ライフサイエンスコーパス: DNA fingerprinting

1 or observations attributed to reinfection by DNA fingerprinting.

2 s of Mycobacterium avium could be matched by DNA fingerprinting.

3 and pulsed-field gel electrophoresis (PFGE) DNA fingerprinting.

4 sis isolates from the study period underwent DNA fingerprinting.

5 their pigs at birth were analyzed by genomic DNA fingerprinting.

6 epetitive-sequence polymerase chain reaction DNA fingerprinting.

7 repeats used for over 20 years in humans for DNA fingerprinting.

8 DNA fingerprinting analysis of serial sputum cultures fr

9 Genotypic analysis was done by IS6110 DNA fingerprinting and a novel strain-specific polymeras

10 IS6110 DNA fingerprinting and automated DNA sequencing of a reg

11 ability in the colonic mucosa as measured by DNA fingerprinting and fluorescent in situ hybridization

12 identified by randomly amplified polymorphic DNA fingerprinting and gene sequencing: one group from s

13 DNA fingerprinting and karyotype analysis demonstrated t

14 in GelBuddy has been successfully applied to DNA fingerprinting applications, such as AFLP.

15 able repetitive-sequence-based PCR (rep-PCR) DNA fingerprinting assay adapted to an automated format,

16 We investigated whether quantitative DNA fingerprinting, based on allele imbalance (AI) or lo

17 We apply HISAT2 for HLA typing and DNA fingerprinting; both applications form part of the H

18 Genomic DNA fingerprinting by pulsed-field gel electrophoresis r

19 DNA fingerprinting by pulsed-field gel electrophoresis s

20 In this study, we assessed whether DNA fingerprinting by repetitive element sequence-based

21 Unbiased DNA fingerprinting by the arbitrarily primed PCR allows

22 Supplementary analyses were done using DNA fingerprinting, cloning, and sequencing.

23 4%) of the remaining 168 isolates were in 15 DNA fingerprinting clusters, which ranged in size from 2

24 and are unlikely to affect findings based on DNA fingerprinting data.

25 ins inferred to be clonally related based on DNA fingerprinting) detected, one, lineage C, dominated

26 DNA fingerprinting establishes the genetic relatedness o

27 Identification of bacterial strains by DNA fingerprinting facilitates epidemiologic studies and

28 The study findings do not support the use of DNA fingerprinting for nosocomial tuberculosis surveilla

29 DNA fingerprinting helps determine loci of TB transmissi

30 Prospective surveillance and DNA fingerprinting identified the cluster, enabling heal

31 Importantly, DNA fingerprinting indicates that the human iPS cells we

32 the molecular epidemiology of tuberculosis, DNA fingerprinting is used to estimate the fraction of i

33 rep-PCR DNA fingerprinting is useful for strain typing and for e

34 sequencing and repetitive element PCR-based DNA fingerprinting, it was found that H. aurati represen

35 tion at vegetative incompatibility (vic) and DNA fingerprinting loci.

36 The use of DNA fingerprinting may be useful in subsequent epidemiol

37 In a pilot study of nine women, this DNA fingerprinting method distinguished CTV-05 from othe

38 North and South America and used a ribosomal DNA-fingerprinting method to compare bacterial community

39 e detection of mRNA expression, and numerous DNA fingerprinting methods have also proved valuable, be

40 ng two polymerase chain reaction (PCR)-based DNA fingerprinting methods, arbitrarily primed PCR and i

41 idlands from 2001-05 (n=20) were assessed by DNA fingerprinting (MIRU-VNTR and spoligotyping), with a

42 ude qualitative detection, sub-species-level DNA fingerprinting, molecular resistance testing and gen

43 IS711-based DNA fingerprinting of 23 isolates from marine mammals sh

44 The DNA fingerprinting of all M. tuberculosis isolates from

45 DNA fingerprinting of Mycobacterium tuberculosis is used

46 of relapse and reinfection, distinguished by DNA fingerprinting of Mycobacterium tuberculosis strains

47 Pulsed-field gel electrophoresis (DNA fingerprinting) of group A streptococcal isolates ob

48 r, recent analyses of the URA5 sequences and DNA fingerprinting patterns suggest significant genetic

49 as defined by insertion sequence (IS) IS6110 DNA fingerprinting, polymorphic GC-rich repetitive seque

50 es, and Southern blot hybridization with the DNA fingerprinting probe Ca3 combined with computer-assi

51 cted for DNA fingerprinting with the complex DNA fingerprinting probe Ca3.

