[1] Cabriel， Clément， et al. "Combining 3D single molecule localization strategies for reproducible bioimaging." Nature communications 10.1 (2019): 1980.

[2] Woodhams， Stephen G.， et al. "Cell type–specific super-resolution imaging reveals an increase in calcium-permeable AMPA receptors at spinal peptidergic terminals as an anatomical correlate of inflammatory pain." Pain 160.11 (2019): 2641-2650.

[3] Belkahla， Hanen， et al. "Carbon dots， a powerful non-toxic support for bioimaging by fluorescence nanoscopy and eradication of bacteria by photothermia." Nanoscale Advances (2019).

[4] Denis， Kevin， et al. "Targeting Type IV pili as an antivirulence strategy against invasive meningococcal disease." Nature microbiology 4.6 (2019): 972.

[5] Szabo， Quentin， et al. "TADs are 3D structural units of higher-order chromosome organization in Drosophila." Science advances 4.2 (2018): eaar8082.

[6] Boudjemaa， Rym， et al. "Impact of bacterial membrane fatty acid composition on the failure of daptomycin to kill Staphylococcus aureus." Antimicrobial agents and chemotherapy 62.7 (2018): e00023-18.

[7] Culley， Sian， et al. "Quantitative mapping and minimization of super-resolution optical imaging artifacts." Nature methods 15.4 (2018): 263.

[8] Berger， Stephen L.， et al. "Localized myosin II activity regulates assembly and plasticity of the axon initial segment." Neuron 97.3 (2018): 555-570.

[9] Cabriel， Clément， et al. "Aberration-accounting calibration for 3D single-molecule localization microscopy." Optics letters 43.2 (2018): 174-177.

[10] Bouissou， Ana?s， et al. "Podosome force generation machinery: a local balance between protrusion at the core and traction at the ring." ACS nano 11.4 (2017): 4028-4040.

[11] Sellés， Julien， et al. "Nuclear pore complex plasticity during developmental process as revealed by super-resolution microscopy." Scientific reports 7.1 (2017): 14732.

[12] Bourg， Nicolas， et al. "Direct optical nanoscopy with axially localized detection." Nature Photonics 9.9 (2015): 587.