Chemical methods for the modification of RNA M Flamme, LK McKenzie, I Sarac, M Hollenstein Methods 161, 64-82, 2019 | 71 | 2019 |
Induction of Necroptosis in Cancer Stem Cells using a Nickel (II)‐Dithiocarbamate Phenanthroline Complex M Flamme, PB Cressey, C Lu, PM Bruno, A Eskandari, MT Hemann, ... Chemistry–A European Journal 23 (40), 9674-9682, 2017 | 43 | 2017 |
Enzymatic formation of an artificial base pair using a modified purine nucleoside triphosphate M Flamme, P Röthlisberger, F Levi-Acobas, M Chawla, R Oliva, ... ACS Chemical Biology 15 (11), 2872-2884, 2020 | 24 | 2020 |
Applications of Ruthenium Complexes Covalently Linked to Nucleic Acid Derivatives M Flamme, E Clarke, G Gasser, M Hollenstein Molecules 23 (7), 1515, 2018 | 20 | 2018 |
Evaluation of 3′-phosphate as a transient protecting group for controlled enzymatic synthesis of DNA and XNA oligonucleotides M Flamme, S Hanlon, I Marzuoli, K Püntener, F Sladojevich, ... Communications Chemistry 5 (1), 68, 2022 | 15 | 2022 |
Enzymatic construction of metal-mediated nucleic acid base pairs M Flamme, C Figazzolo, G Gasser, M Hollenstein Metallomics 13 (4), mfab016, 2021 | 15 | 2021 |
A ruthenium–oligonucleotide bioconjugated photosensitizing aptamer for cancer cell specific photodynamic therapy LK McKenzie, M Flamme, PS Felder, J Karges, F Bonhomme, A Gandioso, ... RSC Chemical Biology 3 (1), 85-95, 2022 | 14 | 2022 |
Towards the enzymatic synthesis of phosphorothioate containing LNA oligonucleotides M Flamme, S Hanlon, H Iding, K Puentener, F Sladojevich, M Hollenstein Bioorganic & Medicinal Chemistry Letters 48, 128242, 2021 | 14 | 2021 |
The Bulk Osteosarcoma and Osteosarcoma Stem Cell Activity of a Necroptosis‐Inducing Nickel (II)–Phenanthroline Complex A Eskandari, M Flamme, Z Xiao, K Suntharalingam ChemBioChem 21 (19), 2854-2860, 2020 | 13 | 2020 |
Towards the controlled enzymatic synthesis of LNA containing oligonucleotides N Sabat, D Katkevica, K Pajuste, M Flamme, A Stämpfli, M Katkevics, ... Frontiers in Chemistry 11, 1161462, 2023 | 8 | 2023 |
Benzoyl and pivaloyl as efficient protecting groups for controlled enzymatic synthesis of DNA and XNA oligonucleotides M Flamme, D Katkevica, K Pajuste, M Katkevics, N Sabat, S Hanlon, ... Asian Journal of Organic Chemistry 11 (10), e202200384, 2022 | 8 | 2022 |
Enzymatic construction of artificial base pairs: the effect of metal shielding M Flamme, F Levi‐Acobas, S Hensel, S Naskar, P Röthlisberger, I Sarac, ... ChemBioChem 21 (23), 3398-3409, 2020 | 8 | 2020 |
Effect of metal shielding on the enzymatic construction of artificial base pairs M Flamme, F Levi-Acobas, S Hensel, S Naskar, P Röthlisberger, I Sarac, ... ChemBioChem 21 (10.1002), 2020 | 3 | 2020 |
Enzymatic formation of an artificial base pair using a modified adenine nucleoside triphosphate M Flamme, P Röthlisberger, F Levi-Acobas, M Chawla, R Oliva, L Cavallo, ... | 3 | 2019 |
Artificial nucleotide codons for enzymatic DNA synthesis N Sabat, A Stämpfli, M Flamme, S Hanlon, S Bisagni, F Sladojevich, ... Chemical Communications 59 (98), 14547-14550, 2023 | 2 | 2023 |
Modified nucleoside triphosphates in aptamer selections. M Hollenstein, JA Tanner, F Levi-Acobas, P Rothlisberger, M Flamme XVIIIth Symposium on Chemistry of Nucleic Acid Components (SCNAC2020), 2022 | | 2022 |
Développement d'aptamères munis de photosensibilisateurs comme agents sélectifs pour la chimie photodynamique contre le cancer M Flamme Université Paris Cité, 2020 | | 2020 |