“Donald E. Ingber”的意思、由来-开放百科全书

Donald E. Ingber (born 1956){{citation needed|date=August 2018}} is an American cell biologist and bioengineer. He is the founding director of the Wyss Institute for Biologically Inspired Engineering at Harvard University,^[1] the Judah Folkman Professor of Vascular Biology at Harvard Medical School and Boston Children's Hospital, and Professor of Bioengineering at the Harvard John A. Paulson School of Engineering and Applied Sciences.^[2] He is also a member of the American Institute for Medical and Biological Engineering, the National Academy of Medicine, the National Academy of Inventors, and the American Academy of Arts and Sciences.

Ingber is a founder of the emerging fields of biologically inspired engineering. He has made pioneering contributions to numerous other disciplines including mechanobiology, cytoskeletal biology, extracellular matrix biology, integrin signaling, tumor angiogenesis, tissue engineering, nanobiotechnology, systems biology, and translational medicine. Ingber has authored more than 470 publications in scientific journals and books, and is an inventor on more than 190 patents spanning anti-cancer therapeutics, tissue engineering, medical devices, drug delivery systems, biomimetic materials, nanotherapeutics, and bioinformatics software.

Ingber has been scientific founder of five companies: Neomorphics, Inc.,^[3] a tissue engineering startup which led to clinical products through subsequent acquisitions (Advanced Tissue Sciences Inc.); Tensegra, Inc. (formerly known as Molecular Geodesics, Inc.,)^[4] which 3D-printed medical devices; and most recently, Emulate, Inc.,^[5] which formed to commercialize human "organs-on-chips" that accelerate drug development, detect toxicities and advance personalized medicine by replacing animal testing; Boa Biomedical, Inc. (originally known as Opsonix, Inc.)^[6], which aims to reduce deaths due to sepsis and blood infections by removing pathogens from the blood; and FreeFlow Medical Devices, LLC, which develops special coatings for medical devices to eliminate the formation of blood clots and biofilms on materials.

Education and academic research

Ingber grew up in East Meadow, New York.^[7] He received a combined B.A./M.A. in molecular biophysics and biochemistry from Yale College and Yale Graduate School in 1977; an M.Phil. in cell biology from Yale Graduate School in 1981; and a combined M.D./Ph.D. from Yale University School of Medicine and Yale Graduate School in 1984.{{citation needed|date=August 2018}} At Yale, he carried out undergraduate research on DNA repair with Paul Howard-Flanders,^[8] and on cancer metastasis with Alan Sartorelli.

Ingber worked on development of cancer therapeutics with Kenneth Harrap at the Royal Cancer Hospital/Royal Marsden Hospital in England, with support from a Bates Traveling Fellowship. He carried out his Ph.D. dissertation research under the direction of Dr. James Jamieson in the department of cell biology,^[9] and his advisory committee included George Palade, Elizabeth Hay and Joseph Madri. From 1984 to 1986 he completed his training as an Anna Fuller Postdoctoral Fellow^[10] under the mentorship of Dr. Judah Folkman in the Surgical Research Laboratory at Boston Children's Hospital and Harvard Medical School.^[11]^[12]

Scientific career

Appointments

Significant contributions

Ingber is best known for his discovery of the role mechanical forces play in developmental control and in cancer formation, and for his application of these principles to develop bioinspired medical devices, nanotechnologies, and therapeutics. Ingber's early scientific work led to the discovery that tensegrity architecture^[14] - first described by the architect Buckminster Fuller and the sculptor Kenneth Snelson - is a fundamental design principle that governs how living systems are structured, from individual molecules and cells to whole tissues, organs and organisms.^[15]

Ingber's work on tensegrity led him to propose that mechanical forces play as important a role in biological control as chemicals and genes do,^[16] and to investigate the molecular mechanism by which cells convert mechanical signals into changes in intracellular biochemistry and gene expression, a process known as "mechanotransduction."^[17] Ingber determined that living cells use tensegrity architecture to stabilize their shape and cytoskeleton, that cellular integrins function as mechanosensors on the cell surface, and that cytoskeletal tension (or "prestress," which is central to the stability of tensegrity structures) is a fundamental regulator of many cellular responses to mechanical cues.^[18] Ingber's tensegrity theory also led to the prediction in the early 1980s that changes in extracellular matrix structure and mechanics play a fundamental role in tissue and organ development, and that deregulation of this form of developmental control can promote cancer formation.^[19]

