ライフサイエンスコーパス: cariogenic

1 The reaction is specific for cariogenic actinomyces, and it can detect as few as 10(4

2 ounds, strengthening their potential as anti-cariogenic agents.

3 dental caries, is considered to be the most cariogenic among all oral streptococci.

4 luding non-mutans) provide binding sites for cariogenic and other organisms.

5 est a differential sensitivity to NO between cariogenic and periodontopathogenic bacteria with implic

6 Children are likely to acquire cariogenic bacteria from a variety of sources, including

7 In cigarette smokers, cariogenic bacteria from genus Streptococcus (including

8 t lipoteichoic acid (LTA) from Gram-positive cariogenic bacteria induces expression of vascular endot

9 nderstanding signaling pathways triggered by cariogenic bacteria may reveal novel therapeutic targets

10 iology that derives from the interplay among cariogenic bacteria on the dentition, the host diet, and

11 ldhood caries (ECC) and its association with cariogenic bacteria Streptococcus mutans remain unclear.

12 an also selectively target the EPS-producing cariogenic bacteria Streptococcus mutans with higher kil

13 A major concern is whether mothers transmit cariogenic bacteria to their children.

14 y period, putative periodontal pathogens and cariogenic bacteria were overabundant in the group that

15 influenced by host factors, dietary intake, cariogenic bacteria, and other microbes.

16 tooth surfaces against the damage caused by cariogenic bacteria, because the bacteria can be easily

17 tyle-related factors such as high numbers of cariogenic bacteria, inadequate salivary flow, insuffici

18 Dental caries is a cariogenic bacteria-mediated, fermentable carbohydrate-d

19 for Streptococcus mutans, the most abundant cariogenic bacteria.

20 In both experiments cariogenic bacterial recoveries were reduced relative to

21 The cariogenic bacterial species Streptococcus mutans metabo

22 ptococcus mutans is considered the principal cariogenic bacterium for dental caries.

23 S. mutans is a major cariogenic bacterium in the multispecies bacterial biofi

24 ALB/c mice with immune complexes (IC) of the cariogenic bacterium Streptococcus mutans and mAbs again

25 The cariogenic bacterium Streptococcus mutans employs so-cal

26 ase system (AgDS) has been identified in the cariogenic bacterium Streptococcus mutans UA159.

27 The cariogenic bacterium Streptococcus mutans uses adhesin P

28 Streptococcus mutans, a primary cariogenic bacterium, plays a central role in dental car

29 of extracellular polysaccharides (EPS) by a cariogenic bacterium, Streptococcus mutans (Cheng et al.

30 varying exposure durations on a multispecies cariogenic biofilm comprising C. albicans, L. casei, and

31 binding interactions with C. albicans during cariogenic biofilm development.

32 Effectively inhibiting cariogenic biofilms and reducing secondary caries could

33 Cariogenic biofilms are structured microbial communities

34 n building sticky glucan matrix to establish cariogenic biofilms by an important opportunistic pathog

35 reak down the EPS glucan matrix in preformed cariogenic biofilms, markedly enhancing bacterial killin

36 film therapy of both single and multispecies cariogenic biofilms.

37 syltransferase (GtfBCD) enzymes to establish cariogenic biofilms.

38 alistic role of S. mutans and C. albicans in cariogenic biofilms.

39 sion could lead to new approaches to control cariogenic biofilms.

40 rs associated with the evolution of virulent-cariogenic biofilms.

41 urring agents that affect the development of cariogenic biofilms.

42 Sucrose has long been regarded as the most cariogenic carbohydrate.

43 amine fluoride, on human dental enamel under cariogenic challenge in situ.

44 A cariogenic challenge was provided in all cases by 5 dail

45 rvoir in plaque that can resist a subsequent cariogenic challenge.

46 the experimental gum may help resist future cariogenic challenges.

47 it affords any protection against subsequent cariogenic challenges.

48 s further support the concept that increased cariogenic conditions are associated with increased prop

49 osition in the 3-species biofilm model under cariogenic conditions.

50 initiation and subsequent development under cariogenic conditions.

51 ide protection during subsequent exposure to cariogenic conditions.

52 of the mineral ions were mobilized under non-cariogenic conditions.

53 Diabetes, current smoking and a frequent cariogenic diet were significantly associated with TL-In

54 rats that were infected with ACUS6 and fed a cariogenic diet with drinking water containing 25 mM ure

55 ontitis and caries (diabetes, smoking, and a cariogenic diet).

56 When challenged with S. mutans and a cariogenic diet, total smooth and sulcal surface lesions

57 e to extensive oral soft tissue damage and a cariogenic diet.

58 eptococcus mutans (sobrinus) 6715, and fed a cariogenic diet.

59 ral bacterial community as a whole to become cariogenic during the onset and progression of ECC, whic

60 ated drinking water attenuated the potential cariogenic effect of both lack of and sustained breastfe

61 than a conventional gum in ameliorating the cariogenic effects of sucrose.

62 esponse to the pH decrease associated with a cariogenic episode are important components of the carie

63 containing strains produced more acid, a key cariogenic feature, and less biofilm than the model cari

64 Frequent consumption of cariogenic foods and bacterial infection are risk factor

65 eptococcus australis and negatively with the cariogenic Lactobacillus genus, suggesting V. rogosae as

66 ically include oral hygiene level, counts of cariogenic micro-organisms in plaque and saliva, fluorid

67 etic risk strata, preventing colonization of cariogenic microbiomes would be universally beneficial.

