Your search keyword '"Fortunato, Elvira"' showing total 9 results

1. Hybrid Digital-Droplet Microfluidic Chip for Applications in Droplet Digital Nucleic Acid Amplification: Design, Fabrication and Characterization.

Author

Coelho, Beatriz J., Neto, Joana P., Sieira, Bárbara, Moura, André T., Fortunato, Elvira, Martins, Rodrigo, Baptista, Pedro V., Igreja, Rui, and Águas, Hugo

Subjects

MICROFLUIDICS, NUCLEIC acids, BIOLOGICAL assay, DROPLETS

Abstract

Microfluidic-based platforms have become a hallmark for chemical and biological assays, empowering micro- and nano-reaction vessels. The fusion of microfluidic technologies (digital microfluidics, continuous-flow microfluidics, and droplet microfluidics, just to name a few) presents great potential for overcoming the inherent limitations of each approach, while also elevating their respective strengths. This work exploits the combination of digital microfluidics (DMF) and droplet microfluidics (DrMF) on a single substrate, where DMF enables droplet mixing and further acts as a controlled liquid supplier for a high-throughput nano-liter droplet generator. Droplet generation is performed at a flow-focusing region, operating on dual pressure: negative pressure applied to the aqueous phase and positive pressure applied to the oil phase. We evaluate the droplets produced with our hybrid DMF–DrMF devices in terms of droplet volume, speed, and production frequency and further compare them with standalone DrMF devices. Both types of devices enable customizable droplet production (various volumes and circulation speeds), yet hybrid DMF–DrMF devices yield more controlled droplet production while achieving throughputs that are similar to standalone DrMF devices. These hybrid devices enable the production of up to four droplets per second, which reach a maximum circulation speed close to 1540 µm/s and volumes as low as 0.5 nL. [ABSTRACT FROM AUTHOR]

Published

2023

2. A Digital Microfluidics Platform for Loop-Mediated Isothermal Amplification Detection.

Author

Coelho, Beatriz Jorge, Veigas, Bruno, Águas, Hugo, Fortunato, Elvira, Martins, Rodrigo, Baptista, Pedro Viana, and Igreja, Rui

Subjects

MICROFLUIDICS, ISOTHERMAL processes, WAVE amplification, NUCLEIC acids, TEMPERATURE control

Abstract

Digital microfluidics (DMF) arises as the next step in the fast-evolving field of operation platforms for molecular diagnostics. Moreover, isothermal schemes, such as loop-mediated isothermal amplification (LAMP), allow for further simplification of amplification protocols. Integrating DMF with LAMP will be at the core of a new generation of detection devices for effective molecular diagnostics at point-of-care (POC), providing simple, fast, and automated nucleic acid amplification with exceptional integration capabilities. Here, we demonstrate for the first time the role of coupling DMF and LAMP, in a dedicated device that allows straightforward mixing of LAMP reagents and target DNA, as well as optimum temperature control (reaction droplets undergo a temperature variation of just 0.3 °C, for 65 °C at the bottom plate). This device is produced using low-temperature and low-cost production processes, adaptable to disposable and flexible substrates. DMF-LAMP is performed with enhanced sensitivity without compromising reaction efficacy or losing reliability and efficiency, by LAMP-amplifying 0.5 ng/μL of target DNA in just 45 min. Moreover, on-chip LAMP was performed in 1.5 μL, a considerably lower volume than standard bench-top reactions. [ABSTRACT FROM AUTHOR]

Published

2017

3. Digital Microfluidics for Nucleic Acid Amplification.

Author

Coelho, Beatriz, Veigas, Bruno, Fortunato, Elvira, Martins, Rodrigo, Águas, Hugo, Igreja, Rui, and Baptista, Pedro V.

Abstract

Digital Microfluidics (DMF) has emerged as a disruptive methodology for the control and manipulation of low volume droplets. In DMF, each droplet acts as a single reactor, which allows for extensive multiparallelization of biological and chemical reactions at a much smaller scale. DMF devices open entirely new and promising pathways for multiplex analysis and reaction occurring in a miniaturized format, thus allowing for healthcare decentralization from major laboratories to point-of-care with accurate, robust and inexpensive molecular diagnostics. Here, we shall focus on DMF platforms specifically designed for nucleic acid amplification, which is key for molecular diagnostics of several diseases and conditions, from pathogen identification to cancer mutations detection. Particular attention will be given to the device architecture, materials and nucleic acid amplification applications in validated settings. [ABSTRACT FROM AUTHOR]

