17 results on '"Soffe, Rebecca"'
Search Results
2. Replicating Arabidopsis Model Leaf Surfaces for Phyllosphere Microbiology
- Author
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Soffe, Rebecca, Bernach, Michal, Remus-Emsermann, Mitja N. P., and Nock, Volker
- Published
- 2019
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3. Exogenous double‐stranded RNA inhibits the infection physiology of rust fungi to reduce symptoms in planta.
- Author
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Degnan, Rebecca M., McTaggart, Alistair R., Shuey, Louise S., Pame, Leny Jane S., Smith, Grant R., Gardiner, Donald M., Nock, Volker, Soffe, Rebecca, Sale, Sarah, Garrill, Ashley, Carroll, Bernard J., Mitter, Neena, and Sawyer, Anne
- Subjects
RUST fungi ,DOUBLE-stranded RNA ,RUST diseases ,FUNGI physiology ,FUNGICIDE resistance ,COMPARATIVE genomics - Abstract
Rust fungi (Pucciniales) are a diverse group of plant pathogens in natural and agricultural systems. They pose ongoing threats to the diversity of native flora and cause annual crop yield losses. Agricultural rusts are predominantly managed with fungicides and breeding for resistance, but new control strategies are needed on non‐agricultural plants and in fragile ecosystems. RNA interference (RNAi) induced by exogenous double‐stranded RNA (dsRNA) has promise as a sustainable approach for managing plant‐pathogenic fungi, including rust fungi. We investigated the mechanisms and impact of exogenous dsRNA on rust fungi through in vitro and whole‐plant assays using two species as models, Austropuccinia psidii (the cause of myrtle rust) and Coleosporium plumeriae (the cause of frangipani rust). In vitro, dsRNA either associates externally or is internalized by urediniospores during the early stages of germination. The impact of dsRNA on rust infection architecture was examined on artificial leaf surfaces. dsRNA targeting predicted essential genes significantly reduced germination and inhibited development of infection structures, namely appressoria and penetration pegs. Exogenous dsRNA sprayed onto 1‐year‐old trees significantly reduced myrtle rust symptoms. Furthermore, we used comparative genomics to assess the wide‐scale amenability of dsRNA to control rust fungi. We sequenced genomes of six species of rust fungi, including three new families (Araucariomyceaceae, Phragmidiaceae, and Skierkaceae) and identified key genes of the RNAi pathway across 15 species in eight families of Pucciniales. Together, these findings indicate that dsRNA targeting essential genes has potential for broad‐use management of rust fungi across natural and agricultural systems. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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4. Using dielectrophoresis to study the dynamic response of single budding yeast cells to Lyticase
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Tang, Shi-Yang, Yi, Pyshar, Soffe, Rebecca, Nahavandi, Sofia, Shukla, Ravi, and Khoshmanesh, Khashayar
- Published
- 2015
- Full Text
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5. Art‐on‐a‐Chip: Preserving Microfluidic Chips for Visualization and Permanent Display.
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Soffe, Rebecca, Mach, Albert J., Onal, Sevgi, Nock, Volker, Lee, Luke P., and Nevill, J. Tanner
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- 2020
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6. Comparison of replica leaf surface materials for phyllosphere microbiology.
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Soffe, Rebecca, Altenhuber, Nicola, Bernach, Michal, Remus-Emsermann, Mitja N.P., and Nock, Volker
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SURFACES (Technology) , *MICROBIOLOGY , *SURFACE topography , *SURFACE energy , *PLANT surfaces - Abstract
Artificial surfaces are routinely used instead of leaves to enable a reductionist approach in phyllosphere microbiology, the study of microorganisms residing on plant leaf surfaces. Commonly used artificial surfaces include, flat surfaces, such as metal and nutrient agar, and microstructured surfaces, such as isolate leaf cuticles or reconstituted leaf waxes. However, interest in replica leaf surfaces as an artificial surface is growing, as replica surfaces provide an improved representation of the complex topography of leaf surfaces. To date, leaf surfaces have predominantly been replicated for their superhydrophobic properties. In contrast, in this paper we investigated the potential of agarose, the elastomer polydimethylsiloxane (PDMS), and gelatin as replica leaf surface materials for phyllosphere microbiology studies. Using a test pattern of pillars, we investigated the ability to replicate microstructures into the materials, as well as the degradation characteristics of the materials in environmental conditions. Pillars produced in PDMS were measured to be within 10% of the mold master and remained stable throughout the degradation experiments. In agarose and gelatin the pillars deviated by more than 10% and degraded considerably within 48 hours in environmental conditions. Furthermore, we investigated the surface energy of the materials, an important property of a leaf surface, which influences resource availability and microorganism attachment. We found that the surface energy and bacterial viability on PDMS was comparable to isolated Citrus × aurantium and Populus × canescens leaf cuticles. Hence indicating that PDMS is the most suitable material for replica leaf surfaces. In summary, our experiments highlight the importance of considering the inherent material properties when selecting a replica leaf surface for phyllosphere microbiology studies. As demonstrated, a PDMS replica leaf offers a control surface that can be used for investigating microbe-microbe and microbe-plant interactions in the phyllosphere, which will enable mitigation strategies against pathogens to be developed. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
