Self Assembly : Nature’s Way To Do It Arbel Artzy Schnirman Biology Seminar 2008 Part 1.

Slides:

Advertisements

Similar presentations

Nanoscience, Nanotechnology and Nanomanufacturing Exciting new science and technology for the 21st century.

Advertisements

In the name of GOD. Zeinab Mokhtari 22-Sep-2010 Angew. Chem. Int. Ed. 2006, 45, 735 –739 Finite-Size, Fully Addressable DNA Tile Lattices Formed by Hierarchical.

Module A-2: SYNTHESIS & ASSEMBLY

1 SODA January 23, 2011 Temperature 1 Self-Assembly: Deterministic Assembly in 3D and Probabilistic Assembly in 2D Matthew CookUniversity of Zurich and.

How to achieve these behaviours: IL 33. Radiolara Ecoli – division and replication Non-trivial 3D self assemblySelf replication In inorganic materials,

Paul Rothemund, Departments of Computer Science and Computation & Neural Systems, California Institute of Technology Jerzy Szablowski : Biological.

Nature provides us of many examples of self- assembled materials, from soft and flexible cell- membranes to hard sea shells. Such materials.

Lecture 14: Special interactions. What did we cover in the last lecture? Restricted motion of molecules near a surface results in a repulsive force which.

First Blueprint, Now Bricks: DNA is nanoscale construction material. Yamuna Krishnan The Chemical Biology Group National Centre for Biological Sciences,

Matthew Mancuso BEE 7600, Professor Dan Luo Department of Biomedical Engineering, Cornell University Presented Thursday February 17 th, 2011 “Give me a.

Mansi Mavani Graduate Student Department of Physics, OSU Stillwater

NANOTECHNOLOGY.

Nanotechnology Understanding and control of matter at dimensions of 1 to 100 nanometers Ultimate aim: design and assemble any structure atom by atom -

Applications of Synthetic Biology Kristala L. J. Prather Department of Chemical Engineering, Massachusetts Institute of Technology NSF Synthetic Biology.

Jong-Sun Yi 1. Molecular self-assembly Many top down processes create patterns serially and require extreme conditions. (vacuum, temperature, etc.) Bottom-up,

A capstone course for BioSUCCEED:

Molecular Nanotechnology By Kavitha, Boppana. Presentation Overview  Molecular Manufacturing  Positional Assembly  Self Replication  Visual Images.

Biology 102 Lecture 10: Energy Flow in Cells (Part 1) Alternate title: “How life on earth can exist despite the fact that the universe is falling apart”

Topics in Biological Physics Design and self-assembly of two-dimensional DNA crystals Benny Gil 16/12/08 Fig3.a.

1.1 Materials Self-Assembly

DNA: Not Merely the Secret of Life Bio-Inspired Bottom-Up Nanoscale Control of the Structure of Matter Nadrian C. Seeman Department of Chemistry New.

Nanoscience at UMCP. Department of Chemistry and Biochemistry Faculty: Jeff Davis, Bryan Eichhorn, Doug English, Lyle Isaacs, Jason Kahn, Janice Reutt-Robey,

Impact on current processes Acknowledgments Literature Cited Abstract Minimum Pots for the Usual Suspects Recent exciting advances in DNA self-assembly.

S-layer proteins Potential Application in Nanobiotechnology.

Nucleic Acid Engineering and Its Applications Dan Luo, Ph.D. Assistant Professor Department of Biological and Environmental Engineering Cornell University.

What Is the Intellectual Goal of Structural DNA Nanotechnology? Controlling the Structure of Matter in 3D to the Highest Extent (Resolution) Possible,

Directed Assembly of Block Copolymer Blends into Nonregular Device-Oriented Structures Mark P. Stoykovich,1 Marcus Mu¨ller,2 Sang Ouk Kim,3 Harun H. Solak,4.

Ashish Goel Stanford University Joint work with Len Adleman, Holin Chen, Qi Cheng, Ming-Deh Huang, Pablo Moisset, Paul.

Molecular Recognition. Lehn 1993: “Self-assembly of molecular and macromolecular systems is a versatile and modular tool for the creation of higher order.

Nanoscale Self-Assembly A Computational View Philip Kuekes Quantum Science Research HP Labs.

Nanotechnology By: Adam Morte.

Nanostructural Architectures from Molecular Building Blocks.

Nano means the things which are in extremely small measure. The size of the particles which are lesser than 100 nanometers are rightly called as Nanoparticles.

Nanotechnologies Do Good or Harm The project made by Karaseva Helena 11 “A” form, school № 574 The science director is Rusanova E. B. Moscow, 2009.

DNA Nanostructures and Patterning Taylor Stevenson Nucleic Acid Engineering February 15 th, 2011.

Content Standard A As a result of activities in grades 9-12, all students should develop: Abilities necessary to do scientific inquiry Understandings about.

