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Author: Casey Carter Glick Publisher: ISBN: Category : Languages : en Pages : 302
Book Description
Microfluidics, the science and engineering of fluid at small scales, affords numerous benefits for applications in chemistry and biology, including rapid reaction rates, reaction uniformity and precision, and reagent minimization but the technology remains limited by the availability of appropriate control mechanisms and related microfluidic components. Microfluidic devices have traditionally been fabricated using soft-lithography, which is time-consuming, costly, and reliant on extensive facilities. Over the past decade, research has shifted towards developing alternate methods such as additive manufacturing (widely known as three-dimensional (3D) printing) to fabricate microfluidic structures. This dissertation has developed three methods for resolving the fabrication and control problems of microfluidics using a combination of standard microfluidic/MEMS techniques with newer 3D printing techniques: optofluidic lithographic microfluidic circuitry, 3D-printed transfer molding, and fully-3D-printed fluidic circuitry. The basic theory of microfluidic control systems, including the hydraulic analogy and fluidic circuitry, the low Reynolds number approximation to the Navier-Stokes equations, and neglectable terms in microfluidic models are first investigated. Optofluidic lithography, where photocurable liquids are selectively solidified under UV exposure, is utilized as a means of fabricating moving microfluidic structures within a microchannel. Several variants of microfluidic control mechanisms are demonstrated, including current sources (for regulation of fluid flow-rates to $29.2 \pm 0.8$ \si{\micro\liter/min} for pressures from $5-10$ kPa), and microfluidic gain valves (for controlling a high-pressure channel with a low-pressure one to achieve a dynamic gain of $6.30 \pm 0.23$). A hybrid manufacturing process, where 3D printed polymer molds are used to make multi-layer PDMS constructions by employing unique molding, bonding, alignment, and rapid assembly processes. Specifically, a novel single-layer, two-sided molding method is developed to realize two channels levels, non-planar membranes/valves, vertical interconnects (vias) between channel levels, and built-in inlet/outlet ports for fast linkages to external fluidic systems. As a demonstration, a single-layer membrane micro-valve is constructed, dramatically reducing the number of fabrication steps. Additionally, multilayer structures are fabricated through an intra-layer bonding procedure which uses custom 3D printed stamps to selectively apply uncured liquid PDMS adhesive only to bonding interfaces without clogging fluidic channels. Using built-in alignment marks to accurately position both stamps and individual layers, this technique is demonstrated by rapidly assembling a six-layer microfluidic device. By using the multi-jet-based additive manufacturing, fully-3D-printed microfluidic circuitry components are demonstrated, including fluidic resistors, capacitors, diodes (for a diodicity of $80.6 \pm 1.8$), and transistors (for a dynamic pressure gain of $3.01 \pm 0.78$) through the combination of experimental, simulation, and analytical methods, which are integrated complex microfluidic circuits, such as half- and full-wave microfluidic rectifiers. The hydraulic analogy circuitry exhibits similar transfer functions to its electronic counterparts, but ultimately behaves more similarly to vacuum triodes than to actual transistors. When combined with fully-realized microfluidic IF-gate and CMOS-analog components, this research may allow for fabrication of analog microfluidic operational-amplifiers, which could allow for fully-analog control of microfluidic systems using high-gain amplification of small pressure signals, and the CAD-based nature of the design process makes it simple for researchers to readily combine multiple microfluidic components into larger integrated microfluidic circuit networks.
