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VCSEL-Based Optical Trapping Systems for Microfluidic Applications

Author: Andrea Kroner
Publisher: Cuvillier Verlag
ISBN: 3736936273
Category : Technology & Engineering
Languages : en
Pages : 164

Book Description
Optical trapping and manipulation by laser beams offers the unique possibility to handle single micrometer-sized particles such as living cells without any mechanical contact, damage or contamination. A second hot topic in biology is microfluidics, where the examination of biological samples in channel structures with widths below 100 µm reduces the used sample volume significantly. While the combination of both techniques results in attractive lab-on-a-chip structures for particle sorting and analysis, the commonly bulky trapping setup is contradictory to the miniaturized concept. Here, the use of vertical-cavity surface-emitting lasers (VCSELs) as light sources in optical trapping systems allows a strong reduction of the setup complexity owing to the small dimensions, low cost and high beam quality of these devices. This thesis gives a detailed study on optical manipulation systems based on vertically emitting laser diodes. A standard optical tweezers setup as well as a novel, miniaturized system, the so-called integrated optical trap are investigated. The latter aims for particle separation and sorting in microfluidics resulting in low-cost, portable modules. A classical optical tweezers system based on a high numerical aperture objective in combination with a VCSEL light source is investigated. Standard multi-mode as well as single-mode surface relief VCSELs are used as laser source. With both kinds of VCSELs, optical trapping of polystyrene particles of sizes ranging from 4 to 15µm is demonstrated with some milliwatts of optical power at the sample stage. A maximum trapping force of 4.4 pN for 15 µm particles is achieved with the multi-mode laser, proving the suitability of multi-mode lasers for optical manipulation despite their inferior beam profile. By using two-dimensional VCSEL arrays instead of solitary lasers, the system is extended to a multiple optical tweezers setup in a straightforward manner. To avoid any additional optics, densely packed VCSEL arrangements with a device spacing of less than 25 µm are used, where a novel fabrication process allows the seamless integration of the inverted surface relief technique for enhanced beam quality. By electrical switching between individual devices of the array, non-mechanical particle translation with velocities of up to 12 µm/s is achieved. With a tilted linear VCSEL array, an optical lattice is generated in the optical tweezers setup, and continuous deflection of particles is realized. By substituting the sample stage in the optical tweezers setup with a microfluidic chip fabricated from polydimethylsiloxane (PDMS), particle redirection at a channel junction is realized using a solitary VCSEL source as well as a tilted linear VCSEL array. For the latter, the particles are deflected when passing the optical lattice, thus, the position of the lasers is fixed and no moving parts are necessary, which further reduces the setup complexity. To achieve a drastic miniaturization of the trapping setup, namely the integrated optical trap, the laser source is placed directly underneath the sample chamber. A weakly focused laser beam is generated in the particle solution by integrating an additional microlens on the VCSEL output facet. To determine appropriate lens geometries, the beam propagation inside the integrated trap structure is calculated and the thermal reflow process for lens fabrication is studied in detail concerning lens diameter, reflow temperature and substrate material. By combining the microlens with the inverted relief technique, the quality of the focused beam is strongly improved with respect to divergence, transverse beam profile and beam diameter, where a minimum of 7 µm is measured at the focal point. With first solitary integrated optical traps, deflection, levitation and transverse trapping of 10 µm polystyrene particles is demonstrated for optical powers of 5mW. In a next step, integrated optical trap arrays are realized based on closely spaced twodimensional arrangements of lensed relief VCSELs. To transfer the continuous deflection scheme demonstrated in the classical tweezers setup to the integrated trap, linear arrays of parallel working VCSELs are investigated. To support the design of the multiple integrated trap structure, a simulation of the optical deflection process is performed. Here, a dependence on the geometric and material properties of the particles is predicted, so applications in microfluidic particle sorting are intended. Compact and portable modules are obtained by integrating the laser chip with the microfluidic chip using flip-chip bonding. Although the finished modules show strong heating of the VCSEL chip resulting in a significant reduction of the device performance, simultaneous trapping as well as continuous particle deflection was successfully demonstrated with a total optical power of just 5mW. The results presented in this work demonstrate the potential of VCSELs as laser sources for optical trapping and microparticle manipulation. In conventional optical tweezers setups, the use of VCSELs reduces the setup complexity significantly, while first prototypes of ultra-compact integrated optical traps based on VCSELs confirm the feasibility of portable and inexpensive microfluidic sorting systems.

