ライフサイエンスコーパス: biomonitor

1 at current environmental exposures by human biomonitoring.

2 anding morpho-taxonomic approaches in future biomonitoring.

3 ast carcinogens in breast cancer studies and biomonitoring.

4 ose that have been observed in limited human biomonitoring.

5 This assay provides a new approach for biomonitoring alachlor levels in experimental animals an

6 Contamination with target analytes during biomonitoring analysis could result from solvents and re

7 and field-deployable tool for the effective biomonitoring and diagnosis of potential exposures to ne

8 hort study resources are available to expand biomonitoring and epidemiology related to breast cancer

9 or application of the shell as a longer-term biomonitoring and forensics tool for historic exposure.

10 and underscores the importance of continued biomonitoring and research efforts to elucidate current

11 ytes, we speculated on their possible use as biomonitors and bioremediation tools.

12 oral and spatial trends from Arctic wildlife biomonitoring, and suggest that the dominant PFOA source

13 Traditional and exposomic biomonitoring approaches have key advantages and disadva

14 DISCUSSION: Traditional and exposomic biomonitoring approaches have key advantages and disadva

15 y traditional and nontraditional (exposomic) biomonitoring are both critical in studies aiming to cap

16 Molecular epidemiology approaches in human biomonitoring are powerful tools that allow for verifica

17 owed implementation of the concepts of human biomonitoring at the community scale, opening the possib

18 and enable a noninvasive sampling method for biomonitoring BDEs in toddlers.

19 d suite of metabolites should be included in biomonitoring campaigns in order to fully characterize e

20 It could be shown that thyroid biomonitors can work under dry conditions, which potenti

21 as humans and represent a relevant model for biomonitoring combinations of environmental pesticide ex

22 oring-I (HBM-I) values from the German Human Biomonitoring Commission.

23 r scientific advances in analytical methods, biomonitoring, computation, and a newly articulated visi

24 0.0001, R2=0.39) with medians inferred using biomonitoring data for 39 chemicals from the National He

25 first time a means for examining population biomonitoring data for multiple environmental chemicals

26 s study also lead to better understanding of biomonitoring data from different blood matrices, which

27 tionally used for market basket analysis, to biomonitoring data from the 2009-2010 cycle of the conti

28 We used biomonitoring data from the U.S. Centers for Disease Con

29 Initial biomonitoring data have provided early indications of re

30 sed values now allow interpretation of these biomonitoring data in a public health risk context.

31 Biomonitoring data reported in the National Report on Hu

32 Biomonitoring data reported in the National Report on Hu

33 ated how FIM can be used in conjunction with biomonitoring data to narrow a large number of possible

34 g pharmacokinetic models-in conjunction with biomonitoring data, diary information, and other related

35 ions, these results, in the context of other biomonitoring data, suggest that earlier reported declin

36 tainty in these predictions by comparison to biomonitoring data.

37 try (LC-MS(n)) is the most common method for biomonitoring DNA adducts, generally targeting single ex

38 As the science and biomonitoring effort progress in this area, more data se

39 Biomonitoring Equivalents (BEs) and other risk assessmen

40 d analysis of the biospecimens collected for biomonitoring evaluations could compromise the reported

41 131)I, its apparent half-life in the thyroid biomonitor exceeds the physical one, thus making (131)I

42 immunoassay has been developed as a tool for biomonitoring exposures to organophosphate (OP) compound

43 ecting bird eggs is an established method of biomonitoring for specific pollution hazards.

44 through retrospective analyses of blood lead biomonitoring from the Bunker Hill Superfund Site in Ida

45 nte) birth cohort, in Sabadell, Spain, using biomonitoring, geospatial modeling, remote sensors, and

46 Human biomonitoring (HBM) often reveals statistical associatio

47 er screening values, including BEs and Human Biomonitoring-I (HBM-I) values from the German Human Bio

48 Mobile biomonitoring in long-term medical diagnostics is anothe

49 rful sources of targets for therapeutics and biomonitoring in oncology.

50 ld cohort and monitored drug intake by LC-MS biomonitoring in urine.

51 cognition as a potentially powerful tool for biomonitoring, including early detection of aquatic inva

52 Traditionally, marine biomonitoring involves the sorting and morphological ide

53 characterize environmental exposures through biomonitoring is key to exposome research efforts.