Author: Casey Carter Glick Publisher: ISBN: Category : Languages : en Pages : 302
Book Description
Microfluidics, the science and engineering of fluid at small scales, affords numerous benefits for applications in chemistry and biology, including rapid reaction rates, reaction uniformity and precision, and reagent minimization but the technology remains limited by the availability of appropriate control mechanisms and related microfluidic components. Microfluidic devices have traditionally been fabricated using soft-lithography, which is time-consuming, costly, and reliant on extensive facilities. Over the past decade, research has shifted towards developing alternate methods such as additive manufacturing (widely known as three-dimensional (3D) printing) to fabricate microfluidic structures. This dissertation has developed three methods for resolving the fabrication and control problems of microfluidics using a combination of standard microfluidic/MEMS techniques with newer 3D printing techniques: optofluidic lithographic microfluidic circuitry, 3D-printed transfer molding, and fully-3D-printed fluidic circuitry. The basic theory of microfluidic control systems, including the hydraulic analogy and fluidic circuitry, the low Reynolds number approximation to the Navier-Stokes equations, and neglectable terms in microfluidic models are first investigated. Optofluidic lithography, where photocurable liquids are selectively solidified under UV exposure, is utilized as a means of fabricating moving microfluidic structures within a microchannel. Several variants of microfluidic control mechanisms are demonstrated, including current sources (for regulation of fluid flow-rates to $29.2 \pm 0.8$ \si{\micro\liter/min} for pressures from $5-10$ kPa), and microfluidic gain valves (for controlling a high-pressure channel with a low-pressure one to achieve a dynamic gain of $6.30 \pm 0.23$). A hybrid manufacturing process, where 3D printed polymer molds are used to make multi-layer PDMS constructions by employing unique molding, bonding, alignment, and rapid assembly processes. Specifically, a novel single-layer, two-sided molding method is developed to realize two channels levels, non-planar membranes/valves, vertical interconnects (vias) between channel levels, and built-in inlet/outlet ports for fast linkages to external fluidic systems. As a demonstration, a single-layer membrane micro-valve is constructed, dramatically reducing the number of fabrication steps. Additionally, multilayer structures are fabricated through an intra-layer bonding procedure which uses custom 3D printed stamps to selectively apply uncured liquid PDMS adhesive only to bonding interfaces without clogging fluidic channels. Using built-in alignment marks to accurately position both stamps and individual layers, this technique is demonstrated by rapidly assembling a six-layer microfluidic device. By using the multi-jet-based additive manufacturing, fully-3D-printed microfluidic circuitry components are demonstrated, including fluidic resistors, capacitors, diodes (for a diodicity of $80.6 \pm 1.8$), and transistors (for a dynamic pressure gain of $3.01 \pm 0.78$) through the combination of experimental, simulation, and analytical methods, which are integrated complex microfluidic circuits, such as half- and full-wave microfluidic rectifiers. The hydraulic analogy circuitry exhibits similar transfer functions to its electronic counterparts, but ultimately behaves more similarly to vacuum triodes than to actual transistors. When combined with fully-realized microfluidic IF-gate and CMOS-analog components, this research may allow for fabrication of analog microfluidic operational-amplifiers, which could allow for fully-analog control of microfluidic systems using high-gain amplification of small pressure signals, and the CAD-based nature of the design process makes it simple for researchers to readily combine multiple microfluidic components into larger integrated microfluidic circuit networks.
Author: Tasoglu Savas Publisher: ISBN: 9783038974680 Category : Electronic books Languages : en Pages : 1
Book Description
3D printing has revolutionized the microfabrication prototyping workflow over the past few years. With the recent improvements in 3D printing technologies, highly complex microfluidic devices can be fabricated via single-step, rapid, and cost-effective protocols as a promising alternative to the time consuming, costly and sophisticated traditional cleanroom fabrication. Microfluidic devices have enabled a wide range of biochemical and clinical applications, such as cancer screening, micro-physiological system engineering, high-throughput drug testing, and point-of-care diagnostics. Using 3D printing fabrication technologies, alteration of the design features is significantly easier than traditional fabrication, enabling agile iterative design and facilitating rapid prototyping. This can make microfluidic technology more accessible to researchers in various fields and accelerates innovation in the field of microfluidics. Accordingly, this Special Issue seeks to showcase research papers, short communications, and review articles that focus on novel methodological developments in 3D printing and its use for various biochemical and biomedical applications.
Author: Andreas Manz Publisher: Royal Society of Chemistry ISBN: 1782628339 Category : Science Languages : en Pages : 307
Book Description
Responding to the need for an affordable, easy-to-read textbook that introduces microfluidics to undergraduate and postgraduate students, this concise book will provide a broad overview of the important theoretical and practical aspects of microfluidics and lab-on-a-chip, as well as its applications.
