Reconfigurable Integrated Optofluidic Droplet Laser Arrays

Zhang, Han; Palit, Prithviraj; Liu, Yonghao; Vaziri, Seyedmohsen; Sun, Yuze

doi:10.1021/acsami.0c05967

Cited by 35 publications

(23 citation statements)

References 38 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…By taking advantage of the scanning technique, laser emission images or laser modes could be captured through a camera to form large-scale images. The accuracy of the laser emission image has also been proven to be the same as spectrum-based measurements, indicating the applicability of laser imaging-based analysis . With the integration of the microarray, − laser images could be obtained from different samples simultaneously. − Despite the recent progress in laser emission imaging, quantitative analysis of laser emission images remains unresolved …”

Section: Introductionmentioning

confidence: 99%

Imaging-Based Optofluidic Biolaser Array Encapsulated with Dynamic Living Organisms

et al. 2021

View full text Add to dashboard Cite

Optofluidic biolasers have emerged as promising tools for biomedical analysis due to their strong light–matter interactions and miniaturized size. Recent developments in optofluidic lasers have opened a new Frontier in monitoring biological processes. However, most biolasers require precise recording of the lasing spectrum at the single cavity level, which limits its application in high-throughput applications. Herein, a microdroplet laser array encapsulated with living Escherichia coli was printed on highly reflective mirrors, where laser emission images were employed to reflect the dynamic changes in living organisms. The concept of image-based lasing analysis was proposed by quantifying the integrated pixel intensity of the lasing image from whispering-gallery modes. Finally, dynamic interactions between E. coli and antibiotic drugs were compared under fluorescence and laser emission images. The amplification that occurred during laser generation enabled the quantification of tiny biological changes in the gain medium. Laser imaging presented a significant increase in integrated pixel intensity by 2 orders of magnitude. Our findings demonstrate that image-based lasing analysis is more sensitive to dynamic changes than fluorescence analysis, paving the way for high-throughput on-chip laser analysis of living organisms.

show abstract

Section: Introductionmentioning

confidence: 99%

Imaging-Based Optofluidic Biolaser Array Encapsulated with Dynamic Living Organisms

et al. 2021

View full text Add to dashboard Cite

show abstract

“…[12,13] Researchers have demonstrated such low-cost devices for various applications. [14][15][16][17][18][19] However, the centralized fabrication process of these devices is still a prevalent limitation.…”

Section: Laserjet Printed Micro/nano Sensors and Microfluidic Systems: A Simple And Facile Digital Platform For Inexpensive Flexible And mentioning

confidence: 99%

Laserjet Printed Micro/Nano Sensors and Microfluidic Systems: A Simple and Facile Digital Platform for Inexpensive, Flexible, and Low‐Volume Devices

Bamshad

Cho

2021

Adv Materials Technologies

View full text Add to dashboard Cite

A facile and digital do‐it‐yourself technique is proposed to fabricate inexpensive sensors on flexible substrates (paper, cloth, and plastic film). A set of office‐grade equipment (i.e., laserjet printer, thermal laminator, computer‐aided paper cutter), and commercially available supplies (i.e., baking wax paper, furniture restoration metal‐leaf) are used. Forming electrodes through traditional printing and defining a fluidic confinement region through crafting practice enable fabrication of a wide range of devices without requiring customized specialty instruments, costly infrastructure, and complicated fabrication steps, unlike previously introduced methods. Three different levels of experiments are designed to assess the comprehensiveness and responsiveness of the proposed method to the needs of existing research fields. The performances of the fabricated features at each level are evaluated to cover various application domains in environmental monitoring and biomedical diagnostics utilizing conductometric, colorimetric, biochemical, and chemoresistive detection principles. Devices with varying size of features, from nanometers to centimeters, are fabricated and characterized. This method provides an alternative route to decentralized production of low‐cost flexible sensors and other devices, with a minimal step, time, and facilities. The operation of such devices is simple and can be further empowered by smartphones for data analysis and transmission.

show abstract

“…The advantages of microfluidic system such as its configuration, size, sensing response and flexibility make it a potential candidate in various applications such as chemical detection, medical diagnostic, environmental monitoring, etc. [14][15][16]. The optical fiber-based optofluidic sensing configurations are simple and support low-cost fabrication support and also easy way for light to be coupled in and out of the chip and interacted with the liquid sample.…”

Section: Introductionmentioning

confidence: 99%

A Highly Sensitive SPR Refractive Index Sensor Based on Microfluidic Channel Assisted With Graphene-Ag Composite Nanowire

et al. 2021

View full text Add to dashboard Cite

A highly sensitive refractive index (RI) sensor based on a microfluidic channel (MFC) incorporated in a single-mode fiber (SMF), filled with Ag-graphene composite nanowire is presented and analyzed here. The sensing performance and the coupling properties of designed sensor are numerically analyzed by using a full vectorial finite element method (FEM) incorporating amplitude and wavelength interrogation techniques in the detection range varied from = 1.330-1.350. The maximum wavelength and amplitude sensitivity are obtained of 13700 nm/RIU and 1026 RIU -1 , respectively. Here, the Ag-graphene composite nanowire can not only solve the problem of oxidation but also enhances the sensitivity of the sensor. In addition of high sensitivity, it also provides better performance than other sensing devices based on similar technologies such as Ag nanowire-filled sensors. Moreover, the influences of polishing depth (D), nanowire radius (rn), graphene layer (Lg) and channel size (s) on the designed sensor, are also thoroughly investigated here. The present work can provide a base for designing a real-time, highly sensitivity, remote sensing, and distributed SPR based RI sensor.

show abstract

Reconfigurable Integrated Optofluidic Droplet Laser Arrays

Cited by 35 publications

References 38 publications

Imaging-Based Optofluidic Biolaser Array Encapsulated with Dynamic Living Organisms

Imaging-Based Optofluidic Biolaser Array Encapsulated with Dynamic Living Organisms

Laserjet Printed Micro/Nano Sensors and Microfluidic Systems: A Simple and Facile Digital Platform for Inexpensive, Flexible, and Low‐Volume Devices

A Highly Sensitive SPR Refractive Index Sensor Based on Microfluidic Channel Assisted With Graphene-Ag Composite Nanowire

Contact Info

Product

Resources

About