about
Emerging of fractal geometry on surface of human cervical epithelial cells during progression towards cancer.High-resolution high-speed dynamic mechanical spectroscopy of cells and other soft materials with the help of atomic force microscopy.Atomic force microscopy detects differences in the surface brush of normal and cancerous cells.Physical labeling of papillomavirus-infected, immortal, and cancerous cervical epithelial cells reveal surface changes at immortal stageVisualization of cytoskeletal elements by the atomic force microscope.Nanosurgery: observation of peptidoglycan strands in Lactobacillus helveticus cell walls.Attachment of nanoparticles to the AFM tips for direct measurements of interaction between a single nanoparticle and surfaces.Atomic force microscopy study of nano-physiological response of ladybird beetles to photostimuli.Towards early detection of cervical cancer: Fractal dimension of AFM images of human cervical epithelial cells at different stages of progression to cancer.If cell mechanics can be described by elastic modulus: study of different models and probes used in indentation experiments.Change in rigidity in the activated form of the glucose/galactose receptor from Escherichia coli: a phenomenon that will be key to the development of biosensors.Towards nonspecific detection of malignant cervical cells with fluorescent silica beads.Recovery of aging-related size increase of skin epithelial cells: in vivo mouse and in vitro human studyPericellular Brush and Mechanics of Guinea Pig Fibroblast Cells Studied with AFM.Ultrabright fluorescent mesoporous silica nanoparticles for prescreening of cervical cancerAFM study shows prominent physical changes in elasticity and pericellular layer in human acute leukemic cells due to inadequate cell-cell communication.Ultrabright fluorescent mesoporous silica nanoparticles.A study of molecular adsorption of a cationic surfactant on complex surfaces with atomic force microscopy.Nanoscale compositional mapping of cells, tissues, and polymers with ringing mode of atomic force microscopy.High sensitivity molecular detection with enzyme-linked immuno-sorbent assay (ELISA)-type immunosensing.Biophysical differences between chronic myelogenous leukemic quiescent and proliferating stem/progenitor cells.A novel in vitro stripping method to study geometry of corneocytes with fluorescent microscopy: example of aging skin.Quantitative mapping of the elastic modulus of soft materials with HarmoniX and PeakForce QNM AFM modes.Towards nano-physiology of insects with atomic force microscopy.Logic networks based on immunorecognition processes.Atomic force microscopy study of immunosensor surface to scale down the size of ELISA-type sensors.Novel fluorescent silica nanoparticles: towards ultrabright silica nanoparticles.Ultrabright fluorescent silica particles with a large number of complex spectra excited with a single wavelength for multiplex applications.Fractal Analysis of Cancer Cell Surface.Control and formation mechanism of extended nanochannel geometry in colloidal mesoporous silica particles.Fractals: a possible new path to diagnose and cure cancer?Load Rate and Temperature Dependent Mechanical Properties of the Cortical Neuron and Its Pericellular Layer Measured by Atomic Force Microscopy.Cell surface as a fractal: normal and cancerous cervical cells demonstrate different fractal behavior of surface adhesion maps at the nanoscale.Self-assembly of multi-hierarchically structured spongy mesoporous silica particles and mechanism of their formation.Dynamics of molecular diffusion of rhodamine 6G in silica nanochannelsData on ultrabright fluorescent cellulose acetate nanoparticles for imaging tumors through systemic and topical applicationsA comparison of methods to assess cell mechanical propertiesNoninvasive diagnostic imaging using machine-learning analysis of nanoresolution images of cell surfaces: Detection of bladder cancerCell surface electrochemical heterogeneity of the Fe(III)-reducing bacteria Shewanella putrefaciensHypothetical long-range interactions and restrictions on their parameters from force measurements
P50
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P50
description
Russian physicist
@en
Venemaa füüsik
@et
fizician rus
@ro
fizikan rus
@sq
físic rus
@ca
físico ruso
@es
físico ruso
@gl
natuurkundige
@nl
physicien russe
@fr
פיזיקאי רוסי
@he
name
Igor Sokolov
@ast
Igor Sokolov
@en
Igor Sokolov
@es
Igor Sokolov
@nl
Igor Sokolov
@sl
Игор Соколов
@ru
type
label
Igor Sokolov
@ast
Igor Sokolov
@en
Igor Sokolov
@es
Igor Sokolov
@nl
Igor Sokolov
@sl
Игор Соколов
@ru
altLabel
Igor Sokholov
@en
Igor Y. Sokolov
@en
Igor Yu. Sokolov
@en
prefLabel
Igor Sokolov
@ast
Igor Sokolov
@en
Igor Sokolov
@es
Igor Sokolov
@nl
Igor Sokolov
@sl
Игор Соколов
@ru
P108
P1053
A-6858-2009
P106
P21
P31
P3829
P496
0000-0001-6260-4326