Published

2017

4. Simulated and Real Sheet-of-Light 3D Object Scanning Using a-Si:H Thin Film PSD Arrays.

Author

Contreras, Javier, Tornero, Josep, Ferreira, Isabel, Martins, Rodrigo, Gomes, Luis, and Fortunato, Elvira

Subjects

POSITION sensitive particle detectors, SILICON, HYDROGEN, THREE-dimensional imaging, OPTICAL sensors, THIN films

Abstract

AMATLAB/SIMULINK software simulation model (structure and component blocks) has been constructed in order to view and analyze the potential of the PSD (Position Sensitive Detector) array concept technology before it is further expanded or developed. This simulation allows changing most of its parameters, such as the number of elements in the PSD array, the direction of vision, the viewing/scanning angle, the object rotation, translation, sample/scan/simulation time, etc. In addition, results show for the first time the possibility of scanning an object in 3D when using an a-Si:H thin film 128 PSD array sensor and hardware/software system. Moreover, this sensor technology is able to perform these scans and render 3D objects at high speeds and high resolutions when using a sheet-of-light laser within a triangulation platform. As shown by the simulation, a substantial enhancement in 3D object profile image quality and realism can be achieved by increasing the number of elements of the PSD array sensor as well as by achieving an optimal position response from the sensor since clearly the definition of the 3D object profile depends on the correct and accurate position response of each detector as well as on the size of the PSD array. [ABSTRACT FROM AUTHOR]

Published

2015

5. Field Effect Sensors for Nucleic Acid Detection: Recent Advances and Future Perspectives.

Author

Veigas, Bruno, Fortunato, Elvira, and Baptista, Pedro V.

Subjects

*FIELD-effect devices, *BIOSENSORS, *DNA analysis, *FIELD-effect transistors, *MOLECULAR recognition

Abstract

In the last decade the use of field-effect-based devices has become a basic structural element in a new generation of biosensors that allow label-free DNA analysis. In particular, ion sensitive field effect transistors (FET) are the basis for the development of radical new approaches for the specific detection and characterization of DNA due to FETs' greater signal-to-noise ratio, fast measurement capabilities, and possibility to be included in portable instrumentation. Reliable molecular characterization of DNA and/or RNA is vital for disease diagnostics and to follow up alterations in gene expression profiles. FET biosensors may become a relevant tool for molecular diagnostics and at point-of-care. The development of these devices and strategies should be carefully designed, as biomolecular recognition and detection events must occur within the Debye length. This limitation is sometimes considered to be fundamental for FET devices and considerable efforts have been made to develop better architectures. Herein we review the use of field effect sensors for nucleic acid detection strategies--from production and functionalization to integration in molecular diagnostics platforms, with special focus on those that have made their way into the diagnostics lab. [ABSTRACT FROM AUTHOR]

Published

2015

6. Micro Cantilever Movement Detection with an Amorphous Silicon Array of Position Sensitive Detectors.

Author

Contreras, Javier, Costa, Daniel, Pereira, Sonia, Fortunato, Elvira, Martins, Rodrigo, Wierzbicki, Rafal, Heerlein, Holger, and Ferreira, Isabel

Subjects

AMORPHOUS semiconductors, DETECTORS, CANTILEVERS, ELECTRONIC systems, ELECTRONICS, SILICON

Abstract

The movement of a micro cantilever was detected via a self constructed portable data acquisition prototype system which integrates a linear array of 32 1D amorphous silicon position sensitive detectors (PSD). The system was mounted on a microscope using a metal structure platform and the movement of the 30 μm wide by 400 μm long cantilever was tracked by analyzing the signals acquired by the 32 sensor array electronic readout system and the relevant data algorithm. The obtained results show a linear behavior of the photocurrent relating X and Y movement, with a non-linearity of about 3%, a spatial resolution of less than 2 μm along the lateral dimension of the sensor as well as of less than 3 μm along the perpendicular dimension of the sensor, when detecting just the micro-cantilever, and a spatial resolution of less than 1 μm when detecting the holding structure. [ABSTRACT FROM AUTHOR]

Published

2010

7. Transduction Mechanisms, Micro-Structuring Techniques, and Applications of Electronic Skin Pressure Sensors: A Review of Recent Advances.

