A rapid and practical technique for real-time monitoring of biomolecular interactions using mechanical responses of macromolecules

Tarhan, Mehmet C.; Lafitte, Nicolas; Tauran, Yannick; Jalabert, Laurent; Kumemura, Momoko; Perret, Gregoire; Kim, Beom Joon; Coleman, Anthony W.; Fujita, Hiroyuki; Collard, Dominique

doi:10.1038/srep28001

Cited by 21 publications

(25 citation statements)

References 42 publications

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“…Although not demonstrated in this study, an integrated displacement sensor (based on parallel plate capacitors) allows measuring the stiffness and viscous losses of the captured filaments (Figure a). This property enables the detection of mechanical changes on microtubules allowing the picking process to be used for a wide range of applications.…”

Section: Resultsmentioning

confidence: 99%

Pick‐and‐Place Assembly of Single Microtubules

Tarhan

Yokokawa

Jalabert

et al. 2017

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Intracellular transport is affected by the filament network in the densely packed cytoplasm. Biophysical studies focusing on intracellular transport based on microtubule-kinesin system frequently use in vitro motility assays, which are performed either on individual microtubules or on random (or simple) microtubule networks. Assembling intricate networks with high flexibility requires the manipulation of 25 nm diameter microtubules individually, which can be achieved through the use of pick-and-place assembly. Although widely used to assemble tiny objects, pick-and-place is not a common practice for the manipulation of biological materials. Using the high-level handling capabilities of microelectromechanical systems (MEMS) technology, tweezers are designed and fabricated to pick and place single microtubule filaments. Repeated picking and placing cycles provide a multilayered and multidirectional microtubule network even for different surface topographies. On-demand assembly of microtubules forms crossings at desired angles for biophysical studies as well as complex networks that can be used as nanotransport systems.

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Section: Resultsmentioning

confidence: 99%

Pick‐and‐Place Assembly of Single Microtubules

Tarhan

Yokokawa

Jalabert

et al. 2017

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“…DNA trapping protocol DNA trapping is based on a combination of dielectrophoresis (DEP) 21 and lateral combing as explained elsewhere 22 . A drop (3 μl) of double-stranded λ-DNA (48.5 kbp, 16 μm in length) solution diluted in deionized water is introduced into the 'DNA cavity' on the side of the main cavity (Figure 3).…”

Section: The Silicon Nanotweezersmentioning

confidence: 99%

Real-time mechanical characterization of DNA degradation under therapeutic X-rays and its theoretical modeling

et al. 2016

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The killing of tumor cells by ionizing radiation beams in cancer radiotherapy is currently based on a rather empirical understanding of the basic mechanisms and effectiveness of DNA damage by radiation. By contrast, the mechanical behaviour of DNA encompassing sequence sensitivity and elastic transitions to plastic responses is much better understood. A novel approach is proposed here based on a micromechanical Silicon Nanotweezers device. This instrument allows the detailed biomechanical characterization of a DNA bundle exposed to an ionizing radiation beam delivered here by a therapeutic linear particle accelerator (LINAC). The micromechanical device endures the harsh environment of radiation beams and still retains molecular-level detection accuracy. In this study, the first real-time observation of DNA damage by ionizing radiation is demonstrated. The DNA bundle degradation is detected by the micromechanical device as a reduction of the bundle stiffness, and a theoretical model provides an interpretation of the results. These first real-time observations pave the way for both fundamental and clinical studies of DNA degradation mechanisms under ionizing radiation for improved tumor treatment.

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“…MEMS tweezers have been developed for the biomolecular characterization of cellular and subcellular samples with an object manipulation function. (8,9) The stiffness and viscoelastic properties of a trapped biosample can be extracted by resonance frequency measurement with high sensitivity (0.1 nm resolution in actuation with integrated value and 300 µN/m in stiffness measurements). The device is capable of high-throughput mechanical characterizing as well as transporting single-cells for subsequent detailed assays such as gene expression analyses.…”

Section: Introductionmentioning

confidence: 99%