Genetic Analysis and Cell Manipulation on Microfluidic Surfaces

Personalized cancer medicine is a cancer care paradigm in which diagnostic and therapeutic strategies are customized for individual patients. Microsystems that are created by Micro-Electro-Mechanical Systems (MEMS) technology and integrate various diagnostic and therapeutic methods on a single chip hold great potential to enable personalized cancer medicine. Toward ultimate realization of such microsystems, this thesis focuses on developing critical functional building blocks that perform genetic variation identification (single-nucleotide polymorphism (SNP) genotyping) and specific, efficient and flexible cell manipulation on microfluidic surfaces. For the identification of genetic variations, we first present a bead-based approach to detect single-base mutations by performing single-base extension (SBE) of SNP specific primers on solid surfaces. Successful genotyping of the SNP on exon 1 of HBB gene demonstrates the potential of the device for simple, rapid, and accurate detection of SNPs. In addition, a multi-step solution-based approach, which integrates SBE with mass-tagged dideoxynucleotides and solid-phase purification of extension products, is also presented. Rapid, accurate and simultaneous detection of 4 loci on a synthetic template demonstrates the capability of multiplex genotyping with reduced consumption of samples and reagents. For cell manipulation, we first present a microfluidic device for cell purification with surface-immobilized aptamers, exploiting the strong temperature dependence of the affinity binding between aptamers and cells. Further, we demonstrate the feasibility of using aptamers to specifically separate target cells from a heterogeneous solution and employing environmental changes to retrieve purified cells. Moreover, spatially specific capture and selective temperature-mediated release of cells on design-specified areas is presented, which demonstrates the ability to establish cell arrays on pre-defined regions and to collect only specifically selected cell groups for downstream analysis. We also investigate tunable microfluidic trapping of cells by exploiting the large compliance of elastomers to create an array of cell-trapping microstructures, whose dimensions can be mechanically modulated by inducing uniform strain via the application of external force. Cell trapping under different strain modulations has been studied, and capture of a predetermined number of cells, from single cells to multiple cells, has been achieved. In addition, to address the lack of aptamers for targets of interest, which is a major hindrance to aptamer-based cell manipulation, we present a microfluidic device for synthetically isolating cell-targeting aptamers from a randomized single-strand DNA (ssDNA) library, integrating cell culturing with affinity selection and amplification of cell-binding ssDNA. Multi-round aptamer isolation on a single chip has also been realized by using pressure-driven flow. Finally, some perspectives on future work are presented, and strategies and notable issues are discussed for further development of MEMS/microfluidics-based devices for personalized cancer medicine

Lab-on-PCB Devices

Lab-on-PCB devices can be considered an emerging technology. In fact, most of the contributions have been published during the last 5 years. It is mainly focussed on both biomedical and electronic applications. The book includes an interesting guide for using the different layers of the Printed Circuit Boards for developing new devices; guidelines for fabricating PCB-based electrochemical biosensors, and an overview of fluid manipulation devices fabricated using Printed Circuit Boards. In addition, current PCB-based devices are reported, and studies for several aspects of research and development of lab-on-PCB devices are described

Microfluidic PCR with plasmonic imaging for rapid multiplexed characterization of DNA from microbial pathogens

Bloodstream infections (BSIs) are a critical concern in modern medicine due to their continued prevalence in modern hospitals, along with high costs and attributable mortality, particularly among those who are immunocompromised. The current gold standard for detection and characterization of causative pathogens involves cell culture, which can take 24-48 hours to complete, increasing time to adequate treatment and thus mortality. The rise of antimicrobial resistance in hospital acquired infections has reduced the effectiveness of broad spectrum antimicrobial treatments, resulting in a clear need for a rapid, sensitive technique for characterization of resistance markers in microbial pathogens without cell culture. Here we present the development of a microfluidic platform for polymerase chain reaction (PCR) mediated amplification of microbial gene targets in a continuous flow system for potential coupling with sample preparation systems to reduce time to diagnosis from days to within two hours. This culminated in a thermoelectric cooler mediated fluidic thermocycler with a recirculating assay region for real-time hybridization measurements to minimize assay time. We subsequently demonstrated development of a low-cost optical system for localized surface plasmon resonance imaging using a digital micromirror device and tuned nanoprism monolayers for DNA hybridization with a spectral resolution of 2nm. This LSPR imaging system was integrated in-flow into the microfluidic thermocycler, enabling detection of input E. coli DNA samples at a minimum concentration of 5fg/ [microliter]. We further demonstrated multiplex detection of target markers, indicating potential for assaying target panels for characterization of pathogens. Overall, the studies in this dissertation demonstrate a microfluidic PCR system with built-in sensitive LSPR detection of DNA hybridization. It should serve as a starting point for exploration of and expansion with fluidic sample preparation with a focus on rapid characterization of pathogens.Biomedical Engineerin

Investigations of Storage Root Development in Cassava (\u3ci\u3eManihot esculenta\u3c/i\u3e Crantz)

