ライフサイエンスコーパス: phytoremediation

1 e both problems, via Se biofortification and phytoremediation.

2 effective, aesthetically pleasing technology-phytoremediation.

3 edible crops or promoting PFOS uptake during phytoremediation.

4 oted hyperaccumulator growth and facilitated phytoremediation.

5 may be applied in crop biofortification and phytoremediation.

6 ntrations, raising concern about its use for phytoremediation.

7 egume herbs provides an effective way for Pb phytoremediation.

8 nts of technical installations to facilitate phytoremediation.

9 CDDs, PCDFs and dl-PCBs may be removed using phytoremediation.

10 n capacity of plants as a potential route to phytoremediation.

11 t to the field of natural endophyte-assisted phytoremediation.

12 the development of improved plants for metal phytoremediation.

13 plant and one that is frequently utilized in phytoremediation.

14 owth, productivity, carbon sequestration and phytoremediation.

15 ribute to the wider and safer application of phytoremediation.

16 and heavy metals and is successfully used in phytoremediation.

17 pNifS overexpressors show promise for use in phytoremediation.

18 wledge to enhance the capacity of plants for phytoremediation.

19 s suggests some of them as candidates for Se phytoremediation.

20 erance and of a plant's potential for use in phytoremediation.

21 the effectiveness of transgenic poplars for phytoremediation.

22 e, providing an attractive technology for Se phytoremediation.

23 toxic impacts to plants used in this type of phytoremediation.

24 a have an inherited advantage in phosphonate phytoremediation.

25 Phytoremediation, a cost-effective, eco-friendly alterna

26 and time-consuming, particularly when using phytoremediation, a long-term remedial approach.

27 As a model system for RDX phytoremediation, A. thaliana expressing xplA was grown

28 is study revealed the synergistic effects of phytoremediation and bioaugmentation on 6:2 FTSA removal

29 he potential application of these species in phytoremediation and bioenergy applications is discussed

30 oward xenobiotics is of major importance for phytoremediation applications.

31 l not only be investigated in the context of phytoremediation but also from a clinical parasitologica

32 ork has the potential to increase the use of phytoremediation by decreasing toxicity and increasing d

33 n that will contribute to the advancement of phytoremediation by the future engineering of plants wit

34 This phytoremediation, by macrophytes, is expected to reduce

35 Characterizing the efficacy of phytoremediation can be challenging as residence time, t

36 We argue that success in phytoremediation can be hastened through understanding t

37 model plant Arabidopsis to determine whether phytoremediation can be used to clean up contaminated si

38 brane proteins could further enhance mercury phytoremediation capabilities.

39 for the creation of plants with enhanced Se phytoremediation capacity.

40 oduction of plants with superior heavy metal phytoremediation capacity.

41 may have implications for the development of phytoremediation concepts.

42 f nitroreductase (NR) in plants suitable for phytoremediation could facilitate the effective cleanup

43 trategies for developing transgenic improved phytoremediation cultivars for commercial use.

44 Our study investigated the phytoremediation efficiency and ion uptake mechanisms of

45 r concentrations, demonstrating its superior phytoremediation efficiency compared to wheat.

46 In summary, to maximize phytoremediation efficiency of hydrophobic pollutants in

47 systematically investigated the potential of phytoremediation for 6:2 FTSA byArabidopsis thalianacoup

48 nderstanding of plant activities critical to phytoremediation has been achieved, but recent progress

49 Plant-based environmental remediation, or phytoremediation, has been widely pursued in recent year

50 s (a macroalga, Chara canescens) for SeCN(-) phytoremediation in upland and wetland situations, respe

51 tes the importance of microscopy methods for phytoremediation investigations.

52 Phytoremediation is a potentially low cost remediation t

53 Phytoremediation is a technique that offers an environme

54 Phytoremediation is an inexpensive and effective techniq

55 of chloroplast transformation to enhance Hg phytoremediation is particularly beneficial because it p

56 Phytoremediation is the use of plants to clean up enviro

57 A major goal of phytoremediation is to transform fast-growing plants wit

58 d inaccessible nature of contaminated areas, phytoremediation may be a viable clean-up approach.

59 ves may be an important, yet under-explored, phytoremediation mechanism.