Ingber's contributions in translational medicine include discovery of one of the first angiogenesis inhibitor compounds (TNP-470)^[20] to enter clinical trials for cancer, creation of tissue engineering scaffolds that led to clinical products, development of a dialysis-like blood cleansing device for treatment of blood stream infections that is moving towards clinical testing,^[21]^[22] creation of a mechanically-activated nanotechnology for targeting clot-busting drugs to sites of vascular occlusion,^[23] and co-development of a new surface coating based on Slippery Liquid Infused Porous Surfaces (SLIPS) for medical devices and implants that could eliminate the conventional dependency on anticoagulant drugs that pose life-threatening side-effect risks.^[24]

One of his more recent innovations is the creation of tiny, complex, three-dimensional models of living human organs, known as "organs-on-chips" (Organ Chips), which mimic complicated human organ functions in vitro as a way to potentially replace traditional animal-based methods for testing of drugs and toxins.^[25] The first human Organ Chip, a human Lung Chip, was reported in Science in 2010.^[26] Created using microchip manufacturing methods, the Lung Chip is a complex three-dimensional model of a breathing lung that incorporates living human lung alveolar epithelial cells interfaced with endothelial cells within microfluidic channels cast in silicone rubber, which recapitulate structure and function of the tissue-vasculature interface of lung alveolus (air sacs). In 2012, Ingber and his team demonstrated in a study in Science Translational Medicine the ability to mimic a complex human disease on the Lung Chip — specifically pulmonary edema, known commonly as “fluid on the lungs” — and to identify new therapeutics using this model.^[27] As an alternative to animal studies, Organ Chips could be used to study the safety and efficacy of new drugs, accelerating the introduction of new drugs to market while significantly lowering research costs.^[28] Ingber's group has since expanded this technology to develop other model organs, including the intestine,^[29] kidney,^[30] bone marrow,^[31] blood-brain barrier,^[32] and liver. In 2012, Ingber's team was awarded a DARPA contract to string together multiple Organ Chips to build an automated human body-on-chips that will recapitulate whole-body physiology.^[33] This system could be used in combination with computational modeling to rapidly assess responses to new drug candidates, providing critical information on their safety, efficacy, and pharmacokinetics.^[34]

Other new technologies from Ingber's lab include development of a fully biodegradable plastic alternative inspired by natural cuticle material found in shrimp shells and insect exoskeletons, known as “Shrilk”;^[35] a mechanically activated nanotherapeutic that selectively directs clot-busting drugs to sites of vascular occlusion while minimizing unintended bleeding;^[36] an siRNA nanoparticle therapy that prevents breast cancer progression;^[37] a dialysis-like sepsis device that cleanses blood of all infectious pathogens, fungi and toxins without requiring prior identification;^[38] a surface coating for medical materials and devices that prevents clot formation and bacteria accumulation that reduces the need for use of conventional anticoagulant drugs that frequently result in life-threatening side effects,^[24] and a computational approach to diagnostics and therapeutics that incorporates both animation and molecular modeling software to virtually develop and test potential drugs designed to fit precisely into their targets’ molecular structures.^[39]

Leadership and public service

Earlier in his career, Ingber helped to bridge Harvard University, its affiliated hospitals, and the Massachusetts Institute of Technology (MIT) through his involvement in the Center for Integration in Medicine and Innovative Technology, Harvard-MIT Division of Health Sciences and Technology, and Dana-Farber/Harvard Cancer Center. He also has been a member of the Center for Nanoscale Systems and the Materials Research Science and Engineering Center at Harvard, as well as the MIT Center for Bioengineering.

In 2009, Ingber was named Founding Director of the Wyss Institute for Biologically Inspired Engineering at Harvard University, which was launched with a $125 million gift— which at the time was the largest philanthropic gift in Harvard's history—from Swiss philanthropist and entrepreneur Hansjörg Wyss. The Wyss Institute was founded to enable high-risk research and disruptive innovation, and to catalyze the field of biologically inspired engineering in which newly uncovered biological design principles are leveraged to develop new engineering innovations in the form of bioinspired materials and devices for medicine, industry, and the environment.^[40] The Institute is a partnership among Harvard University, its major affiliated hospitals (Beth Israel Deaconess Medical Center, Brigham and Women's Hospital, Boston Children's Hospital, Dana Farber Cancer Institute, Massachusetts General Hospital, Spaulding Rehabilitation Hospital), Boston University, Massachusetts Institute of Technology, Tufts University, University of Massachusetts Medical School, Charité - Universitätsmedizin Berlin, and University of Zurich.

