M.T. Fernández-Abedul

Bio: M.T. Fernández-Abedul is an academic researcher from University of Oviedo. The author has contributed to research in topics: Working electrode & Detection limit. The author has an hindex of 15, co-authored 45 publications receiving 917 citations. Previous affiliations of M.T. Fernández-Abedul include Harvard University.

Disposable Sensors in Diagnostics, Food, and Environmental Monitoring.

Abstract: Disposable sensors are low-cost and easy-to-use sensing devices intended for short-term or rapid single-point measurements. The growing demand for fast, accessible, and reliable information in a vastly connected world makes disposable sensors increasingly important. The areas of application for such devices are numerous, ranging from pharmaceutical, agricultural, environmental, forensic, and food sciences to wearables and clinical diagnostics, especially in resource-limited settings. The capabilities of disposable sensors can extend beyond measuring traditional physical quantities (for example, temperature or pressure); they can provide critical chemical and biological information (chemo- and biosensors) that can be digitized and made available to users and centralized/decentralized facilities for data storage, remotely. These features could pave the way for new classes of low-cost systems for health, food, and environmental monitoring that can democratize sensing across the globe. Here, a brief insight into the materials and basics of sensors (methods of transduction, molecular recognition, and amplification) is provided followed by a comprehensive and critical overview of the disposable sensors currently used for medical diagnostics, food, and environmental analysis. Finally, views on how the field of disposable sensing devices will continue its evolution are discussed, including the future trends, challenges, and opportunities.

Universal mobile electrochemical detector designed for use in resource-limited applications

Abstract: This paper describes an inexpensive, handheld device that couples the most common forms of electrochemical analysis directly to “the cloud” using any mobile phone, for use in resource-limited settings. The device is designed to operate with a wide range of electrode formats, performs on-board mixing of samples by vibration, and transmits data over voice using audio—an approach that guarantees broad compatibility with any available mobile phone (from low-end phones to smartphones) or cellular network (second, third, and fourth generation). The electrochemical methods that we demonstrate enable quantitative, broadly applicable, and inexpensive sensing with flexibility based on a wide variety of important electroanalytical techniques (chronoamperometry, cyclic voltammetry, differential pulse voltammetry, square wave voltammetry, and potentiometry), each with different uses. Four applications demonstrate the analytical performance of the device: these involve the detection of (i) glucose in the blood for personal health, (ii) trace heavy metals (lead, cadmium, and zinc) in water for in-field environmental monitoring, (iii) sodium in urine for clinical analysis, and (iv) a malarial antigen (Plasmodium falciparum histidine-rich protein 2) for clinical research. The combination of these electrochemical capabilities in an affordable, handheld format that is compatible with any mobile phone or network worldwide guarantees that sophisticated diagnostic testing can be performed by users with a broad spectrum of needs, resources, and levels of technical expertise.

Poly(methylmethacrylate) and Topas capillary electrophoresis microchip performance with electrochemical detection

Abstract: A capillary electrophoresis (CE) microchip made of a new and promising polymeric material: Topas (thermoplastic olefin polymer of amorphous structure), a cyclic olefin copolymer with high chemical resistance, has been tested for the first time with analytical purposes, employing an electrochemical detection. A simple end-channel platinum amperometric detector has been designed, checked, and optimized in a poly-(methylmethacrylate) (PMMA) CE microchip. The end-channel design is based on a platinum wire manually aligned at the exit of the separation channel. This is a simple and durable detection in which the working electrode is not pretreated. H(2)O(2) was employed as model analyte to study the performance of the PMMA microchip and the detector. Factors influencing migration and detection processes were examined and optimized. Separation of H(2)O(2) and L-ascorbic acid (AsA) was developed in order to evaluate the efficiency of microchips using different buffer systems. This detection has been checked for the first time with a microchip made of Topas, obtaining a good linear relationship for mixtures of H(2)O(2) and AsA in different buffers.

Electroanalytical devices with pins and thread

Abstract: An electroanalytical device includes a pin set comprising at least two conductive pins for use as working and counter electrodes, wherein the first and second pins are comprised of a head, a shaft and a piercing tip; and a hydrophobic or omniphobic paper substrate, wherein the substrate is shaped to provide at least one recess for holding a liquid, wherein the shafts of two conductive pins traverse the paper substrate to anchor the heads of the two conductive pins on the recess surface. An electroanalytical device can also include at least two conductive pins for use as working and counter electrodes, a thread, serially wound around the shafts of each of the two conductive pins; and a base into which the piercing tip of each of the pins is secured.

Polymer microfabrication technologies for microfluidic systems

Abstract: Polymers have assumed the leading role as substrate materials for microfluidic devices in recent years. They offer a broad range of material parameters as well as material and surface chemical properties which enable microscopic design features that cannot be realised by any other class of materials. A similar range of fabrication technologies exist to generate microfluidic devices from these materials. This review will introduce the currently relevant microfabrication technologies such as replication methods like hot embossing, injection molding, microthermoforming and casting as well as photodefining methods like lithography and laser ablation for microfluidic systems and discuss academic and industrial considerations for their use. A section on back-end processing completes the overview.

Wearable sweat sensors

Abstract: Sweat potentially contains a wealth of physiologically relevant information, but has traditionally been an underutilized resource for non-invasive health monitoring. Recent advances in wearable sweat sensors have overcome many of the historic drawbacks of sweat sensing and such sensors now offer methods of gleaning molecular-level insight into the dynamics of our bodies. Here we review key developments in sweat sensing technology. We highlight the potential value of sweat-based wearable sensors, examine state-of-the-art devices and the requirements of the underlying components, and consider ways to tackle data integrity issues within these systems. We also discuss challenges and opportunities for wearable sweat sensors in the development of personalized healthcare.

Gold Nanoparticles for In Vitro Diagnostics

Abstract: 1.1. Significance of IVDs in the Clinic IVD test is a crucial component of clinical care that performs a diagnostic test on biological samples that have been taken from a living body, such as blood, urine, and tissue.1 Such tests are usually performed to determine or confirm the presence of disease in an individual. “In vitro” literally means “within the glass”, which indicates that the test was historically conducted in glass test tubes. In contrast, in vivo tests, literally “within the living”, are conducted within a whole, living organism including human body.2 IVD tests have received much public attention because of their distinct features in the medical profession. First, IVD tests do not interact with the human body directly, making such diagnosis accessible without invasive surgeries and thus saving a great deal of suffering. Second, the procedures of IVDs are performed on samples rather than human body, avoiding the possible biological safety problems on patients that often take place in the in vivo diagnostics. Third, an IVD test can quickly provide valuable information on a patient’s healthcare conditions. On the basis of the information, physicians or patients are able to make a timely decision for patient care or treatment. Fourth, the application of IVDs enables early diagnosis and makes treatment of serious diseases easier. Generally, the cost of early testing is much lower than that of the later on extensive treatment. Last, IVDs play a particularly vital role in remote settings for managing outbreaks of acute infectious diseases, where effective but simple diagnostic systems are highly desirable. These features make IVDs unique and of great importance among medical technologies.