Recent Lipid Membrane-Based Biosensing Platforms

Nikoleli, Georgia‐Paraskevi; Siontorou, Christina G.; Nikolelis, Marianna-Thalia; Bratakou, Spyridoula; Bendos, Dimitrios K.

doi:10.3390/app9091745

Cited by 27 publications

(23 citation statements)

References 97 publications

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“…The incorporation of ion channels is generally preferable in biosensing since they allow for low detection limits. Controlling the orientation of OR within the SLB, however, is still considered a challenge [80].…”

Section: Nanovesiclesmentioning

confidence: 99%

The Emergence of Insect Odorant Receptor-Based Biosensors

Bohbot

Vernick

2020

Biosensors

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The olfactory receptor neurons of insects and vertebrates are gated by odorant receptor (OR) proteins of which several members have been shown to exhibit remarkable sensitivity and selectivity towards volatile organic compounds of significant importance in the fields of medicine, agriculture and public health. Insect ORs offer intrinsic amplification where a single binding event is transduced into a measurable ionic current. Consequently, insect ORs have great potential as biorecognition elements in many sensor configurations. However, integrating these sensing components onto electronic transducers for the development of biosensors has been marginal due to several drawbacks, including their lipophilic nature, signal transduction mechanism and the limited number of known cognate receptor-ligand pairs. We review the current state of research in this emerging field and highlight the use of a group of indole-sensitive ORs (indolORs) from unexpected sources for the development of biosensors.

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Section: Nanovesiclesmentioning

confidence: 99%

The Emergence of Insect Odorant Receptor-Based Biosensors

Bohbot

Vernick

2020

Biosensors

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“…17,18 However, recent works have also demonstrated the possibility of directly introducing a biological interface without any surface modication. 19,20 In this review, we discuss recent progress in the development of biologically interfaced nanoplasmonic sensors with emphasis on the latest strategies employed for surface modication and biological functionalization. We begin by describing the processes involved in the design and fabrication of nanoplasmonic architectures within the context of biological-related applications, highlighting notable design features that have been adopted to facilitate biological interfacing.…”

Section: Bo Kyeong Yoon Is a Research Fellow In The Translationalmentioning

confidence: 99%

Biologically interfaced nanoplasmonic sensors

et al. 2020

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“…Figure 1 shows the function and composition of a biosensor based on lipid film technology, illustrating, also, the physicochemical mechanism for the electrochemical transduction and the most common screening strategies employed. A number of recent articles have appeared in the literature that mainly describe recent advances and applications of various platforms of lipid film-based biosensors [6,[10][11][12][13][14].…”

Section: Jca: November-2019: Page No: 32-40mentioning

confidence: 99%

Nanotechnological advances of Lipid film-based biosensors for the rapid detection of biological compounds and toxicants

Nikoleli

2019

J Chem Appl

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The exploration of lipid membranes for the construction of nanobiosensors has recently provided the opportunity to construct devices to monitor a wide range of compounds of biological interest. Nanobiosensor miniaturization using nanotechnological tools has given novel ways to attach a wide range of “receptors” in the lipid membrane. The lipids used to construct a lipid film-based device are dipalmiloylphosphatidylcholine {DPPC} and in some cases dipalmitoylphosphatidic acid (DPPA) which is an anionic lipid and is used to increase the sensitivity of detection. Most common “receptors” used in lipid film biosensors are enzymes such as urease, cholesterol oxidase, urecase, etc, antibodies such as D-dimer antibody and artificial or natural receptors such as saxitoxin, cholera toxin, calyx [4] arene phospjoryl receptor, etc. This chapter reviews and investigates the construction of nanobiosensors based on lipid membranes that are used to monitor various toxicants. It also exploits examples of applications with an emphasis on novel devices, new nanobiosensing techniques and nanotechnology-based transduction schemes. The compounds that can be detected are insecticides, toxins, hormones, dioxins, etc. Keywords: Lipid membrane based nanosensors; Nanoyechology; Graphene and ZnO electrodes; Food toxicants; Environmental pollutants; Clinical analysis

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Recent Lipid Membrane-Based Biosensing Platforms

Cited by 27 publications

References 97 publications

The Emergence of Insect Odorant Receptor-Based Biosensors

The Emergence of Insect Odorant Receptor-Based Biosensors

Biologically interfaced nanoplasmonic sensors

Nanotechnological advances of Lipid film-based biosensors for the rapid detection of biological compounds and toxicants

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