Your search keyword '"Winnie Edith Svendsen"' showing total 5 results

1. Investigating the Use of Impedance Flow Cytometry for Classifying the Viability State of E. coli

Author

Christian Vinther Bertelsen, Julio César Franco, Gustav Erik Skands, Maria Dimaki, and Winnie Edith Svendsen

Subjects

impedance spectroscopy, impedance flow cytometry, bacteria detection, bacteria characterization, bacteria inactivation, lab-on-a-chip, Chemical technology, TP1-1185

Abstract

Bacteria detection, counting and analysis is of great importance in several fields. When viability plays a major role in decision making, the counting of colony-forming units grown on agar plates remains the gold standard. However, because plate counts depend on the growth of the bacteria, it is a slow procedure and only works with culturable species. Impedance flow cytometry (IFC) is a promising technology for particle detection, counting and characterization. It relies on the perturbation of an electric field by particles flowing through a microfluidic channel. The perturbation is directly related to the electrical properties of the particles, and therefore provides information about their composition and structure. In this work we investigate whether IFC can be used to differentiate viable cells from inactivated cells. Our findings demonstrate that the specific viability state of the bacteria has to be considered, but that with proper characterization thresholds, IFC can be used to classify bacterial viability states. By using three different inactivation methods—ethanol, heat and autoclavation—we have been able to show that the impedance response of Escherichia coli depends on its viability state, but that the specific response depends on the inactivation method. With these findings we expect to be able to optimize IFC for more reliable bacteria detection and counting in the future.

Published

2020

2. Investigating the Use of Impedance Flow Cytometry for Classifying the Viability State of E. coli

Author

Gustav Erik Skands, Winnie Edith Svendsen, Maria Dimaki, Julio César Franco, and Christian Vinther Bertelsen

Subjects

Impedance spectroscopy, 02 engineering and technology, Impedance response, lcsh:Chemical technology, 01 natural sciences, Biochemistry, Article, Analytical Chemistry, law.invention, Flow cytometry, Agar plate, law, Bacteria characterization, Microfluidic channel, medicine, Electric Impedance, Escherichia coli, lcsh:TP1-1185, bacteria detection, Electrical and Electronic Engineering, Instrumentation, Electrical impedance, impedance spectroscopy, medicine.diagnostic_test, biology, Lab-on-a-chip, lab-on-a-chip, Chemistry, 010401 analytical chemistry, Impedance flow cytometry, 021001 nanoscience & nanotechnology, biology.organism_classification, Flow Cytometry, Atomic and Molecular Physics, and Optics, Bacteria inactivation, bacteria characterization, 0104 chemical sciences, bacteria inactivation, impedance flow cytometry, 0210 nano-technology, Biological system, Bacterial Viability, Bacteria, Bacteria detection

Abstract

Bacteria detection, counting and analysis is of great importance in several fields. When viability plays a major role in decision making, the counting of colony-forming units grown on agar plates remains the gold standard. However, because plate counts depend on the growth of the bacteria, it is a slow procedure and only works with culturable species. Impedance flow cytometry (IFC) is a promising technology for particle detection, counting and characterization. It relies on the perturbation of an electric field by particles flowing through a microfluidic channel. The perturbation is directly related to the electrical properties of the particles, and therefore provides information about their composition and structure. In this work we investigate whether IFC can be used to differentiate viable cells from inactivated cells. Our findings demonstrate that the specific viability state of the bacteria has to be considered, but that with proper characterization thresholds, IFC can be used to classify bacterial viability states. By using three different inactivation methods&mdash, ethanol, heat and autoclavation&mdash, we have been able to show that the impedance response of Escherichia coli depends on its viability state, but that the specific response depends on the inactivation method. With these findings we expect to be able to optimize IFC for more reliable bacteria detection and counting in the future.

Published

2020

3. Bacteria Detection and Differentiation Using Impedance Flow Cytometry

Author

Romen Rodriguez-Trujillo, Gustav Erik Skands, Joachim Dahl Thomsen, Winnie Edith Svendsen, Casper Hyttel Clausen, Maria Dimaki, and Christian Vinther Bertelsen

Subjects

Staphylococcus aureus, Microfluidics, 02 engineering and technology, lcsh:Chemical technology, 01 natural sciences, Biochemistry, water quality, Article, Analytical Chemistry, Flow cytometry, Electrical impedance spectroscopy, medicine, Electric Impedance, Escherichia coli, lcsh:TP1-1185, bacteria detection, Electrical and Electronic Engineering, Instrumentation, Electrical impedance, Bacteria counting, Bacteriological Techniques, Solid particle, biology, medicine.diagnostic_test, Drinking Water, 010401 analytical chemistry, Bacteria differentiation, Equipment Design, Microfluidic Analytical Techniques, 021001 nanoscience & nanotechnology, biology.organism_classification, Flow Cytometry, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, electrical impedance spectroscopy, Contaminated water, bacteria counting, Water quality, Environmental science, 0210 nano-technology, Biological system, Water Microbiology, Bacteria, Bacteria detection, bacteria differentiation

