Miniaturization of fluorescence sensing in optofluidic devices

Măriuța, Daniel; Colin, Stéphane; Barrot-Lattes, Christine; Calvé, Stéphane Le; Korvink, Jan G.; Baldas, Lucien; Brandner, Juergen J.

doi:10.1007/s10404-020-02371-1

Cited by 33 publications

(18 citation statements)

References 116 publications

(152 reference statements)

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“…However, the making of the sensor would be quite complicated with the fiber alignment, and direct contact of the flowing fluid with the fiber cantilever is also required. In another report using the optical approach for flow sensing, miniaturized fluorescence sensing is attempted for micro molecular tagging velocimetry in microfluidics [76], but these methods are not cost-effective and yet to reach the small footprint.…”

Section: Optical Microfluidic Flow Sensingmentioning

confidence: 99%

Microfluidic Flow Sensing Approaches

Huang¹

2021

Advances in Microfluidics and Nanofluids

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Precise flow metrology has an increasing demand in many microfluidic related applications. At the scale and scope of interests, Capillary number instead of Reynold number defines the flow characteristics. The interactions between fluid medium and flow channel surface or the surface tension, cavitation, dissolution, and others play critical roles in microfluidic flow metrology. Conventional flow measurement approaches are not sufficient for solving these issues. This chapter will review the currently available products on the market, their microfluidic flow sensing technologies, the technologies with research and development, the major factors impacting flow metrology, and the prospective sensing approaches for future microfluidic flow sensing.

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Section: Optical Microfluidic Flow Sensingmentioning

confidence: 99%

Microfluidic Flow Sensing Approaches

Huang¹

2021

Advances in Microfluidics and Nanofluids

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“…Notwithstanding these options, the vast majority of organ-on-a-chip current readouts are microscopy-based, typically combined with sacrificial off-chip analytical techniques (eg, qPCR, FACS, mass spectroscopy, and ELISA). 28 Optical methods offer several advantages, which render them highly suitable for merging with organ-on-a-chip platforms, such as being nondestructive, robust, sensitive, and, importantly, compatible with in situ and/or inline monitoring, 29 as elegantly depicted in the example in Figure 1D. Well known by the required mild conditions and noninvasiveness, luminescence-based biosensors are based on imaging light emission resulting from thermo, electrogenerated-, or chemi-BL reactions.…”

Section: Monitoring Organ-on-a-chip Systems Using Biosensorsmentioning

confidence: 99%

“…It is widely accepted that from all optical methods, fluorescence sensing is still the most popular detection method used in organ-on-chip platforms. 29 Indeed, most of the readouts compatible with organs-on-chips so far reported in literature remain heavily dependent on fluorescencebased microscopy assessment. [45][46][47] Fluorescence-based analysis is typically reliant on prelabeled cells or demand invasive end-point procedures, such as cell fixation, necessary for further processing for immunohistochemistry or histological staining.…”

Section: Microscopy-based Biosensorsmentioning

confidence: 99%

New bioimaging avenues for organs‐on‐chips by integration of bioluminescence

Teixeira

Mezzanotte

2021

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The unmet demand for the development of advanced in vitro models that emulate key features of human (patho-)physiology and organ or tissue functionality led to the emergence of organ-on-a-chip screening platforms. This biomimetic microtechnology enables accurate prediction of human responses, even at the multitissue or organ interaction level. With these advances, the necessity of incorporating biosensing within these platform becomes increasingly evident, to ultimately allow in situ, noninvasive, monitoring of cells, tissues and organs' behavior. Seamlessly integrated biosensors on-chip also offer the prospect of uninterrupted and fully automated analysis. The continuous search for biosensors that not only avoid disruptive analyses, but are also highly sensitive and permit instant in situ evaluation, steered further developments of optical biosensors including bioluminescence (BL). BL is particularly suitable to interrogate biological systems at the multiparameter level and it is well matched to address the intrinsic biological systems' heterogeneity due to its inherent high signal to background ratio, to which the demand of simple measurement equipment can be added. Moreover, BL can be effortlessly integrated into any available organ-ona-chip platform and provides unique groundbreaking means for online monitoring, at the cellular level, and/or detection of cell secreted/excreted compounds. This review depicts recent advances in biosensors, with particular focus on BL. We highlight current challenges and future directions, aimed at stimulating the application of BL to interface organ-on-a-chip systems, leading to the exponential advancement of both fields.

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“…The integration features of optofluidic technology can (1) accelerate the reaction speed due to the short diffusion distance, high surface‐to‐volume ratio, and efficient heat transfer [ 10 ] ; (2) improve the sensitivity due to the efficient mass transfer in a small volume and enhanced light–matter interaction using on‐chip optical modules such as optofluidic laser [ 11 ] ; (3) reduce the cost due to the lower reagent and sample consumption [ 12 ] ; (4) miniaturize the diagnostic system because of the integrated optics in chips. [ 13 ] Those advantages make the optofluidics a promising solution for biodiagnosis. The advances of optofluidic technology will be useful for addressing global health issues such as the current COVID‐19 pandemic in many aspects, from the direct detection of the COVID‐19 virus using optofluidic genetic detection system to antibody‐based blood diagnosis test using optofluidic protein detection tool, and to antibody screening for therapeutic purpose using optofluidic cell analysis platform.…”

Section: Introductionmentioning

confidence: 99%

Emerging optofluidic technologies for biodiagnostic applications

Dai

et al. 2021

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The unprecedented global COVID‐19 pandemic strongly argues the critical need for innovative diagnostic tools meeting the requirement of test speed, accuracy, and throughput. Owing to the integration of optics and microfluidics technologies, optofluidic technology enables highly precise flow manipulation and highly sensitive signal detection at the microscale, thus offering the promising potential for developing biodiagnostic applications. Research toward this direction is fast growing into an emerging area. In this paper, we give an overview of emerging optofluidic technologies for biodiagnostic applications with the focus on three common types of biomarkers: nucleic acid, protein, and cell. We conclude by discussing the challenges, opportunities, and future perspectives of this field.

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Miniaturization of fluorescence sensing in optofluidic devices

Cited by 33 publications

References 116 publications

Microfluidic Flow Sensing Approaches

Microfluidic Flow Sensing Approaches

New bioimaging avenues for organs‐on‐chips by integration of bioluminescence

Emerging optofluidic technologies for biodiagnostic applications

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