VCSEL-Based Optical Trapping Systems for Microfluidic Applications

Author: Andrea Kroner
Publisher: Cuvillier Verlag
ISBN: 3736936273
Category : Technology & Engineering
Languages : en
Pages : 164

Monolithically Integrated Transceiver Chips for Bidirectional Optical Data Transmission

Author: Alexander Kern
Publisher: BoD – Books on Demand
ISBN: 3734720877
Category : Technology & Engineering
Languages : en
Pages : 197

Book Description
Vertical-cavity surface-emitting lasers (VCSELs) emitting at 850 nm wavelength are known for their attractive optical features and a continuously growing range of applications. The main goal of the present thesis is to demonstrate the feasibility of a monolithical integration of VCSELs with PIN-type photodiodes (PDs) for the operation as transceiver (TRx) chips in optical data links. The project milestones comprise the chip and the epitaxial layer design of the VCSEL–PIN PD device based on a traditional AlGaAs/GaAs material system, its fabrication development, electro-optical characterizations, and data transmission in a bidirectional optical link over a single, two-side butt-coupled standard graded-index (GI) multimode fiber (MMF). The monolithic design lowers the costs in the semiconductor technology as well as in packaging and additionally avoids the use of external optics, even though it is employed with a single 50 μm core diameter GI MMF. Thus, the very compact optical link saves space, weight, and module cost. Deep insights into the electro-optical properties of VCSELs and PIN PDs are given by the theoretical description and measurements. The limitations of small-signal modulation responses are of main interest of this thesis. Thus, the dynamic characteristics including the extraction of modeled parasitics are presented. Also the electrical and optical crosstalk between the integrated devices and both transmission channels as well as the fiber alignment tolerances are covered. The results in optical data transmission consisting of various experiments in half-duplex and full-duplex mode, both free-space and fiber-coupled over a single MMF are comprised. The monolithic TRx design is well suited for low-cost, compact optical links over distances of a few hundred meters. Capable to handle data rates of up to 10 Gbit/s and more, these TRx chips can be employed, e.g., to upgrade existing standard MMF networks to bidirectional operation or in mobile, low-cost, automotive networks.

Microfluidic Integration of a Double-Nanohole Optical Trap with Applications

Author: Ana Zehtabi-Oskuie
Publisher:
ISBN:
Category :
Languages : en
Pages :

Book Description
This thesis presents optical trapping of various single nanoparticles, and the method for integrating the optical trap system into a microfluidic channel to examine the trapping stiffness and to study binding at the single molecule level.Optical trapping is the capability to immobilize, move, and manipulate small objects in a gentle way. Conventional trapping methods are able to trap dielectric particles with size greater than 100 nm. Optical trapping using nanostructures has overcome this limitation so that it has been of interest to trap nanoparticles for bio-analytical studies. In particular, aperture optical trapping allows for trapping at low powers, and easy detection of the trapping events by noting abrupt jumps in the transmission intensity of the trapping beam through the aperture. Improved trapping efficiency has been achieved by changing the aperture shape from a circle; for example, to a rectangle, double nanohole (DNH), or coaxial aperture. The DNH has the advantage of a well-defined trapping region between the two cusps where the nanoholes overlap, which typically allows only single particle trapping due to steric hindrance. Trapping of 21 nm encapsulated quantum dot has been achieved which shows optical trapping can be used in technologies that seek to place a quantum dot at a specific location in a plasmonic or nanophotonic structure.The DNH has been used to trap and unfold a single protein. The high signal-to-noise ratio of 33 in monitoring single protein trapping and unfolding shows a tremendous potential for using the double nanohole as a sensor for protein binding events at a single molecule level. The DNH integrated in a microfluidic chip with flow to show that stable trapping can be achieved under reasonable flow rates of a few ?L/min. With such stable trapping under flow, it is possible to envision co-trapping of proteins to study their interactions. Co-trapping is achieved for the case where we flow in a protein (bovine serum albumin--BSA) and co-trap its antibody (anti-BSA).

Microfabricated Systems and MEMS VI

Author: Peter J. Hesketh
Publisher: The Electrochemical Society
ISBN: 9781566773720
Category : Microelectromechanical systems
Languages : en
Pages : 268

Book Description

Biological Applications of Microfluidics

Author: Frank A. Gomez
Publisher: John Wiley & Sons
ISBN: 0470074833
Category : Science
Languages : en
Pages : 562

Book Description
Microfluidics has numerous potential applications in biotechnology, pharmaceuticals, the life sciences, defense, public health, and agriculture. This book details recent advances in the biological applications of microfluidics, including cell sorting, DNA sequencing on-a-chip, microchip capillary electrophoresis, and synthesis on a microfluidic format. It covers microfabricated LOC technologies, advanced microfluidic tools, microfluidic culture platforms for stem cell and neuroscience research, and more. This is an all-in-one, hands-on resource for analytical chemists and researchers and an excellent text for students.

