https://galderisi-lab.webnode.it/https://galderisi-lab.webnode.it/who-are/https://galderisi-lab.webnode.it/progetti/https://galderisi-lab.webnode.it/progetti/progetti-residenziali/https://galderisi-lab.webnode.it/radiation/https://galderisi-lab.webnode.it/secretome/https://galderisi-lab.webnode.it/contatti/https://galderisi-lab.webnode.it/our-publications/https://galderisi-lab.webnode.it/rett-syndrome/https://galderisi-lab.webnode.it/nicola-alessio/https://galderisi-lab.webnode.it/rb-family/https://galderisi-lab.webnode.it/stem-cells/https://galderisi-lab.webnode.it/autism/https://galderisi-lab.webnode.it/deanira-patrone/https://galderisi-lab.webnode.it/domenico-aprile/https://galderisi-lab.webnode.it/umberto-galderisi/https://galderisi-lab.webnode.it/giovanni-di-bernardo/https://galderisi-lab.webnode.it/dario-siniscalco/https://galderisi-lab.webnode.it/afshin-samiminemati/https://galderisi-lab.webnode.it/other-collaborations/https://galderisi-lab.webnode.it/senolytic-drugs/https://galderisi-lab.webnode.it/booking/https://galderisi-lab.webnode.it/sura-hilal-ahmed-al-sammarraie/https://galderisi-lab.webnode.it/tiziana-squillaro/https://galderisi-lab.webnode.it/yesuf-ade-siraj/https://galderisi-lab.webnode.it/valeria-mazzone/https://galderisi-lab.webnode.it/mohd-/https://galderisi-lab.webnode.it/claudia-/https://galderisi-lab.webnode.it/maria-bernazeaud/https://galderisi-lab.webnode.it/l/stress-and-stem-cells/https://galderisi-lab.webnode.it/l/hybrid-complexes/https://galderisi-lab.webnode.it/l/circulation-factors/https://galderisi-lab.webnode.it/l/mesenchymal-stromal-cells-from-amniotic-fluid-are-less-prone-to-senescence-compared-to-those-obtained-from-bone-marrow-an-in-vitro-study/https://galderisi-lab.webnode.it/l/neural-stem-cells-from-a-mouse-model-of-rett-syndrome-are-prone-to-senescence-show-reduced-capacity-to-cope-with-genotoxic-stress-and-are-impaired-in-the-differentiation-process/https://galderisi-lab.webnode.it/l/misidentified-human-gene-functions-with-mouse-models-the-case-of-the-retinoblastoma-gene-family-in-senescence/https://galderisi-lab.webnode.it/l/impact-of-lysosomal-storage-disorders-on-biology-of-mesenchymal-stem-cells-evidences-from-in-vitro-silencing-of-glucocerebrosidase-gba-and-alpha-galactosidase-a-gla-enzymes/https://galderisi-lab.webnode.it/l/unbiased-analysis-of-senescence-associated-secretory-phenotype-sasp-to-identify-common-components-following-different-genotoxic-stresses/https://galderisi-lab.webnode.it/l/irradiation-of-mesenchymal-stromal-cells-with-low-and-high-doses-of-alpha-particles-induces-senescence-and-or-apoptosis/https://galderisi-lab.webnode.it/l/stem-cell-therapy-in-autism-recent-insights/https://galderisi-lab.webnode.it/l/cellular-therapy-for-autism-spectrum-disorder-a-step-forward-to-the-optimal-treatments/https://galderisi-lab.webnode.it/l/senescence-phenomena-and-metabolic-alteration-in-mesenchymal-stromal-cells-from-a-mouse-model-of-rett-syndrome/https://galderisi-lab.webnode.it/l/a-rapid-safe-and-quantitative-in-vitro-assay-for-measurement-of-uracil-dna-glycosylase-activity/https://galderisi-lab.webnode.it/l/the-senescence-associated-secretory-phenotype-sasp-from-mesenchymal-stromal-cells-impairs-growth-of-immortalized-prostate-cells-but-has-no-effect-on-metastatic-prostatic-cancer-cells/https://galderisi-lab.webnode.it/l/increase-of-circulating-igfbp-4-following-genotoxic-stress-and-its-implication-for-senescence/https://galderisi-lab.webnode.it/l/stem-cell-derived-exosomes-in-autism-spectrum-