ライフサイエンスコーパス: optofluidic

1 photonic function is one of the hallmarks of optofluidics.

2 forces, vortex laser beams, plasmonics, and optofluidics.

3 rganism behavior, embryonic development, and optofluidics.

4 r applications ranging from lab-on-a-chip to 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 introduce an optofluidic application based on a direct optical-to-hyd

8 y plasmonic nanostructures is attractive for optofluidic applications.

9 In this review, we describe various optofluidic architectures developed in the past five yea

10 We present a semiquantitative optofluidic assay for studying the uptake of autofluores

11 We recently developed an optofluidic assay that directly determines the permeabil

12 g a compact, lightweight, and cost-effective optofluidic attachment.

13 of the solubility data, the applicability of optofluidics based analytics for small-scale high-throug

14 or and microfluidic technology, an all-fiber optofluidics-based bioassay platform (AFOB) was develope

15 We describe the principle of the optofluidic biolaser, review recent progress and provide

16 Optofluidic biolasers are emerging as a highly sensitive

17 We report an optofluidic catalytic laser for sensitive sulfide ion de

18 ies after pre-reaction was introduced to the optofluidic cell.

19 ed absorption of volatile organics inside an optofluidic channel array, is discussed in terms of its

20 Herein an optofluidic chip that can reliably detect PSA as well as

21 es multiple fluidic waveguide channels on an optofluidic chip to create multi-spot excitation pattern

22 The optofluidic chip, which consists of arrayed nanopore-bas

23 ltiplexed single biomolecule detection on an optofluidic chip.

24 ntial brick for the generation of future all-optofluidic chip.

25 Instead, our optofluidic control method will allow the fabrication of

26 The presence of alcohol molecules in the optofluidic core quenches the fiber transmissions if the

27 ies to subtle differences in fluid behavior, optofluidic crystals may also prove useful in rapid anal

28 In these optofluidic crystals, dynamically tunable disorder is su

29 This integrated optofluidic device can significantly cut down the test t

30 In this work, we present a single-layer, optofluidic device for real-time, high-throughput, quant

31 These fibers were used as an optofluidic device for the detection of DNA by measuring

32 The optofluidic device is compact and has long interaction l

33 The optofluidic device is designed for adjusting the concent

34 st, size, and reliability, the droplet-based optofluidic device presented here can be a valuable tool

35 The key innovation is an optofluidic device that can detect enzyme amplified exos

36 An optofluidic device with tunable optical limiting propert

37 on is demonstrated by employing the proposed optofluidic device.

38 owever, a persistent challenge with existing optofluidic devices has been achieving controlled and pr

39 We describe examples of optofluidic devices in each category.

40 detection developed here will lead to novel optofluidic devices that enable rapid and simple analysi

41 Here we demonstrate bioinspired optofluidic dye lasers excited by FRET, in which the don

42 Optofluidic dye lasers hold great promise for adaptive p

43 1,000 times lower than that in conventional optofluidic dye lasers.

44 ive years, emphasize the mechanisms by which optofluidics enhances bio/chemical analysis capabilities

45 Here, we present a novel method called optofluidic fabrication for the generation of complex 3D

46 The fundamental advantages of optofluidic fabrication include high-resolution, multi-s

47 In this cell-phone-based optofluidic imaging cytometry platform, fluorescently la

48 This cell-phone-enabled optofluidic imaging flow cytometer could especially be u

49 Ebola virus on clinical samples using hybrid optofluidic integration.

50 ly investigate DNA melting analysis using an optofluidic laser and then experimentally explore this s

51 nstrated to illustrate vast possibilities in optofluidic laser designs.

52 laser-based ELISA, and then characterize the optofluidic laser performance.

53 We first elucidate the principle of the optofluidic laser-based ELISA, and then characterize the

54 aneously obtained by the traditional and the optofluidic laser-based ELISA, showing a detection limit

55 Here we develop the optofluidic laser-based ELISA, where ELISA occurs inside

56 ity DNA melting analysis scheme utilizing an optofluidic laser.

57 nd envision new research directions to which optofluidics leads.

58 The first demonstration of an optofluidic metamaterial is reported where resonant prop

59 introduce photonic crystal fibre as a novel optofluidic microdevice that can be employed as both a v

60 The optofluidic microscope design, readily fabricable with e

61 , and fully on-chip microscopes based on the optofluidic microscopy (OFM) method.

62 ajor classes of lensless microscopy methods, optofluidic microscopy and digital in-line holography mi

63 cedures for implementing ultrathin, flexible optofluidic neural probe systems that provide targeted,

64 n protocols will increase access to wireless optofluidic neural probes for advanced in vivo pharmacol

65 Here, we introduce wireless optofluidic neural probes that combine ultrathin, soft m

66 Recent advances in optofluidics offer tremendous opportunities for biologic

67 Here, we present a unique optofluidic platform comprising organic molecules in sol

68 This optofluidic platform has advantages over traditional gen

69 hallenges, we developed a smartphone-enabled optofluidic platform to measure brain-derived exosomes.

70 e development of a simple and cost-effective optofluidic platform, integrating liquid-core PDMS waveg

71 lates were collected within 3.5 h using this optofluidic platform.

72 Miniaturizing optical trap instruments onto optofluidic platforms holds promise for high-throughput

73 Metallic nanopore arrays have emerged as optofluidic platforms with multifarious sensing and anal

74 In this work, we developed an optofluidic ring resonator (OFRR) sensor and the corresp

75 ally explore this scheme with a high-quality optofluidic ring resonator.

76 The optofluidic SERS device utilizes a porous microfluidic m

77 Using the optofluidic SERS device, the food contaminant melamine w

78 This combination of the optofluidic SERS microsystem with a portable spectromete

79 Here we present an optofluidic single-particle intrinsic dissolution rate (

80 Here, we present an optofluidic single-particle technique for microscale equ

81 ngation in a nanochannel and a technique for optofluidic surface enhanced Raman detection of nucleic

82 contaminants using a portable and automated optofluidic surface enhanced Raman spectroscopy (SERS) m

83 d demonstrated the feasibility of using this optofluidic system at different laboratories for bacteri

84 Our fully integrated optofluidic system successfully detected cocaine in real

85 The use of SU-8-based optofluidic systems (OFS) is validated as an affordable

86 and is also well in line with the spirit of optofluidics technology-fusion of optics and microfluidi

87 Optofluidics - the synergistic integration of photonics

88 eated and -untreated cells (N = 240,000) by optofluidic time-stretch microscopy with high throughput

89 Here we present an approach to optofluidic transport that overcomes these limitations,

90 rofluidic device also acts as a multilayered optofluidic waveguide and efficiently guides our excitat

91 ate for the first time that the design of an optofluidic waveguide system can be optimised to enable

92 to the xyz alignment of 2D flakes within the optofluidic waveguide.