DNA brings materials to life
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| This shows two colloids interacting over time in relation to temperature. Credit: Giuseppe Foffi, EPFL |
Self-assembly refers to the ability of a colloid's particles to spontaneously form a kind of stable structural arrangement as a result of the shape and direction of the colloid's particles as they interact with the dispersal medium. Although no external force is required, self-assembly generally takes place as a response to a change in an environmental factor such as temperature, light, etc. In biological colloids like DNA, proteins and other macromolecules, self-assembly is usually the first step to self-organization, which underlies many cellular structures. But in terms of technology, self-assembling colloids could have a wide range of applications, fuelling much research in the field.
But what about self-assembly of two -- or more -- species of different colloids? This is the question addressed by Giuseppe Foffi's group at EPFL, working in collaboration with Erika Eiser's group at the University of Cambridge. The scientists showed that when the interactions between the particles of two different colloids are carefully designed, they result in the formation of new structures. Specifically, they have discovered a ways to obtain self-assembled structures that depend strongly on temperature changes. Giuseppe Foffi says: "In a sense, the new structures have a 'memory' of their preparation history."
Using DNA-coated colloids, the group of Erika Eiser was able to control the self-assembling progress between two different colloidal species. Fluorescent polystyrene spheres were coated with different DNA strands (giving them a 'hairy' appearance) that acted as means of particle interaction and can be used to characterize the different species. The advantage of using DNA strands was that the interactions between the particles could be programed using the compatibility of the DNA sequences. Another very interesting property is their responsiveness to sharp changes in temperature, offering a high degree in specificity and programmability. The two species of colloids were mixed together in a 'binary mixture' where one could aggregate faster, therefore creating a structural 'scaffold' for the other to assemble upon.
By exploiting the selectivity of DNA base-pairing, supported by simulation studies by the EPFL group, the scientists found that they could achieve an unprecedented control of the morphology of the interacting colloids. By gathering data about the system's morphology and the dynamics of particle interactions, the authors concluded that this approach is not restricted to nano-scale objects like other methods, but can be applied to the entire range of colloidal sizes. In addition, they foresee that this method can have a number of applications, for example light-reacting paints or smart patches that respond to changes in the body's temperature or pH by releasing particles filled with a drug like an antibiotic or antipyretic.
Source: Ecole Polytechnique Fédérale de Lausanne
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on Saturday, June 15, 2013.
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