Your search keyword '"Rustem F. Ismagilov"' showing total 9 results

1. Microfluidic SlipChip device for multistep multiplexed biochemistry on a nanoliter scale

Author

Dmitriy V. Zhukov, Tahmineh Khazaei, Rustem F. Ismagilov, Eugenia Khorosheva, Wenbin Du, David A. Selck, and Alexander A. Shishkin

Subjects

Materials science, Extramural, 010401 analytical chemistry, Microfluidics, Biomedical Engineering, Bioengineering, Nanotechnology, 02 engineering and technology, General Chemistry, Microfluidic Analytical Techniques, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, Multiplexing, 0104 chemical sciences, Droplet merging, Lab-On-A-Chip Devices, Humans, RNA, Single-Cell Analysis, 0210 nano-technology, Merge (version control)

Abstract

We have developed a multistep microfluidic device that expands the current SlipChip capabilities by enabling multiple steps of droplet merging and multiplexing. Harnessing the interfacial energy between carrier and sample phases, this manually operated device accurately meters nanoliter volumes of reagents and transfers them into on-device reaction wells. Judiciously shaped microfeatures and surface-energy traps merge droplets in a parallel fashion. Wells can be tuned for different volumetric capacities and reagent types, including for pre-spotted reagents that allow for unique identification of original well contents even after their contents are pooled. We demonstrate the functionality of the multistep SlipChip by performing RNA transcript barcoding on-device for synthetic spiked-in standards and for biologically derived samples. This technology is a good candidate for a wide range of biological applications that require multiplexing of multistep reactions in nanoliter volumes, including single-cell analyses.

Published

2019

2. Evaluating 3D printing to solve the sample-to-device interface for LRS and POC diagnostics: example of an interlock meter-mix device for metering and lysing clinical urine samples

Author

Nathan G. Schoepp, Daan Witters, Rustem F. Ismagilov, and Erik Jue

Subjects

Rapid prototyping, Engineering, Sample (material), Interface (computing), Biomedical Engineering, 3D printing, Bioengineering, Chlamydia trachomatis, 02 engineering and technology, Urine, Real-Time Polymerase Chain Reaction, 01 natural sciences, Biochemistry, Lab-On-A-Chip Devices, Metre, Humans, Metering mode, Interlock, Process engineering, Urine Specimen Collection, business.industry, 010401 analytical chemistry, Process (computing), Reproducibility of Results, General Chemistry, 021001 nanoscience & nanotechnology, Neisseria gonorrhoeae, 0104 chemical sciences, Printing, Three-Dimensional, 0210 nano-technology, business, Biomedical engineering

Abstract

This paper evaluates the potential of 3D printing, a semi-automated additive prototyping technology, as a means to design and prototype a sample-to-device interface, amenable to diagnostics in limited-resource settings, where speed, accuracy and user-friendly design are critical components. As a test case, we built and validated an interlock meter-mix device for accurately metering and lysing human urine samples for use in downstream nucleic acid amplification. Two plungers and a multivalve generated and controlled fluid flow through the device and demonstrate the utility of 3D printing to create leak-free seals. Device operation consists of three simple steps that must be performed sequentially, eliminating manual pipetting and vortexing to provide rapid (5 to 10 s) and accurate metering and mixing. Bretherton's prediction was applied, using the bond number to guide a design that prevents potentially biohazardous samples from leaking from the device. We employed multi-material 3D printing technology, which allows composites with rigid and elastomeric properties to be printed as a single part. To validate the meter-mix device with a clinically relevant sample, we used urine spiked with inactivated Chlamydia trachomatis and Neisseria gonorrhoeae. A downstream nucleic acid amplification by quantitative PCR (qPCR) confirmed there was no statistically significant difference between samples metered and mixed using the standard protocol and those prepared with the meter-mix device, showing the 3D-printed device could accurately meter, mix and dispense a human urine sample without loss of nucleic acids. Although there are some limitations to 3D printing capabilities (e.g. dimension limitations related to support material used in the printing process), the advantages of customizability, modularity and rapid prototyping illustrate the utility of 3D printing for developing sample-to-device interfaces for diagnostics.

Published

2016

3. Isolation, incubation, and parallel functional testing and identification by FISH of rare microbial single-copy cells from multi-species mixtures using the combination of chemistrode and stochastic confinement

Author

Hyun-Jung Kim, Wenbin Du, Elena M. Lucchetta, Rustem F. Ismagilov, and Weishan Liu

Subjects

Cell division, Microorganism, Microfluidics, Biomedical Engineering, Bioengineering, Cellulase, Biochemistry, Article, Paenibacillus, RNA, Ribosomal, 16S, medicine, Escherichia coli, Incubation, In Situ Hybridization, Fluorescence, Soil Microbiology, Bacteriological Techniques, Stochastic Processes, biology, medicine.diagnostic_test, General Chemistry, Equipment Design, Microfluidic Analytical Techniques, Isolation (microbiology), biology.organism_classification, Molecular biology, biology.protein, Biological system, Fluorescence in situ hybridization

