ライフサイエンスコーパス: nucleic acid hybridization

1 d DAs are inherently tunable on the basis of nucleic acid hybridization.

2 e energy transfer (FRET) for transduction of nucleic acid hybridization.

3 a detailed understanding of the kinetics of nucleic acid hybridization.

4 e chemistry and are found to readily undergo nucleic acid hybridization.

5 al enzymatic reactions, metering, mixing and nucleic acid hybridization.

6 on conditions required for sequence-specific nucleic acid hybridization.

7 restriction digestion, Southern blotting, or nucleic acid hybridization.

8 red carbon-based materials with programmable nucleic acid hybridization.

9 ations influence the kinetics of solid-phase nucleic acid hybridizations.

10 ers suitable for image analysis and repeated nucleic acid hybridizations.

11 how m(6)A reshapes the kinetic landscape of nucleic acid hybridization and conformational transition

12 Cy5-FDNs were used to assay single-molecule nucleic acid hybridization and for immunofluorescence im

13 The results of in situ nucleic acid hybridization and GUS reporter gene fusion

14 Nucleic acid hybridization and HCV genotypic analysis co

15 Nucleic acid hybridization and immunoelectrophoresis stu

16 In situ nucleic acid hybridization and immunohistochemistry were

17 ignal amplification by RCA can be coupled to nucleic acid hybridization and multicolor fluorescence i

18 od provided a highly efficient substrate for nucleic acid hybridization and primer extension assays.

19 The biophysics of nucleic acid hybridization and strand displacement have

20 They accelerate nucleic acid hybridization and strand exchange, which ma

21 We used real-time quantitative PCR, in situ nucleic acid hybridization, and immunohistochemistry to

22 l data, peptide mapping of the coat protein, nucleic acid hybridization, and nucleotide sequence simi

23 By re-writing the rules for nucleic acid hybridization, Argonautes allow oligonucleo

24 The AMP CT is a sensitive and specific nucleic acid hybridization assay for the detection of C.

25 dida QuickFISH BC, a multicolor, qualitative nucleic acid hybridization assay for the identification

26 lutathione-coated QDs for the development of nucleic acid hybridization assay integrated on a paper-b

27 A multiplexed solid-phase nucleic acid hybridization assay on a paper-based platfo

28 A nucleic acid hybridization assay was assembled onto a ro

29 ement in limit of detection (LoD) in a 3 min nucleic acid hybridization assay.

30 some aspects, homogeneous (all-in-solution) nucleic acid hybridization assays are superior to the tr

31 are-wave voltammetry measurements applied to nucleic acid hybridization assays at the electrode surfa

32 l dyes or haptenes available for fluorescent nucleic acid hybridization assays is far greater than wh

33 velopment of paper-based solid-phase QD-FRET nucleic acid hybridization assays that make use of a rat

34 ment of sensitive TCL-based immunoassays and nucleic acid hybridization assays, in which the detectio

35 for the development of paper-based UCP-LRET nucleic acid hybridization assays, which offer potential

36 a molding (RM) for highly uniform and robust nucleic acid hybridization assays.

37 The use of nucleic acid hybridization-based assays has expanded our

38 Nucleic acid hybridization-based lateral flow assay (LFA

39 strate two nonstem-loop designs for light-up nucleic acid hybridization beacons that utilize time-res

40 er nanorod arrays as substrates for assaying nucleic acid hybridization by surface enhanced Raman sca

41 Two new approaches for nucleic acid hybridizations by MALDI-TOF mass spectromet

42 In addition, the principle of nucleic acid hybridization can be applied to realize mob

43 Generally, nucleic acid hybridization can be performed using two ma

44 By in situ nucleic acid hybridization, diabetic, but not nondiabeti

45 ences and the detection of sequence-specific nucleic acid hybridization events can be parallelized.

46 We have used a nucleic acid hybridization example to develop a theoreti

47 dology for the implementation of multiplexed nucleic acid hybridization fluorescence assays on microc

48 e method relies on concepts of additivity of nucleic acids hybridization free energies and on equilib

49 s method for visual detection of multiplexed nucleic acid hybridizations from complex media and devel

50 The programmability of nucleic acid hybridization has inspired applications bey

51 ewable microcolumn flow cell for solid-phase nucleic acid hybridization in an automated sequential in

52 However, the specificity of nucleic acid hybridization is compromised for long stran

53 A quantitative understanding of nucleic acid hybridization is essential to many aspects

54 anced Raman spectroscopy (SERS) detection of nucleic acid hybridization is impeded by poor spectral r

55 cability of SERS for label-free detection of nucleic acid hybridization is limited to short oligos of

56 Since this design is based purely on nucleic acid hybridization, it can be generally applied

57 noninvasively and site-specifically measure nucleic acid hybridization kinetics.

58 resolution by performing multiple cycles of nucleic acid hybridization of fluorescent molecular barc

59 for quantitative ratiometric transduction of nucleic acid hybridization on a paper-based platform usi

60 al imaging for a ratiometric transduction of nucleic acid hybridization on a paper-based platform.

61 "fingerprinting" techniques usually based on nucleic acid hybridization or enzymatic amplification.

62 d by ethidium bromide staining (PCR-ETBr) or nucleic acid hybridization (PCR-NA) to detect viral gene

63 ross-reacts with the M. tuberculosis complex nucleic acid hybridization probe, a M. tuberculosis gamm

64 B assay was compared to identification using nucleic acid hybridization probes and 16S rRNA gene sequ

65 Nucleic acid hybridization probes are sought after for n

66 The assay uses novel nucleic acid hybridization probes called molecular beaco

67 ic stability and specificity in conventional nucleic acid hybridization probes make it challenging to

68 length-shifting molecular beacons, which are nucleic acid hybridization probes that fluoresce in a va

69 azole) dibromide]), and neutral PNA (peptide nucleic acid) hybridization probes.

70 ysico-chemical foundation to modeling of the nucleic acids hybridization process on solid surfaces.

71 Remarkably, the first nucleic acid hybridization reaction was also described i

72 is (ITP) to control and increase the rate of nucleic acid hybridization reactions in free solution.

73 ology is a rapid, high-throughput method for nucleic acid hybridization reactions.

74 Nucleic acid hybridization serves as backbone for many h

75 Nucleic acid hybridization studies demonstrated the expr

76 DNA microchip technology as well as in other nucleic acid hybridization studies.

77 It is a nucleic acid hybridization test which uses signal amplif

78 ocused on the thermodynamics and kinetics of nucleic acid hybridization, the behavior of complex mixt

79 oassays for monitoring protease activity and nucleic acid hybridization; the latter included a dual t

80 phase assay is presented for transduction of nucleic acid hybridization using immobilized quantum dot

81 The selectivity of nucleic acid hybridization was demonstrated by single-nu

82 Nucleic acid hybridization with bPoNA enables DNA loadin

83 The assay exhibited rapid transduction of nucleic acid hybridization within minutes.