54 s during analysis of biological specimens in biomonitoring laboratories equipped with state-of-the-ar

55 A biomonitoring method was developed for the determination

56 Exposomic approaches differ from traditional biomonitoring methods in that they can include all expos

57 ifespan, both traditional and nontraditional biomonitoring methods should be used.

58 We describe the biomonitoring needs of exposome research and approaches

59 For the information obtained from biomonitoring, no association was found for ibuprofen an

60 ation of genetic tools for bioassessment and biomonitoring of aquatic ecosystems.

61 There is a clear need for continued biomonitoring of blood contaminant levels in this popula

62 enzymatic inhibition and phosphorylation for biomonitoring of exposure to organophosphorus (OP) pesti

63 ication of OP-BChE and enzyme inhibition for biomonitoring of OP and nerve agent exposures.

64 It includes the periodical biomonitoring of PCDD/Fs body burden.

65 based assay may enable frequent longitudinal biomonitoring of PFCs and other environmental toxins usi

66 for frequent blood sampling and longitudinal biomonitoring of PFCs.

67 Biomonitoring of pollutants and their metabolites and de

68 may be a useful noninvasive matrix for human biomonitoring of specific organic contaminants, but furt

69 The long-term biomonitoring of the effects of insecticide use on the n

70 Continued biomonitoring of these bisphenols in populations and fur

71 cursors) suggest that for general population biomonitoring of these nonpersistent phenols, urine, not

72 ing life span, suggesting their potential as biomonitors of aging.

73 Lichens have been used as biomonitors of the impacts of S for over 40 years, but t

74 Hence thyroid biomonitors offer even some quantitative information, wh

75 for organism bioaccumulation is viable when biomonitoring organisms are not available.

76 ap Fusion mass spectrometer were employed to biomonitor PhIP in dyed hair.

77 ic progress made during the 29 years of this biomonitoring program is relevant to future, large-scale

78 itu-based effects measures recorded during a biomonitoring program on a French watershed impacted by

79 (POPs) in Californians prompted the state's biomonitoring program to conduct a study in firefighters

80 DNA barcoding, have the potential to enhance biomonitoring programs worldwide.

81 he precautionary principle, establishment of biomonitoring programs, and funding of community-based e

82 cost and logistical constraints to existing biomonitoring programs.

83 ng opens up new perspectives in the field of biomonitoring providing a device with acceptable stabili

84 ated flame retardants (BFRs) in toddlers for biomonitoring purposes.

85 No biomonitoring reference data have been reported to chara

86 Biomonitoring results demonstrate that pregnant women in

87 ncentrations in organisms, interpretation of biomonitoring results, and assessment of toxicity.

88 and the integration of emerging techniques, biomonitoring strategies can be maximized in research to

89 Biomonitoring studies are conducted to assess internal d

90 Meta-HO-TPHP could be relevant for future biomonitoring studies concerning flame retardants.

91 We will apply the method in future human biomonitoring studies for OC exposure and risk assessmen

92 Human biomonitoring studies have shown that concentrations of

93 We recommend biomonitoring studies include these 6 DAPs as well as se

94 This lack of biomonitoring studies is partially due to the absence of

95 tives in canned foods and consumer products, biomonitoring studies of human exposure to these compoun

96 double the average intake levels observed in biomonitoring studies worldwide.

97 esults and the data obtained in two previous biomonitoring studies.

98 ereoisomer-specific HBCD exposures in future biomonitoring studies.

99 This human biomonitoring study presents the first body burden data

100 -health impact relationships from the NHANES biomonitoring survey studies.

101 Biomonitoring surveys, such as the NHANES (National Heal

102 Further biomonitoring to ascertain current trends and determinan

103 uggesting potential use of snail shells as a biomonitoring tool for metal contamination.

104 dy uses bird eggs of seven wild species as a biomonitoring tool for sunscreens occurrence.

105 luid that has not been used extensively as a biomonitoring tool in epidemiological studies.

106 to evaluate the utility of microarrays as a biomonitoring tool in field studies.

107 ing of COI could be a powerful and efficient biomonitoring tool to protect local aquatic ecosystems.

108 he importance of developing avian tissues as biomonitoring tools for assessing local risk of mercury

109 Small organisms can be used as biomonitoring tools to assess chemicals in the environme

110 g its potential for developing environmental biomonitoring tools, as it can provide an a priori asses

111 cation of DNA barcoding and metagenomics for biomonitoring using benthic macroinvertebrates.