Biomod/2011/MIT/Origami
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| - | [[Biomod/2011/MIT/Origami | <font face=" | + | [[Biomod/2011/MIT/Origami | <font face="courier new" style="color:#000000"> '''Home''' </font>]] |
| - | [[Biomod/2011/MIT/Origami/ | <font face=" | + | [[Biomod/2011/MIT/Origami/ | <font face="courier new" style="color:#ffffff"> '''Motivation''' </font>]] |
| - | [[Biomod/2011/MIT/Origami/Process | <font face=" | + | [[Biomod/2011/MIT/Origami/Process | <font face="courier new" style="color:#ffffff"> '''Process''' </font>]] |
| - | + | [[Biomod/2011/MIT/Origami/ScrappedIdeas | <font face="courier new" style="color:#ffffff"> '''Tentative Ideas''' </font>]] | |
| - | [[Biomod/2011/MIT/Origami/ScrappedIdeas | <font face=" | + | [[Biomod/2011/MIT/Origami/TeamMembers | <font face="courier new" style="color:#ffffff"> '''Team Members''' </font>]] |
| - | [[Biomod/2011/MIT/Origami/TeamMembers | <font face=" | + | [[Biomod/2011/MIT/Origami/Literature | <font face="courier new" style="color:#ffffff"> '''Literature''' </font>]] |
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| - | + | =MIT Origami= | |
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==Abstract== | ==Abstract== | ||
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''Effective Drug Delivery Vehicles Exhibiting Specific Deformation Programmability'' | ''Effective Drug Delivery Vehicles Exhibiting Specific Deformation Programmability'' | ||
The synthetic technique of DNA origami, involving a single scaffold strand being folded into arbitrary shapes through the attachment of smaller staple strands to various locations along its sequence, has provided a powerfully programmable framework for the spatial design of nanostructures. Our research has involved adding an additional layer of programmability to these constructs, the ability to respond to external stimuli viz. electromagnetic radiation and pH by means of conformational changes. In particular we are exploring how these stimuli stabilize/destabilize linkers in the DNA origami so as to cause the structure to collapse and expand; thereby dramatically enhancing the utility of DNA nanostructures in controlled particle release. An immediately apparent application for such a technology is the precise delivery of drugs at certain targets as a result of stimulated release. | The synthetic technique of DNA origami, involving a single scaffold strand being folded into arbitrary shapes through the attachment of smaller staple strands to various locations along its sequence, has provided a powerfully programmable framework for the spatial design of nanostructures. Our research has involved adding an additional layer of programmability to these constructs, the ability to respond to external stimuli viz. electromagnetic radiation and pH by means of conformational changes. In particular we are exploring how these stimuli stabilize/destabilize linkers in the DNA origami so as to cause the structure to collapse and expand; thereby dramatically enhancing the utility of DNA nanostructures in controlled particle release. An immediately apparent application for such a technology is the precise delivery of drugs at certain targets as a result of stimulated release. | ||
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| + | ==Video== | ||
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==Team== | ==Team== | ||
===Undergrads=== | ===Undergrads=== | ||
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*Aliya Dincer | *Aliya Dincer | ||
*Maria Elena Martinez | *Maria Elena Martinez | ||
*Michael Hernandez | *Michael Hernandez | ||
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===Graduate Student Mentors=== | ===Graduate Student Mentors=== | ||
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*Matthew Adendorff | *Matthew Adendorff | ||
*Ishan Gupta | *Ishan Gupta | ||
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===Faculty Mentor=== | ===Faculty Mentor=== | ||
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| + | *Professor Mark Bathe | ||
| - | ==Websites== | + | <font face="courier new" style="color:#ffffff> |
| + | ==Useful Websites== | ||
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*News story on the MIT webpage about work currently being done in the LCBB on DNA Origami - [http://web.mit.edu/newsoffice/2011/dna-origami-0427.html] | *News story on the MIT webpage about work currently being done in the LCBB on DNA Origami - [http://web.mit.edu/newsoffice/2011/dna-origami-0427.html] | ||
Current revision
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Contents |
MIT Origami
Abstract
Effective Drug Delivery Vehicles Exhibiting Specific Deformation Programmability
The synthetic technique of DNA origami, involving a single scaffold strand being folded into arbitrary shapes through the attachment of smaller staple strands to various locations along its sequence, has provided a powerfully programmable framework for the spatial design of nanostructures. Our research has involved adding an additional layer of programmability to these constructs, the ability to respond to external stimuli viz. electromagnetic radiation and pH by means of conformational changes. In particular we are exploring how these stimuli stabilize/destabilize linkers in the DNA origami so as to cause the structure to collapse and expand; thereby dramatically enhancing the utility of DNA nanostructures in controlled particle release. An immediately apparent application for such a technology is the precise delivery of drugs at certain targets as a result of stimulated release.
Video
Team
Undergrads
- Aliya Dincer
- Maria Elena Martinez
- Michael Hernandez
Graduate Student Mentors
- Matthew Adendorff
- Ishan Gupta
Faculty Mentor
- Professor Mark Bathe
Useful Websites
- News story on the MIT webpage about work currently being done in the LCBB on DNA Origami - [1]
- Laboratory for Cell Biology and Biophysics, MIT- [2]
- Laboratory for Biomolecular Nanotechnology, TUM - [3]
- International Bio-Molecular Design Competition - [4]