7. Towards Point-of-Care Insulin Detection.
- Author
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Soffe, Rebecca, Nock, Volker, and Chase, James Geoffrey
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- 2019
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8. Concurrent shear stress and chemical stimulation of mechano-sensitive cells by discontinuous dielectrophoresis.
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Soffe, Rebecca, Baratchi, Sara, Shi-Yang Tang, Mitchell, Arnan, McIntyre, Peter, and Khoshmanesh, Khashayar
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DIELECTROPHORESIS , *SHEARING force , *MICROFLUIDIC devices , *INTRACELLULAR calcium , *TRP channels - Abstract
Microfluidic platforms enable a variety of physical or chemical stimulation of single or multiple cells to be examined and monitored in real-time. To date, intracellular calcium signalling research is, however, predominantly focused on observing the response of cells to a single mode of stimulation; consequently, the sensitising/desensitising of cell responses under concurrent stimuli is not well studied. In this paper, we provide an extended Discontinuous Dielectrophoresis procedure to investigate the sensitising of chemical stimulation, over an extensive range of shear stress, up to 63 dyn/cm², which encompasses shear stresses experienced in the arterial and venus systems (10 to 60 dyn/cm²). Furthermore, the TRPV4-selective agonist GSK1016790A, a form of chemical stimulation, did not influence the ability of the cells' to remain immobilised under high levels of shear stress; thus, enabling us to investigate shear stress stimulation on agonism. Our experiments revealed that shear stress sensitises GSK1016790A-evoked intracellular calcium signalling of cells in a shear-stimulus dependent manner, as observed through a reduction in the cellular response time and an increase in the pharmacological efficacy. Consequently, suggesting that the role of TRPV4 may be underestimated in endothelial cells--which experience high levels of shear stress. This study highlights the importance of conducting studies at high levels of shear stress. Additionally, our approach will be valuable for examining the effect of high levels of shear on different cell types under different conditions, as presented here for agonist activation. [ABSTRACT FROM AUTHOR]
- Published
- 2016
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9. Creation of Liquid Metal 3D Microstructures Using Dielectrophoresis.
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Tang, Shi‐Yang, Zhu, Jiuyang, Sivan, Vijay, Gol, Berrak, Soffe, Rebecca, Zhang, Wei, Mitchell, Arnan, and Khoshmanesh, Khashayar
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METAL microstructure ,LIQUID metals ,DIELECTROPHORESIS ,SCANNING electron microscopy ,SONICATION - Abstract
Patterning customized arrays of microscale Galinstan or EGaIn liquid metals enables the creation of a variety of microfabricated systems. Current techniques for creating microsized 3D structures of liquid metals are limited by the large dimension or low aspect ratio of such structures, and time-consuming processes. Here, a novel technique for creating 3D microstructures of Galinstan using dielectrophoresis is introduced. The presented technique enables the rapid creation of Galinstan microstructures with various dimensions and aspect ratios. Two series of proof-of-concept experiments are conducted to demonstrate the capabilities of this technique. First, the 3D Galinstan microstructures are utilized as 3D microelectrodes to enhance the trapping of tungsten trioxide (WO
3 ) nanoparticles flowing through a microfluidic channel. Second, the patterned Galinstan microstructures are utilized as microfins to improve the dissipation of heat within a microfluidic channel that is located onto a hot spot. The presented technique can be readily used for creating customized arrays of 3D Galinstan microstructures for a wide range of applications. [ABSTRACT FROM AUTHOR]- Published
- 2015
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10. Controlled Rotation and Vibration of Patterned Cell Clusters Using Dielectrophoresis.
