1 rganism behavior, embryonic development, and
optofluidics.
2 r applications ranging from lab-on-a-chip to
optofluidics.
3 photonic function is one of the hallmarks of
optofluidics.
4 forces, vortex laser beams, plasmonics, and
optofluidics.
5 We categorize
optofluidics according to three broad categories of inte
6 be used in sensing, photonics, microfluidic,
optofluidic and lab-on-a-chip applications as they do no
7 Here we show how the convergence of
optofluidics and metasurface optics can lead to conceptu
8 Here, we introduce an
optofluidic application based on a direct optical-to-hyd
9 to explore the potential for developing new
optofluidic applications.
10 y plasmonic nanostructures is attractive for
optofluidic applications.
11 sent exciting opportunities for their use in
optofluidics applications requiring tunable flow behavio
12 In this review, we describe various
optofluidic architectures developed in the past five yea
13 We present a semiquantitative
optofluidic assay for studying the uptake of autofluores
14 We recently developed an
optofluidic assay that directly determines the permeabil
15 g a compact, lightweight, and cost-effective
optofluidic attachment.
16 of the solubility data, the applicability of
optofluidics based analytics for small-scale high-throug
17 or and microfluidic technology, an all-fiber
optofluidics-
based bioassay platform (AFOB) was develope
18 We describe the principle of the
optofluidic biolaser, review recent progress and provide
19 Optofluidic biolasers are emerging as a highly sensitive
20 We report an
optofluidic catalytic laser for sensitive sulfide ion de
21 ies after pre-reaction was introduced to the
optofluidic cell.
22 ed absorption of volatile organics inside an
optofluidic channel array, is discussed in terms of its
23 Here, we introduce a programmable
optofluidic chip for nanopore-based particle analysis: f
24 Herein an
optofluidic chip that can reliably detect PSA as well as
25 The assay uses an
optofluidic chip that combines optical waveguides with a
26 es multiple fluidic waveguide channels on an
optofluidic chip to create multi-spot excitation pattern
27 The
optofluidic chip, which consists of arrayed nanopore-bas
28 tive nanometric gold layer, integrated in an
optofluidic chip.
29 ltiplexed single biomolecule detection on an
optofluidic chip.
30 ntial brick for the generation of future all-
optofluidic chip.
31 o manipulate light and liquids on integrated
optofluidics chips has spurred a myriad of important dev
32 Instead, our
optofluidic control method will allow the fabrication of
33 The presence of alcohol molecules in the
optofluidic core quenches the fiber transmissions if the
34 ies to subtle differences in fluid behavior,
optofluidic crystals may also prove useful in rapid anal
35 In these
optofluidic crystals, dynamically tunable disorder is su
36 G5-MNI-Glu was used with
optofluidic delivery to stimulate dopamine neurons of th
37 This integrated
optofluidic device can significantly cut down the test t
38 In this work, we present a single-layer,
optofluidic device for real-time, high-throughput, quant
39 These fibers were used as an
optofluidic device for the detection of DNA by measuring
40 we report the development and testing of an
optofluidic device for the rapid and label-free detectio
41 The
optofluidic device is compact and has long interaction l
42 The
optofluidic device is designed for adjusting the concent
43 st, size, and reliability, the droplet-based
optofluidic device presented here can be a valuable tool
44 The key innovation is an
optofluidic device that can detect enzyme amplified exos
45 deep learning-based denoising method and an
optofluidic device tuned for nanoparticle detection, we
46 An
optofluidic device with tunable optical limiting propert
47 on is demonstrated by employing the proposed
optofluidic device.
48 owever, a persistent challenge with existing
optofluidic devices has been achieving controlled and pr
49 Integrated
optofluidic devices have become subjects of high interes
50 We describe examples of
optofluidic devices in each category.
51 detection developed here will lead to novel
optofluidic devices that enable rapid and simple analysi
52 Here we demonstrate bioinspired
optofluidic dye lasers excited by FRET, in which the don
53 Optofluidic dye lasers hold great promise for adaptive p
54 1,000 times lower than that in conventional
optofluidic dye lasers.
55 ive years, emphasize the mechanisms by which
optofluidics enhances bio/chemical analysis capabilities
56 Here, we present a novel method called
optofluidic fabrication for the generation of complex 3D
57 The fundamental advantages of
optofluidic fabrication include high-resolution, multi-s
58 demonstrate the first online hyphenation of
optofluidic force induction (OF2i) with Raman spectrosco
59 In this cell-phone-based
optofluidic imaging cytometry platform, fluorescently la
60 This cell-phone-enabled
optofluidic imaging flow cytometer could especially be u
61 This work developed an
optofluidic immunochip that uses whispering gallery mode
62 Ebola virus on clinical samples using hybrid
optofluidic integration.
63 n of monodisperse droplets within a uniaxial
optofluidic Lab-in-a-Fiber scheme.
64 ly investigate DNA melting analysis using an
optofluidic laser and then experimentally explore this s
65 nstrated to illustrate vast possibilities in
optofluidic laser designs.
66 laser-based ELISA, and then characterize the
optofluidic laser performance.
67 Here, a new concept,
optofluidic laser TIIA (OFL-TIIA), is proposed and demon
68 We first elucidate the principle of the
optofluidic laser-based ELISA, and then characterize the
69 aneously obtained by the traditional and the
optofluidic laser-based ELISA, showing a detection limit
70 Here we develop the
optofluidic laser-based ELISA, where ELISA occurs inside
71 ity DNA melting analysis scheme utilizing an
optofluidic laser.
72 By integrating dynamically reconfigurable
optofluidic lasers on-chip, complex coupling can be elim
73 ble, single biomarker analysis using on-chip
optofluidic lasers.
