3,431 research outputs found

    Advanced sensors technology survey

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    This project assesses the state-of-the-art in advanced or 'smart' sensors technology for NASA Life Sciences research applications with an emphasis on those sensors with potential applications on the space station freedom (SSF). The objectives are: (1) to conduct literature reviews on relevant advanced sensor technology; (2) to interview various scientists and engineers in industry, academia, and government who are knowledgeable on this topic; (3) to provide viewpoints and opinions regarding the potential applications of this technology on the SSF; and (4) to provide summary charts of relevant technologies and centers where these technologies are being developed

    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

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    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

    High-precision fluorescence photometry for real-time biomarkers detection

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    Les derniers évènements planétaires et plus particulièrement l'avènement sans précédent du nouveau coronavirus augmente la demande pour des appareils de test à proximité du patient. Ceux-ci fonctionnent avec une batterie et peuvent identifier rapidement des biomarqueurs cibles. Pareils systèmes permettent aux utilisateurs, disposant de connaissances limitées en la matière, de réagir rapidement, par exemple dans la détection d'un cas positif de COVID-19. La mise en œuvre de l'élaboration d'un tel instrument est un projet multidisciplinaire impliquant notamment la conception de circuits intégrés, la programmation, la conception optique et la biologie, demandant tous une maîtrise pointue des détails. De plus, l'établissement des spécifications et des exigences pour mesurer avec précision les interactions lumière-échantillon s'additionnent au besoin d'expérience dans la conception et la fabrication de tels systèmes microélectriques personnalisés et nécessitent en elles-mêmes, une connaissance approfondie de la physique et des mathématiques. Ce projet vise donc à concevoir et à mettre en œuvre un appareil sans fil pour détecter rapidement des biomarqueurs impliqués dans des maladies infectieuses telles que le COVID-19 ou des types de cancers en milieu ambulatoire. Cette détection se fait grâce à des méthodes basées sur la fluorescence. La spectrophotométrie de fluorescence permet aux médecins d'identifier la présence de matériel génétique viral ou bactérien tel que l'ADN ou l'ARN et de les caractériser. Les appareils de paillasse sont énormes et gourmand énergétiquement tandis que les spectrophotomètres à fluorescence miniatuarisés disponibles dans le commerce sont confrontés à de nombreux défis. Ces appareils miniaturisés ont été découverts en tirant parti des diodes électroluminescentes (DEL) à semi-conducteurs peu coûteuses et de la technologie des circuits intégrés. Ces avantages aident les scientifiques à réduire les erreurs possibles, la consommation d'énergie et le coût du produit final utilisé par la population. Cependant, comme leurs homologues de paillasse, ces appareils POC doivent quantifier les concentrations en micro-volume d'analytes sur une large gamme de longueurs d'onde suivant le cadre d'une économie en ressources. Le microsystème envisagé bénéficie d'une approche de haute précision pour fabriquer une puce microélectronique CMOS. Ce procédé se fait de concert avec un boîtier personnalisé imprimé en 3D pour réaliser le spectrophotomètre à la fluorescence nécessaire à la détection quantitative d'analytes en microvolume. En ce qui a trait à la conception de circuits, une nouvelle technique de mise à auto-zeroing est appliquée à l'amplificateur central, celui-ci étant linéarisé avec des techniques de recyclage et de polarisation adaptative. Cet amplificateur central est entièrement différentiel et est utilisé dans un amplificateur à verrouillage pour récupérer le signal d'intérêt éclipsé par le bruit. De plus, l'augmentation de la sensibilité de l'appareil permet des mesures quantitatives avec des concentrations en micro-volume d'analytes ayant moins d'erreurs de prédiction de concentration. Cet avantage cumulé à une faible consommation d'énergie, un faible coût, de petites dimensions et un poids léger font de notre appareil une solution POC prometteuse dans le domaine de la spectrophotométrie de fluorescence. La