ライフサイエンスコーパス: periodontal bone loss

1 ic regimen targeting DC-STAMP could suppress periodontal bone loss.

2 hat resembles pulpitis while also displaying periodontal bone loss.

3 al link between neuronal TRPV1 signaling and periodontal bone loss.

4 hat TLR9 signaling mediates the induction of periodontal bone loss.

5 periodontitis and contribute to induction of periodontal bone loss.

6 eir growth and differentiation contribute to periodontal bone loss.

7 ignificant reduction in number of teeth with periodontal bone loss.

8 ienced >60% more naturally occurring chronic periodontal bone loss.

9 ture delineation of the precise mechanism of periodontal bone loss.

10 een recognized as a key factor implicated in periodontal bone loss.

11 ntitis, as evidenced by reduced induction of periodontal bone loss.

12 cannot be complacent about the diagnosis of periodontal bone loss.

13 axillary jaws were removed for assessment of periodontal bone loss.

14 ce of factors that may be involved in active periodontal bone loss.

15 he possible role of PLAP-1 and sclerostin in periodontal bone loss.

16 ion of Pg-LPS-induced osteoclastogenesis and periodontal bone loss.

17 central proinflammatory cytokine related to periodontal bone loss.

18 teria are associated with the progression of periodontal bone loss.

19 mic PTB administration significantly reduced periodontal bone loss, AGE deposition, and expressions o

20 lla forsythia is also a vital contributor to periodontal bone loss, almost nothing is known about imm

21 Periodontal bone loss (an index of PD severity) was eval

22 a relationship between poor oral hygiene or periodontal bone loss and chronic obstructive pulmonary

23 ingiva of mandibular first molars to measure periodontal bone loss and collagen content.

24 cco use is generally linked with accelerated periodontal bone loss and diminished post-surgical wound

25 This effect might be important for periodontal bone loss and for the enhanced bone loss see

26 , in part, explain the increased rapidity of periodontal bone loss and refractory disease incidence i

27 Periodontal bone loss and tooth mobility were also incre

28 thod was evaluated for its ability to detect periodontal bone loss and was compared with that of conv

29 mmatory processes affecting atherosclerosis, periodontal bone loss ,and possibly, diet-induced weight

30 treatment of estrogen deficiency-aggravated periodontal bone loss, and berberine represents a promis

31 is critical for macrophage polarization and periodontal bone loss, and for the first time, to our kn

32 Periodontal bone loss appears to be a major factor in th

33 g to this definition, the patients exhibited periodontal bone loss at a much higher prevalence (60%)

34 dal anti-inflammatory drugs (NSAIDs) inhibit periodontal bone loss, but little is known about the mec

35 e, we hypothesize that berberine ameliorates periodontal bone loss by improving the intestinal barrie

36 CD5(+) B cell transfer demonstrated reduced periodontal bone loss compared to the no-transfer group

37 significant in multivariable models), while periodontal bone loss did not.

38 AG reduced periodontal bone loss during the induction of experiment

39 th rHag B on protection against experimental periodontal bone loss following infection with P. gingiv

40 sion) in which there is a furcal lesion with periodontal bone loss; Group I (intermediate) in which t

41 vD1) confers protection against IL-17-driven periodontal bone loss in a Del-1-dependent manner, indic

42 Coffee consumption may be protective against periodontal bone loss in adult males.

43 Dry mouth may indicate periodontal bone loss in children with diabetes.

44 ne the effects of TLR-activated B10 cells on periodontal bone loss in experimental periodontitis.

45 ic animals revealed higher susceptibility to periodontal bone loss in Mc3r(-/-) compared with wild-ty

46 aboratory revealed that T. forsythia induces periodontal bone loss in mice and that this bone loss de

47 ined the extent and severity of radiographic periodontal bone loss in patients with different stages

48 ntal contribution of periodontal bacteria to periodontal bone loss in patients with MetS remains uncl

49 icroinjection of anti-MFG-E8 mAb exacerbated periodontal bone loss in wild-type mice.

50 r TLR2-deficient mice were both resistant to periodontal bone loss, in stark contrast with wild-type

51 Finally, radiographic measurements of periodontal bone loss indicated that rats immunized with

52 ge-associated disorder clinically defined by periodontal bone loss, inflammation of the specialized t

53 vivo studies revealed that ligature-induced periodontal bone loss is significantly greater in Akita

54 ion, using a P. gingivalis infection-induced periodontal bone loss model, we found that SGK1 inhibiti

55 fic Stat3-deficient mice exhibited increased periodontal bone loss (p < 0.001), whereas T cell- and B

56 in significantly restricted ligature-induced periodontal bone loss (P <0 .01) and suppressed the leve

57 in significantly restricted ligature-induced periodontal bone loss (P <0 .01) and suppressed the leve

58 hydrogel sites showed significantly reduced periodontal bone loss (P <0.05) and inflammatory infiltr

59 ings of the upper posterior teeth, including periodontal bone loss, periapical lesions, and root cana

60 lysis was used to determine the influence of periodontal bone loss, periapical lesions, and root cana

61 h hypophosphatemic rickets are more prone to periodontal bone loss than the general population and ma

62 Th17-to-Tfh plasticity resulted in elevated periodontal bone loss that was not simply due to increas

63 in 2 (NOD2) signaling in atherosclerosis and periodontal bone loss using an Apolipoprotein E(-/-) (Ap

64 ligand (RANKL), which, in turn, promotes the periodontal bone loss via upregulation of osteoclastogen

65 ctices were determined by questionnaire, and periodontal bone loss was defined as alveolar bone loss

66 Periodontal bone loss was induced in 16-wk-old myeloid-s

67 Periodontal bone loss was measured via histological and

68 with experimental periodontitis, significant periodontal bone loss was noted in animals both with and

69 Severe periodontal bone loss was significantly associated with

70 Severe periodontal bone loss was significantly associated with

71 Periodontal bone loss was significantly associated with

72 Periodontal bone loss was significantly decreased and th

73 In the induction sites, periodontal bone loss was significantly reduced (P <0.05

74 The CsA-induced attenuation of periodontal bone loss was strongly correlated positively

75 Periodontal bone loss was three times more common among

76 Sinuses with severe periodontal bone loss were three times more likely to ha

77 reased inflammation, osteoclastogenesis, and periodontal bone loss when transferred to normal germ-fr

78 e correlations of CsA-induced attenuation of periodontal bone loss with the expressions of gelatinase