Research articles

Last update 2023-12-18



[1] Wasif Razzaq et al. “Simultaneous photo-induced polymerization and surface modification by microfluidic spinning to produce functionalized polymer microfibers: the effect of their surface modification on cell adhesion”. In: RSC Applied Polymers (2024).

[2] Anaıs Brion et al. “Photoactivatable Liposomes for Blue to Deep Red Light-Activated Surface Drug Release: Application to Controlled Delivery of the Antitumoral Drug Melphalan”. In: Bioconjugate Chemistry (2023).

[3] Anaıs Brion et al. “Red Light-Responsive Upconverting Nanoparticles for Quantitative and Controlled Release of a Coumarin-Based Prodrug”. In: Advanced Healthcare Materials 12.2 (2023), p. 2201474.

[4] Cheick Oumar Diarra et al. “Exciton diffusion in poly (3-hexylthiophene) by first-principles molecular dynamics”. In: Physical Chemistry Chemical Physics 25.22 (2023), pp. 15539–15546.

[5] Florent Fessler et al. “Entry of microparticles into giant lipid vesicles by optical tweezers”. In: Physical Review E 107.5 (2023), p. L052601.

[6] Carlotta Figliola et al. “Lysosomes targeting pH activable imaging-guided photodynamic agents”. In: ChemBioChem (2023), e202300139.

[7] Martin Hamann et al. “Directing the pore size of rigid polyurethane foam via controlled air entrainment”. In: Journal of Cellular Plastics (2023), p. 0021955X231152680.

[8] Martin Hamann et al. “Fluorocarbon-driven pore size reduction in polyurethane foams: an effect of improved bubble entrainment”. In: (2023).

[9] Martin Hamann et al. “Quantitative investigation of the pore size–reducing effect of perfluorocarbons in polyurethane foaming”. In: Colloid and Polymer Science (2023), pp. 1–11.

[10] Leila Hammoud et al. “The role of the gold–platinum interface in AuPt/TiO 2-catalyzed plasmon-induced reduction of CO 2 with water”. In: Faraday Discussions (2023).

[11] Amine Khitous et al. “Plasmon-Induced Photopolymerization of Molecularly Imprinted Polymers for Nanosensor Applications”. In: Advanced Materials Interfaces (2023), p. 2201651.

[12] Patricia Fernandez de Larrinoa et al. “Triphenylphosphonium-functionalized N-heterocyclic carbene platinum complexes [(NHC-TPP+) Pt] induce cell death of human glioblastoma cancer stem cells”. In: International Journal of Pharmaceutics 641 (2023), p. 123071.

[13] Duncan Schwaller et al. “Impact of polymorphism in oleogels of N-palmitoyll-phenylalanine”. In: Soft Matter 19.23 (2023), pp. 4277–4285.

[14] Julie Schweitzer et al. “Morphology of ultrathin gold and copper coatings thermally evaporated on polydimethylsiloxane elastomers: from isolated nanoparticles to continuous coatings”. In: Thin Solid Films (2023), p. 139972.

[15] Katja Steck et al. “Fluorocarbon vapors slow down coalescence in foams: influence of surfactant concentration”. In: Colloid and Polymer Science (2023), pp. 1–11.

[16] Timoth´ee Stoerkler et al. “Interplay between Dual-State and AggregationInduced Emission with ESIPT Scaffolds Containing Triphenylamine Substituents: Experimental and Theoretical Studies”. In: The Journal of Organic Chemistry (2023).

[17] Wenbing Wu et al. “Bottom-Up Tunable Broadband Semi-Reflective Chiral Mirrors”. In: Advanced Optical Materials (2023), p. 2202831.



[18] Imene Ben Djemaa et al. “One-Step Generation of Alginate-Based Hydrogel Foams Using CO2 for Simultaneous Foaming and Gelation”. In: Gels 8.7 (2022), p. 444.

[19] Ga¨el Ginot et al. “PEG-in-PDMS drops stabilised by soft silicone skins as a model system for elastocapillary emulsions with explicit morphology control”. In: Journal of Colloid and Interface Science 628 (2022), pp. 1044–1057.

[20] Manon Jouanlanne et al. “Elastocapillary deformation of thin elastic ribbons in 2D foam columns”. In: Soft Matter 18.12 (2022), pp. 2325–2331.

[21] Quentin Kirscher et al. “Deep-UV laser direct writing of photoluminescent ZnO submicron patterns: an example of nanoarchitectonics concept”. In: Science and Technology of Advanced Materials 23.1 (2022), pp. 535–546.

