Development and evaluation of a calibration free exhaustive coulometric detection system for remote sensing.

Most quantitative analytical measurement techniques require calibration to correlate signal with the quantity of analyte. The purpose of this study was to employ exhaustive coulometry, an implementation of coulometric analysis in a stopped-flow, fixed-volume, thin-layer cell, to attain calibration-free measurements that would directly benefit intervention-free analysis systems designed for remote deployment. This technique capitalizes on the short diffusion lengths (\u3c 100 µm) to dramatically reduce the time for analysis (\u3c 30 sec). For this work, a thin-layer fluidic cell was designed in software, fabricated via CNC machining, and evaluated using Ferri/Ferrocyanide {Fe(CN)63-/4-} as a model analyte. The 2 µL fixed volume incorporated an oval, 8mm by 4 mm, thin-film gold electrode sensor with an integrated Ag|AgCl pseudo-reference electrode. The flow cell area matched the shape of the sensor, with a volume set by the thickness of a laser-cut silicone rubber gasket (~80 µm). A semi-permeable membrane isolated the working electrode and counter electrode chambers to prevent analyte diffusion. A miniaturized custom potentiostat was designed and built to measure reaction currents ranging from 10 mA to 0.1 nA. Software was developed to perform step voltammetry as well as cyclic voltammetry analysis for verifying electrode condition and optimal redox potential levels. Experimentally determined oxidation/reduction potentials of -100 mV and 400 mV, respectively, were applied to the working electrode for sample concentrations ranging from 50 µM to 10,000 µM. The current generated during the reactions was recorded and the total charge captured at each concentration was obtained by integrating the amperograms. When compared to the expected charge for a 2 µL sample, the total charge vs. concentration plots displayed a near perfect linearity over the full concentration range, and the expected charge (100 % converted) was reached within 20 seconds. The reaction currents ideally should have decayed to background levels, but exhibited constant offset values slightly larger than the background signal, a phenomenon assumed to be lingering residual flow from sample injection. After adding rigid tubing and external valves, the thin-layer cell was shown to remain within 6% of the theoretical charge after 200 seconds. Continued development of this system will offer the possibility of remote, calibration-free determinations of real-world analytes such mercury and lead

Hybrid microfluidic CMOS capacitive sensors for lab-on-chip applications

Methods and applications of CMOS-based Locs -- Hybrid microfluidic/cmos platform -- Cmos based capacitive sensors for locs -- Direct-write microfluidic packaging procedure -- Core-cbcm capacitive sensor array for locs

Micro/nanofluidic and lab-on-a-chip devices for biomedical applications

Micro/Nanofluidic and lab-on-a-chip devices have been increasingly used in biomedical research [1]. Because of their adaptability, feasibility, and cost-efficiency, these devices can revolutionize the future of preclinical technologies. Furthermore, they allow insights into the performance and toxic effects of responsive drug delivery nanocarriers to be obtained, which consequently allow the shortcomings of two/three-dimensional static cultures and animal testing to be overcome and help to reduce drug development costs and time [2–4]. With the constant advancements in biomedical technology, the development of enhanced microfluidic devices has accelerated, and numerous models have been reported. Given the multidisciplinary of this Special Issue (SI), papers on different subjects were published making a total of 14 contributions, 10 original research papers, and 4 review papers. The review paper of Ko et al. [1] provides a comprehensive overview of the significant advancements in engineered organ-on-a-chip research in a general way while in the review presented by Kanabekova and colleagues [2], a thorough analysis of microphysiological platforms used for modeling liver diseases can be found. To get a summary of the numerical models of microfluidic organ-on-a-chip devices developed in recent years, the review presented by Carvalho et al. [5] can be read. On the other hand, Maia et al. [6] report a systematic review of the diagnosis methods developed for COVID-19, providing an overview of the advancements made since the start of the pandemic. In the following, a brief summary of the research papers published in this SI will be presented, with organs-on-a-chip, microfluidic devices for detection, and device optimization having been identified as the main topics.info:eu-repo/semantics/publishedVersio

Establishment of a fully automatized microfluidic platform for the screening and characterization of novel Hepatitis B virus capsid assembly modulators

