ライフサイエンスコーパス: tooth surface

1 trol site (i.e., natural colonization of the tooth surface).

2 the presence of decayed, missing, or filled tooth surfaces).

3 supragingival plaque (PI > or =2 on >40% of tooth surfaces).

4 sting and newly formed alveolar bone and the tooth surface.

5 mutans attachment to and accumulation on the tooth surface.

6 liva, is a bacterial receptor that coats the tooth surface.

7 ortant role in microbial colonization of the tooth surface.

8 luid-derived protein layer that forms on the tooth surface.

9 sease induced by a biofilm that forms on the tooth surface.

10 uw ) distribution caused by the drops on the tooth surface.

11 dhesion of this gram-positive species to the tooth surface.

12 droxyapatite (sHA), an in vitro model of the tooth surface.

13 hanisms to colonize and form biofilms on the tooth surface.

14 oped that correlate with mineral loss of the tooth surface.

15 olonizers that initiate biofilm formation on tooth surfaces.

16 ing to be 27% for decayed and 14% for filled tooth surfaces.

17 protection against S. mutans colonization of tooth surfaces.

18 the salivary pellicle coating supragingival tooth surfaces.

19 the ability of some streptococci to colonize tooth surfaces.

20 may modulate oral bacterial colonization of tooth surfaces.

21 ty of S. sputigena to colonize supragingival tooth surfaces.

22 were collected from caries-free and carious tooth surfaces.

23 r that has a seamless interface with natural tooth surfaces.

24 antimicrobial protection to the mucosal and tooth surfaces.

25 ily exert their effects uniformly across all tooth surfaces.

26 odulate the dynamic formation of biofilms on tooth surfaces.

27 on cumulative caries increments on different tooth surfaces.

28 ry (d(2,3)fs) and total (d(2,3)fs+D(2,3)MFS) tooth surfaces.

29 the multispecies environment in biofilms on tooth surfaces.

30 and mediate sucrose-independent adherence to tooth surfaces.

31 rganisms, such as Streptococcus gordonii, to tooth surfaces.

32 anaerobes that initiate biofilm formation on tooth surfaces.

33 ed separate criteria for smooth and occlusal tooth surfaces.

34 ion of the acquired salivary pellicle on the tooth surface, a conditioned film that provides the crit

35 protein layer formed from natural saliva on tooth surfaces, acquired enamel pellicle (AEP), protects

36 outcomes within individual patients, such as tooth surfaces affected by a caries lesion, tended to be

37 hypothesize that such polishing may protect tooth surfaces against the damage caused by cariogenic b

38 Forty-two consented young adults, blinded to tooth surface allocation, were treated with resin infilt

39 the children had at least 1 unfilled decayed tooth surface and 33% had at least 1 filled surface.

40 bacteria that accumulate in a biofilm on the tooth surface and affect the adjacent periodontal tissue

41 occus sanguinis is an early colonizer of the tooth surface and competes with oral pathogens such as S

42 sucrose to initiate biofilm formation on the tooth surface and consequently produces lactic acid to d

43 romote accumulation of microorganisms on the tooth surface and further establishment of pathogenic bi

44 are initiated by bacteria that colonize the tooth surface and gingival sulcus, the host response is

45 uced by mutans streptococci demineralize the tooth surface and lead to dental caries.

46 us parasanguis is a primary colonizer of the tooth surface and plays a pivotal role in the formation

47 cocci and actinomyces and their adherence to tooth surface and the associated host cells are key earl

48 s streptococci are primary colonizers of the tooth surface and thus form the foundation for the compl

49 Actinomyces naeslundii to the saliva-coated tooth surface and to each other.

50 ciation between caries of the mid- dentition tooth surfaces and AJAP1 (p value = 2e-8), a gene possib

51 val dental plaque differ substantially among tooth surfaces and children of different caries activiti

52 It mediates attachment of S. mutans to tooth surfaces and has been a focus for immunization stu

53 f filled (p < 0.001) and decayed (p = 0.036) tooth surfaces and negatively associated with number of

54 les that selectively adsorb from saliva onto tooth surfaces and provides a protective interface betwe

55 tial adherence of S. mutans to saliva-coated tooth surfaces and subsequent development of dental cari

56 elies on the bacterium's ability to colonize tooth surfaces and survive a strongly acidic environment

57 er of decayed, missing, and filled permanent tooth surfaces and teeth, and the number of decayed, and

58 nd the number of decayed, and filled primary tooth surfaces and teeth.

