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Beilstein J. Nanotechnol. 2015, 6, 1164–1175, doi:10.3762/bjnano.6.118
Figure 1: The lateral force calibration concept. (A) An illustration of the calibration approach. (B,C) Image...
Figure 2: Topography image of FN deposited on a mica surface recorded while scanning in contact mode AFM with...
Figure 3: (A) Friction loop determined for a load of 2 nN. The difference, D, between the lateral signal reco...
Figure 4: Unbinding of a FN-Mab complex studied using AFM-FS. (A) For each force curve recorded at a given lo...
Figure 5: Unbinding of a FN-Mab complex measured by LFM. (A) An exemplary, single LFM signal showing peaks th...
Figure 6: Unbinding force–loading rate dependence obtained for FN-Mab complexes using AFM-FS and LFM. (A) A l...
Beilstein J. Nanotechnol. 2014, 5, 447–457, doi:10.3762/bjnano.5.52
Figure 1: (A) Scheme of experimental setup. (1) V-shaped cantilever-tip ensemble; (2) cell membrane; (3) cell...
Figure 2: Force and fluorescence microscopy images of bladder cells. (A–D) Non-malignant cells, HCV29; (E–H),...
Figure 3: Total expression of actin in human bladder cells. The used antibody targets all known actin isoform...
Figure 4: (A) Exemplary force curve recorded on a HT-1376 cell (blue dots). The red solid line represents a c...
Figure 5: Distribution of Young’s moduli determined by fitting the curves within the indentation range up to ...
Figure 6: (A) Elasticity of living bladder cells as a function of the indentation depth. The data is presente...