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Mavali-Zadeh A, Gatto E, Lettieri R, Bokharaie B, Caravella A, D'Ottavi C, et al.. Biomass-derived Lignin Nanoparticles for the Sustained Delivery of Vascular Endothelial Growth Factor-C. Molecular Pharmaceutics [Internet]. Submitted;. https://doi.org/10.1101/2025.04.23.649697

Preprint (8.34 MB)

2025

Iqbal S, Andersson S, Nesta E, Pentinmikko N, Kumar A, Jha SK, et al.. Fetal-like reversion in the regenerating intestine is regulated by mesenchymal asporin. Cell Stem Cell [Internet]. 2025;32(4):613 - 626.e8. https://www.sciencedirect.com/science/article/pii/S1934590925000487

Iqbal S, Andersson S, Nesta E, Pentinmikko N, Kumar A, Jha SK, et al.. Fetal-like reversion in the regenerating intestine is regulated by mesenchymal asporin. Cell Stem Cell [Internet]. 2025;32(4):613 - 626.e8. https://www.sciencedirect.com/science/article/pii/S1934590925000487

Iqbal S, Andersson S, Nesta E, Pentinmikko N, Kumar A, Jha SK, et al.. Fetal-like reversion in the regenerating intestine is regulated by mesenchymal asporin. Cell Stem Cell [Internet]. 2025;32(4):613 - 626.e8. https://www.sciencedirect.com/science/article/pii/S1934590925000487

Iqbal S, Andersson S, Nesta E, Pentinmikko N, Kumar A, Jha SK, et al.. Fetal-like reversion in the regenerating intestine is regulated by mesenchymal asporin. Cell Stem Cell [Internet]. 2025;32(4):613 - 626.e8. https://www.sciencedirect.com/science/article/pii/S1934590925000487

Reunanen S, Ghemtio L, Patel JZ, Patel DR, Airavaara K, Yli-Kauhaluoma J, et al.. Targeting Bacterial and Human Levodopa Decarboxylases for Improved Drug Treatment of Parkinson's Disease: Discovery and Characterization of New Inhibitors. European Journal of Pharmaceutical Sciences [Internet]. 2025;:107133. https://authors.elsevier.com/sd/article/S0928-0987(25)00132-0

Reunanen et al. 2025 - Targeting Bacterial and Human Levodopa Decarboxylases for Improved Drug Treatment of Parkinson’s Disease (1.18 MB)

2024

Niemelä A, Giorgi L, Nouri S, Yurttaş B, Rauniyar K, Jeltsch M, et al.. Gliflozins, sucrose and flavonoids are allosteric activators of lecithin-cholesterol acyltransferase. Scientific Reports [Internet]. 2024;14(1):26085. https://www.nature.com/articles/s41598-024-77104-3

Panara V, Varaliová Z, Wilting J, Koltowska K, Jeltsch M. The relationship between the secondary vascular system and the lymphatic vascular system in fish. Biological Reviews [Internet]. 2024;. https://onlinelibrary.wiley.com/doi/10.1111/brv.13114

Panara et al. - 2024 - The relationship between the secondary vascular system and the lymphatics vascular system in fish (3.51 MB)

López-Cerdá S, Molinaro G, ParejaTello R, Correia A, Künig S, Steinberger P, et al.. Study of the Synergistic Immunomodulatory and Antifibrotic Effects of Dual-Loaded Budesonide and Serpine1 siRNA Lipid–Polymer Nanoparticles Targeting Macrophage Dysregulation in Tendinopathy. ACS Applied Materials & Interfaces [Internet]. 2024;16(15):18643 - 18657. https://pubs.acs.org/doi/10.1021/acsami.4c02363

López-Cerdá et al. - 2024 - Study of the Synergistic Immunomodulatory and Antifibrotic Effects of Dual-Loaded Budesonide [...] (7.06 MB)

2023

Rauniyar K, Bokharaie H, Jeltsch M. Expansion and collapse of VEGF diversity in major clades of the animal kingdom. Angiogenesis [Internet]. 2023;26(3):437 - 461. https://link.springer.com/10.1007/s10456-023-09874-9

Rauniyar et al. - 2023 - Expansion and collapse of VEGF diversity in major clades of the animal kingdom (3.59 MB)

2022

Rauniyar K, Akhondzadeh S, Gąciarz A, Künnapuu J, Jeltsch M. Bioactive VEGF-C from E. coli. Scientific Reports [Internet]. 2022;12(1). https://www.nature.com/articles/s41598-022-22960-0

Rauniyar et al. - 2022 - Bioactive VEGF-C from E. coli (4.19 MB)

Jeltsch M, Alitalo K. Lymphatic-to-blood vessel transdifferentiation in zebrafish. Nature Cardiovascular Research [Internet]. 2022;1(6):539 - 541. https://rdcu.be/cOjJ0

2021

Jeltsch M. Drug-induced lymphangiogenesis. In 3. Schweizer Lymphsymposium [Internet]. Juzo; 2021. https://doi.org/10.5281/zenodo.6034307

