6533b7d1fe1ef96bd125bafd
RESEARCH PRODUCT
A 3D‑scaffold of PLLA induces the morphological differentiation and migration of primary astrocytes and promotes the production of extracellular vesicles
Valerio BrucatoGabriella SchieraIlenia VitranoFrancesco Carfì PaviaCarlo Maria Di LiegroValeria BlandaItalia Di LiegroGiulio GhersiMaria Antonietta Di BellaFrancesca Zummosubject
3D culture0301 basic medicineCancer ResearchScaffoldCell SurvivalPolyestersneural tissue engineeringBiochemistryNeural tissue engineeringExtracellular matrixExtracellular Vesicles03 medical and health sciences0302 clinical medicineSettore BIO/13 - Biologia ApplicataCell MovementSettore BIO/10 - BiochimicaGeneticsExtracellularAnimalsSettore BIO/06 - Anatomia Comparata E CitologiaRats WistarCell ShapeMolecular BiologyCells CulturedNeural tissue engineering astrocytes 3D cultures poly‑L‑ lactic acid scaffold extracellular vesicles.Cell ProliferationSettore ING-IND/24 - Principi Di Ingegneria Chimica3D culturesTissue ScaffoldsbiologyChemistryastrocytesCell DifferentiationArticlesMicrovesiclesFibronectin030104 developmental biologyAnimals NewbornOncology030220 oncology & carcinogenesisReticular connective tissuepoly-L-lactic acid scaffoldbiology.proteinBiophysicsMolecular MedicineExtracellular vesicleAstrocyteIntracellulardescription
The present study analyzed the ability of primary rat astrocytes to colonize a porous scaffold, mimicking the reticular structure of the brain parenchyma extracellular matrix, as well as their ability to grow, survive and differentiate on the scaffold. Scaffolds were prepared using poly-L-lactic acid (PLLA) via thermally-induced phase separation. Firstly, the present study studied the effects of scaffold morphology on the growth of astrocytes, evaluating their capability to colonize. Specifically, two different morphologies were tested, which were obtained by changing the polymer concentration in the starting solution. The structures were characterized by scanning electron microscopy, and a pore size of 20 µm (defined as the average distance between the pore walls) was detected. For comparison, astrocytes were also cultured in the traditional 2D culture system that we have been using since 2003. Then the effects of different substrates, such as collagen I and IV, and fibronectin were analyzed. The results revealed that the PLLA scaffolds, coated with collagen IV, served as very good matrices for astrocytes, which were observed to adhere, grow and colonize the matrix, acquiring their typical morphology. In addition, under these conditions, they secreted extracellular vesicles (EVs) that were compatible in size with exosomes. Their ability to produce exosomes was also suggested by transmission electron microscopy pictures which revealed both EVs and intracellular structures that could be interpreted as multivesicular bodies. The fact that these cells were able to adapt to the PLLA scaffold, together with our previous results, which demonstrated that brain capillary endothelial cells can grow and differentiate on the same scaffold, could support the future use of 3D brain cell co-culture systems.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2019-06-01 | Molecular Medicine Reports |