Přímá klasifikace metagenomických signálů ze sekvenace nanopórem / Direct Binning of Metagenomic Signals from Nanopore Sequencing

Lebó, Marko

January 2019

This diploma thesis deals with taxonomy independent methods for classification of metagenomic signals, aquired by a MinION sequencer. It describes the formation and character of metagenomic data and already existing methods of metagenomic data classification and their development. This thesis also evaluates an impact of the third generation sequencing techniques in the world of metagenomics and further specialises on the function of the Oxford Nanopore MinION sequencing device. Lastly, a custom method for metagenomic data classification, based on data obtained from a MinION sequencer, is proposed and compared with an already existing method of classification.

Expanding the Knowledgebase of Earth’s Microbiome Using Culture Dependent and Independent Methods

Murphy, Trevor

01 June 2021

Microorganisms exist ubiquitously on Earth, yet their functions and ecological roles remain elusive. Investigating these microbes is accomplished by using culture-dependent and culture-independent methodologies. This study employs both methodologies to characterize: 1) the genomic potential of the novel deep-subsurface bacterial isolate Thermanaerosceptrum fracticalcis strain DRI-13T by combining next-generation and nanopore sequencing technologies and 2) the microbiome of the artificial marine environment for the Hawaiian Bobtail Squid in aquaculture using next-generation sequencing of 16S rRNA gene. Microbial ecology of the deep-subsurface remains understudied in terms of microbial diversity and function. The genomic information of DRI-13T revealed a potential for syntrophic relationships, diverse metabolic potential including prophages/antiviral defenses, and novel methylation motifs. Artificial marine environments housing marine the Hawaiian Bobtail Squid (Euprymna scolopes) contain microorganisms that can directly influence animal and aquaculture health. No studies presently show if bacterial communities of the tank environment correlate with the health and productivity of E. scolopes. This study sought to address this by sampling from a year of unproductive aquaculture yield and comparing the bacterial communities from productive cohorts. Bacterial communities from unproductive samples show less bacterial diversity and abundance coupled with shifts in bacterial composition. Nitrate and pH levels between the tanks were found to be strong influences on determining the bacterial populations of productive and unproductive cohorts.

Deep-Subsurface

Genome Assembly

Microbiome

Oxford Nanopore

Sequencing

Electrospun nanofiber meshes: applications in oil absorption, cell patterning, and biosensing

Hersey, Joseph S.

17 February 2016

Nanofabrication techniques produce materials with enhanced physicochemical properties through a combination of nanoscale roughness and the use of chemically diverse polymers which enable advanced applications in separation science (air/water purification), tissue engineering, and biosensing. Since the late 1990’s, electrospinning has been extensively studied and utilized to produce nano- to microfiber meshes with 3D porosity on the gram scale. By combining a high surface area to volume ratio and tunable surface chemistry, electrospinning is a facile platform for generating non-woven polymeric fibers for many biomedical and industrial applications. This thesis describes three applications of electrospun nano- and microfiber meshes spun from both commercially available and novel polymer systems for: 1) oil and water separation after an accidental oil spill; 2) ultraviolet light controlled protein and cell patterning throughout 3-dimensional nanofiber meshes; and 3) novel diagnostic platform by combining electrospun nanofiber meshes with solid state nanopores for enhanced single molecule nucleic acid and protein detection. Each application embodies the philosophy that electrospun materials have the potential to solve a wide variety of problems by simply tuning the physicochemical properties and mesh morphologies towards the design requirements for a specific problem. For example, to solve the problem of recovering crude oil after an oil spill while generating a minimal waste burden, a hydrophobic and biodegradable microfiber mesh was designed to repeatedly separate oil and water and naturally biodegrade after use. In order to solve the problem of spatiotemporal placement of cells within a 3-dimensional tissue engineering construct, an ultraviolet light activated mesh was designed to transition from hydrophobic (water impermeable) to hydrophilic (water permeable) upon exposure to ultraviolet light facilitating protein and cell patterning. Finally to address two problems with single molecule solid state nanopore biosensors, namely rapid nucleic acid translocation rates and limited protein identification capabilities, a new biosensor platform was developed based on two novel polymeric systems which were synthesized and electrospun into high surface area nanofiber mesh coatings. / 2018-02-17T00:00:00Z

Biomedical engineering

Biosensor

Electrospinning

Nanofiber

Nanopore

Stimuli-responsive polymer

Top-Down and Bottom-Up Strategies to Prepare Nanogap Sensors for Controlling and Characterizing Single Biomolecules

