Nanoscale Analysis of Randall’s Plaques by Electron Energy Loss Spectromicroscopy: Insight in Early Biomineral Formation in Human Kidney. ACS Nano 14, 1823 - 1836 (2020).
Reconstruction of Partially Sampled Multiband Images—Application to STEM-EELS Imaging. IEEE Transactions on Computational Imaging 4, 585 - 598 (2018).
ABCC6 Deficiency Promotes Development of Randall Plaque. Journal of the American Society of Nephrology 292994370, 2337 - 2347 (2018).
Ligand-induced twisting of nanoplatelets and their self-assembly into chiral ribbons. Science Advances 3, e1701483 (2017).
Facile synthesis of carbon quantum dot/silver nanocomposite and its application for colorimetric detection of methimazole. Sensors and Actuators B: Chemical 244, 425 - 432 (2017).
Can Changes in Temperature or Ionic Conditions Modify the DNA Organization in the Full Bacteriophage Capsid?. The Journal of Physical Chemistry B 120, 5975 - 5986 (2016).
Constribution of transmission electron microscopy and electron energy-loss spectroscopy for characterizing the composition and the initial formation site of incipient Randall's plaque. EUROPEAN JOURNAL OF CLINICAL INVESTIGATION 46, 116 (2016).
Relationship between the genome packing in the bacteriophage capsid and the kinetics of DNA ejection. Biophysical Reviews and Letters 09, 81 - 104 (2014).
Phase diagrams of DNA and poly(styrene-sulfonate) condensed by a poly-cationic protein, the salmon protamine. Soft Matter 7, 8847 (2011).
Bacteriophage–host interactions leading to genome internalization. Current Opinion in Microbiology 14, 492 - 496 (2011).
Is the In Vitro Ejection of Bacteriophage DNA Quasistatic? A Bulk to Single Virus Study. Biophysical Journal 99, 447 - 455 (2010).
DNA Condensed by Protamine: A “Short” or “Long” Polycation Behavior. Biomacromolecules 10, 2129 - 2134 (2009).
Chemical mapping of the distribution of viruses into infected bacteria with a photothermal method. Ultramicroscopy 108, 635 - 641 (2008).
A Kinetic Analysis of DNA Ejection from Tailed Phages Revealing the Prerequisite Activation Energy. Biophysical Journal 93, 3999 - 4005 (2007).
Pressure Built by DNA Packing Inside Virions: Enough to Drive DNA Ejection in Vitro, Largely Insufficient for Delivery into the Bacterial Cytoplasm. Journal of Molecular Biology 374, 346 - 355 (2007).
Solubility and Charge Inversion of Complexes of DNA and Basic Proteins. Physical Review Letters 97, (2006).
Are liquid crystalline properties of nucleosomes involved in chromosome structure and dynamics?. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 364, 2615 - 2633 (2006).
DNA Ejection from Bacteriophage T5: Analysis of the Kinetics and Energetics. Biophysical Journal 88, 1364 - 1370 (2005).
Thermal and chemical nanofractal relaxation. The European Physical Journal D - Atomic, Molecular and Optical Physics 24, 265 - 268 (2003).
Channeling phage DNA through membranes: from in vivo to in vitro. Research in Microbiology 154, 283 - 287 (2003).
Control of island morphology by dynamic coalescence of soft-landed clusters. European Physical Journal D 16, 265–269 (2001).
Morphology control of the supported islands grown from soft-landed clusters. Surface Science 443, 76 - 88 (1999).
Size effects in nucleation and growth processes from preformed soft-landed clusters. Physical Review B 57, R2084–R2087 (1998).
Loss of metallicity in metal rich lithium oxide clusters. Zeitschrift f�r Physik D Atoms, Molecules and Clusters 42, 303 - 307 (1997).
Mobility and aggregation of free clusters soft landed on amorphous and crystalline carbon substrates. Zeitschrift Fur Physik D-Atoms Molecules And Clusters 40, 516–519 (1997).
Experimental Evidence for the Entropy Effect in Coulombic Cluster Fission. Physical Review Letters 77, 251 - 254 (1996).
Large Clusters of Atoms and MoleculesPhotofragmentation of Hot Clusters: Evaporation, Fission, Photofragmentation Spectroscopy. 315 - 353 (Dordrecht, 1996).doi:10.1007/978-94-009-0211-4_12
Coulombic fission and evaporation of antimony cluster ions. The Journal of Chemical Physics 102, 763 (1995).
Dissociation energies of tellurium cluster ions from thermoevaporation experiments. The Journal of Chemical Physics 103, 6631 (1995).
Stability of charged metal clusters. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 88, 91 - 96 (1994).
Dynamics and energy release in fission of small doubly charged clusters. Physical Review Letters 72, 1636 - 1639 (1994).
Shell effects in fission of small doubly charged lithium clusters. Physical Review B 49, 2825 - 2831 (1994).
Thermodynamical properties of ionized lithium oxide clusters, Li2n+pO+n. The Journal of Chemical Physics 99, 6848 (1993).
Temperature effects in the electronic shells and supershells of lithium clusters. Physical Review B 47, 2271 - 2277 (1993).
Optical excitation in small ionized sodium clusters: closed-shell and open-shell systems. Chemical Physics Letters 189, 28 - 34 (1992).
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