Collaboration over the World Wide Web Using IN-VSEE’s remote SPM B.L. Ramakrishna Arizona state University August 2nd 2001.

DNA-Scaffolded Self-Assembling Nano-Circuitry An Ongoing Research Project with Dr. Soha Hassoun Presentation by Brandon Lucia and Laura Smith.

MAS.961 How To Make Something That Makes (Almost) Anything Complexity, Self Replication and all that…

Nanotechnology The biggest science and engineering initiative since the Apollo program.

What is Biophysics? Biophysics is that branch of knowledge that applies the principles of physics and chemistry and the methods of mathematical analysis.

Quantum to the continuum is the key theme Mesoscale is a frontier for control science Emphasize what is new/why now Lead by specific examples through the.

Surface Enhanced Raman Scattering (SERS) Effect and Applications Cheng Guo 07/15/2008 Mini Symposium on Surface Plasmons.

Techniques for Synthesis of Nano-materials

Algorithmic self-assembly for nano-scale fabrication Erik Winfree Computer Science Computation & Neural Systems and The DNA Caltech DARPA NSF NASA.

Nanotechnology and Medicine Marisoiu Marius Class XI A Colegiul National “Nicolae Titulescu”’ Pucioasa.

EPSRC Chemistry Grand Challenges ENGINEERING AND PHYSICAL SCIENCES RESEARCH COUNCIL Alex Berry, Physical Sciences Portfolio Manager

Nanoscale Science and Engineering. Nanoscale Science and Engineering embodies fundamental research and technology development of materials, structures,

Chapter 2 Properties on the Nanoscale

Nanotechnology (sometimes shortened to "nanotech") is the study of manipulating matter on an atomic and molecular scale. Generally, nanotechnology deals.

Nanochemistry NAN 601 Dr. Marinella Sandros

DNA nanotechnology: Geometric sorting boards

Can Nanoscale Science and Engineering be seamlessly integrated into the STEM Curriculum? Rob Snyder STEM Education.

Chapter 2 The Chemistry of the Cell. The Importance of Carbon The Importance of Water The Importance of Selectively Permeable Membranes The Importance.

A Computational Method for Property Prediction Design and Discovery of Optimal Molecular Scale Solar Antennas Sofia Izmailov Princeton University Chemistry.

Advanced Computing and Information Systems laboratory Nanocomputing technologies José A. B. Fortes Dpt. of Electrical and Computer Eng. and Dpt. of Computer.

Nano Technology and Toxicity Science Project Oregon Islamic Academy.

NANO TECHNOLOGY. Something to think about Imagine being able to cure cancer by drinking a medicine stirred into your favorite fruit juice. Imagine a supercomputer.

Bonding A covalent bond is stronger and holds the atoms in a molecule together. A Hydrogen bond is weaker and it attracts molecules to one another.

“Nanotechnology” (Lecture 1) Shagufta Kanwal Evolution of Technologies.

Entropy & Spontaneity Chapter 17. Review Enthalpy – ∆H=q - heat of reaction Exothermic vs. endothermic Exothermic is generally favored in nature Kinetics.

Nanoscale Thin Films Rob Snyder University of Massachusetts Amherst

“Molecular Self-Assembly of 3D Nanostructures Using DNA Scaffolding”

Goals for Today: Nano-In-The-News Finish Introduction

Quantum corral of 48 iron atoms on copper surface

Programmable DNA Lattices: Design Synthesis & Applications

Department of Chemistry

Hydrocarbon, Fluorocarbon, and Mixed Hydrocarbon/Fluorocarbon Liquid Crystalline Materials from Predictable Supramolecular Assembly of Piperazine-2,5-diones.

Hydrocarbon, Fluorocarbon, and Mixed Hydrocarbon/Fluorocarbon Liquid Crystalline Materials from Predictable Supramolecular Assembly of Piperazine-2,5-diones.

Presentation transcript:

Self Assembly : Nature’s Way To Do It Arbel Artzy Schnirman Biology Seminar 2008 Part 1

Self Assembly Self-Assembly (SA) is the spontaneous organization of molecules or objects into well-defined aggregates via noncovalent interactions (or forces) Building Blocks: molecules and objects with coded information for self-assembly Processing: mix, shake, and form product

Attractive Features of Self- Assembly Understanding life Self-assembly proceeds spontaneously The self-assembled structure is often at or close to thermodynamic equilibrium Self-assembly tends to reject defects, and also has self-healing capability Self-assembly is one of the few practical strategies for making ensembles of nanostructures

The development of self-assembly as a useful approach to the synthesis and manufacturing of complex systems and materials has been identified as a "grand challenge" in the 2003 U.S. National Academies report "Beyond the Molecular Frontier". Science magazine included (7/1/05) "How far can we push chemical self-assembly" in the top-25 list of "big questions" facing science

