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Liquid crystals (LCs) were discovered more than a century ago, and were, for a long time, treated as a physical curiosity, until the development of flat panel screens and display devices caused a revolution in the information display industry, and in fact in society. There would be no mobile phones without liquid crystals, no flat screen TVs or computer monitors, no virtual reality, just to name a few of the applications that have changed our whole world of vision and perception. All of these inventions are based on liquid crystals that are formed through a change in temperature, thermotropic LCs. However, there is another form of liquid crystals, described even earlier, yet much less talked about; the lyotropic liquid crystals that occur through the change of concentration of some molecules in a solvent. These are found in abundance in nature, making up the cell membranes, and are used extensively in the food, detergents and cosmetics industries. In this collection of articles by experts in their respective research areas, we bring together some of the most recent and innovative aspects of lyotropic liquid crystals, which we believe will drive future research and set novel trends in this field.

Lyotropic liquid crystals --- uniaxial nematic phase --- biaxial nematic phase --- stabilization of nematic phases --- micelle --- surfactants --- chromonics --- structure --- physico-chemical properties --- rods --- curved surface --- Potts --- liquid crystal --- graphene oxide --- lyotropic --- colloid --- nematic --- lyotropic liquid crystals --- SmC* phase --- chirality --- ferroelectricity --- hydrogen bonds --- hydration forces --- cellulose nanocrystals --- hydroxypropyl cellulose --- chiral nematic --- cholesteric liquid crystals --- colloidal suspensions --- kinetic arrest --- gelation --- glass formation --- coffee-ring effect --- bragg reflection --- chromonic --- amphiphilic --- colloidal --- application --- biaxial nematic transition --- field behavior --- diluted nematic systems --- lyotropic liquid crystal --- nanomaterial --- mesogen --- phase behavior

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Liquid crystals (LCs) were discovered more than a century ago, and were, for a long time, treated as a physical curiosity, until the development of flat panel screens and display devices caused a revolution in the information display industry, and in fact in society. There would be no mobile phones without liquid crystals, no flat screen TVs or computer monitors, no virtual reality, just to name a few of the applications that have changed our whole world of vision and perception. All of these inventions are based on liquid crystals that are formed through a change in temperature, thermotropic LCs. However, there is another form of liquid crystals, described even earlier, yet much less talked about; the lyotropic liquid crystals that occur through the change of concentration of some molecules in a solvent. These are found in abundance in nature, making up the cell membranes, and are used extensively in the food, detergents and cosmetics industries. In this collection of articles by experts in their respective research areas, we bring together some of the most recent and innovative aspects of lyotropic liquid crystals, which we believe will drive future research and set novel trends in this field.

Research & information: general --- Lyotropic liquid crystals --- uniaxial nematic phase --- biaxial nematic phase --- stabilization of nematic phases --- micelle --- surfactants --- chromonics --- structure --- physico-chemical properties --- rods --- curved surface --- Potts --- liquid crystal --- graphene oxide --- lyotropic --- colloid --- nematic --- lyotropic liquid crystals --- SmC* phase --- chirality --- ferroelectricity --- hydrogen bonds --- hydration forces --- cellulose nanocrystals --- hydroxypropyl cellulose --- chiral nematic --- cholesteric liquid crystals --- colloidal suspensions --- kinetic arrest --- gelation --- glass formation --- coffee-ring effect --- bragg reflection --- chromonic --- amphiphilic --- colloidal --- application --- biaxial nematic transition --- field behavior --- diluted nematic systems --- lyotropic liquid crystal --- nanomaterial --- mesogen --- phase behavior

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Electrical and electro-optical biosensing technologies are critical to the development of innovative POCT devices, which can be used by both professional and untrained personnel for the provision of necessary health information within a short time for medical decisions to be determined, being especially important in an era of global pandemics. This Special Issue includes a few pioneering works concerning biosensors utilizing electrochemical impedance, localized surface plasmon resonance, and the bioelectricity of sensing materials in which the amount of analyte is pertinent to the signal response. The presented results demonstrate the potential of these label-free biosensing approaches in the detection of disease-related small-molecule metabolites, proteins, and whole-cell entities.

printed circuit board --- sensor electrode --- electrochemical sensor --- printed biosensors --- printing technologies --- electrochemistry --- point-of-care --- ovarian cancer --- nanowire biosensor --- nanowire --- silicon-on-insulator --- CA 125 --- antibodies --- liquid crystal --- photopolymer --- UV exposure --- bovine serum albumin --- protein assay --- dielectric spectroscopy --- lyotropic chromonic liquid crystal --- label-free biosensor --- optical biosensor --- immunoassay --- transmission spectrometry --- spoof localized surface plasmon polariton --- sensor --- glucose solution --- millimeter wave --- metamaterial --- spin-coating --- single-substrate --- cancer biomarker CA125 --- dengue virus --- dengue serotype --- mosquito-borne viral disease --- virus detection --- electrochemical impedance spectroscopy --- cancer cells --- dielectrophoresis --- crossover frequency --- electrical impedance spectroscopy --- n/a