Applications of Microfluidic Chips in Optical Manipulation & Photoporation

Author: Robert Frank Marchington
Publisher:
ISBN:
Category : Biochips
Languages : en
Pages : 364

Book Description

Fundamentals of BioMEMS and Medical Microdevices

Author: Steven Saliterman
Publisher: SPIE Press
ISBN: 9780819459770
Category : Medical
Languages : en
Pages : 644

Book Description
The world is on the threshold of a revolution that will change medicine and how patients are treated forever. Bringing together the creative talents of electrical, mechanical, optical and chemical engineers, materials specialists, clinical-laboratory scientists, and physicians, the science of biomedical microelectromechanical systems (bioMEMS) promises to deliver sensitive, selective, fast, low cost, less invasive, and more robust methods for diagnostics, individualized treatment, and novel drug delivery. This book is an introduction to this multidisciplinary technology and the current state of micromedical devices in use today. The first text of its kind dedicated to bioMEMS training. Fundamentals of BioMEMS and Medical Microdevices is Suitable for a single semester course for senior and graduate-level students, or as an introduction to others interested or already working in the field.

Optofluidics: Fundamentals, Devices, and Applications

Author: Yeshaiahu Fainman
Publisher: McGraw Hill Professional
ISBN: 0071601570
Category : Technology & Engineering
Languages : en
Pages : 545

Book Description
Publisher's Note: Products purchased from Third Party sellers are not guaranteed by the publisher for quality, authenticity, or access to any online entitlements included with the product. Cutting-Edge Optofluidics Theories, Techniques, and Practices Add novel functionalities to your optical design projects by incorporating state-of-the-art microfluidic technologies and tools. Co-written by industry experts, Optofluidics: Fundamentals, Devices, and Applications covers the latest functional integration of optical devices and microfluidics, as well as automation techniques. This authoritative guide explains how to fabricate optical lab-on-a-chip devices, synthesize photonic crystals, develop solid and liquid core waveguides, use fluidic self-assembly methods, and accomplish direct microfabrication in solutions. The book includes details on developing biological sensors and arrays, handling maskless lithography, designing high-Q cavities, and working with nanoscale plasmonics. Research outcomes from the DARPA-funded Center for Optofluidics Integration are also discussed. Discover how to: Work with optofluidic sources, lenses, filters, switches, and splitters Use dielectric waveguiding devices to input, move, and manipulate fluids Integrate colloidal crystals and fibers with microfluidic systems Develop bio-inspired fluidic lens systems and aspherical lenses Deploy miniaturized dye lasers, microscopes, biosensors, and resonators Analyze microfluidic systems using flow injection and fluorescent spectroscopy Build optofluidic direct fabrication platforms for innovative microstructures Accomplish optofluidic liquid actuation and particle manipulation

The Nanobiotechnology Handbook

Author: Yubing Xie
Publisher: CRC Press
ISBN: 1439838690
Category : Medical
Languages : en
Pages : 694

Book Description
A thorough overview of nanobiotechnology and its place in advances in applied science and engineering, The Nanobiotechnology Handbook combines contributions from physics, bioorganic and bioinorganic chemistry, molecular and cellular biology, materials science, and medicine as well as from mechanical, electrical, chemical, and biomedical engineering to address the full scope of current and future developments. World-class experts discuss the role of nanobiotechnology in bioanalysis, biomolecular and biomedical nanotechnology, biosensors, biocatalysis and biofuel, and education and workforce development. It includes a companion CD that contains all figures in the book. The book begins with discussions of biomimetic nanotechnology, including a comprehensive overview of DNA nanostructure and DNA-inspired nanotechnology, aptamer-functionalized nanomaterials as artificial antibodies, artificial enzymes, molecular motors, and RNA structures and RNA-inspired nanotechnology. It shows how nanotechnology can be inspired by nature as well as adverse biological events in diagnostic and therapeutic development. From there, the chapters cover major important and widely used nanofabrication techniques, applications of nanotechnology for bioprocessing followed by coverage of the applications of atomic force microscopy (AFM), optical tweezers and nanofluidics as well as other nanotechnology-enabled biomolecular and cellular manipulation and detection. Focusing on major research trends, the book highlights the importance of nanobiotechnology to a range of medical applications such as stem cell technology and tissue engineering, drug development and delivery, imaging, diagnostics, and therapeutics. And with coverage of topics such as nanotoxicity, responsible nanotechnology, and educational and workforce development, it provides a unique overview and perspective of nanobiotechnology impacts from a researcher’s, entrepreneur’s, economist’s and educator’s point of view. It provides a resource for current applications and future development of nanobiotechnology.

Optical Trapping and Manipulation

Author: Philip Jones
Publisher: MDPI
ISBN: 303943537X
Category : Technology & Engineering
Languages : en
Pages : 128

Book Description
We are pleased to present “Optical Trapping and Manipulation: From Fundamentals to Applications”, a Special Issue of Micromachines dedicated to the latest research in optical trapping. In recognition of the broad impact of optical manipulation techniques across disciplines, this Special Issue collected contributions related to all aspects of optical trapping and manipulation. Both theoretical and experimental studies were welcome, and applications of optical manipulation methods in fields including (but not limited to) single molecule biophysics, cell biology, nanotechnology, atmospheric chemistry, and fundamental optics were particularly welcome in order to showcase the breadth of the current research. The Special Issue accepted diverse forms of contributions, including research papers, short communications, methods, and review articles representing the state-of-the-art in optical trapping.