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Soffe, Rebecca, Shi-Yang Tang, Baratchi, Sara, Nahavandi, Sofia, Nasabi, Mahyar, Cooper, Jonathan M., Mitchell, Aman, and Khoshmanesh, Khashayar
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DIELECTROPHORESIS , *CELL proliferation , *MORPHOGENESIS , *SERUM albumin , *SINUSOIDAL projection (Cartography) - Abstract
The localized motion of cells within a cluster is an important feature of living organisms and has been found to play roles in cell signaling, communication, and migration, thus affecting processes such as proliferation, transcription, and organogenesis. Current approaches for inducing dynamic movement into cells, however, focus predominantly on mechanical stimulation of single cells, affect cell integrity, and, more importantly, need a complementary mechanism to pattern cells. In this article, we demonstrate a new strategy for the mechanical stimulation of large cell clusters, taking advantage of dielectrophoresis. This strategy is based on the cellular spin resonance mechanism, but it utilizes coating agents, such as bovine serum albumin, to create consistent rotation and vibration of individual cells. The treatment of cells with coating agents intensifies the torque induced on the cells while reducing the friction at the cell-cell and cell-substrate interfaces, resulting in the consistent motion of the cells. Such localized motion can be modulated by varying the frequency and voltage of the applied sinusoidal AC signal and can be achieved in the absence and presence of flow. This strategy enables the survival and functioning of moving cells within large-scale clusters to be investigated. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
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11. Microfluidic Platforms for the Investigation of Intercellular Signalling Mechanisms.
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Nahavandi, Sofia, Tang, Shi‐Yang, Baratchi, Sara, Soffe, Rebecca, Nahavandi, Saeid, Kalantar‐zadeh, Kourosh, Mitchell, Arnan, and Khoshmanesh, Khashayar
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- 2014
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12. High Resolution Scanning Electron Microscopy of Cells Using Dielectrophoresis.
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Tang, Shi-Yang, Zhang, Wei, Soffe, Rebecca, Nahavandi, Sofia, Shukla, Ravi, and Khoshmanesh, Khashayar
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SCANNING electron microscopy ,CELL imaging ,DIELECTROPHORESIS ,CELL physiology ,CELL morphology ,BIOCHEMISTRY ,CELL membranes - Abstract
Ultrastructural analysis of cells can reveal valuable information about their morphological, physiological, and biochemical characteristics. Scanning electron microscopy (SEM) has been widely used to provide high-resolution images from the surface of biological samples. However, samples need to be dehydrated and coated with conductive materials for SEM imaging. Besides, immobilizing non-adherent cells during processing and analysis is challenging and requires complex fixation protocols. In this work, we developed a novel dielectrophoresis based microfluidic platform for interfacing non-adherent cells with high-resolution SEM at low vacuum mode. The system enables rapid immobilization and dehydration of samples without deposition of chemical residues over the cell surface. Moreover, it enables the on-chip chemical stimulation and fixation of immobilized cells with minimum dislodgement. These advantages were demonstrated for comparing the morphological changes of non-budding and budding yeast cells following Lyticase treatment. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
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13. A hydrodynamic microchip for formation of continuous cell chains.
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Khoshmanesh, Khashayar, Wei Zhang, Shi-Yang Tang, Nasabi, Mahyar, Soffe, Rebecca, Tovar-Lopez, Francisco J., Rajadas, Jayakumar, and Mitchell, Arnan
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HYDRODYNAMICS ,INTEGRATED circuits ,CONTINUOUS cell lines ,MICROFLUIDIC devices ,POLYDIMETHYLSILOXANE ,POLYSTYRENE - Abstract
Here, we demonstrate the unique features of a hydrodynamic based microchip for creating continuous chains of model yeast cells. The system consists of a disk shaped microfluidic structure, containing narrow orifices that connect the main channel to an array of spoke channels. Negative pressure provided by a syringe pump draws fluid from the main channel through the narrow orifices. After cleaning process, a thin layer of water is left between the glass substrate and the polydimethylsiloxane microchip, enabling leakage beneath the channel walls. A mechanical clamp is used to adjust the operation of the microchip. Relaxing the clamp allows leakage of liquid beneath the walls in a controllable fashion, leading to formation of a long cell chain evenly distributed along the channel wall. The unique features of the microchip are demonstrated by creating long chains of yeast cells and model 15 lm polystyrene particles along the side wall and analysing the hydrogen peroxide induced death of patterned cells. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
