Directed Growth of Orthorhombic Crystals in a Micropillar Array

Holzner, G.; Binder, Claudia; Kriel, Frederik H.; Priest, Craig

doi:10.1021/acs.langmuir.6b04026

Cited by 4 publications

(4 citation statements)

References 27 publications

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“…The microfluidic component of the optofluidic sensor reported here is based on an open micropillar array system where liquid can spontaneously fill into the void space between pillars via a capillary action called wicking, and form a well-defined film [22][23][24]. The thickness of the liquid film is precisely determined by the height of the pillars (in µm), and the volume required to fill the microfluidic chip is of the order of several µL [22].…”

Section: Introductionmentioning

confidence: 99%

Caged-Sphere Optofluidic Sensors: Whispering Gallery Resonators in Wicking Microfluidics

Riesen

Peterkovic

Guan

et al. 2022

Sensors

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The rapid development of optofluidic technologies in recent years has seen the need for sensing platforms with ease-of-use, simple sample manipulation, and high performance and sensitivity. Herein, an integrated optofluidic sensor consisting of a pillar array-based open microfluidic chip and caged dye-doped whispering gallery mode microspheres is demonstrated and shown to have potential for simple real-time monitoring of liquids. The open microfluidic chip allows for the wicking of a thin film of liquid across an open surface with subsequent evaporation-driven flow enabling continuous passive flow for sampling. The active dye-doped whispering gallery mode microspheres placed between pillars, avoid the use of cumbersome fibre tapers to couple light to the resonators as is required for passive microspheres. The performance of this integrated sensor is demonstrated using glucose solutions (0.05–0.3 g/mL) and the sensor response is shown to be dynamic and reversible. The sensor achieves a refractive index sensitivity of ~40 nm/RIU, with Q-factors of ~5 × 103 indicating a detection limit of ~3 × 10−3 RIU (~20 mg/mL glucose). Further enhancement of the detection limit is expected by increasing the microsphere Q-factor using high-index materials for the resonators, or alternatively, inducing lasing. The integrated sensors are expected to have significant potential for a host of downstream applications, particularly relating to point-of-care diagnostics.

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Section: Introductionmentioning

confidence: 99%

Caged-Sphere Optofluidic Sensors: Whispering Gallery Resonators in Wicking Microfluidics

Riesen

Peterkovic

Guan

et al. 2022

Sensors

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“…The pillar arrays (“pillar cuvettes” − ) were prepared in fused silica by photolithography and plasma etching (ULVAC, NLD570). Before etching, a 6 in.…”

Section: Methodsmentioning

confidence: 99%

Evaporation-Driven Flow in Micropillar Arrays: Transport Dynamics and Chemical Analysis under Varied Sample and Ambient Conditions

et al. 2020

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Microfluidic flow in lab-on-a-chip devices is typically very sensitive to the variable physical properties of complex samples, e.g., biological fluids. Here, evaporation-driven fluid transport (transpiration) is achieved in a configuration that is insensitive to interfacial tension, salinity, and viscosity over a wide range. Micropillar arrays ("pillar cuvettes") were preloaded by wicking a known volatile fluid (water) and then adding a microliter sample of salt, surfactant, sugar, or saliva solution to the loading zone. As the preloaded fluid evaporates, the sample is reliably drawn from a reservoir through the pillar array at a rate defined by the evaporation of the preloaded fluid (typically nL/s). Including a reagent in the preloaded fluid allows photometric reactions to take place at the boundary between the two fluids. In this configuration, a photometric signal enhancement is observed and chemical analysis is independent of both humidity and temperature. The ability to reliably transport and sense an analyte in microliter volumes without concern over salt, surfactant, viscosity (in part), humidity, and temperature is a remarkable advantage for analytical purposes.

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“…The streams merged upstream of the optical cell, mixed by diffusion, and were then measured through the optical window. Proof-of-principle experiments were successfully conducted using LEDs and photodiodes; however, the results presented here were obtained using a custom-built micro-spectrophotometer, based on an Olympus BH2-UMA frame [27]. This allowed the full spectrum (200-1000 nm) to be collected and inspected for potential interferences or anomalies (e.g., in real pool samples).…”

Section: On-chip Experimentsmentioning

confidence: 99%

Photometric Sensing of Active Chlorine, Total Chlorine, and pH on a Microfluidic Chip for Online Swimming Pool Monitoring

Elmas

Pospisilova

Sekulska

et al. 2020

Sensors

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A microfluidic sensor was studied for the photometric detection of active chlorine, total chlorine, and pH in swimming pool samples. The sensor consisted of a four-layer borosilicate glass chip, containing a microchannel network and a 2.2 mm path length, 1.7 mL optical cell. The chip was optimised to measure the bleaching of methyl orange and spectral changes in phenol red for quantitative chlorine (active and total) and pH measurements that were suited to swimming pool monitoring. Reagent consumption (60 mL per measurement) was minimised to allow for maintenance-free operation over a nominal summer season (3 months) with minimal waste. The chip was tested using samples from 12 domestic, public, and commercial swimming pools (indoor and outdoor), with results that compare favourably with commercial products (test strips and the N,N’-diethyl-p-phenylenediamine (DPD) method), precision pH electrodes, and iodometric titration.

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Directed Growth of Orthorhombic Crystals in a Micropillar Array

Cited by 4 publications

References 27 publications

Caged-Sphere Optofluidic Sensors: Whispering Gallery Resonators in Wicking Microfluidics

Caged-Sphere Optofluidic Sensors: Whispering Gallery Resonators in Wicking Microfluidics

Evaporation-Driven Flow in Micropillar Arrays: Transport Dynamics and Chemical Analysis under Varied Sample and Ambient Conditions

Photometric Sensing of Active Chlorine, Total Chlorine, and pH on a Microfluidic Chip for Online Swimming Pool Monitoring

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