Computational Studies Using COMSOL Multiphysics on Dielectrophoretic Characterization and Separation of Mesenchymal Stem Cells Undergoing Tenogenic Differentiation

Authors

  • Raphael Oladokun West Virginia University

DOI:

https://doi.org/10.55632/pwvas.v96i1.1089

Keywords:

Stem cells, differentiation, regenerative medicine, tendon repair, dielectrophoresis, dielectric properties, cell capacitance, cell conductivity, cell permittivity, COMSOL Multiphysics, particle tracing module, creeping flow, electric current, Peak-to-peak voltage

Abstract

Stem cells have unique self-renewal and differentiation capacities, which are advantageous for regenerative medicine and tissue engineering applications. Stem cells can recreate cells needed to repair injured tissues and organs in the body, for example, by regenerating connective tissues, which provide support, protection, and a structural framework for various organs and other tissues. However, a significant limitation is the susceptibility of tendons to injury with long-term loss of function.

 

Mesenchymal Stem Cell (MSC) therapies are promising for healing tendon injuries and tears but controlling stem cell differentiation and generating homogeneous tenogenic stem cell populations remains challenging. Therefore, separating differentiating and non-differentiating MSCs to collect homogenous cells is critical for further tissue repair after transplantation. To substantiate our hypothesis that differentiating and non-differentiating stem cells have unique dielectric properties, we focused on characterizing-obtaining dielectric signatures for differentiating tenogenic and non-tenogenic MSCs on the third day of differentiation using dielectrophoresis (DEP) focused on crossover frequencies [1, 2]. The estimated values for membrane capacitance, conductivity, and permittivity after 3-day treatment of undifferentiated cells differentiating into tenogenic MSCs are 2.46±0.1 pF, 0.82±0.01 S/m, and 1.97±0.05, respectively, and cytoplasm conductivity 0.82±0.02 S/m. The treated stem cells undergo differentiation, but the untreated cells don’t. The results showed a significant difference between the 3-day treatment and no-treatment group.

 

The estimated properties from the dielectrophoretic characterization studies are crucial in designing a DEP-based enrichment microdevice to collect homogeneous differentiated stem cell populations for tendon repair. Using particle tracing, creeping flow (transport of diluted species model), and electric current physics in COMSOL Multiphysics simulation software, we designed a microdevice that achieves 100% separation of untreated and treated mesenchymal stem cells undergoing differentiation towards tendon.

Applying dielectrophoresis to the microdevice architecture demonstrated high selectivity and yield, processing one million treated and untreated stem cells in 6.4 and 27.8 hours, respectively.

References

Giduthuri, A.A.-O., et al., Dielectrophoretic Characterization of Tenogenically Differentiating Mesenchymal Stem Cells. LID - 10.3390/bios11020050 [doi] LID - 50. (2079-6374 (Electronic)).

Oladokun, R. and S.K. Srivastava, Dielectric characterization of differentiated human stem cells using dielectrophoresis technique, in 2023 AIChE Annual Meeting. 2023, AIChE.

Published

2024-04-18

How to Cite

Oladokun, R. (2024). Computational Studies Using COMSOL Multiphysics on Dielectrophoretic Characterization and Separation of Mesenchymal Stem Cells Undergoing Tenogenic Differentiation . Proceedings of the West Virginia Academy of Science, 96(1). https://doi.org/10.55632/pwvas.v96i1.1089

Issue

Section

Meeting Abstracts-Poster