60 leaf tissue could potentially be used in the phytoremediation of any pollutant for which it is possib

61 ne the potential impact of photolysis on the phytoremediation of contaminants.

62 ing CYP76B1 may also be a potential tool for phytoremediation of contaminated sites.

63 applications for recycling industrial waste, phytoremediation of contaminated soils and biofortificat

64 adaptability, especially for reclamation and phytoremediation of contaminated soils and waters.

65 e been reported in the use of plants for the phytoremediation of cyanide compounds and evidence for t

66 rass species should play a vital role in the phytoremediation of environmental arsenic contamination.

67 ons for phytoscreening and shed new light on phytoremediation of HCH at field sites.

68 merA constructs may provide a means for the phytoremediation of mercury pollution.

69 ncrease crop productivity in marginal soils, phytoremediation of metal contaminated soils, and organi

70 y viable molecular genetic approaches to the phytoremediation of metal ion pollution.

71 The phytoremediation of metal-contaminated soils offers a lo

72 veloping plant species better suited for the phytoremediation of metal-contaminated soils.

73 products and foreign proteins to a model for phytoremediation of organic and metal contaminants.

74 Phytoremediation of organic pollutants, such as explosiv

75 Tl uptake or conversely for potential use in phytoremediation of polluted soils.

76 mulator plants with increased efficiency for phytoremediation of Se-contaminated environments.

77 Indian mustard is promising for the phytoremediation of SeCN(-) -contaminated soil and water

78 ating or volatilizing plants may be used for phytoremediation of selenium pollution and as fortified

79 serve a direct degradative function for the phytoremediation of sites contaminated by organic nitrat

80 The efficacy of transgenic plants in the phytoremediation of small organic contaminants has been

81 um has particular relevance to PGPB enhanced phytoremediation of soils contaminated through mining an

82 A limitation to phytoremediation of solvents has been toxicity of the co

83 e on the influence of endophytic bacteria on phytoremediation of widespread environmental contaminant

84 three-year field trial of endophyte-assisted phytoremediation on the Middlefield-Ellis-Whisman Superf

85 cystin-LR, remove it from the environment by phytoremediation, or enhance yields in crops exposed to

86 forestry or energy plantations, reclamation, phytoremediation, or other applications.

87 pollutants, the plant microbiome may improve phytoremediation outcomes for arsenic-contaminated sites

88 veloped to evaluate the cadmium and lead ion phytoremediation potential by the floating aquatic macro

89 lities for enhancing the metal tolerance and phytoremediation potential of higher plants via expressi

90 from a hyperaccumulator in order to increase phytoremediation potential.

91 ble trait for the development of a practical phytoremediation processes for removal of this potential

92 Promising phytoremediation research using transgenic model plant s

93 sess the significance of these pathways from phytoremediation sites at Travis and Fairchild Air Force

94 latilization of TCE and similar compounds at phytoremediation sites.

95 nobiotic compound, which should help improve phytoremediation strategies directed at TNT and other ni

96 vity could contribute towards development of phytoremediation strategies to clean up TNT from pollute

97 We have developed a genetics-based phytoremediation strategy for arsenic in which the oxyan

98 ssential for the development of an efficient phytoremediation strategy for this element.

99 Most phytoremediation studies utilize merA or merB genes to m

100 stress tolerance strategies in a real-world phytoremediation system.

101 mineralization has relevant implications for phytoremediation techniques and for further biotechnolog

102 cal and environmentally friendly approach to phytoremediation techniques, but analytical methods for

103 uable insights to enhance the development of phytoremediation technologies and farmland manipulation.

104 A real-world biological application of phytoremediation, the field growth of 10 Salix cultivars

105 Phytoremediation, the use of plants for remediation of s

106 to the trophic chain but are also promising phytoremediation tools.

107 Phytoremediation uses plants to remove pollutants from t

108 conclude that hemp has good potential for Se phytoremediation while producing Se-biofortified dietary

109 and the presence of legume or grass herbs on phytoremediation with a legume tree, Robinia pseudoacaci

110 , particularly in the rhizosphere, providing phytoremediation with a solid mechanistic understanding.

111 ely, especially when recycling of ashes from phytoremediation wood through application in agriculture

112 The phytoremediation wood was harvested from a TE-contaminat