ライフサイエンスコーパス: molecular typing

1 cid sequences of the peptide-binding region (molecular typing).

2 ive adhesin protein (PvpA) as the target for molecular typing.

3 ed for antifungal susceptibility testing and molecular typing.

4 ent antimicrobial susceptibility testing and molecular typing.

5 iverse species and strains, as determined by molecular typing.

6 their exacerbation (72%), was analyzed using molecular typing.

7 ous for early detection and is essential for molecular typing.

8 genous strains is often made on the basis of molecular typing.

9 Some MRSA isolates were not available for molecular typing.

10 ecimens were cultured and isolates underwent molecular typing.

11 hly in a prospective study were subjected to molecular typing.

12 (A to H), which are distinguishable only by molecular typing.

13 On the basis of molecular typing, an exacerbation was diagnosed at 33.0

14 We also performed molecular typing and in vitro susceptibility testing of

15 Molecular typing and virulence analysis are powerful too

16 by using a chromogenic medium, subculturing, molecular typing, and antifungal susceptibility testing

17 related infection, characterized microbes by molecular typing, and determined their susceptibility to

18 cterized, including susceptibility profiles, molecular typing, and molecular characterization of plas

19 m may be useful for epidemiological studies, molecular typing, and surveillance of Aspergillus specie

20 The applicability of this molecular typing assay for environmental studies was dem

21 commercially available HAdV PCR assay and a molecular typing assay for species identification.

22 Methods for molecular typing based on phylogenetic comparisons of a

23 Molecular typing based on the allelic profile of houseke

24 rriage in a contact patient was positive and molecular typing by pulsed-field gel electrophoresis (PF

25 Serotyping and molecular typing by pulsed-field gel electrophoresis wer

26 Molecular typing by three independent methods establishe

27 ens from leprosy patients for the purpose of molecular typing by using short tandem repeats; the succ

28 Since molecular typing can complement contact tracing for reco

29 Molecular typing can estimate an E. coli isolate's extra

30 ifferent molecular typing systems, and thus, molecular typing cannot be the only means used to track

31 Molecular typing complements sequence-based identificati

32 Molecular typing confirmed these changes were likely due

33 Limited comprehensive molecular typing data exist currently for Panton-Valenti

34 tory infection were characterized to compile molecular typing data spanning 37 years (1978-2014).

35 for class I HLA antigens and low-resolution molecular typing for class II HLA alleles.

36 Case records were reviewed and molecular typing for common carbapenemases was performed

37 tion, we have developed a technique based on molecular typing for HLA class II alleles, which enables

38 Because molecular typing has been increasingly used since 1996,

39 Molecular typing identified 120 episodes of acquisition

40 Molecular typing identified 3 statistically distinct gen

41 Molecular typing indicated that the outbreak was due to

42 Molecular typing is an important adjunct to nucleic acid

43 These results indicate that PrP(Sc) molecular typing is based on quantitative rather than qu

44 In conclusion, molecular typing lowered the rate of DR and DQ blanks, b

45 el, based on 14 gene parameters, including 3 molecular typing markers and 11 genes implicated in redu

46 ation was evident between the results of one molecular typing method and those of the others, suggest

47 A molecular typing method based on the 16S rRNA sequence d

48 nce typing (MLST) is a highly discriminatory molecular typing method that defines isolates of bacteri

49 We therefore developed a molecular typing method to examine these isolates.

50 We report on a comparison of four molecular typing methods (ribotyping, pulsed-field gel e

51 Combining molecular typing methods and geographical information sy

52 Molecular typing methods can discriminate unique alleles

53 Molecular typing methods combined with spatial analysis

54 Commonly used rapid molecular typing methods often leave large groups of Man

55 Molecular typing methods were used to characterize 38 Es

56 fication can be coupled with error-sensitive molecular typing methods with low-copy-number sequences

57 The molecular typing methods, i.e., PFGE, MLST, and Rep-PCR,

58 Three molecular typing methods, IS6110 restriction fragment le

59 Among the several molecular typing methods, pulsed-field gel electrophores

60 ducibility were compared with those of other molecular typing methods.

61 and capable of higher throughput than other molecular typing methods.

62 from a single institution, were identical by molecular typing methods.

63 tes prior to conducting more labor-intensive molecular typing methods.

64 ed by antibiotic susceptibility patterns and molecular typing methods.

65 morphism (RFLP) analysis and three PCR-based molecular typing methods: random amplified polymorphic D

66 from cultures of sputum was performed by two molecular typing methods: spacer oligonucleotide typing

67 Current molecular-typing methods for detection of outbreaks and

68 is the current "gold standard" for bacterial molecular typing, multilocus sequence typing (MLST) may

69 Molecular typing of 246 Staphylococcus aureus isolates f

70 The molecular typing of 81 pretreatment Helicobacter pylori

71 iguous and electronically portable, allowing molecular typing of bacterial pathogens (or other infect

72 We used molecular typing of Borrelia burgdorferi isolates obtain

73 latively rapid and discriminatory method for molecular typing of C. rugosa in outbreaks.