Ingber is a member of the National Academy of Medicine, the National Academy of Inventors, the American Institute for Medical and Biological Engineering, and the American Academy of Arts and Sciences. He served as a member of the Space Studies Board^[41] of the U.S. National Research Council (NRC), which advises the National Academy of Sciences, National Academy of Engineering, and National Institute of Medicine, and he chaired its Committee on Space Biology and Medicine. He has been an external reviewer of multiple NRC reports, including “Plan for the International Space Station,” “Future Biotechnology Research on the International Space Station,”^[42] "Assessment of Directions in Microgravity and Physical Sciences Research at NASA",^[43] and “The Astrophysical Context of Life.”^[44]

Ingber also has served as a consultant to numerous companies in the pharmaceutical, biotechnology, and cosmetics industries, including Merck, Roche, Astrazeneca, Biogen, Chanel, and L’Oreal, among others. He currently chairs the Scientific Advisory Boards of Emulate, Inc. and Boa Biomedical, Inc.

Awards

Ingber has also been named to multiple Who's Who lists for his diverse contributions including: Science and Engineering (1991), America (1994), the World (1997), Medicine and Healthcare (1999), Business Leaders and Professionals—Honors Edition (2007), and was honored with the Albert Nelson Marquis Lifetime Achievement Award in 2018.^[64]

Art and design exhibitions

Ingber collaborates internationally with artists, architects, and designers, as well as scientists, physicians, engineers, and the public. Examples of his involvement in the art/design community include:

References

1. ^Crow, James Mitchell (19 January 2015). [https://cosmosmagazine.com/biology/man-who-built-organs-chips "The man who built organs on chips"], Cosmos.
2. ^[https://www.hms.harvard.edu/dms/bbs/fac/Ingber.php "Donald Ingber"], Harvard Medical School.
3. ^{{cite web|title=Neomorphics, Inc: Private Company Information|url=https://www.bloomberg.com/research/stocks/private/snapshot.asp?privcapId=22354525|website=www.bloomberg.com|accessdate=5 February 2015}}
4. ^{{cite web|title=Tensegra, Inc.: Private Company Information|url=https://www.bloomberg.com/research/stocks/private/snapshot.asp?privcapId=31677|website=www.bloomberg.com|accessdate=5 February 2015}}
5. ^{{cite web|title=Emulate Launches to Commercialize Human Organs-on-Chips|url=http://www.businesswire.com/news/home/20140728005140/en/Emulate-Launches-Commercialize-Automated-Human-Organs-on-Chips-Platform|website=www.businesswire.com|accessdate=5 February 2015}}
6. ^{{Cite web|url=https://opsonix.com/|title=Welcome to Opsonix|website=Opsonix Website|language=en-US|access-date=2019-01-10}}
7. ^Ingber, Donald (2011). "What We Sort: Venus Paradise Coloring Set", in Sherry Turkle (ed). Falling for Science: Objects in Mind. MIT Press (pp. 252–261), p. 254.
8. ^{{cite web|url=http://www.medscape.com/viewarticle/829739_2|title=Medscape Log In|website=www.medscape.com}}
9. ^{{cite web|title=Mechanical Engineering of the Cytoskeleton in Developmental Biology|url=https://books.google.com/books?id=pQp3NZMKLL8C&pg=PA188|publisher=Science Academic Press}}
10. ^{{cite web|title=Engineering Information: Donald Ingber, MD, PhD|url=http://www.engineerdir.com/dictionary/catalog/3643/|website=www.engineeringdir.com|accessdate=5 February 2015}}
11. ^{{cite journal|last1=Ingber|first1=Donald|title=Mechanochemical Switching between Growth and Differentiation during Fibroblast Growth Factor-stimulated Angiogenesis In Vitro: Role of Extracellular Matrix|journal=The Journal of Cell Biology|date=July 1, 1989|volume=109|issue=July|pages=317–330|url=http://jcb.rupress.org/content/109/1/317.full.pdf|accessdate=5 February 2015|doi=10.1083/jcb.109.1.317 |pmc=2115480}}
12. ^{{cite web|title=Lab on a Chip Editorial Board Details|url=http://www.rsc.org/Publishing/Journals/lc/EBDetails/DonaldIngber.asp|website=www.rsc.org|accessdate=5 February 2015}}
13. ^{{cite web|title=Build it Like Mother Nature|url=http://wyss.harvard.edu/viewpage/203/build-it-like-mother-nature|website=wyss.harvard.edu|accessdate=11 February 2015}}
14. ^{{cite web|title=Tensegrity|url=http://www.scholarpedia.org/article/Tensegrity|website=www.scholarpedia.org|accessdate=11 February 2015}}
15. ^{{cite journal|last1=Ingber|first1=Donald|title=Tensegrity I. Cell structure and hierarchical systems biology|journal=Journal of Cell Science|date=April 1, 2003|pages=613–627|url=http://jcs.biologists.org/content/116/7/1157.short|accessdate=11 February 2015}}
16. ^{{cite book|vauthors=Ingber DE, Jamieson JD|title=Cells as tensegrity structures: architectural regulation of histodifferentiation by physical forces transducer over basement membrane|date=1985|publisher=Academic Press|location=Orlando|pages=13–32|url=https://apps.childrenshospital.org/clinical/research/ingber/PDF/book/Ingber1985-cellastensegrity.pdf|accessdate=11 February 2015}}
17. ^{{cite journal|last1=Ingber|first1=Donald|title=Cellular mechanotransduction: putting all the pieces together again|journal=FASEB Journal|date=May 2006|volume=20|issue=7|pages=811–827|pmid=16675838|doi=10.1096/fj.05-5424rev}}
18. ^{{cite journal|last1=Ingber|first1=Donald|title=Tensegrity and mechanotransduction|journal=Journal of Bodywork and Movement Therapies|date=June 16, 2008|volume=12|issue=3|pages=198–200|doi=10.1016/j.jbmt.2008.04.038|pmid=19083675|pmc=2614693}}
19. ^{{cite journal|vauthors=Ingber DE, Madri JA, Jamieson JD|title=Role of basal lamina in neoplastic disorganization of tissue architecture|journal=PNAS|date=June 1981|volume=78|issue=6|pages=3901–3905|doi=10.1073/pnas.78.6.3901|pmid=7022458|pmc=319681}}