validation de ce projet s'est fait en concevant, fabriquant et testant un prototype discret et sans fil. Son article de référence a été publié dans IEEE LSC 2018. Quant à la caractérisation et l'interprétation du prototype d'expériences in vitro à l'aide d'une interface MATLAB personnalisée, cet article a été publié dans IEEE Sensors journal (2021). Les circuits intégrés et les photodétecteurs ont été fabriqués ont été conçus et fabriqués par Cadence en 2019. Relativement aux solutions de circuit proposées, elles ont été fabriquées avec la technologie CMOS 180 nm et publiées lors de la conférence IEEE MWSCAS 2020. Tout comme cette dernière contribution, les expériences in vitro avec le dispositif proposé incluant la puce personnalisée et le boîtier imprimé en 3D ont été réalisés et les résultats électriques et optiques ont été soumis au IEEE Journal of Solid-State Circuits (JSSC 2022).The most recent and unprecedented experience of the novel coronavirus increases the demand for battery-operated near-patient testing devices that can rapidly identify the target biomarkers. Such systems enable end-users with limited resources to quickly get feedback on various medical tests, such as detecting positive COVID-19 cases. Implementing such a device is a multidisciplinary project dealing with multiple areas of expertise, including integrated circuit design, programming, optical design, and biology, each of which needs a firm grasp of details. Alongside the need for experience in designing and manufacturing custom microelectronic systems, establishing the specifications and requirements to precisely measure the light-sample interactions requires an in-depth knowledge of physics and mathematics. This project aims to design and implement a wireless point-of-care (POC) device to rapidly detect biomarkers involved in infectious diseases such as COVID-19 or different types of cancers in an ambulatory setting using fluorescence-based methods. Fluorescence spectrophotometry allows physicians to identify and characterize viral or bacterial genetic materials such as DNAs or RNAs. The benchtop devices that are currently available are bulky and power-hungry, whereas the commercially available miniaturized fluorescence spectrophotometers are facing many challenges. Many of these difficulties have been resolved in literature thanks to inexpensive semiconductor light-emitting diodes (LEDs) and integrated circuits technology. Such advantages aid scientists in decreasing the size, power consumption, and cost of the final product for end-users. However, like the benchtop counterparts, such POC devices must quantify micro-volume concentrations of analytes across a wide wave length range under an economy of resources. The envisioned microsystem benefits from a high-precision approach to fabricating a CMOS microelectronic chip combined with a custom 3D-printed housing. This implementation results in a fluorescence spectrophotometer for qualitative and quantitative detection of micro-volume analytes. In terms of circuit design, a novel switched-biasing ping-pong auto-zeroed technique is applied to the core amplifier, linearized with recycling and adaptive biasing techniques. The fully differential core amplifier is utilized within a lock-in amplifier to retrieve the signal of interest overshadowed by noise. Increasing the device's sensitivity allows quantitative measurements down to micro-volume concentrations of analytes with less concentration prediction error. Such an advantage, along with low-power consumption, low cost, low weight, and small dimensions, make our device a promising POC solution in the fluorescence spectrophotometry area. The approach of this project was validated by designing, fabricating, and testing a discrete and wireless prototype. Its conference paper was published in IEEE LSC 2018, and the prototype characterization and interpretation of in vitro experiments using a custom MATLAB interface were published in IEEE Sensors Journal (2021). The integrated circuits and photodetectors were designed and fabricated by the Cadence circuit design toolbox (2019). The proposed circuit solutions were fabricated with 180-nm CMOS technology and published at IEEE MWSCAS 2020 conference. As the last contribution, the in vitro experiments with the proposed device, including the custom chip and 3D-printed housing, were performed, and the electrical and optical results were submitted to the IEEE Journal of Solid-State Circuits (JSSC 2022)

