View allAll Photos Tagged Bioengineering
Cindy Chew
9/7/12
Bioengineering graduate students Sarah Jane Taylor, left, and Kylie Ball share a laugh at the photobooth at the UCSF Graduate Division Celebration held at Mission Bay on Friday.
Bioengineering techniques (used coir fabric). UCC had to work with school district and city. City required riprap. Project designed by Ann Riley. Installation by East Bay Conservation Corps (EBCC).
Students in Bioengineering Lab. Micro Pump Close ups of Microscope, Printer, etc., Santa Clara University
FMP DB# 3383
University of Washington Bioengineering graduate student Chris Sip takes a break while working in a lab at the UW Medical Center under the direction of Associate Professor of Bioengineering Albert Folch. Folch, a professor at the UW since 2000, specializes in BioMEMS and Microfluidics.
A visit to Cellular Bioengineering. Located in Moiliili, the company is a Hawaii based accelerator of disruptive technologies with biomedical and biodefense applications.
Dept. of Chemical Engineering & Applied Chemistry - Edwards' Lab, Faculty of Applied Science & Engineering, University of Toronto
Photo by Sara Collaton
Dept. of Chemical Engineering & Applied Chemistry - Edwards' Lab, Faculty of Applied Science & Engineering, University of Toronto
Photo by Sara Collaton
PSDTUTS 6th Entry
Interpretation: Something went completely wrong when a laboratory accident occurred in an underground bioengineering facility. A mutating virus accidentally was released and it soon began to spread. A virus which caused aggression in the dead ones and turned them into flesh eating monsters. The virus soon wiped out most of the population and only a few survived. This soon became a war for survival. 'Extinction is not an option.'
Design: It's a 'New Dawn' and a new kind of world has emerged. Buildings have been isolated by people and have been infiltrated by flesh eating zombies. Streets have been abandoned due to the high risk of being infected by the virus.
Sources:
Sky: storage.sxc.hu/g/gu/gun4hire/1114414_81863243.jpg
Street Sign: storage.sxc.hu/e/ea/eastop/909782_36417737.jpg
Sand: storage.sxc.hu/p/pi/pitklad/591765_63167479.jpg
Buildings: storage.sxc.hu/s/sh/shwizle/1071334_23244384.jpg
People walking: www.sxc.hu/browse.phtml?f=download&id=494615
Bio Hazard Sign: www.google.com/imgres?imgurl=http://www.justaddwordsonlin...
Source links are not working for some reason so here is a link to all the pics together: www.flickr.com/photos/33516325@N03/3139326832/in/pool-psd... (all from stock xchng. ) Will fix links soon
PROMES Camp students design micro devices to test pH levels during a microfluidics bioengineering lab experiment on July 9, 2019.
The company logo of the manufacturer of the elevator in the Bioengineering Building at SUNY Binghamton University.
Biodegradable netting made of coir (coconut husk fiber) is stapled to the soil to prevent surface erosion
Jho Low, Director of Jynwel Foundation, visits Children’s National Medical Center on February 12, 2015.
Pictured (L to R): Rohan Fernandes, PhD, MS, Assistant Professor, Bioengineering; Jho Low, Director, Jynwel Foundation; Mark Batshaw, MD, Chief Academic Office and Physician-in-Chief; Ray Sze, MD, Division Chief, Diagnostic Imaging and Radiology
The research team from the Institute of Bioengineering and Nanotechnology that developed the green tea nanocomplexes for targeted cancer drug delivery - (from left) Dr Nunnarpas Yongvongsoontorn, Dr Joo Eun Chung, Dr Shujun Gao, Prof Jackie Ying, Dr Susi Tan (holding the green tea formulation), and Dr Motoichi Kurisawa.
www.straitstimes.com/opinion/the-invisible-disruption-of-...
Laurence Jackson (UCL Medical Physics & Bioengineering)
The heart is an extraordinarily complex muscle, providing the circulation of blood throughout the body. Both the muscular action which pumps the blood as well as the electrical pacing of these contractions depends heavily on the highly ordered muscle fibre architecture. This image was created using Diffusion Tensor Magnetic Resonance Imaging, which uses the movement of water along these fibres to determine their orientation.
The image shows the spiral structure of the myofibres around the left ventricular chamber, note that the inside and outside walls of the chamber spiral in different directions, contraction along these fibres causes an upwards twisting motion reducing the volume of the chamber and expelling the blood.
AsianScientist (Dec. 30, 2015) - Professor Jackie Y. Ying, executive director of the Institute of Bioengineering and Nanotechnology (IBN) of A*STAR has won the inaugural Mustafa Prize Top Scientific Achievement Award for her contributions to and achievements in advanced nanostructured materials and systems, nanostructured biomaterials and miniaturized biosystems.
Rebecca Richards-Kortum, PhD, Department of Bioengineering, Rice University
From Cell Phones to Cell Biology: High Tech, Low Cost Solutions for Global Health
Professor Jackie Y. Ying, Executive Director of A*STAR’s Institute of Bioengineering and Nanotechnology, has been conferred the prestigious Singapore National Academy of Sciences (SNAS) Fellowship for her administrative leadership and research excellence in the areas of nanomedicine, synthetic biosystems, bio-devices and diagnostics, and green chemistry and energy. Prof Ying is one of two female fellows of SNAS since the Fellowships were inaugurated in 2011.
www.a-star.edu.sg/News-and-Events/Our-People/Honours-and-...
Graduation organ_printer riceuniversity bioengineering phd
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Matthew Wettergreen
mwettergreen@gmail.com
713.825.4613
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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.
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.
A fancy bioengineering building at Stanford, where you can watch the bioengineers at work through the glass windows. Warning: eye contact inadvisable, as the engineers will charge the glass.
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.
International Centre for Environmental Management:
Promoting Climate Resilient Rural Infrastructure in the Northern Mountain Provinces of Vietnam
Donor / Partner: Asian Development Bank (ADB) | Duration: 2013-2016 | Location: The Northern Mountain Provinces of Vietnam
About: The objective of the project in northern Vietnam to demonstrate effective bio-engineered solutions which, where possible, provide ‘win-win’ outcomes for resilience of rural infrastructure to climate risk and opportunities for community livelihood enhancement.
The project focuses on rural irrigation, slope stability for roads, river-bank protection, and flood protection works. Lessons learned from the project works will provide the basis for capacity building activities with local community members, contractors and government staff at local, provincial and national levels. The extension of this work is to make recommendations for the broader adoption of bio-engineered approaches as an effective solution to manage climate risk in Vietnam. The project will also raise awareness of climate risks and vulnerabilities in local communities and empower them with the capability to manage risk through practical, cost effective solutions which can be implemented with local resources.