Jeltsch - 2021 - Drug-induced lymphangiogenesis (1.9 MB)

Koistinen H, Künnapuu J, Jeltsch M. KLK3 in the Regulation of Angiogenesis—Tumorigenic or Not?. International Journal of Molecular Sciences [Internet]. 2021;22(24):13545. https://www.mdpi.com/1422-0067/22/24/13545

Koistinen et al. - 2021 - KLK3 in the Regulation of Angiogenesis—Tumorigenic or Not? (1.28 MB)

Künnapuu J, Jeltsch M. Outside in and brakes off for lymphatic growth. Science Signaling [Internet]. 2021;14(695). https://www.science.org/doi/10.1126/scisignal.abj5058

Künnapuu and Jeltsch - 2021 - Outside in and brakes off for lymphatic growth (268.05 KB)

Künnapuu J, Bokharaie H, Jeltsch M. Proteolytic Cleavages in the VEGF Family: Generating Diversity among Angiogenic VEGFs, Essential for the Activation of Lymphangiogenic VEGFs. Biology [Internet]. 2021;10(2):167. https://www.mdpi.com/2079-7737/10/2/167

Künnapuu et al. - 2021 - Proteolytic Cleavages in the VEGF Family: Generating Diversity among Angiogenic VEGFs, Essential [...] (3.44 MB)

2020

Mukenge S, Jha SK, Catena M, Manara E, Leppänen V‐M, Lenti E, et al.. Investigation on the role of biallelic variants in VEGF‐C found in a patient affected by Milroy‐like lymphedema. Molecular Genetics & Genomic Medicine [Internet]. 2020;00:e1389. https://onlinelibrary.wiley.com/doi/abs/10.1002/mgg3.1389

Mukenge et al. 2020 (1.06 MB)

Mukenge S, Jha SK, Catena M, Manara E, Leppänen V‐M, Lenti E, et al.. Investigation on the role of biallelic variants in VEGF‐C found in a patient affected by Milroy‐like lymphedema. Molecular Genetics & Genomic Medicine [Internet]. 2020;00:e1389. https://onlinelibrary.wiley.com/doi/abs/10.1002/mgg3.1389

Mukenge et al. 2020 (1.06 MB)

Gucciardo E, Lehti TA, Korhonen A, Salvén P, Lehti K, Jeltsch M, et al.. Lymphatics and the eye. [Finnish]. Duodecim Lääketieteellinen Aikakauskirja [Internet]. 2020;136(16):1777-1788. https://www.duodecimlehti.fi/lehti/2020/16/duo15739

Gucciardo et al. Lymphatics and the Eye (English version). (3.31 MB)

Jha SK. Mechanism of VEGF-C Activation and Effect on Lymphatic Vessel Growth and Regeneration [Internet]. [Helsinki, Finland]: University of Helsinki; 2020. https://helda.helsinki.fi/handle/10138/314714

Jha - 2020 - Mechanism of VEGF-C Activation and Effect on Lymphatic Vessel Growth and Regeneration (1.96 MB)

Fang S, Chen S, Nurmi H, Leppänen V-M, Jeltsch M, Scadden DT, et al.. VEGF-C Protects the Integrity of Bone Marrow Perivascular Niche. Blood [Internet]. 2020;:accepted - for publication. https://ashpublications.org/blood/article/doi/10.1182/blood.2020005699/463465/VEGF-C-Protects-the-Integrity-of-Bone-Marrow

Fang et al. 2020 - VEGF-C protects the integrity of bone marrow perivascular niche (6 MB)

2019

Jha SK, Rauniyar K, Chronowska E, Mattonet K, Maina EW, Koistinen H, et al.. KLK3/PSA and cathepsin D activate VEGF-C and VEGF-D. eLife [Internet]. 2019;8:e44478. https://elifesciences.org/articles/44478

Jha & Rauniyar et al. 2019 (3.84 MB)

Jha SK, Rauniyar K, Chronowska E, Mattonet K, Maina EW, Koistinen H, et al.. KLK3/PSA and cathepsin D activate VEGF-C and VEGF-D. eLife [Internet]. 2019;8:e44478. https://elifesciences.org/articles/44478

Jha & Rauniyar et al. 2019 (3.84 MB)

Lackner M, Schmotz C, Jeltsch M. The Proteolytic Activation of Vascular Endothelial Growth Factor-C. Lymphologie in Forschung und Praxis [Internet]. 2019;23(2):88 - 98. https://doi.org/10.5281/zenodo.3629263

English version: Lackner et al. 2019 (2.94 MB)

German version: Lackner et al. 2019 (673.37 KB)

2018

Rauniyar K, Jha SK, Jeltsch M. Biology of Vascular Endothelial Growth Factor C in the Morphogenesis of Lymphatic Vessels. Frontiers in Biotechnology and Bioengineering [Internet]. 2018;6. https://www.frontiersin.org/articles/10.3389/fbioe.2018.00007/full

Rauniyar et al. - Biology of Vascular Endothelial Growth Factor C in the Morphogenesis of Lymphatic Vessels (4.42 MB)

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