Author: Wing Cheung Mak Publisher: Elsevier ISBN: 012823847X Category : Technology & Engineering Languages : en Pages : 370
Book Description
Microfluidic Biosensors provides a comprehensive overview covering the most recent emerging technologies on the design, fabrication, and integration of microfluidics with transducers. These form various integrated microfluidic biosensors with device configurations ranging from 2D to 4D levels. Coverage also includes advanced printed microfluidic biosensors, flexible microfluidics for wearable biosensors, autonomous lab-on-a-chip biosensors, CMOS-base microanalysis systems, and microfluidic devices for mobile phone biosensing. The editors and contributors of this book represent both academia and industry, come from a varied range of backgrounds, and offer a global perspective. This book discusses the design and principle of microfluidic systems and uses them for biosensing applications. The microfluidic fabrication technologies covered in this book provide an up-to-date view, allowing the community to think of new ways to overcome challenges faced in this field. The focus is on existing and emerging technologies not currently being analyzed extensively elsewhere, providing a unique perspective and much-needed content. The editors have crafted this book to be accessible to all levels of academics from graduate students, researchers, and professors working in the fields of biosensors, microfluidics design, material science, analytical chemistry, biomedical devices, and biomedical engineering. It can also be useful for industry professionals working for microfluidic device manufacturers, or in the industry of biosensors and biomedical devices. Presents an in-depth overview of microfluidic biosensors and associated emerging technologies such as printed microfluidics and novel transducers Addresses a range of microfluidic biosensors with device configurations ranging from 2D to 4D levels Includes the commercialization aspects of microfluidic biosensors that provide insights for scientists and engineers in research and development
Author: Panagiotis Kyratsis Publisher: Springer Nature ISBN: 3030694720 Category : Technology & Engineering Languages : en Pages : 288
Book Description
This book presents the latest advances in manufacturing from both the experimental and simulation point of view. It covers most aspects of manufacturing engineering, i.e. theoretical, analytical, computational and experimental studies. Experimental studies on manufacturing processes require funds, time and expensive facilities, while numerical simulations and mathematical models can improve the efficiency of using the research results. It also provides high level of prediction accuracy and the basis for novel research directions.
Author: Publisher: Academic Press ISBN: 0323989004 Category : Science Languages : en Pages : 328
Book Description
Micro/Nanofluidics and Lab-on-Chip Based Emerging Technologies for Biomedical and Translational Research Applications, Volume 185, Part A represents the collation of chapters written by eminent scientists worldwide. Chapters in this updated release include An introduction to microfluidics and their applications, Design and fabrication of Micro/Nanofluidics devices and systems, Detection and separation of proteins using Micro/Nanofluidics devices, Micro/Nanofluidics devices for DNA/RNA detection and separation, Paper based microfluidics a forecast towards the most affordable and rapid point-of-care devices, Paper based micro/Nanofluidics devices for biomedical applications, Advances of Microfluidics Devices and their Applications in Personalized Medicine, and much more. Additional chapters cover Microfluidics for single cell analysis, Fluorescence Based Miniaturized Microfluidic and Nanofluidic Systems for Biomedical Applications, Active Matter Dynamics in Confined Microfluidic Environments, Challenges and opportunities in micro/nanofluidics and lab-on-a-chip, and Paper-microfluidic signal-enhanced immunoassays. Offers basic understanding of the state-of-the-art design and fabrication of microfluidics/ nanofluidics and lab-on-chip Explains how to develop microfluidics/nanofluidics for biomedical application such as high throughout biological screening and separation Discusses the applications, challenges and opportunities in biomedical and translational research applications of microfluidics/nanofluidics
Author: Vahid Karamzadeh Publisher: ISBN: Category : Languages : en Pages : 104
Book Description