20. ^{{cite web|url=https://www.cancer.gov/publications/dictionaries/cancer-drug|title=NCI Drug Dictionary|website=National Cancer Institute}}
21. ^{{cite journal|last1=Reardon|first1=Sara|title=Artificial spleen cleans up blood|journal=Nature News|date=September 14, 2014|doi=10.1038/nature.2014.15917|url=http://www.nature.com/news/artificial-spleen-cleans-up-blood-1.15917}}
22. ^Phillip, Abby (September 16, 2014). [https://www.washingtonpost.com/news/to-your-health/wp/2014/09/16/from-e-coli-to-ebola-a-device-that-can-filter-deadly-pathogens-out-of-the-body/ "From E. coli to Ebola: A device that can filter deadly pathogens out of the body"], The Washington Post.
23. ^{{cite journal|last1=Storr|first1=Krystnell A.|title=A Shotgun for Blood Clots|journal=Science|date=July 5, 2012|url=http://news.sciencemag.org/biology/2012/07/shotgun-blood-clots|accessdate=11 February 2015}}
24. ^¹{{cite journal|vauthors=Ingber DE, Aizenberg J, Leslie D, Waterhouse A|title=A bioinspired omniphobic surface coating on medical devices prevents thrombosis and biofouling|journal=Nature Biotechnology|date=October 12, 2013|volume=32|pages=1134–1140|doi=10.1038/nbt.3020|url=http://www.nature.com/nbt/journal/v32/n11/full/nbt.3020.html|accessdate=11 February 2015|pmid=25306244}}
25. ^{{cite web|title=Organs-on-Chips|url=http://wyss.harvard.edu/viewpage/461/|website=wyss.harvard.edu|publisher=Wyss Institute|accessdate=11 February 2015}}
26. ^{{cite journal|author1=DE Ingber |author2=Hsin HY |author3=Huh D |title=Reconstituting Organ-Level Lung Functions on a Chip|journal=Science|date=June 25, 2010|volume=328|issue=5986|pages=1662–1668|doi=10.1126/science.1188302|url=http://www.sciencemag.org/content/328/5986/1662.abstract|accessdate=11 February 2015|pmid=20576885}}
27. ^{{cite journal|vauthors=Ingber DE, McAlexander MA, Huh D, Leslie DC|title=A Human Disease Model of Drug Toxicity-Induced Pulmonary Edema in Lung-on-a-Chip Microdevice|journal=Science Translational Medicine|date=November 7, 2012|volume=4|issue=159|page=159ra147|doi=10.1126/scitranslmed.3004249|url=http://stm.sciencemag.org/content/4/159/159ra147|accessdate=11 February 2015|pmid=23136042}}
28. ^{{cite news|last1=Burrell|first1=Teal|title=Can We Eliminate Animals from Medical Research?|url=https://www.pbs.org/wgbh/nova/next/body/eliminating-animal-models/|accessdate=11 February 2015|work=Online Article|agency=PBS.org|publisher=PBS|date=August 7, 2013}}
29. ^{{cite web|title=Harvard's Wyss Institute Creates Living Human Gut-on-a-Chip|url=http://wyss.harvard.edu/viewpressrelease/80/|website=wyss.harvard.edu|publisher=Wyss Institute|accessdate=11 February 2015}}
30. ^{{cite web|title=Three 'Organs-on-Chips' ready to serve as disease models, drug testbeds|url=http://wyss.harvard.edu/viewpage/484/|website=wyss.harvard.edu|publisher=Wyss Institute|accessdate=11 February 2015}}
31. ^{{cite web|title=Bone marrow-on-a-chip unveiled|url=http://wyss.harvard.edu/viewpressrelease/153/bone-marrowonachip-unveiled|website=wyss.harvard.edu|publisher=Wyss Institute|accessdate=11 February 2015}}
32. ^{{Cite web|url=https://wyss.harvard.edu/taking-the-brain-apart-to-put-it-all-together-again/|title=Taking the brain apart to put it all together again|date=2018-08-20|website=Wyss Institute|language=en-US|access-date=2019-01-10}}
33. ^{{cite web|title=Wyss Institute to Receive up to $37 Million from DARPA to Integrate Multiple Organ-on-Chip Systems to Mimic the Whole Human Body|url=http://wyss.harvard.edu/viewpressrelease/91/wyss-institute-to-receive-up-to-37-million-from-darpa-to-integrate-multiple-organonchip-systems-to-mimic-the-whole-human-body|website=wyss.harvard.edu|publisher=Wyss Institute|accessdate=11 February 2015}}
34. ^{{cite news|last1=Drummond|first1=Katie|title=Military's 'Body-on-a-chip' Could Fast-Track Pharmaceuticals|url=https://www.forbes.com/sites/katiedrummond/2012/07/31/body-on-chip/|accessdate=11 February 2015|work=Online article|agency=Forbes|publisher=Forbes Magazine|date=July 31, 2012}}
