Nicolas Lafitte scite author profile

Nicolas Lafitte

3Publications

54Citation Statements Received

78Citation Statements Given

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Affiliations

Fluigent (France), Laboratory for Integrated Micro-Mechatronic Systems, The University of Tokyo

Publications

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

Tarhan

Lafitte

Tauran

et al. 2016

Sci Rep

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Monitoring biological reactions using the mechanical response of macromolecules is an alternative approach to immunoassays for providing real-time information about the underlying molecular mechanisms. Although force spectroscopy techniques, e.g. AFM and optical tweezers, perform precise molecular measurements at the single molecule level, sophisticated operation prevent their intensive use for systematic biosensing. Exploiting the biomechanical assay concept, we used micro-electro mechanical systems (MEMS) to develop a rapid platform for monitoring bio/chemical interactions of bio macromolecules, e.g. DNA, using their mechanical properties. The MEMS device provided real-time monitoring of reaction dynamics without any surface or molecular modifications. A microfluidic device with a side opening was fabricated for the optimal performance of the MEMS device to operate at the air-liquid interface for performing bioassays in liquid while actuating/sensing in air. The minimal immersion of the MEMS device in the channel provided long-term measurement stability (>10 h). Importantly, the method allowed monitoring effects of multiple solutions on the same macromolecule bundle (demonstrated with DNA bundles) without compromising the reproducibility. We monitored two different types of effects on the mechanical responses of DNA bundles (stiffness and viscous losses) exposed to pH changes (2.1 to 4.8) and different Ag+ concentrations (1 μM to 0.1 M).

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Improvement of Silicon Nanotweezers Sensitivity for Mechanical Characterization of Biomolecules Using Closed-Loop Control

Lafitte

Haddab

Gorrec

et al. 2015

IEEE/ASME Trans. Mechatron.

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In this paper, we show that closed-loop control can be 6 advantageously used for the characterization of mechanical prop-7 erties of biomolecules using silicon nanotweezers (SNT). SNT have 8 already been used in open-loop mode for the characterization of 9 mechanical properties of DNA molecules. Up to now, such an ap-10 proach allows the detection of stiffness variations equivalent to 11 about 15 DNA molecules. Here, it is shown that this resolution 12 is inversely proportional to the resonance frequency of the whole 13 system and that real-time feedback control with state observer 14 can drastically improve the performances of the tweezers used as 15 biosensors. Such improvement is experimentally validated in the 16 case of the manipulation of fibronectin molecules. The results are 17 promising for the accurate characterization of biopolymers such 18 as DNA molecules.

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Nicolas Lafitte

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

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

Improvement of Silicon Nanotweezers Sensitivity for Mechanical Characterization of Biomolecules Using Closed-Loop Control

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