59 ocesses are important in different groups of tooth surfaces and that innate liability to some pattern

60 utcomes (e.g., number of carious and missing tooth surfaces), and oral health-related quality of life

61 yces are the major initial colonizers of the tooth surface, and the interactions between them and the

62 sms are not so effective against biofilms on tooth surfaces, and oral hygiene measures such as brushi

63 tached gingiva, the calculus deposition over tooth surfaces, and the subgingival calculus that enable

64 al pH fluctuations within the biofilm on the tooth surface are a ubiquitous and natural phenomenon, t

65 Biofilms formed on tooth surfaces are comprised of mixed microbiota enmeshe

66 Tooth surfaces are exposed to different proteinaceous mi

67 ilm formation of Streptococcus mutans on the tooth surface as it directly regulates the extracellular

68 ying the 3D surface textures that develop on tooth surfaces as a consequence of feeding, we show that

69 silica nanoparticles were used to polish the tooth surfaces, as compared with conventional polishing

70 Tooth surfaces at baseline (preparation), after restorat

71 g the permanent dentition into categories of tooth surfaces based on co-occurrence of caries) to nomi

72 rgeting care to groups, individuals, or even tooth surfaces based on their caries risk has become a r

73 al remained over the dentin and at the outer tooth surface, but between these regions were invading f

74 Colonization of the tooth surface by actinomyces and viridans group streptoc

75 ted sequential nature of colonization of the tooth surface by members of different genera can be inve

76 parable to the shear stress generated at the tooth surface by salivary flow ( approximately 0.8 dyn/c

77 gen membrane that readily adapts to bone and tooth surfaces by a gel formation of collagen fibers and

78 al, sub-micrometre scale textures created on tooth surfaces by interactions with food, reveals that t

79 Percentages of tooth surfaces carrying dental plaque were 41% and 36% f

80 time, ease, number of strokes, and gingival/tooth surfaces changes were recorded.

81 For instance, tooth surfaces close to the gingival sulcus contact seru

82 g a split-mouth design, with half the buccal tooth surfaces coated with serum and the other half with

83 S. sanguinis, which yields understanding of tooth surfaces colonization and contributions to dental

84 her, we find that a rigorous cleaning of the tooth surface combining diluted bleach and UV light irra

85 Our null hypothesis is that tooth-surface defect dimensions, resulting from instrume

86 ies scores in groups of biologically similar tooth surfaces derived from hierarchical clustering of t

87 led teeth (DMF-Teeth) and decayed and filled tooth surfaces (DF-Surfaces).

88 tion time points, the microbiomes of healthy tooth surfaces differed substantially from those found d

89 e with baseline decayed, missing, and filled tooth surfaces (dmfs) (intercept) and rate of change in

90 d INT impact on decayed, missing, and filled tooth surfaces (dmfs) increment compared with UC.

91 to compute the decayed, missing, and filled tooth surfaces (DMFS) index and the number of remaining

92 umber of decayed, missing and filled primary tooth surfaces (dmfs) were used as a repeated outcome me

93 sion by monitoring thermal emission from the tooth surfaces during 30 s of air drying.

94 The mean number of tooth surfaces exposed to BisGMA materials (composites/s

95 tococcus mutans uses adhesin P1 to adhere to tooth surfaces, extracellular matrix components, and oth

96 entation may partially explain why groups of tooth surfaces form clusters within the mouth.

97 ed significantly more cellular attachment to tooth surfaces formerly covered by subgingival calculus

98 ary colonizer of the multispecies biofilm on tooth surfaces forming dental plaque and a potential age

99 ctinomyces that initiate colonization of the tooth surface frequently coaggregate with each other as

100 ibronectin in the attachment of cells to the tooth surface has been of considerable interest.

101 arasanguis FW213, a primary colonizer of the tooth surface, has been purified from the culture medium

102 ccus parasanguis, a primary colonizer of the tooth surface, has long, peritrichous fimbriae.

103 , clusters 1-5, groups of similarly behaving tooth surfaces identified through hierarchical clusterin

104 , clusters 1-5, groups of similarly behaving tooth surfaces identified through hierarchical clusterin

105 human dental caries, lives primarily on the tooth surface in biofilms.

106 growth and creates horizontal grooves on the tooth surface in humans and other mammals, yet there is

107 the number of untreated carious and missing tooth surfaces in adulthood.

108 5-2.9) and filled (OR, 1.4; 95% CI, 1.1-1.8) tooth surfaces in deciduous but not in permanent teeth.