January 2019

abstract: My research centers on the design and fabrication of biomolecule-sensing devices that combine top-down and bottom-up fabrication processes and leverage the unique advantages of each approach. This allows for the scalable creation of devices with critical dimensions and surface properties that are tailored to target molecules at the nanoscale. My first project focuses on a new strategy for preparing solid-state nanopore sensors for DNA sequencing. Challenges for existing nanopore approaches include specificity of detection, controllability of translocation, and scalability of fabrication. In a new solid-state pore architecture, top-down fabrication of an initial electrode gap embedded in a sealed nanochannel is followed by feedback-controlled electrochemical deposition of metal to shrink the gap and define the nanopore size. The resulting structure allows for the use of an electric field to control the motion of DNA through the pore and the direct detection of a tunnel current through a DNA molecule. My second project focuses on top-down fabrication strategies for a fixed nanogap device to explore the electronic conductance of proteins. Here, a metal-insulator-metal junction can be fabricated with top-down fabrication techniques, and the subsequent electrode surfaces can be chemically modified with molecules that bind strongly to a target protein. When proteins bind to molecules on either side of the dielectric gap, a molecular junction is formed with observed conductances on the order of nanosiemens. These devices can be used in applications such as DNA sequencing or to gain insight into fundamental questions such as the mechanism of electron transport in proteins. / Dissertation/Thesis / Doctoral Dissertation Physics 2019

Biophysics

Nanoscience

biosensing

DNA

nanogap

nanopore

protein

sequencing

Trajectory-Dependent Simulation of Nanoparticle Translocation

Vieira, Luiz Fernando

26 August 2022

No description available.

Nanoscience

Physics

Polymers

Mechanical Engineering

Nanoparticles

nanopore

diffusion

electrophoresis

translocation

Exploring fast drying and evaporation from nanofluidic conduits

Xiao, Siyang

30 August 2022

Drying and evaporation from nanoscale conduits are two ubiquitous phenomena found in nature. As these two nanoscale liquid-vapor phase change phenomena are significantly “accelerated” compared with the corresponding ones at micro- and macro-scales, various industrial applications, including oil recovery, electronic cooling, membrane desalination, and energy harvesting, have been developed. Despite their important implications, the fundamental mechanisms for these two accelerated phase-change processes have not been completely understood. For drying, it is widely accepted that liquid corner flow and film flow could significantly enhance mass transport in microscale conduits other than the sole contribution by vapor diffusion. However, it is unclear if the same principles apply to smaller scales and if the vapor diffusivity will change at the nanoscale. For evaporation, the evaporation kinetics at the nanoscale interface, rather than liquid/vapor transport toward/from the interface, determine the ultimate transport limit, which can be significantly higher than the classical prediction derived under quasi-equilibrium evaporation conditions. Still, the contributions to such enhanced kinetically limited evaporation remain unclear. This thesis aims to answer these unsolved questions by conducting systematic experimental studies on drying and evaporation from single nanochannels and nanopores. We used state-of-art fabrication to create close-end 2D nanochannels with heights from 29 to 122 nm and measure water drying in such channels using an optical microscope. Combining with the channel confinement study and relative humidity study, we decoupled the individual contributions from vapor and liquid transport to the drying and extracted the water vapor diffusivity in nanochannels. We also developed a hybrid nanochannel-nanopore design to achieve and measure kinetically limited evaporation flux from silicon nitride nanopores and graphene nanopores with pore diameters ranging from 24 to 347 nm. Our results show that the evaporation flux increases with the decreasing diameter for both types of nanopores. Furthermore, graphene nanopores overall exhibit higher evaporation fluxes than silicon nitride nanopores with similar diameters. We attribute the diameter-dependent evaporation flux to the diameter-dependent hydronium ion concentration in silicon nitride nanopores and the edge-facilitated evaporation in graphene nanopores, respectively. We expect this work to advance our understanding of nanoscale fast drying and evaporation and provide design guidance for novel nanoporous membrane evaporators.

