Multi-parametric rigid and flexible, low-cost, disposable sensing platforms for biomedical applications

Anastasova, Salzitsa; Kassanos, Panagiotis; Yang, Guang

doi:10.1016/j.bios.2017.10.038

Cited by 46 publications

(31 citation statements)

References 21 publications

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“…The sharp increase in development and testing of new biomaterials in recent years means that there is a real need for higher throughput screening systems in the biomedical field to accelerate the development of new and improved implant biomaterials with lower costs [1][2][3][4]. Conventional in vitro cell culture experimental set-ups are used in early stages of development to characterize cell culture/biomaterials interactions.…”

Section: Introductionmentioning

confidence: 99%

Development of a multiparametric (bio)sensing platform for continuous monitoring of stress metabolites

Chmayssem

Verplanck

Tanase

et al. 2021

Talanta

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There is a growing need for real-time monitoring of metabolic products that could reflect cell damages over extended periods. In this paper, we report the design and development of an original multiparametric (bio)sensing platform that is tailored for the real-time monitoring of cell metabolites derived from cell cultures. Most attractive features of our developed electrochemical (bio)sensing platform are its easy manufacturing process, that enables seamless scale-up, modular and versatile approach, and low cost. In addition, the developed platform allows a multiparametric analysis instead of single-analyte analysis. Here we provide an overview of the sensors-based analysis of four main factors that can indicate a possible cell deterioration problem during cell-culture: pH, hydrogen peroxide, nitric oxide/nitrite and lactate. Herein, we are proposing a sensors platform based on thick-film coupled to microfluidic technology that can be integrated into any microfluidic system using Luer-lock connectors. This platform allows obtaining an accurate analysis of the secreting stress metabolites during cell/tissues culture.

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Section: Introductionmentioning

confidence: 99%

Development of a multiparametric (bio)sensing platform for continuous monitoring of stress metabolites

Chmayssem

Verplanck

Tanase

et al. 2021

Talanta

View full text Add to dashboard Cite

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“…Alternatively, if this is not the case or possible, additional sensors must be used to corroborate impedance measurements. One example is tissue ischemia measurements where measurement of tissue pH, Na + , K + , lactate and glucose, as well as near infrared spectroscopy (NIRS) can be used in conjunction with bioimpedance measurements [133]- [135]. These are all non-specific indirect markers or ischemia, but together they provide a holistic analysis of tissue dynamics.…”

Section: The Issue Of Selectivitymentioning

confidence: 99%

Bioimpedance Sensors: A Tutorial

Kassanos

2021

IEEE Sensors J.

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Electrical bioimpedance entails the measurement of the electrical properties of tissues as a function of frequency. It is thus a spectroscopic technique. It has been applied in a plethora of biomedical applications for diagnostic and monitoring purposes. In this tutorial, the basics of electrical bioimpedance sensor design will be discussed. The electrode/electrolyte interface is thoroughly described, as well as methods for its modelling with equivalent circuits and computational tools. The design optimization and modelling of bipolar and tetrapolar bioimpedance sensors is presented in detail, based on the sensitivity theorem. Analytical and numerical modelling approaches for electric field simulations based on conformal mapping, point electrode approximations and the finite element method (FEM) are also elaborated. Finally, current trends on bioimpedance sensors are discussed followed by an overview of instrumentation methods for bioimpedance measurements, covering aspects of voltage signal excitations, current sources, voltage measurement front-end topologies and methods for computing the electrical impedance.

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“…The pictures of these platforms are shown in Fig. 6; they are divided into two rigid platforms for in vitro liquid sample measurement and two flexible platforms for postoperative intestinal tissue testing [59]. To demonstrate their detection performance, the detection results of the four platforms .…”

Section: Lab-on-pcb For Detecting Electrolytesmentioning

confidence: 99%

The review of Lab‐on‐PCB for biomedical application

et al. 2020

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Prevention of infectious diseases, diagnosis of diseases, and determination of treatment options all rely on biosensors to detect and analyze biomarkers, which are usually divided into four parts: cell analysis, biochemical analysis, immunoassay, and molecular diagnosis. However, traditional biosensing devices are expensive, bulky, and require a lot of time to detect, which also limited its application in resource‐limited areas. In recent years, Lab‐on‐PCB, which combines biosensing technology and PCB technology, has been widely used in biomedical applications due to its high integration, personalized design, and easy mass production. Among these Lab‐on‐PCB sensing devices, the PCB circuit plays an important role. It can be directly used as a resistance sensor to count cells, and also used as a control device to automatically control the detection device. Flexible PCBs can be used to make wearable medical biosensors. In addition, due to the high degree of integration of the PCB circuit, Lab‐on‐PCB can perform multiple inspections on the same platform, which reduces the inspection time equivalently. Therefore, in this review paper, we discuss the application of Lab‐on‐PCB in four analysis methods of cell analysis, biochemical analysis, immunoassay, and molecular diagnosis, and give some suggestions for improvement and future development trends at the end.

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Multi-parametric rigid and flexible, low-cost, disposable sensing platforms for biomedical applications

Cited by 46 publications

References 21 publications

Development of a multiparametric (bio)sensing platform for continuous monitoring of stress metabolites

Development of a multiparametric (bio)sensing platform for continuous monitoring of stress metabolites

Bioimpedance Sensors: A Tutorial

The review of Lab‐on‐PCB for biomedical application

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