52 microevolutionary changes identified by the DNA fingerprinting probe Cg6 and does not involve tandem

53 Molecular fingerprinting with Ca3, a complex DNA fingerprinting probe specific for C. albicans, and C

54 pecific for C. albicans, and Cd25, a complex DNA fingerprinting probe specific for C. dubliniensis, p

55 A complex 15-kb DNA fingerprinting probe, Cp3-13, was therefore isolated

56 rable for some applications than traditional DNA fingerprinting probes that detect tandemly repeated

57 re cloned and analyzed for their efficacy as DNA fingerprinting probes.

58 for antibiotic susceptibility, O:H serotype, DNA fingerprinting, pulsed-field gel electrophoretic pat

59 Short tandem repeats for DNA fingerprinting represents an efficient and reproduci

60 DNA fingerprinting results confirm that the NIKS cells o

61 Microsatellite DNA fingerprinting revealed that a male's relative sperm

62 is, mapping studies, human identity testing (DNA fingerprinting), sequence homology and population st

63 h a setting, we performed a population-based DNA fingerprinting study among TB patients in Botswana.

64 e patients had indistinguishable profiles by DNA fingerprinting, suggesting common-source exposure.

65 There was a common pattern of DNA fingerprinting, suggesting that the isolates belonge

66 Therefore, we applied a novel DNA fingerprinting technique based on polymerase chain r

67 n site PCR (IRS-PCR) is a recently described DNA fingerprinting technique based on selective amplific

68 The use of a supplemental DNA fingerprinting technique decreased clustering and im

69 Here we describe results from a DNA fingerprinting technique that overcomes this problem

70 fragment polymorphism (AFLP) is a PCR-based DNA fingerprinting technique.

71 c microbes works by genotyping isolates with DNA fingerprinting techniques and then using these genot

72 opulation from an undisturbed site, and (iv) DNA fingerprinting techniques can be exploited to unders

73 rms at least comparably to other established DNA fingerprinting techniques.

74 We present the use of short tandem repeat DNA "fingerprinting" technology as a method of early, de

75 DNA fingerprinting through tubulin-based polymorphism (T

76 We used multilocus minisatellite DNA fingerprinting to examine the local genetic structur

77 study of sufficient size and duration using DNA fingerprinting to investigate tuberculosis relapse a

78 We used DNA fingerprinting to test the assumption that tuberculo

79 the value of MLST relative to those of other DNA fingerprinting tools for discriminating among strain

80 ycobacterium tuberculosis isolates underwent DNA fingerprinting using IS6110 restriction fragment len

81 within the species that had been selected by DNA fingerprinting using probes linked to mating type.

82 DNA fingerprinting was performed on Mycobacterium tuberc

83 The efficacy of Cp3-13 for DNA fingerprinting was verified by a comparison of its c

84 DNA fingerprinting with a digoxigenin-labeled C. albican

85 f clinical E. coli mastitis were compared by DNA fingerprinting with enterobacterial repetitive inter

86 Candida albicans isolates were selected for DNA fingerprinting with the complex DNA fingerprinting p

87 Computer-assisted DNA fingerprinting with the complex probe Ca3 has been u

88 urrent infections was assessed by sequential DNA fingerprinting with the following three probes: the

89 We performed DNA fingerprinting with the IS6110 insertion sequence of

90 DNA fingerprinting with the IS6110 technique was not a s