Mechanical engineering

Drying

Graphene

Nanofluidic conduits

Nanopore evaporation

Characterization of molecule and particle transport through nanoscale conduits

Alibakhshi, Mohammad Amin

05 November 2016

Nanofluidic devices have been of great interest due to their applications in variety of fields, including energy conversion and storage, water desalination, biological and chemical separations, and lab-on-a-chip devices. Although these applications cross the boundaries of many different disciplines, they all share the demand for understanding transport in nanoscale conduits. In this thesis, different elusive aspects of molecule and particle transport through nanofluidic conduits are investigated, including liquid and ion transport in nanochannels, diffusion- and reaction-governed enzyme transport in nanofluidic channels, and finally translocation of nanobeads through nanopores. Liquid or solvent transport through nanoconfinements is an essential yet barely characterized component of any nanofluidic systems. In the first chapter, water transport through single hydrophilic nanochannels with heights down to 7 nm is experimentally investigated using a new measurement technique. This technique has been developed based on the capillary flow and a novel hybrid nanochannel design and is capable of characterizing flow in both single nanoconduits as well as nanoporous media. The presence of a 0.7 nm thick hydration layer on hydrophilic surfaces and its effect on increasing the hydraulic resistance of the nanochannels is verified. Next, ion transport in a new class of nanofluidic rectifiers is theoretically and experimentally investigated. These so called nanofluidic diodes are nanochannels with asymmetric geometries which preferentially allow ion transport in one direction. A nondimensional number as a function of electrolyte concentration, nanochannel dimensions, and surface charge is derived that summarizes the rectification behavior of this system. In the fourth chapter, diffusion- and reaction-governed enzyme transport in nanofluidic channels is studied and the theoretical background necessary for understanding enzymatic activity in nanofluidic channels is presented. A simple analytical expression that describes different reaction kinetics is derived and confirmed against available experimental data of reaction of Trypsin with Poly-L-lysine. Finally, in the last chapter translocation of nanobeads through synthetic nanopores is experimentally investigated using resistive pulse sensing. The emphasis is placed on elucidating the effect of nanobead size on the translocation current and time. The key goals pursued in this study are multiplex detection of different nanobead sizes in a mixture of nanobeads as well as determining the concentration of each component. This problem other than its fundamental significance paves the way for developing new biosensing mechanisms for detection of biomolecules. This thesis further explores the molecule and particle transport in nanoscale conduits and serves for better characterization and development of nanofluidic devices for various applications.

Nanotechnology

Enzymatic reaction

Ion transport

Nanofluidics

Nanopore sensing

Water transport

DNA Capture and Translocation through Nanopore

Seth, Swarnadeep

01 January 2023

This thesis investigates DNA dynamics and translocation through nanopores using Brownian dynamics (BD) simulations, offering insights into sequencing technologies, DNA marker detection, and accurate barcoding utilizing solid-state nanopore platforms. First, we in silico study the intricate process of capture and translocation in a single nanopore. Our simulation reveals a high probability of hairpin loop formation during the capture process. However, attaching a charged tag to one end of DNA improves multi-scan rates and enhances unidirectional translocations. We use modulating voltage biases to multi-scan a lambda-phage dsDNA with oligonucleotide flap markers (tags) through a single and double nanopore system. Our study shows that the bulkier tags introduce velocity variations along the chain length that lead to potential inaccuracies in genetic distance (barcode) estimations. We introduce an interpolation scheme that incorporates both the tag velocities and the average velocity of the chain to improve barcode precision. Subsequently, we include bead and side-chain tags to explain asymmetric dwell time distributions as observed in double nanopore experiments. Our findings indicate that local charge interactions between tags and the nanopore's electric field introduce dwell time asymmetries that can be used for discriminating tags based on their net charges. Finally, we obtain the current blockades of the molecular motifs attached to a dsDNA using electrokinetic Brownian dynamics (EKBD) simulation. Our simulation demonstrates that divalent salt reduces the translocation speed, facilitating precise measurement of the motif's dwell time. Finally, we formulate a volumetric ansatz to construct current blockade diagrams from the ordinary BD simulation in a computationally efficient way and show that using simple scale factors, these volumetric blockades can be mapped accurately to the ionic current blockades obtained from more expensive EKBD simulation. Our studies present comprehensive explorations of DNA translocation and barcoding methods in solid-state nanopores, demonstrating their utility in nanopore sequencing and nanobiotechnology

Nanopore Translocation

Brownian Dynamics

DNA Capture

Polymer Dynamics

Physics

Application of Long-Read Sequencing in Microbiome Compositional Studies related to Disease

