Monitoring with In Vivo Electrochemical Sensors: Navigating the Complexities of Blood and Tissue Reactivity

Vadgama, Pankaj

doi:10.3390/s20113149

Cited by 19 publications

(12 citation statements)

References 124 publications

(138 reference statements)

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“…Although electrochemical sensors are relatively simple to use and easy to miniaturize, several instances, such as real-time monitoring of critically ill patients in an ICU (intensive care unit) setting, require the use of minimally invasive sensors that can be inserted inside the body with ease. Research demonstrates the development of implantable electrochemical sensors for in vivo monitoring [ 175 , 176 , 177 , 178 ]. However, such in vivo detection strategies require invasive surgery, which is often not feasible for neonates, seniors, or critically ill patients.…”

Section: Outlook: Towards Multimodal Sensor Platformsmentioning

confidence: 99%

Towards Multiplexed and Multimodal Biosensor Platforms in Real-Time Monitoring of Metabolic Disorders

Chung

Nguyen

Zhang

et al. 2022

Sensors

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Metabolic syndrome (MS) is a cluster of conditions that increases the probability of heart disease, stroke, and diabetes, and is very common worldwide. While the exact cause of MS has yet to be understood, there is evidence indicating the relationship between MS and the dysregulation of the immune system. The resultant biomarkers that are expressed in the process are gaining relevance in the early detection of related MS. However, sensing only a single analyte has its limitations because one analyte can be involved with various conditions. Thus, for MS, which generally results from the co-existence of multiple complications, a multi-analyte sensing platform is necessary for precise diagnosis. In this review, we summarize various types of biomarkers related to MS and the non-invasively accessible biofluids that are available for sensing. Then two types of widely used sensing platform, the electrochemical and optical, are discussed in terms of multimodal biosensing, figure-of-merit (FOM), sensitivity, and specificity for early diagnosis of MS. This provides a thorough insight into the current status of the available platforms and how the electrochemical and optical modalities can complement each other for a more reliable sensing platform for MS.

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Section: Outlook: Towards Multimodal Sensor Platformsmentioning

confidence: 99%

Towards Multiplexed and Multimodal Biosensor Platforms in Real-Time Monitoring of Metabolic Disorders

Chung

Nguyen

Zhang

et al. 2022

Sensors

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“…Rong et al (2017) and Cho et al (2020) have summarized the current status of in vivo biosensors in general, and Cai et al (2020) have discussed the methods of characterization, cytotoxicity and animal studies with respect to glucose monitoring. Vadgama (2020) has just published an elegant analysis of the present day issues with in vivo electrochemical sensors; to quote from this paper with respect to the generic problem of biocompatibility, ‘ it has been an inappropriate quest to search for the single material or surface that absolves us from this problem (of developing tools for examining the separate entities at different locations in the reactive, hostile, environment)— the result has simply been more model systems. The quest needs to be more deeply rooted in the study of reactive biology—it is the biological control of the implant site that remains to be resolved ’.…”

Section: The Triad Of Biocompatibility Device Functionality and Biolmentioning

confidence: 99%

mentioning

confidence: 99%

Assessing the triad of biocompatibility, medical device functionality and biological safety

Williams

2020

Med Devices & Sens

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Biomaterials, defined as 'materials designed to take a form that can direct, through interactions with living systems, the course of any therapeutic or diagnostic procedure' (Zhang & Williams, 2019), are used in an increasing number of medical applications (Williams, 2014a). From both engineering and regulatory perspectives, the 'form' that the biomaterials take is usually referred to as a 'device'; the interaction with living systems may occur in vivo or ex vivo. The devices have functions that range from mechanical (joint replacements, heart valves), optical (intra-ocular lenses) and electrical (cardiac pacemakers, deep brain stimulators) to those of complex systems that may incorporate the delivery of molecules to the body (prolonged release of drugs) or involve diagnostic character (imaging contrast agents, continuous glucose measurement).Of all the required properties of the biomaterials and devices, two are of profound importance. These are biocompatibility and functionality. Biocompatibility, defined as 'the ability of a material to perform with an appropriate host response in a specific application', (Zhang & Williams, 2019) encompasses all types of interaction that can occur between the material / device and the host. These interactions can be considered negatively in the sense that they may inhibit the appropriate host response, for example being responsible for blood clots forming within intravascular devices, or positively if they promote superior host responses, for example enhanced bonding with bone in orthopaedic devices. The full spectrum of potential mechanisms of biocompatibility has not yet been identified, but much progress has been made in recent years (Williams 2008;Williams 2017a;Villanueva-Flores et al. 2020). It is difficult to itemize the required functionality characteristics of medical devices since they vary from one applications to another,

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“…Generalizing the problematic solutes as hydrophilic presents a significant opportunity for more robust sensing of hydrophobic solutes since hydrophilic/hydrophobic selective protection could theoretically be added to sensors. Implementing such a hydrophilic/hydrophobic filter would provide protection even beyond the widely deployed size-selective protective membranes such as those used for in vivo glucose sensors − and other EAB sensors . Furthermore, this membrane should filter out redox-active interfering agents such as the negatively charged FAD/FADH2 and NAD+/NADH coenzymes.…”

Section: Introductionmentioning

confidence: 99%

Oil-Membrane Protection of Electrochemical Sensors for Fouling- and pH-Insensitive Detection of Lipophilic Analytes

Yuan

DeBrosse

Kim

et al. 2021

ACS Appl. Mater. Interfaces

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To take full advantage of the reagent- and label-free sensing capabilities of electrochemical sensors, a frequent and remaining challenge is interference and degradation of the sensors due to uncontrolled pH or salinity in the sample solution or foulants from the sample solution. Here, we present an oil-membrane sensor protection technique that allows for the permeation of hydrophobic (lipophilic) analytes into a sealed sensor compartment containing ideal salinity and pH conditions while simultaneously blocking common hydrophilic interferents (proteins, acids, bases, etc.) In this paper, we validate the oil-membrane sensor protection technique by demonstrating continuous cortisol detection via electrochemical aptamer-based (EAB) sensors. The encapsulated EAB cortisol sensor exhibits a 5 min concentration-on rise time and maintains a measurement signal of at least 7 h even in the extreme condition of an acidic solution of pH 3.

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Monitoring with In Vivo Electrochemical Sensors: Navigating the Complexities of Blood and Tissue Reactivity

Cited by 19 publications

References 124 publications

Towards Multiplexed and Multimodal Biosensor Platforms in Real-Time Monitoring of Metabolic Disorders

Towards Multiplexed and Multimodal Biosensor Platforms in Real-Time Monitoring of Metabolic Disorders

Assessing the triad of biocompatibility, medical device functionality and biological safety

Oil-Membrane Protection of Electrochemical Sensors for Fouling- and pH-Insensitive Detection of Lipophilic Analytes

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