Rapid determination of general cell status, cell viability, and optimal harvest time in eukaryotic cell cultures by impedance flow cytometry

Opitz, Christian; Schade, Grit; Kaufmann, Silvan; Berardino, Marco Di; Ottiger, Marcel; Grzesiek, Stephan

doi:10.1007/s00253-019-10046-3

Cited by 19 publications

(17 citation statements)

References 26 publications

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“…Recent IFC devices applied in single-cell analysis are summarized in Table 1 . These applications, discussed in this subsection, are simply classified according to cell species, including blood cells [ 110 , 111 , 112 , 113 , 114 ], tumor cells [ 43 , 52 , 115 , 116 , 117 , 118 , 119 , 120 , 121 , 122 ], stem cells [ 123 , 124 , 125 , 126 , 127 ], plant cells [ 60 , 128 , 129 , 130 , 131 , 132 ] and microbes [ 53 , 62 , 133 , 134 , 135 , 136 , 137 , 138 , 139 , 140 , 141 ]. In terms of blood cells, researchers focused on the identification and counting of normal or diseased blood cells.…”

Section: Applications Of Single-cell Impedance Sensing Technologymentioning

confidence: 99%

Recent Advances in Electrical Impedance Sensing Technology for Single-Cell Analysis

et al. 2021

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Cellular heterogeneity is of significance in cell-based assays for life science, biomedicine and clinical diagnostics. Electrical impedance sensing technology has become a powerful tool, allowing for rapid, non-invasive, and label-free acquisition of electrical parameters of single cells. These electrical parameters, i.e., equivalent cell resistance, membrane capacitance and cytoplasm conductivity, are closely related to cellular biophysical properties and dynamic activities, such as size, morphology, membrane intactness, growth state, and proliferation. This review summarizes basic principles, analytical models and design concepts of single-cell impedance sensing devices, including impedance flow cytometry (IFC) to detect flow-through single cells and electrical impedance spectroscopy (EIS) to monitor immobilized single cells. Then, recent advances of both electrical impedance sensing systems applied in cell recognition, cell counting, viability detection, phenotypic assay, cell screening, and other cell detection are presented. Finally, prospects of impedance sensing technology in single-cell analysis are discussed.

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Section: Applications Of Single-cell Impedance Sensing Technologymentioning

confidence: 99%

Recent Advances in Electrical Impedance Sensing Technology for Single-Cell Analysis

et al. 2021

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“…Flow cytometry is undoubtedly the most promising method to simultaneously obtain the quantification of yeast cells; the determination of their viability; and the assessment of their physiology, e.g., by morphological analysis of the budding division process [64,65]. The latter authors carried out online monitoring on a laboratory scale, thanks to automated sampling and sample processing (dilution and addition of a fluorochrome), but they considered that this monitoring is currently difficult to implement for process control.…”

Section: Sensorsmentioning

confidence: 99%

Study of Oenological Fermentation: Which Strategy and Which Tools?

et al. 2021

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Wine fermentation is a specific and complex research subject and its control is essential to ensure full process completion while improving wine quality. It displays several specificities, in particular, (i) musts with a very high sugar content, low pH, and some limiting nutrients, as well as a great variability in must composition according to the year, grape variety, and so on; (ii) atypical fermentation conditions with non-isothermal temperature profiles, a quasi-anaerobiosis and legal constraints with a limited and predefined list of authorized operations. New challenges have emerged, related to the increasing diversity of commercially available yeast strains; the fluctuating composition of musts, particularly owing to climate change; and sustainability, which has become a key issue. This paper synthesizes approaches implemented to address all these issues. It details the example of our laboratory that, for many years, has been developing an integrated approach to study yeast diversity, understand their metabolism, and develop new fermentation control strategies. This approach requires the development of specific fermentation devices to study yeast metabolism in a controlled environment that mimics practical conditions and to develop original fermentation control strategies. All these tools are described here, together with their role in the overall scientific strategy and complementary approaches in the literature.

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“…Dielectric properties of the cell suspension, such as capacitance (pF) and permittivity (pF/cm), proportionally relate to viable cell volume. This phenomenon is used by in-situ permittivity sensors [26,27] and Coulter-counters [28,29]. Modern instruments use frequency-scanning techniques in a range from 100 KHz to 20 MHz, capable for cell size and biomass concentration estimation (dielectric spectroscopy).…”

Section: Introductionmentioning

confidence: 99%

Application of In-Situ and Soft-Sensors for Estimation of Recombinant P. pastoris GS115 Biomass Concentration: A Case Analysis of HBcAg (Mut+) and HBsAg (MutS) Production Processes under Varying Conditions

Grīgs

Bolmanis

Galvanauskas

2021

Sensors

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Microbial biomass concentration is a key bioprocess parameter, estimated using various labor, operator and process cross-sensitive techniques, analyzed in a broad context and therefore the subject of correct interpretation. In this paper, the authors present the results of P. pastoris cell density estimation based on off-line (optical density, wet/dry cell weight concentration), in-situ (turbidity, permittivity), and soft-sensor (off-gas O2/CO2, alkali consumption) techniques. Cultivations were performed in a 5 L oxygen-enriched stirred tank bioreactor. The experimental plan determined varying aeration rates/levels, glycerol or methanol substrates, residual methanol levels, and temperature. In total, results from 13 up to 150 g (dry cell weight)/L cultivation runs were analyzed. Linear and exponential correlation models were identified for the turbidity sensor signal and dry cell weight concentration (DCW). Evaluated linear correlation between permittivity and DCW in the glycerol consumption phase (<60 g/L) and medium (for Mut+ strain) to significant (for MutS strain) linearity decline for methanol consumption phase. DCW and permittivity-based biomass estimates used for soft-sensor parameters identification. Dataset consisting from 4 Mut+ strain cultivation experiments used for estimation quality (expressed in NRMSE) comparison for turbidity-based (8%), permittivity-based (11%), O2 uptake-based (10%), CO2 production-based (13%), and alkali consumption-based (8%) biomass estimates. Additionally, the authors present a novel solution (algorithm) for uncommon in-situ turbidity and permittivity sensor signal shift (caused by the intensive stirrer rate change and antifoam agent addition) on-line identification and minimization. The sensor signal filtering method leads to about 5-fold and 2-fold minimized biomass estimate drifts for turbidity- and permittivity-based biomass estimates, respectively.

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Rapid determination of general cell status, cell viability, and optimal harvest time in eukaryotic cell cultures by impedance flow cytometry

Cited by 19 publications

References 26 publications

Recent Advances in Electrical Impedance Sensing Technology for Single-Cell Analysis

Recent Advances in Electrical Impedance Sensing Technology for Single-Cell Analysis

Study of Oenological Fermentation: Which Strategy and Which Tools?

Application of In-Situ and Soft-Sensors for Estimation of Recombinant P. pastoris GS115 Biomass Concentration: A Case Analysis of HBcAg (Mut+) and HBsAg (MutS) Production Processes under Varying Conditions

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