Greenman, Noah

01 January 2024

Metagenomic sequencing has provided scientists with the ability to investigate microbial populations, termed microbiomes, in environmental and clinical settings. Current approaches to metagenomic research involve the use of next-generation sequencing (NGS) to generate short, precise reads for characterization of microbial compositions. While highly accurate, short reads possess several limitations that restrict their application in metagenomic research. Third generation, long-read sequencing technologies may offer several advantages for metagenomic research. Here, we used simulated datasets, as well as experimental data from murine fecal samples, to compare the relative performance of short and long reads for metagenomic research, and their impact on assessing microbial composition. Long-read data demonstrated increased precision for identification of microbiome constituents and assessing abundance without sacrificing sensitivity. Hierarchical clustering of microbiome similarity from paired short- and long-read datasets obtained from murine fecal samples revealed clustering was driven by read type as opposed to sample type, underscoring the importance of sequence type. These findings led us to use long-read sequencing for elucidating the effects of propionic acid (PPA) on the murine gut microbiome. PPA has been shown to induce physiological changes like those observed in autism spectrum disorder (ASD). Individuals with ASD may suffer from gastrointestinal comorbidities, suggesting an association with the gut microbiome. Murine offspring fed a PPA-rich diet were assessed for microbiota perturbations. Our results demonstrated that a PPA-rich diet alters the gut microbiome of progeny mice, selecting for several bacterial species that have previously been found in greater abundance among people iv with ASD. In our study, changes to microbial abundance were also associated with significant variation in bacterial metabolic pathways related to steroid hormone biosynthesis, amino sugar, and nucleotide sugar metabolism. Taken together, our findings provide empirical evidence supporting the use of long-read sequencing in metagenomic research by elucidating links between PPA exposure and gut microbiome composition.

Metagenomics

Sequencing

Long read

Nanopore

Propionic acid

Propionate

Nano-Confined Room-Temperature Ionic Liquids for Electrochemical Applications

He, Yadong

28 February 2018

Room-temperature ionic liquids (RTILs) and their derivatives are promising electrolytes for electrochemical devices including supercapacitors. Understanding the behavior of RTILs in these devices is critical for improving their performance. The energy density of supercapacitors can be improved greatly by using RTILs as electrolytes and nanoporous carbon as electrodes, but the mechanism of the charge storage using these materials is not well understood. In this dissertation, the diffusion and charging dynamics of RTILs in nanopores are studied. The results show that ion packing typically plays the most important role in ion diffusion. The study also demonstrates that the cyclic charging and discharging of a pore can exhibit a number of interesting features (e.g., sloshing of ionic charge along the pores during cyclic scans), which help explain experimental observations such as the negligible contribution of co-ions to charge storage at high scan rates. Solid electrolytes with both high ionic conductivities and excellent mechanical strength are needed in many electrochemical devices. The invention of ion gels featuring aligned polyanions immersed inside RTILs has shown promise in meeting this demand, but the mechanism behind their superior mechanical strength remains elusive. Using molecular simulations, it is discovered that the high elastic moduli of model PBDT ion gels originate from the RTIL-mediated interactions between the polyanions. This insight is useful for future design of ion gels to improve their transport and mechanical properties. / Ph. D. / Room-temperature ionic liquids (RTILs) and their derivatives are promising electrolytes for electrochemical devices including supercapacitors. Understanding the behavior of RTILs in these devices is critical for improving their performance. The energy density of supercapacitors can be improved greatly by using RTILs as electrolytes and nanoporous carbon as electrodes, but the mechanism of the charge storage using these materials is not well understood. In this dissertation, the diffusion and charging dynamics of RTILs in nanopores are studied. The results show that ion packing typically plays the most important role in ion diffusion. The study also demonstrates that the cyclic charging and discharging of a pore can exhibit a number of interesting features (e.g., sloshing of ionic charge along the pores during cyclic scans), which help explain experimental observations such as the negligible contribution of co-ions to charge storage at high scan rates. Solid electrolytes with both high ionic conductivities and excellent mechanical strength are needed in many electrochemical devices. The invention of ion gels featuring aligned polyanions immersed inside RTILs has shown promise in meeting this demand, but the mechanism behind their superior mechanical strength remains elusive. Using molecular simulations, it is discovered that the high elastic moduli of model PBDT ion gels originate from the RTIL-mediated interactions between the polyanions. This insight is useful for future design of ion gels to improve their transport and mechanical properties.

Room-temperature ionic liquids

nanopore

ion gel

molecular dynamics