SANCO, European Commision
Dr. Rafael De Andres Medina, President, Ambient Assisted Living (AAL) Joint Program, “AAL 2014 call”
PROMES Camp students design micro devices to test pH levels during a microfluidics bioengineering lab experiment on July 9, 2019.
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
PROMES Camp students design micro devices to test pH levels during a microfluidics bioengineering lab experiment on July 9, 2019.
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.
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.
PROMES Camp students design micro devices to test pH levels during a microfluidics bioengineering lab experiment on July 9, 2019.
PROMES Camp students design micro devices to test pH levels during a microfluidics bioengineering lab experiment on July 9, 2019.
PROMES Camp students design micro devices to test pH levels during a microfluidics bioengineering lab experiment on July 9, 2019.
Dept. of Chemical Engineering & Applied Chemistry - Edwards' Lab, Faculty of Applied Science & Engineering, University of Toronto
Photo by Sara Collaton
Henry Lai, a professor of bioengineering at the University of Washington who has researched the issue in the past, reviewed EWG’s report and says the group is on the right track.
www.emfnews.org/Study-Reveals-How-Much-Cellphone-Radiatio...
Studenter 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
Wireless sensors that monitor your heart even though they do not actually touch your skin are at the center of UC San Diego electrical engineering PhD student Yu Mike Chi’s dissertation. This technology – and the plan for commercializing it – earned Chi and his Cognionics team the top spot in the UC San Diego Entrepreneurship Challenge. The prize includes $25K in cash for the startup and $15K in legal services. Chi is developing these technologies under the guidance of professor Gert Cauwenberghs from the Department of Bioengineering at the UC San Diego Jacobs School of Engineering.
More information: www.jacobsschool.ucsd.edu/news/news_releases/release.sfe?...
Dept. of Chemical Engineering & Applied Chemistry - Edwards' Lab, Faculty of Applied Science & Engineering, University of Toronto
Photo by Sara Collaton
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.
(L-R) University of California, San Diego Bioengineering Professor Geert Schmid-Schönbein and InflammaGen Therapeutics CEO John Rodenrys. Photo Credit: Joshua Knoff, UC San Diego Jacobs School of Engineering.
Time rate of change of design space volume, normalized modulus (with respect to the scaffold), and possible scaffold strength schema.
Originally Published in:
Bucklen B., Wettergreen M., Liebschner M.: "Mechanical Aspects of Tissue Engineering". In Seminars in Plastic Surgery/Publisher Thieme on the topic of "Tissue Repair, Regeneration and Engineering in Plastic Surgery". Editors: Dr. C. Randall Harrell/Dr. Saleh M. Shenaq/Dr. Eser Yuksel. Volume 19, Number 3, 261-270,2005.
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/