phytoremediation mechanisms and applications · 2009. 8. 6. · grande, (1200 m2) valorlis, 2003...
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![Page 1: PHYTOREMEDIATION MECHANISMS AND APPLICATIONS · 2009. 8. 6. · Grande, (1200 m2) VALORLIS, 2003 (LECA®) Hybrid System Efluent from MSW Transfer Station (450 m2), Alcanadas, VALORLIS,](https://reader035.vdocuments.mx/reader035/viewer/2022070223/6144c98b34130627ed509289/html5/thumbnails/1.jpg)
Luísa Davies
Renata Ferreira
Carlos Antunes
Lília Alexandre
Luís Batista
Vera Ramalho
Adelaide Almeida
Gonçalo Cabrita
Filipe Freire
Júlio Novais
Susete Martins‐Dias
PPHYTOREMEDIATION MECHANISMS AND APPLICATIONSHYTOREMEDIATION MECHANISMS AND APPLICATIONS
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Phytoremediation Phytoremediation tools and mechanisms
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Phytoremediation Phytoremediation tools and mechanisms
Reservoir
Wastewater
Pumping system Treated wastewater
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VFCW planted with Phragmites sp. treating azo dye contaminated wastewater
VFCW planted with Vetiveria zizanioides treating swine wastewater
CW with light expanded clay aggregates matrix treating mine drainage and aquaculture wastewaters
From Pilot to Full Scale (On going projects)
Phytoremediation of soils contaminated by organic compounds
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Hybrid SystemLandfill leachate treatment in Marinha Grande, (1200 m2) VALORLIS, 2003 (LECA®)
Hybrid SystemEfluent from MSW Transfer Station (450 m2), Alcanadas, VALORLIS, 2000
Vertical Flow Constructed WetlandIndustrial efluent with nitroaromatic compounds (10000m2), CUF‐ QI, 1994
Horizontal Flow Constructed WetlandDenitrification in hydroponic reed bed (3000 m2), CUF‐QI, 1999 (LECA®)
From Pilot to Full Scale
Chemical Industry
Municipal Solid
Wastes Leachates
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Research at ENVERG
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•AO7 has 16 carbons •TOC removal efficiencies (85‐90%)•Only linear aliphatic chains (C2‐C5)
Example of successful treatment of an azo dye (3 years)
HL= 28HL= 28
HL= 40HL= 40
HL= 53HL= 53
HL= 108HL= 108
Dilution of 1:20, no colour was detected, as required by EC Directives (76/464/EEC and 80/68/EEC)
[AO7][AO7]ININ = 130 mg l= 130 mg l‐‐11
PILOT PLANT RESULTS (C16H11N2(OH).SO3Na)HL (l m‐2 d‐1)
Inlet load(gCOD m‐2 d‐1)
CODRem.(%)
TOCRem.(%)
Colour Rem.(%)
28 5.82 91 89 98 ‐ 99
40 10.3 93 90 98 ‐ 99
53 11.2 86 86 82 ‐ 97
108 26.1 89 85 74 ‐ 84
Davies et al., 2006. Water Research, 40, 2055‐2063
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Modelling the CW (Mechanistic analogy) Davies et al., 2007. Water Science and Technology, 55, 127‐134
This work was carried out in collaboration with CRERG‐IBB
Overall k (system)Overall k (system)
Pilot CW at IST campus
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Mechanistic Model (MatLab 7.5)
Non homogeneous bioreactors•Rainfall and evapotranspiration are considered•Richards’ equation describes water movement in variably saturated soils (large spatial heterogeneities)•Nonlinear multivariate optimization of the model within the experimental data
Freire et al., 2009. Ecological Engineering, xx, xx‐xxxhttp://dx.doi.org/10.1016/j.ecoleng.2009.03.012
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Graphical User Interface
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Research at ENVERG
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GreenGreenLiver Liver modelmodel
Plant Plant UpUp‐‐taketake
EnzymaticEnzymaticbreakdownbreakdown
PhytoPhyto‐‐remediationremediation
Recognitionthat plants
cantransform pollutants
(metabolise Pesticides)
Plants are autotrophic butup‐take water
nutrientsand
pollutantsfrom soil and groundwater
Plant enzymesfrom their natural
defence system against
a variety of Allelochemicals
(peroxidases)
Plants can be seen as
natural, solar‐powered clean up vehicles for contaminated environments
Carias et al., 2008. Bioresource Technology, 99, 243‐251
Plants cannot move away from stress!!!
Plants have an Enzymatic system to mineralize natural and exogenous xenobiotics
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Pollutants+
Metabolic adjustments
ROS signal transduction pathway
ROS scavenging mechanisms and gene overexpression of
enzymes
ROS – Reactive Oxygen Species
Plant Defence Mechanism Activation
ROS generating reactions
(oxidative stress)
GSTUnidirectional active
transport
Conjugation reactions
Metabolites (exudates)
P. Schröder et al. Env Sci Pollut Res 14 (2007) 114‐122
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H2O + O2
PODPOD CATCAT
H2O + GSSG
GPXGPX
ROS Scavenging Enzymes
• The scavenging enzymes operate in order to eliminate and avoid protonation of O2‐
• H2O2 is able to enter cellular membranes• Prevent OH• formation that leads to cell death
OH•H2O2
SODSOD
LOOH LOHGPXGPX
O2-
1O2
O2
Self lipid auto-oxidation Fe2+
Molecular Oxygen GPX – Glutathione Peroxidase
SOD – Superoxide Dismutase POD – PeroxidaseCAT – Catalase
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Glutathione Peroxidase and catalase gene expression in roots and leaves submitted to stress
Enzymes activities
Davies et al., 2009. Ecological Engineering, 35(6),961‐970
Wastewater treatment scale down
Total RNA
An indirect methodology has been established that enables the
correlation between PhragmitesReactive Oxygen Species production induced by the AO7 through the
measurement of mRNA accumulation
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Genes sequenced so far…
• Phragmites australis putative catalase mRNA – Genbank accession number: DQ 786751
• Phragmites australis 23S ribosomal RNA, partial sequence, chloroplast; 301 bp rRNA linear
– Genbank accession number: DQ 786752
• Phragmites australis glutathione peroxidase pseudogene mRNA, partial sequence, 383 bp mRNA linear
– Genbank accession number: DQ 786753
• Phragmites australis 18S ribosomal RNA, partial sequence– Genbank accession number: DQ 786754
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Towards Phragmites’ Proteome (On going Work)
PhragmitesPhragmitesLeavesLeaves
Phragmites australis leaves’proteome (March 2009)
Differential analysis of the proteomes subjected to different oxidative stress induced by the pollutants
In collaboration with BSRG‐IBB