The tropical root crop cassava is cultivated for its large starchy storage roots. Understanding critical processes in root tuberization is essential if improvement programs are to secure future yields for farmers. Studies were undertaken to identify critical components of storage root development at the anatomical and gene expression levels. Two types of roots were identified from greenhouse-grown stem cuttings: basal roots, which develop from the stem cut end and are prolific in nature, and nodal roots, which originate from the region of the buried axillary bud. Only nodal roots develop to produce storage organs. Anatomical sectioning was performed to determine the origin of both root types. Basal roots were seen to develop from the cambium of the semi-woody stems, while nodal roots originated from deep within the secondary xylem or pith regions. This data contradicts accepted knowledge that storage roots develop from a subset of the fibrous roots. As a result, it is proposed here that storage and basal/fibrous roots are fundamentally different organs, originate through different rhizogenic processes, and are committed to their different developmental fates from initiation onwards. cDNA microarray analysis was performed on roots at different stages of storage root development. Gene Set Enrichment Analysis revealed up-regulation of the jasmonic acid biosynthesis pathway during the initiation stage of tuberization. K-means clustering identified three clusters of up-regulated genes at storage root initiation and later developmental stages, while Heatmap analysis revealed major latex allergen Hev b 4 proteins to be highly up-regulated at the initiation stage. Three candidate genes seen to be highly up-regulated at the later starch filling stages were identified as possible homologues of Mec1, cassava ATDI21 and ENOD40-like genes. RT-PCR analysis revealed their enhanced expression in storage roots compared to fibrous roots and leaves. Mec1 has previously been associated with cassava storage roots, but no reports exist for the involvement of ATDI21 or ENOD40. The homologues of the latter two genes require further characterization to determine their functional role in storage root development. Integration of anatomical studies with functional genomics tools has provided new knowledge of root tuberization in cassava and identified new avenues of research

Analysis of relevant technical issues and deficiencies of the existing sensors and related initiatives currently set and working in marine environment. New generation technologies for cost-effective sensors

The last decade has seen significant growth in the field of sensor networks, which are currently collecting large amounts of environmental data. This data needs to be collected, processed, stored and made available for analysis and interpretation in a manner which is meaningful and accessible to end users and stakeholders with a range of requirements, including government agencies, environmental agencies, the research community, industry users and the public. The COMMONSENSE project aims to develop and provide cost-effective, multi-functional innovative sensors to perform reliable in-situ measurements in the marine environment. The sensors will be easily usable across several platforms, and will focus on key parameters including eutrophication, heavy metal contaminants, marine litter (microplastics) and underwater noise descriptors of the MSFD. The aims of Tasks 2.1 and 2.2 which comprise the work of this deliverable are: • To obtain a comprehensive understanding and an up-to-date state of the art of existing sensors. • To provide a working basis on “new generation” technologies in order to develop cost-effective sensors suitable for large-scale production. This deliverable will consist of an analysis of state-of-the-art solutions for the different sensors and data platforms related with COMMONSENSE project. An analysis of relevant technical issues and deficiencies of existing sensors and related initiatives currently set and working in marine environment will be performed. Existing solutions will be studied to determine the main limitations to be considered during novel sensor developments in further WP’s. Objectives & Rationale The objectives of deliverable 2.1 are: • To create a solid and robust basis for finding cheaper and innovative ways of gathering data. This is preparatory for the activities in other WPs: for WP4 (Transversal Sensor development and Sensor Integration), for WP(5-8) (Novel Sensors) to develop cost-effective sensors suitable for large-scale production, reducing costs of data collection (compared to commercially available sensors), increasing data access availability for WP9 (Field testing) when the deployment of new sensors will be drawn and then realized

Lab-on-a-Chip Fabrication and Application

The necessity of on-site, fast, sensitive, and cheap complex laboratory analysis, associated with the advances in the microfabrication technologies and the microfluidics, made it possible for the creation of the innovative device lab-on-a-chip (LOC), by which we would be able to scale a single or multiple laboratory processes down to a chip format. The present book is dedicated to the LOC devices from two points of view: LOC fabrication and LOC application

Micro/Nano-Chip Electrokinetics

Micro/nanofluidic chips have found increasing applications in the analysis of chemical and biological samples over the past two decades. Electrokinetics has become the method of choice in these micro/nano-chips for transporting, manipulating and sensing ions, (bio)molecules, fluids and (bio)particles, etc., due to the high maneuverability, scalability, sensitivity, and integrability. The involved phenomena, which cover electroosmosis, electrophoresis, dielectrophoresis, electrohydrodynamics, electrothermal flow, diffusioosmosis, diffusiophoresis, streaming potential, current, etc., arise from either the inherent or the induced surface charge on the solid-liquid interface under DC and/or AC electric fields. To review the state-of-the-art of micro/nanochip electrokinetics, we welcome, in this Special Issue of Micromachines, all original research or review articles on the fundamentals and applications of the variety of electrokinetic phenomena in both microfluidic and nanofluidic devices