Your search keyword '"Micouin G"' showing total 3 results

1. Efficient cytosolic delivery of luminescent lanthanide bioprobes in live cells for two-photon microscopy.

Author

Malikidogo KP, Charnay T, Ndiaye D, Choi JH, Bridou L, Chartier B, Erbek S, Micouin G, Banyasz A, Maury O, Martel-Frachet V, Grichine A, and Sénèque O

Abstract

Lanthanide(iii) (Ln 3+ ) complexes have desirable photophysical properties for optical bioimaging. However, despite their advantages over organic dyes, their use for microscopy imaging is limited by the high-energy UV excitation they require and their poor ability to cross the cell membrane and reach the cytosol. Here we describe a novel family of lanthanide-based luminescent probes, termed dTAT[Ln·L], based on (i) a DOTA-like chelator with a picolinate moiety, (ii) a two-photon absorbing antenna to shift the excitation to the near infrared and (ii) a dimeric TAT cell-penetrating peptide for cytosolic delivery. Several Tb 3+ and Eu 3+ probes were prepared and characterized. Two-photon microscopy of live cells was attempted using a commercial microscope with the three probes showing the highest quantum yields (>0.15). A diffuse Ln 3+ emission was detected in most cells, which is characteristic of cytosolic delivery of the Ln 3+ complex. The cytotoxicity of these three probes was evaluated and the IC 50 ranged from 7 μM to >50 μM. The addition of a single positive or negative charge to the antenna of the most cytotoxic compound was sufficient to lower significantly or suppress its toxicity under the conditions used for two-photon microscopy. Therefore, the design reported here provides excellent lanthanide-based probes for two-photon microscopy of living cells., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2024

2. Domes and semi-capsules as model systems for infrared microspectroscopy of biological cells.

Author

Solheim JH, Brandsrud MA, Kong B, Banyasz A, Borondics F, Micouin G, Lossius S, Sulé-Suso J, Blümel R, and Kohler A

Subjects

Scattering, Radiation, Light, Microscopy, Algorithms, Models, Biological

Abstract

It is well known that infrared microscopy of micrometer sized samples suffers from strong scattering distortions, attributed to Mie scattering. The state-of-the-art preprocessing technique for modelling and removing Mie scattering features from infrared absorbance spectra of biological samples is built on a meta model for perfect spheres. However, non-spherical cell shapes are the norm rather than the exception, and it is therefore highly relevant to evaluate the validity of this preprocessing technique for deformed spherical systems. Addressing these cases, we investigate both numerically and experimentally the absorbance spectra of 3D-printed individual domes, rows of up to five domes, two domes with varying distance, and semi-capsules of varying lengths as model systems of deformed individual cells and small cell clusters. We find that coupling effects between individual domes are small, corroborating previous related literature results for spheres. Further, we point out and illustrate with examples that, while optical reciprocity guarantees the same extinction efficiency for top vs. bottom illumination, a scatterer's internal field may be vastly different in these two situations. Finally, we demonstrate that the ME-EMSC model for preprocessing infrared spectra from spherical biological systems is valid also for deformed spherical systems., (© 2023. The Author(s).)

Published

2023

3. Nanocarriers with ultrahigh chromophore loading for fluorescence bio-imaging and photodynamic therapy.

Author

Navarro JR, Lerouge F, Cepraga C, Micouin G, Favier A, Chateau D, Charreyre MT, Lanoë PH, Monnereau C, Chaput F, Marotte S, Leverrier Y, Marvel J, Kamada K, Andraud C, Baldeck PL, and Parola S

Subjects

Cell Line, Tumor, Humans, Molecular Structure, Fluorescence, Gold chemistry, Nanoparticles chemistry, Optical Imaging methods, Photochemotherapy methods

Abstract

We describe the design of original nanocarriers that allows for ultrahigh chromophore loading while maintaining the photo-activity of each individual molecule. They consist in shells of charged biocompatible polymers grafted on gold nanospheres. The self-organization of extended polymer chains results from repulsive charges and steric interactions that are optimized by tuning the surface curvature of nanoparticles. This type of nano-scaffolds can be used as light-activated theranostic agents for fluorescence imaging and photodynamic therapy. We demonstrate that, labeled with a fluorescent photosensitizer, it can localize therapeutic molecules before triggering the cell death of B16-F10 melanoma with an efficiency that is similar to the efficiency of the polymer conjugate alone, and with the advantage of extremely high local loading of photosensitizers (object concentration in the picomolar range)., (© 2013 Elsevier Ltd. All rights reserved.)

Published

2013