Abstract

This paper illustrates a plug-based microfluidic approach combining the technique of the chemistrode and the principle of stochastic confinement, which can be used to i) starting from a mixture of cells, stochastically isolate single cells into plugs, ii) incubate the plugs to grow clones of the individual cells without competition among different clones, iii) split the plugs into arrays of identical daughter plugs, where each plug contained clones of the original cell, and iv) analyze each array by an independent technique, including cellulase assays, cultivation, cryo-preservation, Gram staining, and Fluorescence In Situ Hybridization (FISH). Functionally, this approach is equivalent to simultaneously assaying the clonal daughter cells by multiple killing and non-killing methods. A new protocol for single-cell FISH, a killing method, was developed to identify isolated cells of Paenibacillus curdlanolyticus in one array of daughter plugs using a 16S rRNA probe, Pc196. At the same time, live copies of P. curdlanolyticus in another array were obtained for cultivation. Among technical advances, this paper reports a chemistrode that enables sampling of nanoliter volumes directly from environmental specimens, such as soil slurries. In addition, a method for analyzing plugs is described: an array of droplets is deposited on the surface, and individual plugs are injected into the droplets of the surface array to induce a reaction and enable microscopy without distortions associated with curvature of plugs. The overall approach is attractive for identifying rare, slow growing microorganisms and would complement current methods to cultivate unculturable microbes from environmental samples.

Published

2009

4. Digital biology and chemistry

Author

Daan Witters, Jesus Rodriguez-Manzano, Stefano Begolo, Bing Sun, Rustem F. Ismagilov, and Whitney Robles

Subjects

chemistry.chemical_classification, Biomolecule, Microfluidics, Biomedical Engineering, Enzyme-Linked Immunosorbent Assay, Bioengineering, Compartmentalization (information security), Context (language use), Nanotechnology, General Chemistry, Biology, Polymerase Chain Reaction, Biochemistry, Signal, 09 Engineering, Analytical Chemistry, chemistry, Limit of Detection, Robustness (computer science), Lab-On-A-Chip Devices, Biological Assay, Digital polymerase chain reaction, 03 Chemical Sciences, AND gate

Abstract

This account examines developments in “digital” biology and chemistry within the context of microfluidics, from a personal perspective. Using microfluidics as a frame of reference, we identify two areas of research within digital biology and chemistry that are of special interest: (i) the study of systems that switch between discrete states in response to changes in chemical concentration of signals, and (ii) the study of single biological entities such as molecules or cells. In particular, microfluidics accelerates analysis of switching systems (i.e., those that exhibit a sharp change in output over a narrow range of input) by enabling monitoring of multiple reactions in parallel over a range of concentrations of signals. Conversely, such switching systems can be used to create new kinds of microfluidic detection systems that provide “analog-to-digital” signal conversion and logic. Microfluidic compartmentalization technologies for studying and isolating single entities can be used to reconstruct and understand cellular processes, study interactions between single biological entities, and examine the intrinsic heterogeneity of populations of molecules, cells, or organisms. Furthermore, compartmentalization of single cells or molecules in “digital” microfluidic experiments can induce switching in a range of reaction systems to enable sensitive detection of cells or biomolecules, such as with digital ELISA or digital PCR. This “digitizing” offers advantages in terms of robustness, assay design, and simplicity because quantitative information can be obtained with qualitative measurements. While digital formats have been shown to improve the robustness of existing chemistries, we anticipate that in the future they will enable new chemistries to be used for quantitative measurements, and that digital biology and chemistry will continue to provide further opportunities for measuring biomolecules, understanding natural systems more deeply, and advancing molecular and cellular analysis. Microfluidics will impact digital biology and chemistry and will also benefit from them if it becomes massively distributed.

Published

2014

5. Chemical stimulation of the Arabidopsis thalianaroot using multi-laminar flow on a microfluidic chip.

Author

Matthias Meier, Elena M. Lucchetta, and Rustem F. Ismagilov

Subjects

ARABIDOPSIS thaliana, LAMINAR flow, MICROFLUIDIC devices, INTEGRATED circuits, GREEN fluorescent protein, GENE expression

Abstract

In this article, we developed a “plant on a chip” microfluidic platform that can control the local chemical environment around live roots of Arabidopsis thalianawith high spatial resolution using multi-laminar flow. We characterized the flow profile around the Arabidopsisroot, and verified that the shear forces within the device (∼10 dyne cm−2) did not impede growth of the roots. Our platform was able to deliver stimuli to the root at a spatial resolution of 10–800 µm. Further, the platform was validated by exposing desired regions of the root with a synthetic auxin derivative, 2,4-dichlorophenoxyacetic acid (2,4-D), and its inhibitor N-1-naphthylphthalamic acid (NPA). The response to the stimuli was observed using a DR5::GFP Arabidopsisline, where GFP expression is coupled to the auxin response regulator DR5. GFP expression in the root matched the position of the flow-focused stream containing 2,4-D. When the regions around the 2,4-D stimulus were exposed to the auxin transport inhibitor NPA, the active and passive transport mechanisms of auxin could be differentiated, as NPA blocks active cell-to-cell transport of auxin. Finally, we demonstrated that local 2,4-D stimulation in a ∼10 µm root segment enhanced morphological changes such as epidermal hair growth. These experiments were proof-of-concept and agreed with the results expected based on known root biology, demonstrating that this “root on a chip” platform can be used to test how root development is affected by any chemical component of interest, including nitrogen, phosphate, salts, and other plant hormones. [ABSTRACT FROM AUTHOR]