35. ^{{cite journal|vauthors=Ingber DE, Fernandez JG|title=Unexpected Strength and Toughness in Chitosan-Fibroin Laminates Inspired by Insect Cuticle|journal=Advanced Materials|date=January 24, 2012|volume=24|issue=4|pages=480–484|doi=10.1002/adma.201104051|pmid=22162193}}
36. ^{{cite journal|author=Ingber, DE|title=Nanoparticles home in to clear clots|journal=Nature|date=July 11, 2012|volume=487|issue=142|doi=10.1038/487142a|url=http://www.nature.com/nature/journal/v487/n7406/full/487142a.html|accessdate=11 February 2015}}
37. ^{{cite journal|vauthors=Ingber DE, Collins JJ, Brock A|title=Silencing HoxA1 by Intraductal Injection of siRNA Lipidoid Nanoparticles Prevents Mammary Tumor Progression in Mice|journal=Science Translational Medicine|date=January 1, 2014|volume=6|issue=217|page=217ra2|doi=10.1126/scitranslmed.3007048|url=http://stm.sciencemag.org/content/6/217/217ra2|accessdate=11 February 2015|pmid=24382894}}
38. ^{{cite journal|vauthors=Ingber DE, Kang JH|title=An extracorporeal blood-cleansing device for sepsis therapy|journal=Nature Medicine|date=September 14, 2014|volume=20|pages=1211–1216|doi=10.1038/nm.3640|url=http://www.nature.com/nm/journal/v20/n10/full/nm.3640.html|accessdate=11 February 2015|pmid=25216635}}
39. ^{{Cite web|url=https://wyss.harvard.edu/can-molecular-modeling-go-quantum/|title=Can molecular modeling go quantum?|date=2018-04-13|website=Wyss Institute|language=en-US|access-date=2019-01-10}}
40. ^{{cite web|title=About Us: Wyss Institute|url=http://wyss.harvard.edu/viewpage/about-us/about-us|website=wyss.harvard.edu|publisher=Wyss Institute|accessdate=11 February 2015}}
41. ^{{cite book|title=Review of NASA Plans for the International Space Station|date=April 5, 2006|publisher=National Academies Press|location=Washington, D.C.|page=vi|url=https://books.google.com/books?id=nglSAgAAQBAJ&pg=PR6&lpg=PR6&dq=plan+for+international+space+station+ingber&source=bl&ots=MK1iAtOL2-&sig=GwJKhK2A8m2kymqUXh0ixvwBD84&hl=en&sa=X&ei=ROLPVKXPNtGmyATYkIHwAQ&ved=0CDsQ6AEwBA#v=onepage&q=plan%20for%20international%20space%20station%20ingber&f=false|accessdate=11 February 2015}}
42. ^{{cite book|title=Future Biotechnology Research on the International Space Station|date=2000|publisher=National Academies Press|location=Washington, D.C.|isbn=0-309-56294-5|page=xiii|url=https://books.google.com/books?id=NNNTAgAAQBAJ&pg=PT13&lpg=PT13&dq=Future+Biotechnology+Research+on+the+International+Space+Station+ingber&source=bl&ots=0erjOylRlG&sig=Xmo-pDXKTxwPG6rzr9tOKUMfA14&hl=en&sa=X&ei=JuLPVJf9OoWwyATT44LoAw&ved=0CCcQ6AEwAQ#v=onepage&q=Future%20Biotechnology%20Research%20on%20the%20International%20Space%20Station%20ingber&f=false|accessdate=11 February 2015}}
43. ^{{cite book|author=National Research Council|title=Assessment of Directions in Microgravity and Physical Sciences Research at NASA|date=2003|publisher=National Academies Press|location=Washington, D.C.|url=http://www.nap.edu/openbook.php?record_id=10624|accessdate=11 February 2015}}
44. ^{{cite book|author=National Research Council|title=The Astrophysical Context of Life|date=May 25, 2005|publisher=National Academies Press|location=Washington, D.C.|page=xi|url=https://books.google.com/books?id=9l1YAgAAQBAJ&pg=PR11&lpg=PR11&dq=donald+ingber+nrc+reports&source=bl&ots=iWUukMgagy&sig=yPNKOaNqLDRl3NSVOASyrieGWcM&hl=en&sa=X&ei=2-HPVP6XCpOzyQTs8IDICA&ved=0CCcQ6AEwAQ#v=onepage&q=donald%20ingber%20nrc%20reports&f=false|accessdate=11 February 2015}}
45. ^https://academic.oup.com/ib/pages/Editorial_Board
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47. ^{{Cite web|url=https://www.biophysics.org/Portals/0/BPSAssets/Newsroom/2017%20Society%20Award%20Winners%20release.pdf|title=2017 Society Award Winners|last=|first=|date=|website=www.biophysics.org|archive-url=|archive-date=|dead-url=|access-date=2019-01-10}}
