Detection of heavy metal ions using whispering gallery mode lasing in functionalized liquid crystal microdroplets

Duan, Rui; Li, Yanzeng; Li, Hanyang; Yang, Jun

doi:10.1364/boe.10.006073

Cited by 50 publications

(39 citation statements)

References 44 publications

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“…WGM biosensors are highly sensitive to changes in the surface conditions and refractive index, and they have been developed for single-molecule detection [ 20 , 21 , 115 ], pico- to atto-molar scale detection [ 21 , 112 , 113 , 116 , 117 , 118 , 119 , 120 , 121 ], and monitoring biological processes [ 122 , 123 , 124 , 125 , 126 ] or enzymatic reactions [ 127 , 128 ]. In recent studies, researchers have also taken advantage of geometric modifications [ 129 , 130 ] and material doping [ 116 , 118 , 119 , 131 , 132 , 133 , 134 ] to improve the Q-factors and sensitivity of WGM-based resonators. Geometric differences in most resonators may depend on fabrication capabilities or desired optical qualities, such as mode confinement, increased binding surface area, simpler fabrication techniques, or material choice.…”

Section: Whispering Gallery Mode (Wgm)-based Biosensorsmentioning

confidence: 99%

“…These are typically based on microbubbles, microspheres, or microdroplets. Some notable modifications were label-free surface functionalization [ 120 , 123 , 137 , 138 ], doping [ 118 , 119 ], and self-referencing [ 111 , 120 ].…”

Section: Whispering Gallery Mode (Wgm)-based Biosensorsmentioning

confidence: 99%

“…A liquid crystal (LC) microdroplet WGM resonator was used to detect heavy metal (HM) ions in real-time [ 119 ]. The LC 5CB microdroplet solution was composed of 1% 4-cyano-4′-pentylbiphenyl (5CB) in n-heptane, with equal doping of 0.01% stearic acid and fluorescent dye (DCM).…”

Section: Whispering Gallery Mode (Wgm)-based Biosensorsmentioning

confidence: 99%

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Label-Free Optical Resonator-Based Biosensors

Rho

Breaux

Kim

2020

Sensors

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The demand for biosensor technology has grown drastically over the last few decades, mainly in disease diagnosis, drug development, and environmental health and safety. Optical resonator-based biosensors have been widely exploited to achieve highly sensitive, rapid, and label-free detection of biological analytes. The advancements in microfluidic and micro/nanofabrication technologies allow them to be miniaturized and simultaneously detect various analytes in a small sample volume. By virtue of these advantages and advancements, the optical resonator-based biosensor is considered a promising platform not only for general medical diagnostics but also for point-of-care applications. This review aims to provide an overview of recent progresses in label-free optical resonator-based biosensors published mostly over the last 5 years. We categorized them into Fabry-Perot interferometer-based and whispering gallery mode-based biosensors. The principles behind each biosensor are concisely introduced, and recent progresses in configurations, materials, test setup, and light confinement methods are described. Finally, the current challenges and future research topics of the optical resonator-based biosensor are discussed.

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Section: Whispering Gallery Mode (Wgm)-based Biosensorsmentioning

confidence: 99%

Section: Whispering Gallery Mode (Wgm)-based Biosensorsmentioning

confidence: 99%

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Label-Free Optical Resonator-Based Biosensors

Rho

Breaux

Kim

2020

Sensors

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“…Compared with traditional biosensing platforms, which usually require complex instruments or fluorophores as reporters, the LC-based sensing platforms provide a simple, rapid, label-free, and cost-effective option for biosensing applications [4,9]. Various LC-based interfaces, such as LC-solid interface, LC-aqueous planar interface, and LC droplet-aqueous interface, have been developed for the detection of biological and chemical species, such as organophosphorus species [10][11][12], endotoxins [13][14][15], cells [16,17], metal ions [18][19][20], protein [21][22][23], nucleic acids [24][25][26], glucose [27][28][29], and bile acids [30][31][32][33]. The ordering of LCs is dictated by the modulation between the elastic energy stored in bulk LCs and the surface anchoring energy of LCs [6].…”

Section: Introductionmentioning

confidence: 99%

Applications of Microfluidics in Liquid Crystal-Based Biosensors

2021

Self Cite

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Liquid crystals (LCs) with stimuli-responsive configuration transition and optical anisotropic properties have attracted enormous interest in the development of simple and label-free biosensors. The combination of microfluidics and the LCs offers great advantages over traditional LC-based biosensors including small sample consumption, fast analysis and low cost. Moreover, microfluidic techniques provide a promising tool to fabricate uniform and reproducible LC-based sensing platforms. In this review, we emphasize the recent development of microfluidics in the fabrication and integration of LC-based biosensors, including LC planar sensing platforms and LC droplets. Fabrication and integration of LC-based planar platforms with microfluidics for biosensing applications are first introduced. The generation and entrapment of monodisperse LC droplets with different microfluidic structures, as well as their applications in the detection of chemical and biological species, are then summarized. Finally, the challenges and future perspectives of the development of LC-based microfluidic biosensors are proposed. This review will promote the understanding of microfluidic techniques in LC-based biosensors and facilitate the development of LC-based microfluidic biosensing devices with high performance.

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“…With a suitable choice of the constituent LC molecules, host liquid, and droplet-stabilizing surfactant, LC emulsions can be prepared in a number of phases ranging from nematic through smectic to cholesteric, with various boundary conditions imposed at the droplet surface. − Slight adjustments of these boundary conditions can then trigger a rearrangement of the director field within the droplet accompanied by corresponding changes of the refractive index. Due to this property, emulsion LC droplets have become attractive candidates for implementing ultra-sensitive environmental sensors , and optofluidic laser microcavities with largely tunable emission spectra. , …”

Section: Introductionmentioning

confidence: 99%

Optically Transportable Optofluidic Microlasers with Liquid Crystal Cavities Tuned by the Electric Field

Jonáš

Pilát

Ježek

et al. 2021

ACS Appl. Mater. Interfaces

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Liquid crystal microdroplets with readily adjustable optical properties have attracted considerable attention for building reconfigurable optofluidic microsystems for sensing, imaging, and light routing applications. In this quest, development of active optical microcavities serving as versatile integrated sources of coherent light and ultra-sensitive environmental sensors has played a prominent role. Here, we study transportable optofluidic microlasers reversibly tunable by an external electric field, which are based on fluorophore-doped emulsion droplets of radial nematic liquid crystals manipulated by optical tweezers in microfluidic chips with embedded liquid electrodes. Full transparency of the electrodes formed by a concentrated electrolyte solution allows for applying an electric field to the optically trapped droplets without undesired heating caused by light absorption. Taking advantage of independent, precise control over the electric and thermal stimulation of the lasing liquid crystal droplets, we characterize their spectral tuning response at various optical trapping powers and study their relaxation upon a sudden decrease in the trapping power. Finally, we demonstrate that sufficiently strong applied electric fields can induce fully reversible phase transitions in the trapped droplets even below the bulk melting temperature of the used liquid crystal. Our observations indicate viability of creating electrically tunable, optically transported microlasers that can be prepared on-demand and operated within microfluidic chips to implement integrated microphotonic or sensing systems.

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Detection of heavy metal ions using whispering gallery mode lasing in functionalized liquid crystal microdroplets

Cited by 50 publications

References 44 publications

Label-Free Optical Resonator-Based Biosensors

Label-Free Optical Resonator-Based Biosensors

Applications of Microfluidics in Liquid Crystal-Based Biosensors

Optically Transportable Optofluidic Microlasers with Liquid Crystal Cavities Tuned by the Electric Field

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