Microfluidics is a multidisciplinary area comprising several disciplines such as biology, chemistry and tissue engineering, which leads to manipulation and analysis of liquid through micro channels. Microfluidic devices provide numerous advantages for economical point-of-care diagnosis compared to conventional testing devices. In addition, more recently organ-on-a-chip which is a 3D microfluidic network for cell culturing has offered a microfluidic chip that stimulates the response of an organ system which can significantly reduce the costs of developing new pharmaceutical drugs. In spite of multiple advantages of microfluidic devices, barriers exist in current microfabrication methods. Fabrication of microfluidic molds requires cleanroom facilities and is a costly and tedious process which hindered the commercialization of microfluidic chips. Although, using 3D printed molds has been suggested to simplify fabrication of chips, their resolution is limited to 100 om. In addition to these factors, molding process is challenging to fully automate which means that it is in contrast to the vision of cost-effective and mass production of these devices. Therefore, a fully automated, rapid process is required to guide microfluidics towards the development of low-cost more commercially devices. In this thesis, different additive manufacturing methods for fabrication of polymeric microfluidic devices are presented. First, a commercial stereolithography (SLA) 3D printer was used to fabricate 3D printed molds. Limitations and accuracy of using 3D printed templates for microfluidic applications were investigated. Then, the thesis presents a promising additive manufacturing method toward printing a polymer-based device by using an acoustic assisted printing method. This method can significantly simplify and improve fabrication of microfluidic devices. Simulation of the acoustic wave and the heat induced by that were obtained in order to optimize the printing process prior to the experiment. The model provided a good understanding and estimation of acoustic field, temperature rise and focal region size. Time and cost required for fabricating a part by this method is considerably low and no additional post processing is required to turn the printed part to a functional part. The proposed method was finally applied to fabricate a fluidic channel. A fluidic channel can be printed in less than 10 minutes without adding additional components.
Author: Jean-Claude André Publisher: John Wiley & Sons ISBN: 1119437369 Category : Technology & Engineering Languages : en Pages : 356
Book Description
Additive manufacturing, which was first invented in France and then applied in the United States, is now 33 years old and represents a market of around 5 billion euros per year, with annual growth of between 20 and 30%. Today, additive manufacturing is experiencing a great amount of innovation in its processes, software, engineering and materials used. Its strength as a process has more recently allowed for the exploration of new niches, ranging from applications at nanometer and decameter scales, to others in mechanics and health. As a result, the limitations of the process have also begun to emerge, which include the quality of the tools, their cost of manufacture, the multi-material aspects, functionalities and surface conditions. Volume 2 of this series presents the current techniques, improvements and limits of additive manufacturing, providing an up-to-date review of this process.
Author: Albert Folch Publisher: MIT Press ISBN: 026204689X Category : Technology & Engineering Languages : en Pages : 353
Book Description
Stories behind essential microfluidic devices, from the inkjet printer to DNA sequencing chip. Hidden from view, microfluidics underlies a variety of devices that are essential to our lives, from inkjet printers to glucometers for the monitoring of diabetes. Microfluidics—which refers to the technology of miniature fluidic devices and the study of fluids at submillimeter levels—is invisible to most of us because it is hidden beneath ingenious user interfaces. In this book, Albert Folch, a leading researcher in microfluidics, describes the development and use of key microfluidic devices. He explains not only the technology but also the efforts, teams, places, and circumstances that enabled these inventions. Folch reports, for example, that the inkjet printer was one of the first microfluidic devices invented, and traces its roots back to nineteenth-century discoveries in the behavior of fluid jets. He also describes how rapid speed microfluidic DNA sequencers have enabled the sequencing of animal, plant, and microbial species genomes; organs on chips facilitate direct tests of drugs on human tissue, leapfrogging over the usual stage of animal testing; at-home pregnancy tests are based on clever microfluidic principles; microfluidics can be used to detect cancer cells in the early stages of metastasis; and the same technology that shoots droplets of ink on paper in inkjet printers enables 3D printers to dispense layers of polymers. Folch tells the stories behind these devices in an engaging style, accessible to nonspecialists. More than 100 color illustrations show readers amazing images of microfluids under the microscope.
Author: Casey Carter Glick
Author: Casey Carter Glick
Author: Savas Tasoglu
Author: Tasoglu Savas
Author: Andreas Manz
Author: Wing Cheung Mak
Author: Panagiotis Kyratsis
Author: 
Author: Vahid Karamzadeh
Author: Jean-Claude André
Author: Albert Folch