Abstract

Monitoring of bacteria concentrations is of great importance in drinking water management. Continuous real-time monitoring enables better microbiological control of the water and helps prevent contaminated water from reaching the households. We have developed a microfluidic sensor with the potential to accurately assess bacteria levels in drinking water in real-time. Multi frequency electrical impedance spectroscopy is used to monitor a liquid sample, while it is continuously passed through the sensor. We investigate three aspects of this sensor: First we show that the sensor is able to differentiate Escherichia coli (Gram-negative) bacteria from solid particles (polystyrene beads) based on an electrical response in the high frequency phase and individually enumerate the two samples. Next, we demonstrate the sensor&rsquo, s ability to measure the bacteria concentration by comparing the results to those obtained by the traditional CFU counting method. Last, we show the sensor&rsquo, s potential to distinguish between different bacteria types by detecting different signatures for S. aureus and E. coli mixed in the same sample. Our investigations show that the sensor has the potential to be extremely effective at detecting sudden bacterial contaminations found in drinking water, and eventually also identify them.

Published

2018

4. Direct Detection of Candida albicans with a Membrane Based Electrochemical Impedance Spectroscopy Sensor

Author

Winnie Edith Svendsen, Catarina Almeida, Maria Dimaki, Ida Schjødt, Dorota Kwasny, and Sheida Esmail Tehrani

Subjects

Pathogen detection, 02 engineering and technology, lcsh:Chemical technology, 01 natural sciences, Biochemistry, Analytical Chemistry, Microbiology, lcsh:TP1-1185, Electrical and Electronic Engineering, Candida albicans, Instrumentation, Candida, biology, Chemistry, 010401 analytical chemistry, High mortality, Impedance sensor, Gold standard (test), 021001 nanoscience & nanotechnology, biology.organism_classification, Atomic and Molecular Physics, and Optics, Yeast, 0104 chemical sciences, Dielectric spectroscopy, membrane based sensor, Membrane, electrochemical impedance spectroscopy, Membrane based sensor, 0210 nano-technology, Electrochemical impedance spectroscopy

Abstract

Candidemia and invasive candidiasis is a cause of high mortality and morbidity rates among hospitalized patients worldwide. The occurrence of the infections increases due to the complexity of the patients and overuse of the antifungal therapy. The current Candida detection method includes blood culturing which is a lengthy procedure and thus delays the administration of the antifungal therapy. Even though the results are available after 48 h it is still the gold standard in pathogen detection in a hospital setting. In this work we present an electrochemical impedance sensor that is capable of detecting Candida albicans yeast. The yeast cells are captured on electrodes specifically functionalized with anti-Candida antibodies and detection is achieved by electrochemical impedance spectroscopy. The sensor allows for detection of the yeast cells at clinically relevant concentrations in less than 1 h.

Published

2018

5. Novel Membrane-Based Electrochemical Sensor for Real-Time Bio-Applications

Author

Winnie Edith Svendsen, Tanya Bakmand, Fatima AlZahraa Alatraktchi, and Maria Dimaki

Subjects

membrane-sensor, Conductometry, Dopamine, Biosensing Techniques, membrane electrodes, Real-time monitoring, lcsh:Chemical technology, Biochemistry, Article, Exocytosis, Analytical Chemistry, Computer Systems, Electrochemical sensing, Animals, lcsh:TP1-1185, Electrical and Electronic Engineering, Electrodes, Instrumentation, Membrane electrodes, Chemistry, PC12 cells, Substrate (chemistry), Membranes, Artificial, electrochemical sensing, Equipment Design, Chronoamperometry, real-time monitoring, Atomic and Molecular Physics, and Optics, Rats, Electrochemical gas sensor, Equipment Failure Analysis, Membrane, Cell culture, Membrane-sensor, Electrode, Cyclic voltammetry, Biomedical engineering

Abstract

This article presents a novel membrane-based sensor for real-time electrochemical investigations of cellular- or tissue cultures. The membrane sensor enables recording of electrical signals from a cell culture without any signal dilution, thus avoiding loss of sensitivity. Moreover, the porosity of the membrane provides optimal culturing conditions similar to existing culturing techniques allowing more efficient nutrient uptake and molecule release. The patterned sensor electrodes were fabricated on a porous membrane by electron-beam evaporation. The electrochemical performance of the membrane electrodes was characterized by cyclic voltammetry and chronoamperometry, and the detection of synthetic dopamine was demonstrated down to a concentration of 3.1 pM. Furthermore, to present the membrane-sensor functionality the dopamine release from cultured PC12 cells was successfully measured. The PC12 cells culturing experiments showed that the membrane-sensor was suitable as a cell culturing substrate for bio-applications. Real-time measurements of dopamine exocytosis in cell cultures were performed, where the transmitter release was recorded at the point of release. The developed membrane-sensor provides a new functionality to the standard culturing methods, enabling sensitive continuous in vitro monitoring and closely mimicking the in vivo conditions.

Published

2014