El procés de descobriment de fàrmacs s'enfronta a importants desafiaments a causa de la constant disminució dels guanys per medicament atesa la disminució en les noves aprovacions de la FDA combinada amb el constant augment dels costos i el temps de desenvolupament. Les plataformes integrades de detecció usant microfluídica van sorgir com a possibles solucions per accelerar el desenvolupament de molècules actives i reduir els requisits de temps i costos. El projecte VIRO-FLOW té com a objectiu identificar nous agents curatius per al virus de l'hepatitis B (VHB), integrant els avantatges de la química de flux continu amb tecnologies de bioassaigs in vitro en microfluídica. Durant aquesta tesi es va construir un sistema microfluídic aplicant dispositius modulars automatitzats. Es van redactar protocols d'avaluació per a les dades de fluorescència i reflexió, permetent el càlcul del factor Z, les desviacions estàndard, les corbes de dilució i els valors de concentracions efectives mitjanes màximes (EC50). La proteïna central del VHB (HBc) es va seleccionar com a objectiu principalEl proceso de descubrimiento de fármacos se enfrenta a importantes desafíos debido a la constante disminución de las ganancias por medicamento dada la disminución en las nuevas aprobaciones de la FDA combinada con el constante aumento de los costes y el tiempo de desarrollo. Las plataformas integradas de detección usando microfluídica surgieron como posibles soluciones para acelerar el desarrollo de moléculas activas y reducir los requisitos de tiempo y costes. El proyecto VIRO-FLOW tiene como objetivo la identificación de nuevos agentes curativos para el virus de la hepatitis B (VHB), integrando las ventajas de la química de flujo continuo con tecnologías de bioensayos in vitro en microfluídica. Durante la presente tesis se construyó un sistema microfluídico aplicando dispositivos modulares automatizados. Se redactaron protocolos de evaluación para los datos de fluorescencia y reflexión, permitiendo el cálculo del factor Z, desviaciones estándar, curvas de dilución y valores de concentraciones efectivas medias máximas (EC50). La proteína central del VHB (HBc) se seleccionó como objetivo principal.Drug Discovery as known today faces major challenges due to the constant decrease of earnings per drug given the decrease in new FDA approvements combined with the steadily rising development costs and time. Integrated microfluidic screening platforms emerged as possible solutions by accelerating the hit-to-lead development cycle and reducing time and cost requirements. The VIRO-FLOW project aims at the fast and efficient identification of novel curative agents for the Hepatitis B Virus (HBV), integrating the advantages of continuous flow chemistry with in vitro microfluidic bioassay technologies. During the present thesis a microfluidic system was built, applying automatized modular devices. Evaluation protocols were written for the fluorescence and reflection data, allowing the Z´-factor calculation, standard deviations, dilution curves, and half‐maximal effective concentrations (EC50) values. HBV core protein (HBc) was selected as primary target due to the ongoing demand for a functional cure to reduce the economic and social challenges imposed by the chronic diseas

Factories of the Future

Engineering; Industrial engineering; Production engineerin

Factories of the Future

Engineering; Industrial engineering; Production engineerin

Glassy Materials Based Microdevices

Microtechnology has changed our world since the last century, when silicon microelectronics revolutionized sensor, control and communication areas, with applications extending from domotics to automotive, and from security to biomedicine. The present century, however, is also seeing an accelerating pace of innovation in glassy materials; as an example, glass-ceramics, which successfully combine the properties of an amorphous matrix with those of micro- or nano-crystals, offer a very high flexibility of design to chemists, physicists and engineers, who can conceive and implement advanced microdevices. In a very similar way, the synthesis of glassy polymers in a very wide range of chemical structures offers unprecedented potential of applications. The contemporary availability of microfabrication technologies, such as direct laser writing or 3D printing, which add to the most common processes (deposition, lithography and etching), facilitates the development of novel or advanced microdevices based on glassy materials. Biochemical and biomedical sensors, especially with the lab-on-a-chip target, are one of the most evident proofs of the success of this material platform. Other applications have also emerged in environment, food, and chemical industries. The present Special Issue of Micromachines aims at reviewing the current state-of-the-art and presenting perspectives of further development. Contributions related to the technologies, glassy materials, design and fabrication processes, characterization, and, eventually, applications are welcome

Modern Applications in Optics and Photonics: From Sensing and Analytics to Communication

Optics and photonics are among the key technologies of the 21st century, and offer potential for novel applications in areas such as sensing and spectroscopy, analytics, monitoring, biomedical imaging/diagnostics, and optical communication technology. The high degree of control over light fields, together with the capabilities of modern processing and integration technology, enables new optical measurement systems with enhanced functionality and sensitivity. They are attractive for a range of applications that were previously inaccessible. This Special Issue aims to provide an overview of some of the most advanced application areas in optics and photonics and indicate the broad potential for the future