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3D topographies promote macrophage M2d-Subset differentiation

Stefania Carrara, Amanda Dávila-Lezama, Clément Cabriel, Erwin Berenschot, Silke Krol, Han Gardeniers, Ignacio Izeddin, Harald Kolmar, Arturo Susarrey‐Arce

2023Materials Today Bio16 citationsDOIOpen Access PDF

Abstract

In vitro cellular models denote a crucial part of drug discovery programs as they aid in identifying successful drug candidates based on their initial efficacy and potency. While tremendous headway has been achieved in improving 2D and 3D culture techniques, there is still a need for physiologically relevant systems that can mimic or alter cellular responses without the addition of external biochemical stimuli. A way forward to alter cellular responses is using physical cues, like 3D topographical inorganic substrates, to differentiate macrophage-like cells. Herein, protein secretion and gene expression markers for various macrophage subsets cultivated on a 3D topographical substrate are investigated. The results show that macrophages differentiate into anti-inflammatory M2-type macrophages, secreting increased IL-10 levels compared to the controls. Remarkably, these macrophage cells are differentiated into the M2d subset, making up the main component of tumour-associated macrophages (TAMs), as measured by upregulated Il-10 and Vegf mRNA. M2d subset differentiation is attributed to the topographical substrates with 3D fractal-like geometries arrayed over the surface, else primarily achieved by tumour-associated factors in vivo. From a broad perspective, this work paves the way for implementing 3D topographical inorganic surfaces for drug discovery programs, harnessing the advantages of in vitro assays without external stimulation and allowing the rapid characterisation of therapeutic modalities in physiologically relevant environments.

Topics & Concepts

MacrophageIn vitroCell biologyIn vivoDrug discoverySecretionBiologyDownregulation and upregulationCellular differentiationComputational biologyImmunologyBioinformaticsGeneGeneticsBiochemistry3D Printing in Biomedical ResearchCellular Mechanics and InteractionsNanoplatforms for cancer theranostics
3D topographies promote macrophage M2d-Subset differentiation | Litcius