ライフサイエンスコーパス: tooth wear

1 early detection and management of pathologic tooth wear.

2 d behavior and clinical evidence of abnormal tooth wear.

3 ermine if MAP users had distinct patterns of tooth wear.

4 d by dentine formation constraints and rapid tooth wear.

5 t by actual foods eaten, such as microscopic tooth wear.

6 tion of the causal role of reflux in erosive tooth wear.

7 Because tooth wear alters crown features gradually, testing whet

8 ffects on oral health, including significant tooth wear and damage, temporomandibular disorders (TMD)

9 dentists with clinically significant erosive tooth wear and increased esophageal acid exposure by 24-

10 We apply ageing, sexing, tooth wear and isotopic techniques to test the hypothesi

11 DJ), which is preserved in cases of moderate tooth wear and known to carry a strong taxonomic signal.

12 tudinal studies of reflux-associated erosive tooth wear and of reflux characteristics have been repor

13 longitudinal study in patients with erosive tooth wear and oligosymptomatic GERD receiving esomepraz

14 ated with bruxism can contribute to abnormal tooth wear and pain in the masticatory system.

15 IOSs facilitate quantitative monitoring of tooth wear and soft-tissue dimensions.

16 Moreover, skull shape, tooth wear, and isotopic data suggest that eastern-Berin

17 nal course of GERD and of associated erosive tooth wear, as well as factors predictive of its progres

18 antly associated with progression of erosive tooth wear at follow-up.

19 ll us what a tooth is capable of processing, tooth wear can help us to understand how teeth have been

20 These results suggest a tooth wear-determined, but rainfall-mediated, onset of r

21 receiving esomeprazole for one year, erosive tooth wear did not progress further in the majority of p

22 This in situ erosive tooth wear (ETW) study tested enamel 3-dimensional (3D)

23 Our data further show that excessive tooth wear eventually leads to a breakdown of the normal

24 We report that tooth wear exposes compensatory shearing blades that mai

25 Scanning electron microscopy study of tooth-wear facets and kinematic functional simulation of

26 patients presenting to dentists with erosive tooth wear have significant gastroesophageal reflux (GER

27 reptile based on repeatable observations of tooth wear in a large sample of intact jaws.

28 mineral dust/grit adhering to plants causes tooth wear in mammalian herbivores.

29 The tooth wear in Rododelphis and an extinct species of Orci

30 ntially snorted MAP had significantly higher tooth wear in the anterior maxillary teeth than patients

31 We analyzed tooth wear in three dimensions with dental topographic a

32 nstrate that total tooth volume and rates of tooth wear increased steadily during ornithopod evolutio

33 This heavy tooth wear might correlate with more intensive food proc

34 theless, the relationship between occlusion, tooth wear rate, and tooth replacement rate has been neg

35 ch count, tooth replacement rate, macrowear, tooth wear rate, traditional microwear, and dental micro

36 Here, we reconstruct tooth wear rates by measuring tooth replacement rates an

37 Dental microwear, the study of microscopic tooth-wear resulting from use, provides direct evidence

38 With increasing occlusal and interproximal tooth wear, the teeth continue to erupt, the posterior d

39 Craniodental morphology, tooth wear, torso vertebral morphology, and body size al

40 tes by measuring tooth replacement rates and tooth wear volumes, and document their dental microwear.

41 Tooth wear was documented for each study participant and

42 follow-up, no further progression in erosive tooth wear was observed in 53 (74%) of patients.

43 Predictive factors for erosive tooth wear were assessed by logistic regression.