0000000000563556

AUTHOR

Luis M. Escudero

showing 3 related works from this author

A Quantitative Biophysical Principle to Explain the 3D Cellular Connectivity in Curved Epithelia

2021

Epithelial cell organization and the mechanical stability of tissues are closely related. In this context, it has been recently shown that packing optimization in bended/folded epithelia is achieved by a surface tension energy minimization mechanism that leads to a novel cellular shape: the scutoid. However, further cellular and tissue level implications of this new developmental paradigm remain unknown. Here we focus on the relation of this complex cellular shape and the connectivity between cells. We address this problem using a combination of computational, experimental, and biophysical approaches in tubular epithelia. We dissect the contribution of the energetic drivers inducing the com…

Mechanical stabilityMechanism (biology)ChemistryBiophysicsTissue levelContext (language use)SSRN Electronic Journal
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Mechanics and self-organization in tissue development

2021

Self-organization is an all-important feature of living systems that provides the means to achieve specialization and functionality at distinct spatio-temporal scales. Herein, we review this concept by addressing the packing organization of cells, the sorting/compartmentalization phenomenon of cell populations, and the propagation of organizing cues at the tissue level through traveling waves. We elaborate on how different theoretical models and tools from Topology, Physics, and Dynamical Systems have improved the understanding of self-organization by shedding light on the role played by mechanics as a driver of morphogenesis. Altogether, by providing a historical perspective, we show how i…

Self-organizationPhysicsSelf-organizationTraveling wavesDynamical systems theoryCell packingSortingCompartmentalization (information security)Cell BiologyMechanicsDevelopmental mechanismsLiving systemsCell sortingERKPhenomenonDevelopmental mechanicsSpecialization (functional)MorphogenesisHumansEpitheliaTopology (chemistry)Developmental BiologySignal Transduction
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The topology of vitronectin: A complementary feature for neuroblastoma risk classification based on computer‐aided detection

2019

Tumors are complex networks of constantly interacting elements: tumor cells, stromal cells, immune and stem cells, blood/lympathic vessels, nerve fibers and extracellular matrix components. These elements can influence their microenvironment through mechanical and physical signals to promote tumor cell growth. To get a better understanding of tumor biology, cooperation between multidisciplinary fields is needed. Diverse mathematic computations and algorithms have been designed to find prognostic targets and enhance diagnostic assessment. In this work, we use computational digital tools to study the topology of vitronectin, a glycoprotein of the extracellular matrix. Vitronectin is linked to…

RiskCancer ResearchStromal celltopologyTumor Markers and SignaturesComputer scienceAngiogenesisTopologyTopologyvitronectinExtracellular matrixComputational biology03 medical and health sciencesNeuroblastoma0302 clinical medicinecomputational biologyNeuroblastNeuroblastomamedicineTumor MicroenvironmentHumansVitronectinCell ProliferationbiologyNeovascularization PathologicComplex networkmedicine.diseasePrognosisExtracellular MatrixOncology030220 oncology & carcinogenesisnetworksbiology.proteinVitronectinStem cellNetworksStromal CellsAlgorithmsInternational Journal of Cancer
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