74 Molecular typing of ESBL-producing E. coli is useful for

75 Advances in molecular typing of fusariosis would facilitate the stud

76 protocols were prepared for serological and molecular typing of GBS strains based on the Strep-B-Lat

77 and epidemiological data were combined with molecular typing of gonococcal isolates by a new methodo

78 Included were studies in which molecular typing of HLA-DRB1 alleles was performed and i

79 Molecular typing of HLA-DRB1 and HLA-DQB1 alleles reveal

80 In addition to case ascertainment, molecular typing of isolates was performed to characteri

81 Clinical information, sputum cultures, molecular typing of isolates, and immunoassays to measur

82 High resolution molecular typing of large, clinically well-defined cohor

83 hat RAPD and AFLP provide valuable tools for molecular typing of M. bovis.

84 ng loci, has become the method of choice for molecular typing of many bacterial and fungal pathogens

85 Molecular typing of Mycobacterium tuberculosis by using

86 Molecular typing of Mycobacterium tuberculosis can be us

87 repeat (VNTR) analysis (MLVA) method for the molecular typing of Mycoplasma pneumoniae.

88 Molecular typing of Neisseria gonorrhoeae and contact tr

89 Molecular typing of Neisseria gonorrhoeae strains is an

90 Molecular typing of NTHi strains revealed that five of n

91 ative catheter cultures, blood cultures, and molecular typing of organisms to determine catheter-rela

92 sequence itself and have been useful for the molecular typing of other organisms.

93 Molecular typing of S aureus strains was performed by re

94 Molecular typing of sputum isolates of nonencapsulated H

95 ic systems in A. fumigatus; for example, the molecular typing of strains during infection.

96 Molecular typing of the abnormal form of the prion prote

97 Detailed molecular typing of the above alleles has previously not

98 Molecular typing of the actinomycete Rhodococcus equi is

99 were improved to enable rapid and convenient molecular typing of the strains.

100 Molecular typing of the tumor by DNA sequencing supports

101 Continued molecular typing of this organism, particularly during o

102 spacer region (ISR) sequence analysis to the molecular typing of U.S. PDD-associated Treponema isolat

103 We conducted a case-series investigation, molecular typing of viral isolates, surveys of rates of

104 typing (NG-MAST) is a highly discriminatory molecular typing procedure that provides precise and una

105 ak setting was identified using a variety of molecular typing procedures, resulting in two P1 genotyp

106 plified and sequenced, and the antigenic and molecular typing results agreed for all isolates.

107 Molecular typing results obtained both by spa sequencing

108 Molecular typing revealed marked temporal clustering of

109 Molecular typing revealed that almost all patients withi

110 Molecular typing revealed that the strains harbored the

111 yping for Antimicrobial Resistance (NG-STAR) molecular typing scheme uses the DNA sequences of 7 gene

112 5 KD samples were unable to be cultured and molecular typing showed either HAdV-C (n = 3) or were no

113 Molecular typing showed that all P. fluorescens isolates

114 Molecular typing showed that most patients had similar s

115 identified a single physician (physician 4); molecular typing showed that the MRSA strain from physic

116 These changes and molecular typing suggest that the United States is on th

117 Molecular typing suggested the spread of a single genoty

118 In this paper, we present a novel molecular typing system based on rapidly evolving variab

119 We have developed a molecular typing system based on reverse transcription-P

120 No molecular typing system currently exists to allow for th

121 We recently developed a molecular typing system for Campylobacter jejuni and Cam

122 tilizing these polymorphisms, we developed a molecular typing system that allows for the genetic diff

123 We propose that the scheme is an important molecular typing system to allow accurate and reproducib

124 botyping in conjunction with a semiautomated molecular typing system.

125 cent years a wide variety of biochemical and molecular typing systems has been employed in the study

126 Molecular typing systems have shown associations of V. v

127 lar fingerprint of a strain in two different molecular typing systems, and thus, molecular typing can

128 ping (MLST) approach with a well-established molecular typing technique, pulsed-field gel electrophor

129 is review, we highlight the role that modern molecular typing techniques can play in tracking and abo

130 system would be greatly bolstered by use of molecular typing techniques to identify genetic subtypes

131 relation between Vsp profiles and any of the molecular typing techniques was observed.

132 Vsp) profiles on the profiles generated with molecular typing techniques was studied.

133 . aureus were collected and characterized by molecular typing techniques.

134 KG2 genes from 68 donors were analyzed using molecular typing techniques.

135 re characterized by a combination of several molecular typing techniques: multilocus sequence typing,

136 We did molecular typing to investigate genetic relatedness of n

137 he performance of the DiversiLab system as a molecular typing tool for 69 Aspergillus isolates (38 A.

138 typing by PFGE appears to be the most useful molecular typing tool for discrimination among strains o

139 WGS has come of age as a molecular typing tool to inform national surveillance of

140 The availability of discriminatory molecular typing tools to inform and assist conventional

141 Molecular typing was done, and risk factors for MRSA col

142 Molecular typing was performed in almost all studies, wi

143 Molecular typing was performed on E. coli isolates to de

144 Molecular typing was used to elucidate Neisseria gonorrh

145 Molecular typing with IS6110 was applied to Mycobacteriu

146 ricin B, voriconazole, and itraconazole; and molecular typing with random amplification of polymorphi

147 Molecular typing with the RAPD technique was useful in d