Published

2010

6. Isolation, incubation, and parallel functional testing and identification by FISH of rare microbial single-copy cells from multi-species mixtures using the combination of chemistrode and stochastic confinementElectronic supplementary information (ESI) available: Supplementary methods, Fig. S1–S4 and Table S1. See DOI: 10.1039/b904958d

Author

Weishan Liu, Hyun Jung Kim, Elena M. Lucchetta, Wenbin Du, and Rustem F. Ismagilov

Subjects

FLUORESCENCE in situ hybridization, MICROBIOLOGY, CELL separation, MICROFLUIDIC devices, STOCHASTIC processes, CELLULASE, BIOLOGICAL assay, CRYOELECTRONICS

Abstract

This paper illustrates a plug-based microfluidic approach combining the technique of the chemistrode and the principle of stochastic confinement, which can be used to i) starting from a mixture of cells, stochastically isolate single cells into plugs, ii) incubate the plugs to grow clones of the individual cells without competition among different clones, iii) split the plugs into arrays of identical daughter plugs, where each plug contained clones of the original cell, and iv) analyze each array by an independent technique, including cellulase assays, cultivation, cryo-preservation, Gram staining, and Fluorescence In SituHybridization (FISH). Functionally, this approach is equivalent to simultaneously assaying the clonal daughter cells by multiple killing and non-killing methods. A new protocol for single-cell FISH, a killing method, was developed to identify isolated cells of Paenibacillus curdlanolyticusin one array of daughter plugs using a 16S rRNA probe, Pc196. At the same time, live copies of P. curdlanolyticusin another array were obtained for cultivation. Among technical advances, this paper reports a chemistrode that enables sampling of nanoliter volumes directly from environmental specimens, such as soil slurries. In addition, a method for analyzing plugs is described: an array of droplets is deposited on the surface, and individual plugs are injected into the droplets of the surface array to induce a reaction and enable microscopy without distortions associated with curvature of plugs. The overall approach is attractive for identifying rare, slow growing microorganisms and would complement current methods to cultivate unculturable microbes from environmental samples. [ABSTRACT FROM AUTHOR]

Published

2009

7. Detecting bacteria and determining their susceptibility to antibiotics by stochastic confinement in nanoliter droplets using plug-based microfluidics.

Author

James Q. Boedicker, Liang Li, Timothy R. Kline, and Rustem F. Ismagilov

Subjects

MICROFLUIDICS, ANTIBIOTICS, DRUGS, BACTERIA, ANTI-infective agents, BLOOD plasma, MEDICAL technology

Abstract

This article describes plug-based microfluidic technology that enables rapid detection and drug susceptibility screening of bacteria in samples, including complex biological matrices, without pre-incubation. Unlike conventional bacterial culture and detection methods, which rely on incubation of a sample to increase the concentration of bacteria to detectable levels, this method confines individual bacteria into droplets nanoliters in volume. When single cells are confined into plugs of small volume such that the loading is less than one bacterium per plug, the detection time is proportional to plug volume. Confinement increases cell density and allows released molecules to accumulate around the cell, eliminating the pre-incubation step and reducing the time required to detect the bacteria. We refer to this approach as ‘stochastic confinement’. Using the microfluidic hybrid method, this technology was used to determine the antibiogram – or chart of antibiotic sensitivity – of methicillin-resistant Staphylococcus aureus (MRSA) to many antibiotics in a single experiment and to measure the minimal inhibitory concentration (MIC) of the drug cefoxitin (CFX) against this strain. In addition, this technology was used to distinguish between sensitive and resistant strains of S. aureus in samples of human blood plasma. High-throughput microfluidic techniques combined with single-cell measurements also enable multiple tests to be performed simultaneously on a single sample containing bacteria. This technology may provide a method of rapid and effective patient-specific treatment of bacterial infections and could be extended to a variety of applications that require multiple functional tests of bacterial samples on reduced timescales. [ABSTRACT FROM AUTHOR]

Published

2008

8. Characterization of the local temperature in space and time around a developing Drosophila embryo in a microfluidic device.

Author

Elena M. Lucchetta, Matthew S. Munson, and Rustem F. Ismagilov

Published

2006

9. Multi-step synthesis of nanoparticles performed on millisecond time scale in a microfluidic droplet-based system.

Author

Ilya Shestopalov, Joshua D. Tice, and Rustem F. Ismagilov

Published

2004