68 s on infants' acquisition of a member of the cariogenic microbiota, and its potential effect on carie

69 ication that leads to the establishment of a cariogenic microflora and demineralization of the tooth.

70 e is multifactorial, but a primary factor is cariogenic microorganisms such as Streptococcus mutans.

71 t GTF to enhance protective immunity against cariogenic microorganisms.

72 ) worldwide and is considered to be the most cariogenic of all of the oral streptococci.

73 response to accumulated plaque select for a cariogenic or periopathogenic microbiota, respectively,

74 cognized as microbial biofilms with healthy, cariogenic, or periodontopathogenic profiles, resulting

75 These provide a substrate for cariogenic oral bacteria to flourish and to generate ena

76 development of agriculture, mediated by the cariogenic oral bacterium Streptococcus mutans.

77 be harder to detect when not accounting for cariogenic oral microbiomes.

78 We determined the requirement in the cariogenic oral pathogen Streptocococcus mutans of the t

79 Streptococcus mutans is a cariogenic oral pathogen whose virulence is determined l

80 mmunized mice maintained high levels of this cariogenic organism ( approximately 60% of the total ora

81 -ECC group containing higher levels of known cariogenic organisms.

82 onment of the oral cavity suggests that this cariogenic pathogen is capable of sensing and responding

83 a direct cell-to-cell interaction, while the cariogenic pathogen Streptococcus mutans (mutans group)

84 ial colonization of the oral cavity with the cariogenic pathogen Streptococcus mutans and other bacte

85 The cariogenic pathogen Streptococcus mutans contains two CR

86 ed for its ability to remove biofilms of the cariogenic pathogen Streptococcus mutans UA159, as well

87 robial peptide, was able to selectively kill cariogenic pathogen Streptococcus mutans with high effic

88 hts on how S. mutans may have become a major cariogenic pathogen.

89 ompositions via bioactive resins to suppress cariogenic/pathogenic species and promote benign species

90 sional structure exhibited densely clustered cariogenic pathogens that were surrounded by outer layer

91 solutions simulating resting (pH = 5.6) and cariogenic plaque fluid (pH = 4.8).

92 glucosyltransferase activity restores a less cariogenic plaque structure.

93 membrane potentials became more negative in "cariogenic plaque" solution for all types of sections: s

94 f the wells showing anion selectivity in the cariogenic "plaque-like" solution.

95 pic level, notably in the differences in the cariogenic potential between strains.

96 ls in post-sucrose plaque fluids reflect the cariogenic potential of dental plaque.

97 ropose that the absence of GbpA elevates the cariogenic potential of S. mutans by altering the struct

98 The cariogenic potential of S. mutans is related to its abil

99 The cariogenic potential of these organisms was evaluated in

100 Processed starches have cariogenic potential when accompanying sucrose, but huma

101 dental plaque in such a way as to reduce its cariogenic potential.

102 vivo finding that sucrose has the strongest cariogenic potential.

103 Oral microbiomes vary in cariogenic potential; these differences may be establish

104 biofilm was predicted to be always or never cariogenic, respectively.

105 Despite the cariogenic role of Candida suggested from recent studies

106 s GBP-B can have a protective effect against cariogenic S. mutans infection and disease.

107 However, having a cariogenic salivary bacterial CST at 24 mo was associate

108 worsens rapidly and can lead to hypotension, cariogenic shock, or even damage to multiple organs.

109 in every enamel well in either "resting" or "cariogenic" solution.

110 situ acid production and distribution by the cariogenic species S. mutans.

111 One example are the interactions between the cariogenic species Streptococcus mutans and oral commens

112 viously, we presented evidence that the oral cariogenic species Streptococcus mutans remains viable b

113 % of their oral bacterial spectra, including cariogenic species.

114 nic feature, and less biofilm than the model cariogenic strain S. mutans UA159, suggesting the import

115 he immune response to a protein antigen from cariogenic streptococci, potentially through suppressive

116 uction of dental caries by interference with cariogenic streptococci.

117 s in phenotypes when cocultured with another cariogenic Streptococcus (Streptococcus sobrinus) or wit

118 ble bactericidal effect was observed against cariogenic Streptococcus mutans at pH 7.4, even when usi

119 Cariogenic Streptococcus mutans is known as a predominan

120 occus gordonii, Streptococcus sanguinis, and cariogenic Streptococcus mutans.

121 fic permease, in the transport of sucrose by cariogenic Streptococcus mutans.

122 nd/or 11 plus 16, followed by infection with cariogenic Streptococcus sobrinus.

123 ce the level of dental caries caused by this cariogenic streptococcus.

124 nced by host genetic background, potentially cariogenic taxa are likely not controlled by genetic fac

125 BCS3-L1 was significantly less cariogenic than JH1140 in both gnotobiotic- and conventi

126 e-dependent adherence and significantly less cariogenic than the UA130 wild-type progenitor in germfr

127 ii colonization abundance: the former highly cariogenic, the latter not.

128 contributions on the ratio of aciduric (i.e. cariogenic) to non-aciduric bacteria to be unambiguously

129 low pH appears to be an important bacterial cariogenic trait.

130 BL-BGC was further investigated by examining cariogenic traits and strain fitness in a deletion mutan

131 At >= 1.0xMIC50, DKG impaired cariogenic traits of S. mutans with reduced biofilm form

132 via SmNiaR contributes significantly to the cariogenic virulence of S. mutans.

133 h prevalence of caries to reliance on highly cariogenic wild plant foods in Pleistocene hunter-gather