Continuous organelle separation in an insulator‐based dielectrophoretic device

Continuous organelle separation in an insulator‐based dielectrophoretic device

Heterogeneity in organelle size has been associated with devastating human maladies such as neurodegenerative diseases or cancer. Therefore, assessing the size‐based subpopulation of organelles is imperative to understand the biomolecular foundations of these diseases. Here, we demonstrated a ratche...

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Bibliographic Details
Published in:Electrophoresis Vol. 43; no. 12; pp. 1283 - 1296
Main Authors: Ortiz, Ricardo, Koh, Domin, Kim, Dai Hyun, Rabbani, Mohammad Towshif, Anguaya Velasquez, Cesar, Sonker, Mukul, Arriaga, Edgar A., Ros, Alexandra
Format: Journal Article
Language:English
Published: Germany Wiley Subscription Services, Inc 01-06-2022
Subjects:
Continuous flow
continuous separation
Dielectrophoresis
Electrokinetics
Electrophoresis - methods
Flow separation
Heterogeneity
Humans
Insulation
insulator‐based dielectrophoresis
Mathematical models
Microfluidic Analytical Techniques
Microfluidic devices
Mitochondria
Mixtures
Numerical models
Organelles
Particle Size
Polystyrene resins
Polystyrenes
ratchet
Separation
size‐based separation
continuous separation
size-based separation
insulator-based dielectrophoresis
ratchet
mitochondria
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Summary:Heterogeneity in organelle size has been associated with devastating human maladies such as neurodegenerative diseases or cancer. Therefore, assessing the size‐based subpopulation of organelles is imperative to understand the biomolecular foundations of these diseases. Here, we demonstrated a ratchet migration mechanism using insulator‐based dielectrophoresis in conjunction with a continuous flow component that allows the size‐based separation of submicrometer particles. The ratchet mechanism was realized in a microfluidic device exhibiting an array of insulating posts, tailoring electrokinetic and dielectrophoretic transport. A numerical model was developed to elucidate the particle migration and the size‐based separation in various conditions. Experimentally, the size‐based separation of a mixture of polystyrene beads (0.28 and 0.87 μ$\umu $m) was accomplished demonstrating good agreement with the numerical model. Furthermore, the size‐based separation of mitochondria was investigated using a mitochondria mixture isolated from HepG2 cells and HepG2 cells carrying the gene Mfn‐1 knocked out, indicating distinct size‐related migration behavior. With the presented continuous flow separation device, larger amounts of fractionated organelles can be collected in the future allowing access to the biomolecular signature of mitochondria subpopulations differing in size.
Bibliography:See article online to view Figures 1–6 in color.
Both authors contributed equally to this work.
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ISSN:0173-0835
1522-2683
DOI:10.1002/elps.202100326