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Emory chemists invent shape-shifting nanomaterial

Emory University | Jan. 6, 2021
Chemists have developed a nanomaterial that they can trigger to shape shift from flat sheets to tubes and back to sheets again in a controllable fashion. The Journal of the American Chemical Society published a description of the nanomaterial, which was developed at Emory University and holds potential for a range of biomedical applications, from controlled-release drug delivery to tissue engineering.
The nanomaterial, which in sheet form is 10,000 times thinner than the width of a human hair, is made of synthetic collagen. Naturally occurring collagen is the most abundant protein in humans, making the new material intrinsically biocompatible. ....

United States , Helen Siaw , Alisina Bazrafshan , Khalid Salaita , Xiaobing Zuo , Jan Pieter Abrahams , Thorsten Blum , Gavin Touponse , Brian Dyer , Robertp Apkarian , Arthur Mccanna , Vincent Conticello , Paul Scherrer Institute In Villigen , University Of California Merced , Emory Office Of Technology , Emory University , National Institutes Of Health , University Of Basel , National Science Foundation , Paul Scherrer Institute , Journal Of The American Chemical Society , Argonne National Laboratory , Swiss National Science Foundation , American Chemical Society , Memory Office , Technology Transfer ,

Nanotechnology Now - Press Release: Chemists invent shape-shifting nanomaterial with biomedical potential It converts from sheets to tubes and back in a controllable fashion

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Home > Press > Chemists invent shape-shifting nanomaterial with biomedical potential It converts from sheets to tubes and back in a controllable fashion
Fluorescent micrograph, above, shows the new nanomaterial in sheet form. The white scale bar is 4 micrometers in the main photo and 2 micrometers in the inset photo.
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Conticello Lab
Abstract:
Chemists have developed a nanomaterial that they can trigger to shape shift from flat sheets to tubes and back to sheets again in a controllable fashion. The Journal of the American Chemical Society published a description of the nanomaterial, which was developed at Emory University and holds potential for a range of biomedical applications, from controlled-release drug delivery to tissue engineering. ....

United States , Helen Siaw , Alisina Bazrafshan , Khalid Salaita , Xiaobing Zuo , Jan Pieter Abrahams , Thorsten Blum , Gavin Touponse , Brian Dyer , Carol Clark , Robertp Apkarian , Vincent Conticello , Arthur Mccanna , Paul Scherrer Institute In Villigen , University Of California Merced , Emory Office Of Technology , Emory University , University Of Basel , National Science Foundation , University Of Oklahoma , Goethe University , Argonne National Laboratory , Swiss National Science Foundation , Wave Inc , Home Press Chemists , Research Awards Scholarships Gifts Contests Honors Records ,

Emory Chemists Invent Shape-Shifting Nanomaterial

Emory University | Jan. 6, 2021
Chemists have developed a nanomaterial that they can trigger to shape shift from flat sheets to tubes and back to sheets again in a controllable fashion. The Journal of the American Chemical Society published a description of the nanomaterial, which was developed at Emory University and holds potential for a range of biomedical applications, from controlled-release drug delivery to tissue engineering.
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The nanomaterial, which in sheet form is 10,000 times thinner than the width of a human hair, is made of synthetic collagen. Naturally occurring collagen is the most abundant protein in humans, making the new material intrinsically biocompatible. ....

Helen Siaw , Alisina Bazrafshan , Khalid Salaita , Xiaobing Zuo , Jan Pieter Abrahams , Gavin Touponse , Thorsten Blum , Brian Dyer , Robertp Apkarian , Arthur Mccanna , Paul Scherrer Institute In Villigen , University Of California Merced , National Institutes Of Health , University Of Basel , National Science Foundation , Paul Scherrer Institute , Argonne National Laboratory , Swiss National Science Foundation , Andrea Merg , California Merced , Cellular Imaging , Integrated Electron Microscopy , National Institutes , ஹெலன் சியாவ் , ஜான் பீட்டர் , முள் ப்ளம் ,

Chemists invent shape-shifting nanomaterial with biomedical potential

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IMAGE: Fluorescent micrograph, above, shows the new nanomaterial in sheet form. The white scale bar is 4 micrometers in the main photo and 2 micrometers in the inset photo.
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Credit: Conticello Lab
Chemists have developed a nanomaterial that they can trigger to shape shift from flat sheets to tubes and back to sheets again in a controllable fashion. The
Journal of the American Chemical Society published a description of the nanomaterial, which was developed at Emory University and holds potential for a range of biomedical applications, from controlled-release drug delivery to tissue engineering.
The nanomaterial, which in sheet form is 10,000 times thinner than the width of a human hair, is made of synthetic collagen. Naturally occurring collagen is the most abundant protein in humans, making the new material intrinsically biocompatible. ....

United States , Helen Siaw , Alisina Bazrafshan , Khalid Salaita , Xiaobing Zuo , Jan Pieter Abrahams , Thorsten Blum , Gavin Touponse , Brian Dyer , Robertp Apkarian , Arthur Mccanna , Vincent Conticello , Paul Scherrer Institute In Villigen , University Of California Merced , Emory Office Of Technology , Emory University , National Institutes Of Health , University Of Basel , National Science Foundation , Paul Scherrer Institute , Journal Of The American Chemical Society , Argonne National Laboratory , Swiss National Science Foundation , American Chemical Society , Memory Office , Technology Transfer ,