    Modular Instrumentation for Controlling and Monitoring In-Vitro Cultivation Environment and Image-based Functionality Measurements of Human Stem Cells

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    Artificial animal cell culture was successfully developed by Ross Harrison in 1907. But it was not until the 1940’s and 1950’s that several developments occurred, which expedited the cell culturing in-vitro (C-Vitro) to be a consistent and reproducible technique to study isolated living-cells in a controlled environment. Currently, CVitro is one of the major tools in cellular and molecular biology both in the academia and industry. They are extensively utilised to study the cellular physiology/biochemistry, to screen drugs/therapeutic compounds, to understand the effects of drugs/toxic compounds and also to identify the pathways of carcinogenesis/mutagenesis. It is also used in large scale manufacturing of vaccines and therapeutic proteins. In any experimental setup, it is important that the C-Vitro model should represent the physiological phenomena of interest with reasonable accuracy so that all experimental results are statistically consistent and reproducible. In this direction, sensors and measurement systems play important roles in in-situ detection and/or control/manipulation of cells/tissues/environment. This thesis aimed to develop new technology for tailored cell culturing and integrated measurements. Firstly, design and assembly of a portable Invert-upright microscope interchangeable modular cell culturing platform (iuCMP) was envisioned. In contrast to conventional methods, micro-scaled systems mimic the cells' natural microenvironment more precisely, facilitating accurate and tractable models. The iuCMP integrates modular measurement schemes with a mini culture chamber using biocompatible cell-friendly materials, automated environment-control (temperature and gas concentrations), oxygen sensing and simultaneous functional measurements (electrophysiological and image-based). Time lapse microscopy is very useful in cell biology, but integration of advanced >i>in-vitro/device based biological systems (e.g. lab/organ/body-on-chips, or mini-bioreactors/microfluidic systems) into conventional microscopes can be challenging in several circumstances due to multiple reasons. But in iuCMP the main advantage is, the microscope can be switched either as an inverted or as an upright system and therefore can accommodate virtually any in-vitro device. It can capture images from regions that are otherwise inaccessible by conventional microscopes, for example, cells cultured on physical or biochemical sensor systems. The modular design also allows accommodating more sensor or measurement systems quite freely. We have demonstrated the system for video-based beating analysis of cardiomyocytes, cell orientation analysis on nanocellulose, and simultaneous long-term in-situ microscopy with oxygen and temperature sensing in hypoxia. In an example application, the system was utilised for long-term temperature stressing and simultaneous mechanobiological analysis of human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs). For this the iuCMP together with a temperature sensor plate (TSP) and a novel non-invasive beating analysis software (CMaN—cardiomyocyte function analysis tool, scripted as a subpart of this thesis), was applied for automated temperature response studies in hiPSC-CM cultures. In-situ temperature sensing is usually challenging with bulky external sensors, but TSPs solved this issue. In the temperature response study, we showed that the relationship between hiPSC-CM beating frequency and temperature is non-linear and measured the Q10 temperature coefficients. Moreover, we observed the hiPSC-CM contractile networking, including propagation of the action potential signal between dissociated clusters and their non-invasive measurements. It was the first case where these events were reported in hiPSC-CM clusters and their noninvasive measurements by image processing. The software CMaN comes with a user-friendly interface and, is equipped with features for batch processing, movement centre detection and cluster finding. It can extract six different signals of the contractile motion of cardiomyocytes (clusters or single cells) per processing. This ensures a minimum of one useful beating signal even in the cases of complex beating videos. On the processing end, compared to similar tools, CMaN is faster, more sensitive, and computationally less expensive and allows ROI based processing. In the case of healthy cells, the waveform of the signal from the CMaN resembles an ECG signal with positive and negative segments, allowing the computation of contraction and relaxation features separately. In addition to iuCMP, a Modular optical pH measurement system (MO-pH) for 24/7 non-contact cell culture measurements was also developed. The MO-pH incorporates modular sterilisable optical parts and is used in phenol-red medium cell cultures. The modular assembly of MO-pH cassettes is unique and reusable. Measurements are carried out in a closed flow system without wasting any culture medium and requires no special manual attention or recalibrations during culture. Furthermore, a new absorption correction model was put forward that minimised errors caused e.g. by biolayers in spectrometric pH measurement, which improved the pH measurement accuracy. MO-pH has been applied in long-term human adipose stem cells (hASC) expansion cultures in CO2 dependent and independent media. Additionally, the MO-pH was also utilised to comprehend the behaviour of pH, temperature and humidity in water jacked incubators as well as to record the pH response as a function of temperature in the presence and absence of CO2 in the context of stem cell cultures. The resulting plots clearly showed the interplay between measured parameters indicating a few stress sources present all through the culture. Additionally, it provided an overall picture of behaviour of critical control parameters in an incubator and pointed out the need for bioprocess systems with automatic process monitoring and smart control for maximum yield, optimal growth and maintenance of the cells. Besides, we also integrated MO-pH into flasks with reclosable lids (RL-F) and tested its applicability in stem cell cultures. A standalone system around an RL-F flask was built by combining the cell culture, medium perfusion and optical measurements. The developed RL-F system has been successfully tested in ASC-differentiation cultures. Finally, a few trial experiments for image-based pH estimation aimed for iuCMP have also been carried out. This includes tests with LCD illumination, optical projection tomography, and webcam systems. In reality, the pH is not distributed uniformly in tissues, and has shown a gradient of up to 1.0 pH unit within 1 cm distance. Therefore, producing reliable pH maps also in in-vitro can be important in understanding various common pathologies and location of lesions. A reliable and adequately developed long-term pH mapping method will be an important addition into the iuCMP

    Fundamentals of SARS-CoV-2 Biosensors

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    COVID-19 diagnostic strategies based on advanced techniques are currently essential topics of interest, with crucial roles in scientific research. This book integrates fundamental concepts and critical analyses that explore the progress of modern methods for the detection of SARS-CoV-2
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