Metal accumulation in intertidal litter through decomposing leaf blades, sheaths and stems of Phragmites australis

Metal accumulation in intertidal litter through decomposing leaf blades, sheaths and stems of Phragmites australis

Metal contents of decomposing leaf blades, leaf sheaths and stems of common reed ( Phragmites australis) were monitored by a litter bag method on the sediment of an intertidal brackish marsh in the Scheldt estuary (The Netherlands). On monthly intervals, two litter bags were retrieved from the marsh...

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Veröffentlicht in:Chemosphere (Oxford) 2006-06, Vol.63 (11), p.1815-1823
Hauptverfasser: Du Laing, Gijs, Ryckegem, Gunther Van, Tack, Filip M.G., Verloo, Marc G.
Format: Artikel
Sprache:eng
Schlagworte:
bioaccumulation
biodegradation
biogeochemical cycles
Brackish
cadmium
chromium
Common reed
copper
Environmental Monitoring
Environmental Pollutants - metabolism
Fungi
heavy metals
lead
leaves
marshes
Metals - analysis
Metals - metabolism
Netherlands
nickel
Organic matter
Phragmites australis
Plant Leaves - metabolism
plant litter
Plant Stems - metabolism
Poaceae - chemistry
Poaceae - metabolism
Scheldt estuary
Sediments
stems
water pollution
Wetlands
zinc
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container_issue 11
container_start_page 1815
container_title Chemosphere (Oxford)
container_volume 63
creator Du Laing, Gijs
Ryckegem, Gunther Van
Tack, Filip M.G.
Verloo, Marc G.
description Metal contents of decomposing leaf blades, leaf sheaths and stems of common reed ( Phragmites australis) were monitored by a litter bag method on the sediment of an intertidal brackish marsh in the Scheldt estuary (The Netherlands). On monthly intervals, two litter bags were retrieved from the marsh during 9 months for both leaf blades and sheaths and during 16 months for stems. All samples were dried, weighed and analysed for ash and Cd, Cu, Cr, Ni, Pb and Zn contents. Most concentrations increased considerably during the decomposition. Generally, also a very important net metal inflow into the litter bags could be observed. The inflow was highest for leaf blades. High correlations between ash contents and metal concentrations for leaf blades suggest that the increase of leaf blade metal contents can be due to physicochemical sorption of dissolved metals and an important infiltration of mud particles, which were not removed by rinsing the leaf blades with distilled water preceding the analyses. For stems, smaller amounts of inflowing ash and even outflowing ash amounts were found, which suggests that inflow of inorganic particles is not the major factor determining metal accumulation by stems on medium term. Ergosterol concentrations in stem tissue however proved to be correlated with metal contents, which suggests a significant role of fungal litter colonizers in metal accumulation. For leaf sheaths, the effects of physicochemical sorption, infiltration of mud particles and incorporation by microbial litter colonizers do not seem to be as pronounced as for stems and leaf blades.
doi_str_mv 10.1016/j.chemosphere.2005.10.034
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On monthly intervals, two litter bags were retrieved from the marsh during 9 months for both leaf blades and sheaths and during 16 months for stems. All samples were dried, weighed and analysed for ash and Cd, Cu, Cr, Ni, Pb and Zn contents. Most concentrations increased considerably during the decomposition. Generally, also a very important net metal inflow into the litter bags could be observed. The inflow was highest for leaf blades. High correlations between ash contents and metal concentrations for leaf blades suggest that the increase of leaf blade metal contents can be due to physicochemical sorption of dissolved metals and an important infiltration of mud particles, which were not removed by rinsing the leaf blades with distilled water preceding the analyses. For stems, smaller amounts of inflowing ash and even outflowing ash amounts were found, which suggests that inflow of inorganic particles is not the major factor determining metal accumulation by stems on medium term. Ergosterol concentrations in stem tissue however proved to be correlated with metal contents, which suggests a significant role of fungal litter colonizers in metal accumulation. For leaf sheaths, the effects of physicochemical sorption, infiltration of mud particles and incorporation by microbial litter colonizers do not seem to be as pronounced as for stems and leaf blades.</abstract><cop>England</cop><pub>Elsevier Ltd</pub><pmid>16330074</pmid><doi>10.1016/j.chemosphere.2005.10.034</doi><tpages>9</tpages></addata></record>
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source MEDLINE; ScienceDirect Journals (5 years ago - present)
subjects bioaccumulation
biodegradation
biogeochemical cycles
Brackish
cadmium
chromium
Common reed
copper
Environmental Monitoring
Environmental Pollutants - metabolism
Fungi
heavy metals
lead
leaves
marshes
Metals - analysis
Metals - metabolism
Netherlands
nickel
Organic matter
Phragmites australis
Plant Leaves - metabolism
plant litter
Plant Stems - metabolism
Poaceae - chemistry
Poaceae - metabolism
Scheldt estuary
Sediments
stems
water pollution
Wetlands
zinc
title Metal accumulation in intertidal litter through decomposing leaf blades, sheaths and stems of Phragmites australis
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