Using a cell-based gas biosensor for investigation of adverse effects of acetone vapors in vitro

Bohrn, Ulrich; Stütz, Evamaria; Fleischer, Maximilian; Schöning, Michael J.; Wagner, Patrick

doi:10.1016/j.bios.2012.08.029

Cited by 6 publications

(2 citation statements)

References 33 publications

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“…In recent years, the concept of molecular imprinting has been extended to surface imprinting of thin polymer films with proteins, , bacteria, − viruses, , pollen grains, yeast, HeLa cells, and erythrocytes. , In this work, surface-imprinted polyurethane layers (SIPs) are used for the selective detection of rodent macrophages (proof-of-principle) and human cancer cells (medically relevant application). Surface-imprinted cell receptors may also be an added value for the emerging field of cell-based biosensors in which the cells themselves act as a transducer element. − The identification of cells by sensor devices is commonly based on microbalances, electronic read-out, , or microfluidic techniques . These concepts require advanced equipment; hence, a low-cost automated sensor platform allowing distinguishing cells on basis of their size, shape, or membrane functionalities is of high relevance.…”

Section: Introductionmentioning

confidence: 99%

Selective Identification of Macrophages and Cancer Cells Based on Thermal Transport through Surface-Imprinted Polymer Layers

Eersels

Grinsven

Ethirajan

et al. 2013

ACS Appl. Mater. Interfaces

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122

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In this article, we describe a novel straightforward method for the specific identification of viable cells (macrophages and cancer cell lines MCF-7 and Jurkat) in a buffer solution. The detection of the various cell types is based on changes of the heat transfer resistance at the solid-liquid interface of a thermal sensor device induced by binding of the cells to a surface-imprinted polymer layer covering an aluminum chip. We observed that the binding of cells to the polymer layer results in a measurable increase of heat transfer resistance, meaning that the cells act as a thermally insulating layer. The detection limit was found to be on the order of 10(4) cells/mL, and mutual cross-selectivity effects between the cells and different types of imprints were carefully characterized. Finally, a rinsing method was applied, allowing for the specific detection of cancer cells with their respective imprints while the cross-selectivity toward peripheral blood mononuclear cells was negligible. The concept of the sensor platform is fast and low-cost while allowing also for repetitive measurements.

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Section: Introductionmentioning

confidence: 99%

Selective Identification of Macrophages and Cancer Cells Based on Thermal Transport through Surface-Imprinted Polymer Layers

Eersels

Grinsven

Ethirajan

et al. 2013

ACS Appl. Mater. Interfaces

Self Cite

122

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“…Biosensor platforms profit from the high degree of specificity that a natural receptor has for its target to detect the analyte of interest. This natural receptor layer can consist of nucleic acids (DNA or RNA), − enzymes, − cells, − or antibodies. , …”

Section: Introductionmentioning

confidence: 99%

The Heat-Transfer Method: A Versatile Low-Cost, Label-Free, Fast, and User-Friendly Readout Platform for Biosensor Applications

Grinsven

Eersels²,

Peeters³

et al. 2014

ACS Appl. Mater. Interfaces

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In recent years, biosensors have become increasingly important in various scientific domains including medicine, biology, and pharmacology, resulting in an increased demand for fast and effective readout techniques. In this Spotlight on Applications, we report on the recently developed heat-transfer method (HTM) and illustrate the use of the technique by zooming in on four established bio(mimetic) sensor applications: (i) mutation analysis in DNA sequences, (ii) cancer cell identification through surface-imprinted polymers, (iii) detection of neurotransmitters with molecularly imprinted polymers, and (iv) phase-transition analysis in lipid vesicle layers. The methodology is based on changes in heat-transfer resistance at a functionalized solid-liquid interface. To this extent, the device applies a temperature gradient over this interface and monitors the temperature underneath and above the functionalized chip in time. The heat-transfer resistance can be obtained by dividing this temperature gradient by the power needed to achieve a programmed temperature. The low-cost, fast, label-free and user-friendly nature of the technology in combination with a high degree of specificity, selectivity, and sensitivity makes HTM a promising sensor technology.

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On-site airborne pheromone sensing

Wehrenfennig¹,

Schott²,

Gasch³

et al. 2013

Anal Bioanal Chem

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Pheromones and other semiochemicals play an important role in the natural world by influencing the behavior of plants, mammals, and insects. In the latter case, species-dependent pheromone communication has numerous applications, including the detection, trapping, monitoring and guiding of insects, as well as pest management in agriculture. On-site sensors are desirable when volatile organic compounds (VOCs) are used as semiochemicals. Insects have evolved highly selective sensors for such compounds, so biosensors comprising complete insects, isolated organs or individual proteins can be highly effective. However, isolated insect organs have a limited lifetime as biosensor, so biomimetic approaches are needed for prolonged monitoring, novel applications, or measurements in challenging environments. We discuss the development of on-site biosensors and biomimetic approaches for airborne-pheromone sensing, together with biomimetic VOC sensor systems. Furthermore, the infochemical effect describing the anthropogenic contamination of the ecosystem through semiochemicals, will be considered in the context of novel on-site pheromone sensing-systems.

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Using a cell-based gas biosensor for investigation of adverse effects of acetone vapors in vitro

Cited by 6 publications

References 33 publications

Selective Identification of Macrophages and Cancer Cells Based on Thermal Transport through Surface-Imprinted Polymer Layers

Selective Identification of Macrophages and Cancer Cells Based on Thermal Transport through Surface-Imprinted Polymer Layers

The Heat-Transfer Method: A Versatile Low-Cost, Label-Free, Fast, and User-Friendly Readout Platform for Biosensor Applications

On-site airborne pheromone sensing

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