- View/download PDF
14. Microfluidic platforms for biomarker analysis.
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Nahavandi, Sofia, Baratchi, Sara, Soffe, Rebecca, Tang, Shi-Yang, Nahavandi, Saeid, Mitchell, Arnan, and Khoshmanesh, Khashayar
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BIOMARKERS ,DIAGNOSIS ,PROGNOSIS ,MICROFLUIDICS ,THERAPEUTICS - Abstract
Biomarkers have been described as characteristics, most often molecular, that provide information about biological states, whether normal, pathological, or therapeutically modified. They hold great potential to assist diagnosis and prognosis, monitor disease, and assess therapeutic effectiveness. While a few biomarkers are routinely utilised clinically, these only reflect a very small percentage of all biomarkers discovered. Numerous factors contribute to the slow uptake of these new biomarkers, with challenges faced throughout the biomarker development pipeline. Microfluidics offers two important opportunities to the field of biomarkers: firstly, it can address some of these developmental obstacles, and secondly, it can provide the precise and complex platform required to bridge the gap between biomarker research and the biomarker-based analytical device market. Indeed, adoption of microfluidics has provided a new avenue for advancement, promoting clinical utilisation of both biomarkers and their analytical platforms. This review will discuss biomarkers and outline microfluidic platforms developed for biomarker analysis. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
- View/download PDF
15. Corrigendum: A multi-functional bubble-based microfluidic system.
- Author
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Khoshmanesh, Khashayar, Almansouri, Abdullah, Albloushi, Hamad, Yi, Pyshar, Soffe, Rebecca, and Kalantar-zadeh, Kourosh
- Abstract
This corrects the article DOI: 10.1038/srep09942 [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
16. Analysing calcium signalling of cells under high shear flows using discontinuous dielectrophoresis.
- Author
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Soffe, Rebecca, Tang, Shi-Yang, Nasabi, Mahyar, Mitchell, Arnan, Khoshmanesh, Khashayar, Baratchi, Sara, and McIntyre, Peter
- Subjects
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CALCIUM , *CELLULAR signal transduction , *ELECTROPHORESIS , *SHEAR flow , *ENCAPSULATION (Catalysis) , *SHEARING force - Abstract
Immobilisation of cells is an important feature of many cellular assays, as it enables the physical/chemical stimulation of cells; whilst, monitoring cellular processes using microscopic techniques. Current approaches for immobilising cells, however, are hampered by time-consuming processes, the need for specific antibodies or coatings, and adverse effects on cell integrity. Here, we present a dielectrophoresis-based approach for the robust immobilisation of cells, and analysis of their responses under high shear flows. This approach is quick and label-free, and more importantly, minimises the adverse effects of electric field on the cell integrity, by activating the field for a short duration of 120 s, just long enough to immobilise the cells, after which cell culture media (such as HEPES) is flushed through the platform. In optimal conditions, at least 90% of the cells remained stably immobilised, when exposed to a shear stress of 63 dyn/cm2. This approach was used to examine the shear-induced calcium signalling of HEK-293 cells expressing a mechanosensitive ion channel, transient receptor potential vaniloid type 4 (TRPV4), when exposed to the full physiological range of shear stress. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
17. A multi-functional bubble-based microfluidic system.
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Khoshmanesh, Khashayar, Almansouri, Abdullah, Albloushi, Hamad, Yi, Pyshar, Soffe, Rebecca, and Kalantar-zadeh, Kourosh
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MICROFLUIDICS ,BUBBLE dynamics ,FLUID flow ,MECHANICAL engineering ,ACTUATORS - Abstract
Recently, the bubble-based systems have offered a new paradigm in microfluidics. Gas bubbles are highly flexible, controllable and barely mix with liquids, and thus can be used for the creation of reconfigurable microfluidic systems. In this work, a hydrodynamically actuated bubble-based microfluidic system is introduced. This system enables the precise movement of air bubbles via axillary feeder channels to alter the geometry of the main channel and consequently the flow characteristics of the system. Mixing of neighbouring streams is demonstrated by oscillating the bubble at desired displacements and frequencies. Flow control is achieved by pushing the bubble to partially or fully close the main channel. Patterning of suspended particles is also demonstrated by creating a large bubble along the sidewalls. Rigorous analytical and numerical calculations are presented to describe the operation of the system. The examples presented in this paper highlight the versatility of the developed bubble-based actuator for a variety of applications; thus providing a vision that can be expanded for future highly reconfigurable microfluidics. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
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