[22] Ching-Fu Lin et al. “NIR Laser Integration of Photodetector on 3D Printed Chamber for Colorimetric Biosensing”. In: Advanced Materials Technologies (2022), p. 2201026.

[23] Romaissaa Mokdad et al. “Anti-inflammatory effects of free and liposomeencapsulated Algerian thermal waters in RAW 264.7 macrophages”. In: International Journal of Pharmaceutics 614 (2022), p. 121452.

[24] Romaissaa Mokdad et al. “Formulation and rheological evaluation of liposomesloaded carbopol hydrogels based on thermal waters”. In: Drug Development and Industrial Pharmacy (2022), pp. 1–11.

[25] Wasif Razzaq, Christophe Serra, and Delphine Chan-Seng. “Production of Janus/Hecate microfibers by microfluidic photopolymerization and evaluation of their potential in dye removal”. In: Chemical Communications 58.29 (2022), pp. 4619–4622.

[26] Wasif Razzaq, Christophe A Serra, and Delphine Chan-Seng. “Microfluidic Janus fibers with dual thermoresponsive behavior for thermoactuation”. In: European Polymer Journal 174 (2022), p. 111321.

[27] R´emy Savin et al. “Nanohybrid biosensor based on mussel-inspired electrocross-linking of tannic acid capped gold nanoparticles and enzymes”. In: Materials Advances 3.4 (2022), pp. 2222–2233.

[28] R´emy Savin et al. “Optimization of Nanohybrid Biosensors Based on Electro-Crosslinked Tannic Acid Capped Nanoparticles/Enzyme”. In: Molecules 27.10 (2022), p. 3309.

[29] Vaibhav Sharma, Carlos M Marques, and Antonio Stocco. “Driven Engulfment of Janus Particles by Giant Vesicles in and out of Thermal Equilibrium”. In: Nanomaterials 12.9 (2022), p. 1434.

[30] Timoth´ee Stoerkler et al. “Heteroaryl-Substituted bis-Anils: AggregationInduced Emission (AIE) Derivatives with Tunable ESIPT Emission Color and pH Sensitivity”. In: Chemistry–A European Journal (2022).

[31] Timoth´ee Stoerkler et al. “Influence of ethynyl extension on the dualstate emission properties of pyridinium-substituted ESIPT fluorophores”. In: Dyes and Pigments 208 (2022), p. 110872.

[32] Timoth´ee Stoerkler et al. “Sterically Hindered 2-(2’-Hydroxyphenyl) benzoxazole (HBO) Emitters: Synthesis, Spectroscopic Studies, and Theoretical Calculations”. In: European Journal of Organic Chemistry 2022.30 (2022), e202200661.

[33] Madeline Vauthier and Christophe A Serra. “Controlled reversible aggregation of thermoresponsive polymeric nanoparticles by interfacial DielsAlder reaction”. In: Colloids and Surfaces A: Physicochemical and Engineering Aspects 648 (2022), p. 129321.



[34] Amine Khitous et al. “Plasmonic Au nanoparticle arrays for monitoring photopolymerization at the nanoscale”. In: ACS Applied Nano Materials 4.9 (2021), pp. 8770–8780.

[35] Agata Krywko-Cendrowska et al. “Ion-imprinted nanofilms based on tannic acid and silver nanoparticles for sensing of Al (III)”. In: ACS Applied Nano Materials 4.5 (2021), pp. 5372–5382.


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The visibility of the ITI program, and in particular its results in terms of research and training, must be reflected in a common policy of acknowledgement in publications and works.
To this end, please include the following acknowledgement in all scientific publications and books resulting from work carried out under the ITI, in the space provided by the publisher for this purpose:

 « Ce travail s’inscrit dans le cadre de l’Institut Thématique Interdisciplinaire des matériaux hiérarchique et fonctionnel, dans les domaines de la santé, de l’environnement, et de l’énergie, du programme ITI 2021-2028 de l’Université de Strasbourg, du CNRS et de l’Inserm. Il a bénéficié du soutien financier de l’IdEx Unistra (ANR-10-IDEX-0002), et du financement au titre du Programme d’Investissement d’Avenir dans le cadre du SFRI-STRATUS (ANR ANR-20-SFRI-0012) ».

« This work of the Interdisciplinary Thematic Institute HiFunMat, as part of the ITI 2021-2028 program of the University of Strasbourg, CNRS and Inserm, was supported by IdEx Unistra (ANR-10-IDEX-0002) and SFRI (STRAT’US project, ANR-20-SFRI-0012) under the framework of the French Investments for the Future Program. »

Faculté de physique & ingénierie
Faculté de chimie
Carnot MICA