Author

dos Santos, Andreia, Fortunato, Elvira, Martins, Rodrigo, Águas, Hugo, and Igreja, Rui

Subjects

*PRESSURE sensors, *ARTIFICIAL skin, *GENETIC transduction, *SKIN, *LASER engraving, *TRIBOELECTRICITY

Abstract

Electronic skin (e-skin), which is an electronic surrogate of human skin, aims to recreate the multifunctionality of skin by using sensing units to detect multiple stimuli, while keeping key features of skin such as low thickness, stretchability, flexibility, and conformability. One of the most important stimuli to be detected is pressure due to its relevance in a plethora of applications, from health monitoring to functional prosthesis, robotics, and human-machine-interfaces (HMI). The performance of these e-skin pressure sensors is tailored, typically through micro-structuring techniques (such as photolithography, unconventional molds, incorporation of naturally micro-structured materials, laser engraving, amongst others) to achieve high sensitivities (commonly above 1 kPa−1), which is mostly relevant for health monitoring applications, or to extend the linearity of the behavior over a larger pressure range (from few Pa to 100 kPa), an important feature for functional prosthesis. Hence, this review intends to give a generalized view over the most relevant highlights in the development and micro-structuring of e-skin pressure sensors, while contributing to update the field with the most recent research. A special emphasis is devoted to the most employed pressure transduction mechanisms, namely capacitance, piezoelectricity, piezoresistivity, and triboelectricity, as well as to materials and novel techniques more recently explored to innovate the field and bring it a step closer to general adoption by society. [ABSTRACT FROM AUTHOR]

Published

2020

8. Fast Prototyping Microfluidics: Integrating Droplet Digital Lamp for Absolute Quantification of Cancer Biomarkers.

Author

Oliveira, Beatriz, Veigas, Bruno, Fernandes, Alexandra R., Águas, Hugo, Martins, Rodrigo, Fortunato, Elvira, and Baptista, Pedro Viana

Subjects

MICROFLUIDICS, DROPLETS, ACID analysis, LAMPS, REVERSE transcriptase, MANUFACTURING processes, BIOLOGICAL tags

Abstract

Microfluidic (MF) advancements have been leveraged toward the development of state-of-the-art platforms for molecular diagnostics, where isothermal amplification schemes allow for further simplification of DNA detection and quantification protocols. The MF integration with loop-mediated isothermal amplification (LAMP) is today the focus of a new generation of chip-based devices for molecular detection, aiming at fast and automated nucleic acid analysis. Here, we combined MF with droplet digital LAMP (ddLAMP) on an all-in-one device that allows for droplet generation, target amplification, and absolute quantification. This multilayer 3D chip was developed in less than 30 minutes by using a low-cost and extremely adaptable production process that exploits direct laser writing technology in "Shrinky-dinks" polystyrene sheets. ddLAMP and target quantification were performed directly on-chip, showing a high correlation between target concentration and positive droplet score. We validated this integrated chip via the amplification of targets ranging from five to 500,000 copies/reaction. Furthermore, on-chip amplification was performed in a 10 µL volume, attaining a limit of detection of five copies/µL under 60 min. This technology was applied to quantify a cancer biomarker, c-MYC, but it can be further extended to any other disease biomarker. [ABSTRACT FROM AUTHOR]

Published

2020

9. E-Skin Bimodal Sensors for Robotics and Prosthesis Using PDMS Molds Engraved by Laser †.

Author

dos Santos, Andreia, Pinela, Nuno, Alves, Pedro, Santos, Rodrigo, Farinha, Ricardo, Fortunato, Elvira, Martins, Rodrigo, Águas, Hugo, and Igreja, Rui

Subjects

PROSTHETICS, POLYDIMETHYLSILOXANE, PIEZORESISTIVE devices, PHOTOLITHOGRAPHY, TEMPERATURE sensors

Abstract

Electronic skin (e-skin) is pursued as a key component in robotics and prosthesis to confer them sensing properties that mimic human skin. For pressure monitoring, a great emphasis on piezoresistive sensors was registered due to the simplicity of sensor design and readout mechanism. For higher sensitivity, films composing these sensors may be micro-structured, usually by expensive photolithography techniques or low-cost and low-customizable molds. Sensors commonly present different sensitivities in different pressure ranges, which should be avoided in robotics and prosthesis applications. The combination of pressure sensing and temperature is also relevant for the field and has room for improvement. This work proposes an alternative approach for film micro-structuration based on the production of highly customizable and low-cost molds through laser engraving. These bimodal e-skin piezoresistive and temperature sensors could achieve a stable sensitivity of −6.4 × 10−3 kPa−1 from 1.6 kPa to 100 kPa, with a very robust and reproducible performance over 27,500 cycles of objects grasping and releasing and an exceptionally high temperature coefficient of resistance (TCR) of 8.3%/°C. These results point toward the versatility and high benefit/cost ratio of the laser engraving technique to produce sensors with a suitable performance for robotics and functional prosthesis. [ABSTRACT FROM AUTHOR]

Published

2019