disorder/https://galderisi-lab.webnode.it/l/new-frontiers-in-stem-cell-research-and-translational-approaches/https://galderisi-lab.webnode.it/l/biomolecular-evaluation-of-piceatannols-effects-in-counteracting-the-senescence-of-mesenchymal-stromal-cells-a-new-candidate-for-senotherapeutics/https://galderisi-lab.webnode.it/l/timely-supplementation-of-hydrogels-containing-sulfated-or-unsulfated-chondroitin-and-hyaluronic-acid-affects-mesenchymal-stromal-cells-commitment-toward-chondrogenic-differentiation/https://galderisi-lab.webnode.it/l/stem-cell-derived-exosomes-in-autism-spectrum-disorder2/https://galderisi-lab.webnode.it/l/pea-oxa-ameliorates-allodynia-neuropsychiatric-and-adipose-tissue-remodeling-induced-by-social-isolation/https://galderisi-lab.webnode.it/l/optimization-of-peripheral-blood-mononuclear-cell-extraction-from-small-volume-of-blood-samples-potential-implications-for-children-related-diseases/https://galderisi-lab.webnode.it/l/muse-stem-cells-can-be-isolated-from-stromal-compartment-of-mouse-bone-marrow-adipose-tissue-and-ear-connective-tissue-a-comparative-study-of-their-in-vitro-properties/https://galderisi-lab.webnode.it/l/a-comparative-study-on-normal-and-obese-mice-indicates-that-the-secretome-of-mesenchymal-stromal-cells-is-influenced-by-tissue-environment-and-physiopathological-conditions/https://galderisi-lab.webnode.it/l/obesity-is-associated-with-senescence-of-mesenchymal-stromal-cells-derived-from-bone-marrow-subcutaneous-and-visceral-fat-of-young-mice/https://galderisi-lab.webnode.it/l/the-secretome-of-muse-cells-contains-factors-that-may-play-a-role-in-regulation-of-stemness-apoptosis-and-immunomodulation/https://galderisi-lab.webnode.it/l/mesenchymal-stromal-cells-having-inactivated-rb1-survive-following-low-irradiation-and-accumulate-damaged-dna-hints-for-side-effects-following-radiotherapy/https://galderisi-lab.webnode.it/l/myeloma-cells-can-corrupt-senescent-mesenchymal-stromal-cells-and-impair-their-anti-tumor-activity/https://galderisi-lab.webnode.it/l/low-dose-radiation-induced-senescence-of-human-mesenchymal-stromal-cells-and-impaired-the-autophagy-process/https://galderisi-lab.webnode.it/l/silencing-of-rb1-and-rb2-p130-during-adipogenesis-of-bone-marrow-stromal-cells-results-in-dysregulated-differentiation/https://galderisi-lab.webnode.it/l/vitamin-d-deficiency-induces-chronic-pain-and-microglial-phenotypic-changes-in-mice/https://galderisi-lab.webnode.it/l/different-stages-of-quiescence-senescence-and-cell-stress-identified-by-molecular-algorithm-based-on-the-expression-of-ki67-rps6-and-beta-galactosidase-activity/https://galderisi-lab.webnode.it/l/alterations-in-the-carnitine-cycle-in-a-mouse-model-of-rett-syndrome/https://galderisi-lab.webnode.it/l/changes-in-autophagy-proteasome-activity-and-metabolism-to-determine-a-specific-signature-for-acute-and-chronic-senescent-mesenchymal-stromal-cells/https://galderisi-lab.webnode.it/l/de-regulated-expression-of-the-brg1-chromatin-remodeling-factor-in-bone-marrow-mesenchymal-stromal-cells-induces-senescence-associated-with-the-silencing-of-nanog-and-changes-in-the-levels-of-chromatin-proteins/https://galderisi-lab.webnode.it/l/reduced-expression-of-mecp2-affects-cell-commitment-and-maintenance-in-neurons-by-triggering-senescence-new-perspective-for-rett-syndrome/https://galderisi-lab.webnode.it/l/why-do-muse-stem-cells-present-an-enduring-stress-capacity-hints-from-a-comparative-proteome-analysis/https://galderisi-lab.webnode.it/l/proteomic-and-biological-analysis-of-the-effects-of-metformin-senomorphics-on-the-mesenchymal-stromal-cells/https://galderisi-lab.webnode.it/l/long-non-coding-rnas-in-regulation-of-adipogenesis-and-adipose-tissue-function/https://galderisi-lab.webnode.it/l/clinical-trials-based-on-mesenchymal-stromal-cells-are-exponentially-increasing-where-are-we-in-recent-years/https://galderisi-lab.webnode.it/l/obesity-induced-by-high-fat-diet-is-associated-with-critical-changes-in-biological-and-molecular-functions-of-mesenchymal-stromal-cells-present-in-visceral-adipose-tissue/https://galderisi-lab.webnode.it/l/sera-of-overweight-people-promote-in-vitro-adipocyte-differentiation-of-bone-marrow-stromal-cells/https://galderisi-lab.webnode.it/l/preamplification-procedure-for-the-analysis-of-ancient-dna-samples/https://galderisi-lab.webnode.it/l/enzymatic-repair-of-selected-cross-linked-homoduplex-molecules-enhances-nuclear-gene-rescue-from-pompeii-and-herculaneum-remains/https://galderisi-lab.webnode.it/l/expression-of-stemness-genes-in-primary-breast-cancer-tissues-the-role-of-sox2-as-a-prognostic-marker-for-detection-of-early-recurrence/https://galderisi-lab.webnode.it/l/reduced-expression-of-mecp2-affects-cell-commitment-and-maintenance-in-neurons-by-triggering-senescence-new-perspective-for-rett-syndrome2/https://galderisi-lab.webnode.it/l/polyphenols-the-healthy-brand-of-olive-oil-insights-and-perspectives/https://galderisi-lab.webnode.it/l/osteosarcoma-in-a-cernet-perspective/https://galderisi-lab.webnode.it/l/circulating-micrornas-in-cancer-a-5-year-update-with-a-focus-on-breast-and-lung-cancers/https://galderisi-lab.webnode.it/l/meta-analysis-of-senescent-cell-secretomes-to-identify-common-and-specific-features-of-the-different-senescent-phenotypes-a-tool-for-developing-new-senotherapeutics/https://galderisi-lab.webnode.it/l/multipotent-pluripotent-stem-cell-populations-in-stromal-tissues-and-peripheral-blood-exploring-diversity-potential-and-therapeutic-applications/https://galderisi-lab.webnode.it/l/igfbp5-is-released-by-senescent-cells-and-is-internalized-by-healthy-cells-promoting-their-senescence-through-interaction-with-retinoic-receptors/https://galderisi-lab.webnode.it/l/senescence-induces-fundamental-changes-in-the-secretome-of-mesenchymal-stromal-cells-mscs-implications-for-the-therapeutic-use-of-mscs-and-their-derivates/https://galderisi-lab.webnode.it/l/https-www-frontiersin-org-journals-bioengineering-and-biotechnology-articles-10-3389-fbioe-2023-1148761-full/https://galderisi-lab.webnode.it/l/an-example-of-neuro-glial-commitment-and-differentiation-of-muse-stem-cells-obtained-from-patients-with-iqsec2-related-neural-disorder-a-possible-new-cell-based-disease-model/https://galderisi-lab.webnode.it/l/progression-of-irradiated-mesenchymal-stromal-cells-from-early-to-late-senescence-changes-in-sasp-composition-and-anti-tumour-properties/https://galderisi-lab.webnode.it/l/role-of-glycosphingolipid-ssea-3-and-fgf2-in-the-stemness-and-lineage-commitment-of-multilineage-differentiating-stress-enduring-muse-cells/https://galderisi-lab.webnode.it/l/germicidal-lamps-using-uv-c-radiation-may-pose-health-safety-issues-a-biomolecular-analysis-of-their-effects-on-apoptosis-and-senescence/https://galderisi-lab.webnode.it/l/igfbp7-is-a-key-component-of-the-senescence-associated-secretory-phenotype-sasp-that-induces-senescence-in-healthy-cells-by-modulating-the-insulin-igf-and-activin-a-pathways/https://galderisi-lab.webnode.it/l/methods-to-investigate-the-secretome-of-senescent-cells/