UHF-Dielectrophoresis Crossover Frequency as a New Marker for Discrimination of Glioblastoma Undifferentiated Cells

Manczak, Rémi; Saada, Sofiane; Provent, Thomas; Dalmay, Claire; Bessette, Barbara; Begaud, G.; Battu, Serge; Blondy, Pierre; Jauberteau, Marie‐Odile; Kaynak, Canan Baristiran; Kaynak, Mehmet; Palego, Cristiano; Lalloué, Fabrice; Pothier, Arnaud

doi:10.1109/jerm.2019.2895539

Cited by 25 publications

(46 citation statements)

References 21 publications

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“…Importantly, we exploited a novel method to discriminate the cell differentiation status using real-time measurements in a microfluidic lab-on-chip (LOC) platform implemented in CMOS technology [31,59,60]. This method was proven to be an efficient approach to identify circulating tumor cells [61] and physiological cell changes [62].…”

Section: Discussionmentioning

confidence: 99%

“…This method was proven to be an efficient approach to identify circulating tumor cells [61] and physiological cell changes [62]. Notably, differentiated cells can be identified and separated from an undifferentiated subpopulation, on the basis of their different dielectric signature, which determines different crossover frequencies [31,63]. The ability to discriminate CSCs through this technique has been recently proved on CSCs enriched and non-enriched populations of two different glioblastoma cell lines (U87 and LN18), showing differences in the intracellular dielectric characteristics [31].…”

Section: Discussionmentioning

confidence: 99%

“…Potential differences in stemness features were analyzed by classical approaches as gene, protein, and flow cytometry analysis of specific stem cell markers. Furthermore, since physical characterization was recently reported as complementary to cell biological features, to identify CSCs, we used high-frequency dielectrophoresis (HF-DEP) crossover frequency, a label-free, accurate, fast, and low-cost diagnostic technique that exploits the polarization and consequent motion of bio-particles in an applied electric fields [31].…”

Section: Introductionmentioning

confidence: 99%

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Human Medulloblastoma Cell Lines: Investigating on Cancer Stem Cell-Like Phenotype

Casciati

Tanori

Manczak

et al. 2020

Cancers

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Medulloblastoma (MB) is the most common malignant pediatric brain tumor. Despite the progress of new treatments, the risk of recurrence, morbidity, and death remains significant and the long-term adverse effects in survivors are substantial. The fraction of cancer stem-like cells (CSCs) because of their self-renewal ability and multi-lineage differentiation potential is critical for tumor initiation, growth, and resistance to therapies. For the development of new CSC-targeted therapies, further in-depth studies are needed using enriched and stable MB-CSCs populations. This work, aimed at identifying the amount of CSCs in three available human cell lines (DAOY, D341, and D283), describes different approaches based on the expression of stemness markers. First, we explored potential differences in gene and protein expression patterns of specific stem cell markers. Then, in order to identify and discriminate undifferentiated from differentiated cells, MB cells were characterized using a physical characterization method based on a high-frequency dielectrophoresis approach. Finally, we compared their tumorigenic potential in vivo, through engrafting in nude mice. Concordantly, our findings identified the D283 human cell line as an ideal model of CSCs, providing important evidence on the use of a commercial human MB cell line for the development of new strategic CSC-targeting therapies.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Human Medulloblastoma Cell Lines: Investigating on Cancer Stem Cell-Like Phenotype

Casciati

Tanori

Manczak

et al. 2020

Cancers

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“…Although this is an effective analysis tool, it is highly manual, has low throughput, and is not easily automated. There is also a number of approaches that use DEP trapping to infer dielectric properties [27,41–43]. There are DEP trapping‐based systems to measure the dielectrophoretic collection rate [9,40].…”

Section: Introductionmentioning

confidence: 99%

“…However, cell repulsion (negative DEP, nDEP) cannot be quantified by this method and moreover, there is a need for a microscope, video camera, and complex image analysis. Trapping‐based DEP systems have the advantage of being scalable and have been demonstrated in complementary metal oxide semiconductor (CMOS) technology [43]. However, trapping is a slow process and also exposes the cells to electric field magnitudes that could alter the cell via processes such as electroporation and in many cases are limited to positive DEP (pDEP) [44].…”

Section: Introductionmentioning

confidence: 99%

Parallel single‐cell optical transit dielectrophoresis cytometer

et al. 2020

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In this work, we present an optical transit DEP flow cytometer for parallel single-cell analysis. Each cell's dielectric property is inferred from velocity perturbations due to DEP actuation in a microfluidic channel. Dual LED sources facilitate velocity measurement by producing two transit shadows for each cell passing through the channel. These shadows are detected using a 256-pixel linear optical array detector. Massively parallel analysis is possible as each pixel of the detector can independently analyze the passing cells. A wide channel (∼18 mm) was employed to carry many particles simultaneously, and the system was capable of detecting the velocity of over 200 cells simultaneously. We have achieved analysis rates for 10 µm diameter polystyrene spheres response exceeding 250 per second. With appropriate calibration, this DEP cytometer can quantitatively measure the dielectric response. The dielectric response (Clausius-Mossotti factor) of viable CHO cells was measured over the frequency range of 100 kHz to 6 MHz, and the obtained response matches the previously measured values by our group. The DEP cytometer uses simple modular components to achieve high throughput label-free single-cell dielectric analysis and can begin analyzing particles within 10 s after starting to pump the sample into the channel.

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A review: Dielectrophoresis for characterizing and separating similar cell subpopulations based on bioelectric property changes due to disease progression and therapy assessment

Duncan

Davalos

2021

Electrophoresis

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This paper reviews the use of dielectrophoresis for high-fidelity separations and characterizations of subpopulations to highlight the recent advances in the electrokinetic field as well as provide insight into its progress toward commercialization. The role of cell subpopulations in heterogeneous clinical samples has been studied to deduce their role in disease progression and therapy resistance for instances such as cancer, tissue regeneration, and bacterial infection. Dielectrophoresis (DEP), a label-free electrokinetic technique, has been used to characterize and separate target subpopulations from mixed samples to determine disease severity, cell stemness, and drug efficacy. Despite its high sensitivity to characterize similar or related cells based on their differing bioelectric signatures, DEP has been slowly adopted both commercially and clinically. This review addresses the use of dielectrophoresis for the identification of target cell subtypes in stem cells, cancer cells, blood cells, and bacterial cells dependent on cell state and therapy exposure and addresses commercialization efforts in light of its sensitivity and future perspectives of the technology, both commercially and academically.

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UHF-Dielectrophoresis Crossover Frequency as a New Marker for Discrimination of Glioblastoma Undifferentiated Cells

Cited by 25 publications

References 21 publications

Human Medulloblastoma Cell Lines: Investigating on Cancer Stem Cell-Like Phenotype

Human Medulloblastoma Cell Lines: Investigating on Cancer Stem Cell-Like Phenotype

Parallel single‐cell optical transit dielectrophoresis cytometer

A review: Dielectrophoresis for characterizing and separating similar cell subpopulations based on bioelectric property changes due to disease progression and therapy assessment

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