74 nd envision new research directions to which
optofluidics leads.
75 The presented work features the
optofluidic light cage as a novel on-chip sensing platfo
76 Here, we introduce the concept of the
optofluidic light cage that allows for fast and reliable
77 address these problems, we have developed an
optofluidic measurement system that can deliver and reco
78 The first demonstration of an
optofluidic metamaterial is reported where resonant prop
79 We report an
optofluidic method that enables to efficiently measure t
80 introduce photonic crystal fibre as a novel
optofluidic microdevice that can be employed as both a v
81 Our
optofluidic microlens provides a self-collimating mechan
82 f a microscale liquid channel and acts as an
optofluidic microreactor with a reaction volume of less
83 kinetic modeling highlights the potential of
optofluidic microreactors as a highly sensitive, quantit
84 The
optofluidic microscope design, readily fabricable with e
85 , and fully on-chip microscopes based on the
optofluidic microscopy (OFM) method.
86 ajor classes of lensless microscopy methods,
optofluidic microscopy and digital in-line holography mi
87 cedures for implementing ultrathin, flexible
optofluidic neural probe systems that provide targeted,
88 n protocols will increase access to wireless
optofluidic neural probes for advanced in vivo pharmacol
89 Here, we introduce wireless
optofluidic neural probes that combine ultrathin, soft m
90 Recent advances in
optofluidics offer tremendous opportunities for biologic
91 This offers an
optofluidic paradigm for particle transport overcoming t
92 we introduce a subwavelength thick (<200 nm)
Optofluidic PlasmonIC (OPtIC) microlens that effortlessl
93 Our
optofluidic platform advances the exploitation of exotic
94 Here, we present a unique
optofluidic platform comprising organic molecules in sol
95 Here, we introduce an
optofluidic platform for automated sorting of stable-iso
96 This
optofluidic platform has advantages over traditional gen
97 These findings show that our
optofluidic platform not only helps to close the current
98 Here we present an integrated
optofluidic platform that addresses this critical point
99 Here, we introduce an
optofluidic platform that brings together state-of-the-a
100 To address this challenge, we developed an
optofluidic platform that miniaturizes digital assays in
101 hallenges, we developed a smartphone-enabled
optofluidic platform to measure brain-derived exosomes.
102 rate automated control in an integrated meta-
optofluidic platform to open up new display functions.
103 We envision that the developed
optofluidic platform will find wide applicability in the
104 less, battery-free, programable multilateral
optofluidic platform with user-selected modalities for o
105 e development of a simple and cost-effective
optofluidic platform, integrating liquid-core PDMS waveg
106 lates were collected within 3.5 h using this
optofluidic platform.
107 Our scalable "
optofluidic"
platform, leveraging a versatile range of a
108 Miniaturizing optical trap instruments onto
optofluidic platforms holds promise for high-throughput
109 Metallic nanopore arrays have emerged as
optofluidic platforms with multifarious sensing and anal
110 rtphone-controlled, minimally invasive, soft
optofluidic probes with replaceable plug-like drug cartr
111 mmetry breaking (RSB) in a weakly scattering
optofluidic random laser (ORL).
112 In this work, we developed an
optofluidic ring resonator (OFRR) sensor and the corresp
113 ally explore this scheme with a high-quality
optofluidic ring resonator.
114 Optofluidic screening enabled isolation of a patient-der
115 ic source beam collimator for use in on-chip
optofluidic sensing applications.
116 The
optofluidic SERS device utilizes a porous microfluidic m
117 Using the
optofluidic SERS device, the food contaminant melamine w
118 This combination of the
optofluidic SERS microsystem with a portable spectromete
119 Using gold NPs as labels and an
optofluidic setup, we demonstrate that DIAMOND achieves
120 In our
optofluidic silicon photonics system we utilize thermoca
121 with fluorescence signals from a chip-based,
optofluidic single particle sensor.
122 Here we present an
optofluidic single-particle intrinsic dissolution rate (
123 Here, we present an
optofluidic single-particle technique for microscale equ
124 ngation in a nanochannel and a technique for
optofluidic surface enhanced Raman detection of nucleic
125 contaminants using a portable and automated
optofluidic surface enhanced Raman spectroscopy (SERS) m
126 An
optofluidic,
surface-enhanced Raman spectroscopy (SERS)
127 d demonstrated the feasibility of using this
optofluidic system at different laboratories for bacteri
128 The
optofluidic system has high sensing performance with nea
129 Our fully integrated
optofluidic system successfully detected cocaine in real
130 Here, we present an
optofluidic system that continuously collects fluorescen
131 The use of SU-8-based
optofluidic systems (OFS) is validated as an affordable
132 These
optofluidic systems may expand the scope of wireless tec
133 Optical chromatography is a powerful
optofluidic technique enabling label-free fractionation
134 ensitivity and robustness of SERS-integrated
optofluidic technology might eventually help the triagin
135 ditional flow cytometry, we utilized a novel
optofluidic technology to evaluate cell division with si
136 and is also well in line with the spirit of
optofluidics technology-fusion of optics and microfluidi
137 Optofluidics -
the synergistic integration of photonics
138 reated and -untreated cells (N = 240,000) by
optofluidic time-stretch microscopy with high throughput
139 Here we present an approach to
optofluidic transport that overcomes these limitations,
140 By contrast,
optofluidics uses light to power, control and monitor li
141 rofluidic device also acts as a multilayered
optofluidic waveguide and efficiently guides our excitat
142 e bacterial nucleic acids flowing through an
optofluidic waveguide chip that produces fluorescence si
143 ate for the first time that the design of an
optofluidic waveguide system can be optimised to enable
144 to the xyz alignment of 2D flakes within the
optofluidic waveguide.