Alisina Bazrafshan scite author profile

Stimuli-responsive color-changing hydrogels, commonly colored using embedded photonic crystals (PCs), have potential applications ranging from chemical sensing to camouflage and anti-counterfeiting. A major limitation in these PC hydrogels is that they require significant deformation (>20%) in order to change the PC lattice constant and generate an observable chromatic shift (∼100 nm). By analyzing the mechanism of how chameleon skin changes color, we developed a strain-accommodating smart skin (SASS), which maintains near-constant size during chromatic shifting. SASS is composed of two types of hydrogels: a stimuli-responsive, PC-containing hydrogel that is patterned within a second hydrogel with robust mechanical properties, which permits strain accommodation. In contrast to conventional “accordion”-type PC responsive hydrogels, SASS maintains near-constant volume during chromatic shifting. Importantly, SASS materials are stretchable (strain ∼150%), amenable to patterning, spectrally tunable, and responsive to both heat and natural sunlight. We demonstrate examples of using SASS for biomimicry. Our strategy, to embed responsive materials within a mechanically matched scaffolding polymer, provides a general framework to guide the future design of artificial smart skins.

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Highly Polyvalent DNA Motors Generate 100+ pN of Force via Autochemophoresis

Blanchard

Bazrafshan

et al. 2019

Nano Lett.

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Motor proteins such as myosin, kinesin, and dynein are essential to eukaryotic life and power countless processes including muscle contraction, wound closure, cargo transport, and cell division. The design of synthetic nanomachines that can reproduce the functions of these motors is a longstanding goal in the field of nanotechnology. DNA walkers, which are programmed to “walk” along defined tracks via the burnt bridge Brownian ratchet mechanism, are among the most promising synthetic mimics of these motor proteins. While these DNA-based motors can perform useful tasks such as cargo transport, they have not been shown to be capable of cooperating to generate large collective forces for tasks akin to muscle contraction. In this work, we demonstrate that highly polyvalent DNA motors (HPDMs), which can be viewed as cooperative teams of thousands of DNA walkers attached to a microsphere, can generate and sustain substantial forces in the 100+ pN regime. Specifically, we show that HPDMs can generate forces that can unzip and shear DNA duplexes (∼12 and ∼50 pN, respectively) and rupture biotin–streptavidin bonds (∼100–150 pN). To help explain these results, we present a variant of the burnt-bridge Brownian ratchet mechanism that we term autochemophoresis, wherein many individual force generating units generate a self-propagating chemomechanical gradient that produces large collective forces. In addition, we demonstrate the potential of this work to impact future engineering applications by harnessing HPDM autochemophoresis to deposit “molecular ink” via mechanical bond rupture. This work expands the capabilities of synthetic DNA motors to mimic the force-generating functions of biological motors. Our work also builds upon previous observations of autochemophoresis in bacterial transport processes, indicating that autochemophoresis may be a fundamental mechanism of pN-scale force generation in living systems.

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Live-cell super-resolved PAINT imaging of piconewton cellular traction forces

et al. 2020

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2D Crystal Engineering of Nanosheets Assembled from Helical Peptide Building Blocks

et al. 2019

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The successful integration of 2D nanomaterials into functional devices hinges on developing fabrication methods that afford hierarchicalcontrol across length scales of the entire assembly.W ed emonstrate structural control over ac lass of crystalline 2D nanosheets assembled from collagen triple helices.Bylengthening the triple helix unit through sequential additions of Pro-Hyp-Gly triads,w ea chieved sub-angstrom tuning over the 2D lattice.T hese subtle changes influence the overall nanosheet size, which can be adjusted across the mesoscale size regime.The internal structure was observed by cryo-TEM with direct electron detection, whichprovides realspace high-resolution images,inwhich individual triple helices comprising the lattice can be clearly discerned. These results establish ag eneral strategy for tuning the structural hierarchy of 2D nanomaterials that employr igid, cylindrical structural units.

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Tunable DNA Origami Motors Translocate Ballistically Over μm Distances at nm/s Speeds

Bazrafshan

Meyer

et al. 2020

Angew Chem Int Ed

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Inspired by biological motor proteins, that efficiently convert chemical fuel to unidirectional motion, there has been considerable interest in developing synthetic analogues. Among the synthetic motors created thus far, DNA motors that undertake discrete steps on RNA tracks have shown the greatest promise. Nonetheless, DNA nanomotors lack intrinsic directionality, are low speed and take a limited number of steps prior to stalling or dissociation. Herein, we report the first example of a highly tunable DNA origami motor that moves linearly over micron distances at an average speed of 40 nm/ min. Importantly, nanomotors move unidirectionally without intervention through an external force field or a patterned track. Because DNA origami enables precise testing of nanoscale structure-function relationships, we were able to experimentally study the role of motor shape, chassis flexibility, leg distribution, and total number of legs in tuning performance. An anisotropic rigid chassis coupled with a high density of legs maximizes nanomotor speed and endurance.Supporting information and the ORCID identification number(s) for the author(s) of this article can be found under https://doi.

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