109 of intact dental plaque biofilms on natural tooth surfaces in human subjects.

110 cterized by a dysbiotic shift at the biofilm-tooth surface interface, yet comprehensive biochemical c

111 cus gordonii to the acquired pellicle of the tooth surface involves specific interactions between bac

112 rasanguis FW213, a primary colonizer, to the tooth surface is mediated mainly by peritrichous long fi

113 Attachment of S. mutans to the tooth surface is required for the development of caries

114 n is initiated by bacteria that colonize the tooth surface, leading to inflammation and bone resorpti

115 y different (P < 0.001) when comparing sound tooth surfaces, lesion areas identified as arrested, and

116 herefore, we used hierarchical clustering on tooth surface-level caries data for 1,068 Appalachian ad

117 ing previously developed permanent dentition tooth surface-level dental caries pattern traits.

118 o stabilize disease or even remineralize the tooth surface, maximizing retention of tooth tissue and

119 Children had a mean of 15 tooth surfaces (median, 14) restored during the 5-year p

120 ar trial period, children had a mean of 18.7 tooth surfaces (median, 16) restored in the amalgam grou

121 a pathogenic shift in the composition of the tooth-surface microflora.

122 ion in its ability to adhere in the in vitro tooth surface model, saliva-coated hydroxylapatite (SHA)

123 restorations placed in previously unrestored tooth surfaces of 4,672 patients by 222 clinicians in th

124 genes may exert differential effects across tooth surfaces of the dentition.

125 teeth (OR = 0.86; 95% CI, 0.60 to 1.22) and tooth surfaces (OR = 0.85; 95% CI, 0.59 to 1.21) were ex

126 09) and a positive trend toward more decayed tooth surfaces (p = 0.027).

127 Plaque samples from caries-free tooth surfaces (PF) and from enamel carious lesions (PE)

128 C-terminal AgI/II fragments to the putative tooth surface receptor salivary agglutinin (SAG), as mon

129 ment loss can vary depending on the external tooth-surface reference points used.

130 A total of 115 tooth surface sites of 32 teeth from the 12 patients wer

131 Although repeated tooth-surface-specific information is commonly collected

132 was the sum of weighted counts of changes in tooth surface status over 13 months.

133 three coaggregating early colonizers of the tooth surface (Streptococcus gordonii DL1, Streptococcus

134 harides to enhance bacterial adhesion on the tooth surface; subsequent lactic acid production reduces

135 aces derived from hierarchical clustering of tooth surfaces (termed caries clusters).

136 t dentition can be subdivided into groups of tooth surfaces that are useful for understanding the fac

137 sis yielded evidence of 5 distinct groups of tooth surfaces that differ with respect to caries: (C1)

138 pragingival dental plaque was collected from tooth surfaces that were caries-lesion-free (PF) and fro

139 can be applied to at least three levels: the tooth surface, the individual, or the group/population.

140 MGS adhere rapidly to saliva-coated tooth surfaces, thereby providing an attachment substrat

141 proteins can promote cell attachment to the tooth surface; therefore, attempts have been made to uti

142 osteoclastic bone resorption on the coronal tooth surface to form an eruption pathway.

143 nctional epithelium directly attaches to the tooth surface via hemidesmosomes, a soft diet requires m

144 The time needed to clean each tooth/surface was recorded.

145 essary first step toward colonization of the tooth surface, we sought to determine what effect deleti

146 The number of untreated carious and missing tooth surfaces were associated with oral health-related

147 Resulting tooth surfaces were evaluated with a laser metrology sys

148 Images of the tooth surfaces were obtained by video camera and convert

149 sed on different ECC definitions and sets of tooth surfaces) were quantified using Brownian distance

150 ccus mutans proliferates as a biofilm on the tooth surface, where it obtains nutrients and metabolize

151 , initiate the formation of oral biofilms on tooth surfaces, which requires differential expression o

152 t 1 follow-up observation and had at least 1 tooth surface with dental caries.

153 e that 23.8 million persons have one or more tooth surfaces with > or = 3 mm gingival recession; 53.2

154 during oral surgery should saturate exposed tooth surfaces with amounts of fibronectin adequate for

155 ales had a lower number of untreated coronal tooth surfaces with caries (1.5), but a higher mean numb

156 the primary trait was the number of primary tooth surfaces with caries experience (i.e., dmfs index)

157 on using a dataset with 3 levels of nesting: tooth surfaces within an interproximal (IP) region, IP r

158 es outcomes defined as the number of carious tooth surfaces within each cluster.