48. ^{{Cite web|url=https://wyss.harvard.edu/ingber-receives-the-2016-bmes-shu-chien-award/|title=Ingber receives the 2016 BMES Shu Chien Award|date=2016-01-08|website=Wyss Institute|language=en-US|access-date=2019-01-10}}
49. ^{{Cite web|url=http://www.mirm.pitt.edu/advanced-training-course/|title=Advanced Training Course {{!}} Regenerative Medicine at the McGowan Institute|language=en-US|access-date=2019-01-10}}
50. ^{{Cite web|url=http://chem.tufts.edu/seminars-spring16.pdf|title=2016 Tufts Tishler Lectures|last=|first=|date=|website=chem.tufts.edu|archive-url=|archive-date=|dead-url=|access-date=2019-01-10}}
51. ^{{Cite web|url=https://2015globalthinkers.foreignpolicy.com/|title=The Leading Global Thinkers of 2015 - Foreign Policy|website=2015globalthinkers.foreignpolicy.com|language=en|access-date=2019-01-10}}
52. ^{{cite web|title=The 2014 Graeme Clark Oration |url=http://www.graemeclarkoration.org.au/the-2014-oration.html |website=www.graemeclarkeoration.org.au |publisher=The Graeme Clark Oration |accessdate=11 February 2015 |deadurl=yes |archiveurl=https://web.archive.org/web/20150203193011/http://www.graemeclarkoration.org.au/the-2014-oration.html |archivedate=3 February 2015 |df= }}
53. ^{{cite web|url=http://www.graemeclarkoration.org.au/the-2014-oration.html|title=Watch video recording here|publisher=|deadurl=yes|archiveurl=https://web.archive.org/web/20150203193011/http://www.graemeclarkoration.org.au/the-2014-oration.html|archivedate=2015-02-03|df=}}
54. ^{{cite web|title=National Center for Advancing Translational Sciences - NCATS Catalyzing Innovation|url=http://www.ncats.nih.gov/news-and-events/e-news/vol02-iss02/may2013.html|website=www.ncats.nih.gov|publisher=NCATS}}
55. ^{{cite news|title=Society of Toxicology honors members for scientific achievements|url=http://www.eurekalert.org/pub_releases/2013-02/sot-sot021513.php|accessdate=11 February 2015|work=Press release|agency=Society of Toxicology|publisher=EurekAlert! AAAS|date=February 15, 2013}}
56. ^{{Cite web|url=https://hms.harvard.edu/news/donald-ingber-elected-institute-medicine|title=Donald Ingber Elected to the Institute of Medicine {{!}} Harvard Medical School|website=hms.harvard.edu|access-date=2019-01-10}}
57. ^{{cite web|title=Don Ingber and Wyss Institute Win World Technology Awards|url=http://wyss.harvard.edu/viewpage/400/|website=wyss.harvard.edu|publisher=Wyss Institute|accessdate=11 February 2015}}
58. ^{{cite news|last1=Mowatt|first1=Twig|title=Founding Director of Harvard's Wyss Institute Elected to the College of Fellows of the American Institute for Medical and Biological Engineering|url=http://wyss.harvard.edu/viewpressrelease/51/founding-director-of-harvards-wyss-institute-elected-to-the-college-of-fellows-of-the-american-institute-for-medical-and-biological-engineering;jsessionid=514858C603CC9FBA09445BDB865093D4.wyss1|accessdate=11 February 2015|work=Press release|agency=Wyss Institute|publisher=Wyss Institute|date=February 4, 2011}}
59. ^{{cite news|last1=Mowatt|first1=Twig|title=Wyss Institute Founding Director Donald Ingber Receives 2011 Holst Medal|url=http://wyss.harvard.edu/viewpressrelease/73/wyss-institute-founding-director-donald-ingber-receives-2011-holst-medal|accessdate=11 February 2015|work=Press release|agency=Wyss Institute|publisher=Wyss Institute|date=December 16, 2011}}
60. ^{{cite web|title=Wyss Founding Director Receives Lifetime Achievement Award from the Society of In Vitro Biology|url=http://wyss.harvard.edu/viewpressrelease/34/wyss-founding-director-receives-lifetime-achievement-award-from-the-society-of-in-vitro-biology|website=wyss.harvard.edu|publisher=Wyss Institute|accessdate=11 February 2015}}
61. ^{{cite web|title=Wyss Leadership: Donald E. Ingber, M.D., Ph.D.|url=http://wyss.harvard.edu/viewpage/121/donald-e-ingber|website=wyss.harvard.edu|publisher=Wyss Institute|accessdate=11 February 2015}}
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