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Fluid flow-induced modulation of viability and osteodifferentiation of periodontal ligament stem cell spheroids-on-chip

Apurva Mishra, Kai Ren, Srividya Atkuru, Yichen Dai, Filippo Piccinini, Philip M. Preshaw, Gopu Sriram

2023Biomaterials Science27 citationsDOIOpen Access PDF

Abstract

(high-flow) to maximum fluid shear stress of 59 μPa and 360 μPa for low and high-flow conditions, respectively. The spheroid-on-chip microfluidic perfusion platform allowed for modulation of flow conditions leading to larger PDLSC spheroids with improved cellular viability under flow compared to static conditions. Modulation of fluid flow enhanced the osteodifferentiation potential of PDLSC spheroids, demonstrated by significantly enhanced alizarin red staining and alkaline phosphatase expression. Additionally, flow conditions, especially high-flow conditions, exhibited extensive calcium staining across both peripheral and central regions of the spheroids, in contrast to the predominantly peripheral staining observed under static conditions. These findings highlight the importance of fluid flow in shaping the morphological and functional properties of PDLSC spheroids. This work paves the way for future investigations exploring the interactions between PDLSC spheroids, microbial pathogens, and biomaterials within a controlled fluidic environment, offering insights for the development of innovative periodontal therapies, tissue engineering strategies, and regenerative approaches.

Topics & Concepts

SpheroidPeriodontal fiberBiomedical engineeringChemistryMicrofluidicsViability assayCell biologyPeriodontal ligament stem cellsBiophysicsMaterials scienceIn vitroAlkaline phosphataseNanotechnologyBiologyMedicineDentistryBiochemistryEnzymePeriodontal Regeneration and TreatmentsMesenchymal stem cell research3D Printing in Biomedical Research
Fluid flow-induced modulation of viability and osteodifferentiation of periodontal ligament stem cell spheroids-on-chip | Litcius