Waveguide confined Raman spectroscopy for microfluidic interrogation

Ashok, P.; Singh, Gajendra; Rendall, Helen Anne; Krauss, Thomas F.; Dholakia, Kishan

doi:10.1039/c0lc00462f

Cited by 62 publications

(59 citation statements)

References 28 publications

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“…2(d)). Different angles between the two fiber optic cables (from 0 to 180 ) were investigated using various device designs to optimize the collection of Raman photons; 90 proved to be the most efficient angle, which is in agreement with a previous report by Ashok et al 30 As illustrated in Fig. 2(d), excitation and collection fiber optics were connected, respectively, to the 785 nm diode laser and the Raman spectrometer (iHR550 Horiba JY).…”

Section: E Sers Measurementssupporting

confidence: 69%

A nanoporous optofluidic microsystem for highly sensitive and repeatable surface enhanced Raman spectroscopy detection

Yazdi

White

2012

Biomicrofluidics

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We report the demonstration of an optofluidic surface enhanced Raman spectroscopy (SERS) device that leverages a nanoporous microfluidic matrix to improve the SERS detection performance by more than two orders of magnitude as compared to a typical open microfluidic channel. Although it is a growing trend to integrate optical biosensors into microfluidic channels, this basic combination has been detrimental to the sensing performance when applied to SERS. Recently, however, synergistic combinations between microfluidic functions and photonics (i.e., optofluidics) have been implemented that improve the detection performance of SERS. Conceptually, the simplest optofluidic SERS techniques reported to date utilize a single nanofluidic channel to trap nanoparticle-analyte conjugates as a method of preconcentration before detection. In this work, we leverage this paradigm while improving upon the simplicity by forming a 3D nanofluidic network with packed nanoporous silica microspheres in a microfluidic channel; this creates a concentration matrix that traps silver nanoclusters and adsorbed analytes into the SERS detection volume. With this approach, we are able to achieve a detection limit of 400 attomoles of Rhodamine 6G after only 2 min of sample loading with high chip-to-chip repeatability. Due to the high number of fluidic paths in the nanoporous channel, this approach is less prone to clogging than single nanofluidic inlets, and the loading time is decreased compared to previous reports. In addition, fabrication of this microsystem is quite simple, as nanoscale fabrication is not necessary. Finally, integrated multimode fiber optic cables eliminate the need for optical alignment, and thus the device is relevant for portable and automated applications in the field, including point-of-sample and point-of-care detection. To illustrate a relevant field-based application, we demonstrate the detection of 12 ppb of the organophosphate malathion in water using the nanofluidic SERS microsystem.

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Section: E Sers Measurementssupporting

confidence: 69%

A nanoporous optofluidic microsystem for highly sensitive and repeatable surface enhanced Raman spectroscopy detection

Yazdi

White

2012

Biomicrofluidics

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“…We chose Raman spectroscopy due to its known capabilities for liquid identification and measurement of analyte concentration [8]. Previous miniaturized Raman systems based on PDMS microfluidic chips and embedded optical fibers [25] required hundreds of milliwatts of input laser power. In contrast, our system uses laser powers that were a factor of 10 lower.…”

Section: Technology Benefits For Raman Spectroscopymentioning

confidence: 99%

Fiber-Based, Injection-Molded Optofluidic Systems: Improvements in Assembly and Applications

et al. 2015

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Abstract:We present a method to fabricate polymer optofluidic systems by means of injection molding that allow the insertion of standard optical fibers. The chip fabrication and assembly methods produce large numbers of robust optofluidic systems that can be easily assembled and disposed of, yet allow precise optical alignment and improve delivery of optical power. Using a multi-level chip fabrication process, complex channel designs with extremely vertical sidewalls, and dimensions that range from few tens of nanometers to hundreds of microns can be obtained. The technology has been used to align optical fibers in a quick and precise manner, with a lateral alignment accuracy of 2.7˘1.8 µm. We report the production, assembly methods, and the characterization of the resulting injection-molded chips for Lab-on-Chip (LoC) applications. We demonstrate the versatility of this technology by carrying out two types of experiments that benefit from the improved optical system: optical stretching of red blood cells (RBCs) and Raman spectroscopy of a solution loaded into a hollow core fiber. The advantages offered by the presented technology are intended to encourage the use of LoC technology for commercialization and educational purposes.

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“…13 For a fair comparison between the SNR of standard and modulated Raman, SNR from the first differential of the standard Raman spectrum was also estimated. Signal to background (S/B) of a Raman peak was estimated as the ratio of the height of the Raman peak from the fluorescence background to the height of the fluorescence background, 28 after subtracting the dark current of the CCD from the recorded spectrum.…”

Section: Data Treatmentmentioning

confidence: 99%

Fluorescence suppression using wavelength modulated Raman spectroscopy in fiber-probe-based tissue analysis

et al. 2012

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Abstract. In the field of biomedical optics, Raman spectroscopy is a powerful tool for probing the chemical composition of biological samples. In particular, fiber Raman probes play a crucial role for in vivo and ex vivo tissue analysis. However, the high-fluorescence background typically contributed by the auto fluorescence from both a tissue sample and the fiber-probe interferes strongly with the relatively weak Raman signal. Here we demonstrate the implementation of wavelength-modulated Raman spectroscopy (WMRS) to suppress the fluorescence background while analyzing tissues using fiber Raman probes. We have observed a significant signal-to-noise ratio enhancement in the Raman bands of bone tissue, which have a relatively high fluorescence background. Implementation of WMRS in fiber-probe-based bone tissue study yielded usable Raman spectra in a relatively short acquisition time (∼30 s), notably without any special sample preparation stage. Finally, we have validated its capability to suppress fluorescence on other tissue samples such as adipose tissue derived from four different species.

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Waveguide confined Raman spectroscopy for microfluidic interrogation

Cited by 62 publications

References 28 publications

A nanoporous optofluidic microsystem for highly sensitive and repeatable surface enhanced Raman spectroscopy detection

A nanoporous optofluidic microsystem for highly sensitive and repeatable surface enhanced Raman spectroscopy detection

Fiber-Based, Injection-Molded Optofluidic Systems: Improvements in Assembly and Applications

Fluorescence suppression using wavelength modulated Raman spectroscopy in fiber-probe-based tissue analysis

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