Principles of Molecular Self- Assembly PNAS April 16, 2002 vol. 99 no –4774

Present Application SCIENCE VOL MARCH 2002

Future Applications Crystallization at All Scales Robotics and Manufacturing Nanoscience and Technology Microelectronics “We understand very little about how dissipation of energy leads to the emergence of ordered structures from disordered components in these systems. But we know that they are vitally important in the cell. That knowledge, by itself, makes it worthwhile to study them” SCIENCE VOL MARCH 2002

Inspiration byNature Inspiration by Nature NATURE VOL JANUARY 2001 René Binet’s entrance to the World Exposition in Paris, 1900, inspired by Haeckel’s drawings of radiolarians

Why DNA? "The nucleic-acid 'system' that operates in terrestrial life is optimized (through evolution) chemistry incarnate. Why not use it... to allow human beings to sculpt something new, perhaps beautiful, perhaps useful, certainly unnatural." Roald Hoffmann, writing in American Scientist, 1994 Roald Hoffmann, writing in American Scientist, 1994 Diameter of about 2 nanometres Short structural repeat (helical pitch) of about 3.4–3.6 nm Stiffness with a persistence length of around 50 nm Programmable molecular recognition-Sticky-ended

One Dimension One Dimension Higher Dimension Higher Dimension

Construction of a DNA Truncated Octahedron J. Am. Chem. SOC. 1994,116,

5-TTGTTCCAGATCTAAATACCTGAACCTTAAGTGTGGTATTTAGATCTGGAACTT-3 5-ACACCAAGGTTCACCGACCAGCGCCTGCTCATTTTTATGAGCAGGCGCTGGTCGGACACTTAGGCTAC-3 J. Am. Chem. SOC. 1994,116,

5-TTGTTCCAGATCTAAATACCTGAACCT-3 5-ACACCAAGGTTCACCGACCAGCGCCTGCTCATT-3 5-TTTATGAGCAGGCGCTGGTCGGACACTTAGGCTAC-3 5-TAAGTGTGGTATTTAGATCTGGAACTT-3 J. Am. Chem. SOC. 1994,116,

5-TTGTTCCAGATCTAAATACC 5-ACACCAAGGTTCACCGACCAGCGCCTGCTCATT-3 5-TTTATGAGCAGGCGCTGGTCGGACACTTAGGCTAC-3 GGTATTTAGATCTGGAACTT-3 5-TAAGTGT TGAACCT-3 J. Am. Chem. SOC. 1994,116,

5-ACACCAAGGTTCA CCGACCAGCGCCTGCTCATT-3 5-TTTATGAGCAGGCGCTGGTCGG ACACTTAGGCTAC-3 5-TTGTTCCAGATCTAAATACC GGTATTTAGATCTGGAACTT-3 5-TAAGTGT TGAACCT-3 J. Am. Chem. SOC. 1994,116,

TGAACCT-3 5-TTGTTCCAGATCTAAATACC GGTATTTAGATCTGGAACTT-3 5-ACACCAAGGTTCA CCGACCAGCGCCTGCTCATT-3 5-TTTATGAGCAGGCGCTGGTCGG 5-TAAGTGT ACACTTAGGCTAC-3 J. Am. Chem. SOC. 1994,116,

16 Yield: 10% J. Am. Chem. SOC. 1994,116,

Yield: 1% J. Am. Chem. SOC. 1994,116,

Yield: 30% J. Am. Chem. SOC. 1994,116,

2

2 Each of the 7 links yield: 50% Total yield: < 1% J. Am. Chem. SOC. 1994,116,

Hierarchical self-assembly of DNA into symmetric supramolecular polyhedra Hierarchical self-assembly of DNA into symmetric supramolecular polyhedra NATURE| Vol March 2008

Hierarchical self-assembly of DNA into symmetric supramolecular polyhedra Hierarchical self-assembly of DNA into symmetric supramolecular polyhedra NATURE| Vol March 2008

Hierarchical self-assembly of DNA into symmetric supramolecular polyhedra Hierarchical self-assembly of DNA into symmetric supramolecular polyhedra NATURE| Vol March 2008

Origami First step Origami First step NATURE Vol March 2006

Origami Second step

NATURE Vol March 2006 Origami third step

NATURE Vol March 2006 Origami Fourth step Origami Fourth step

NATURE Vol March 2006 Origami Fifth step Origami Fifth step

NATURE Vol March 2006 Examples

NATURE Vol March 2006 Examples

Self-assembly is one of the few practical strategies for making ensembles of nanostructures Summary DNA will be a key player in bottom-up nanotechnology nanotechnology

1.Ball, P. (2001) Nature 409, He, Y., Ye, T., Su, M., Zhang, C., Ribbe, A. E., Jiang, W. & Mao, C. (2008) Nature 452, Kamien, R. D. (2003) Science 299, Rothemund, P. W. K. (2006) Nature 440, Seeman, N. C. (2003) Nature 421, Whitesides, G. M. & Grzybowski, B. (2002) Science 295, Zhang, Y. & Seeman, N. C. (1994) J. Am. Chem. Soc. 116,