PHYTOREMEDIATION OF INORGANICS: REALISM AND SYNERGIES

There are very few practical demonstrations of the phytoextraction of metals and metalloids from soils and sediments beyond small-scale and short-term trials. The two approaches used have been based on using 1) hyperaccumulator species, such as Thlaspi caerulescens (Pb, Zn, Cd, Ni), Alyssum spp. (Ni, Co), and Pteris vittata (As) or 2) fast-growing plants, such as Salix and Populus spp. that accumulate above-average concentrations of only a smaller number of the more mobile trace elements (Cd, Zn, B). Until we have advanced much more along the pathway of genetic isolation and transfer of hyperaccumulator traits into productive plants, there is a high risk in marketing either approach as a technology or stand-alone solution to clean up contaminated land. There are particular uncertainties over the longer-term effectiveness of phytoextraction and associated environmental issues. Marginally contaminated agricultural soils provide the most likely land use where phytoextraction can be used as a polishing technology. An alternative and more useful practical approach in many situations currently would be to give more attention to crops selected for phytoexclusion: selecting crops that do not translocate high concentrations of metals to edible parts. Soils of brownfield, urban, and industrial areas provide a large-scale opportunity to use phytoremediation, but the focus here should be on the more realistic possibilities of risk-managed phytostabilization and monitored natural attenuation. We argue that the wider practical applications of phytoremediation are too often overlooked. There is huge scope for cross-cutting other environmental agenda, with synergies that involve the recovery and provision of services from degraded landscapes and contaminated soils. An additional focus on biomass energy, improved biodiversity, watershed management, soil protection, carbon sequestration, and improved soil health is required for the justification and advancement of phytotechnologies.

[1]  John Proctor,et al.  The Vegetation of Ultramafic (Serpentine) Soils. , 1994 .

[2]  Brett H. Robinson,et al.  Natural and induced cadmium-accumulation in poplar and willow: Implications for phytoremediation , 2000, Plant and Soil.

[3]  S. Singh,et al.  A comparative study of cadmium phytoextraction by accumulator and weed species. , 2005, Environmental pollution.

[4]  John E. Lloyd,et al.  Distinguishing urban soils with physical, chemical, and biological properties , 2005 .

[5]  P. Putwain,et al.  Robust descriptors of soil health for use in reclamation of brownfield land , 2005 .

[6]  P. Römkens,et al.  Potentials and drawbacks of chelate-enhanced phytoremediation of soils. , 2002, Environmental pollution.

[7]  Yong Cai,et al.  A fern that hyperaccumulates arsenic , 2001, Nature.

[8]  H. Harmens,et al.  Uptake and Transport of Zinc in Zinc-sensitive and Zinc-tolerant Silene vulgaris , 1993 .

[9]  S. McGrath,et al.  Leaching of heavy metals from contaminated soils using EDTA. , 2001, Environmental pollution.

[10]  D. Leclair,et al.  Cadmium concentrations in tissues of willow ptarmigan (Lagopus lagopus) and rock ptarmigan (Lagopus muta) in Nunavik, Northern Québec. , 2007, Environmental pollution.

[11]  K. Verheyen,et al.  Tree species effect on the redistribution of soil metals. , 2007, Environmental pollution.

[12]  Baoshan Xing,et al.  Comparison of natural organic acids and synthetic chelates at enhancing phytoextraction of metals from a multi-metal contaminated soil. , 2006, Environmental pollution.

[13]  David J Walker,et al.  Uptake of heavy metals and As by Brassica juncea grown in a contaminated soil in Aznalcóllar (Spain): the effect of soil amendments. , 2005, Environmental pollution.

[14]  David E. Salt,et al.  Research Priorities for Conservation of Metallophyte Biodiversity and their Potential for Restoration and Site Remediation , 2004 .

[15]  W. A. Berg The Restoration of Land , 1981 .

[16]  Jaco Vangronsveld,et al.  Metal-contaminated soils : In situ inactivation and phytorestoration , 1998 .

[17]  W. Ernst,et al.  Phytoextraction of mine wastes - Options and impossibilities. Chemie der Erde - Geochemie der Erde. , 2005 .

[18]  A. Baker,et al.  Heavy metal accumulation and tolerance in British populations of the metallophyte Thlaspi caerulescens J. & C. Presl (Brassicaceae). , 1994, The New phytologist.

[19]  A. Lehmann,et al.  Nature and significance of anthropogenic urban soils , 2007 .

[20]  A. Baker,et al.  INDUCTION AND LOSS OF CADMIUM TOLERANCE IN HOLCUS LANA TUS L. , 1986 .

[21]  A. Baker ACCUMULATORS AND EXCLUDERS ?STRATEGIES IN THE RESPONSE OF PLANTS TO HEAVY METALS , 1981 .

[22]  R. Lark,et al.  Carbon losses from all soils across England and Wales 1978–2003 , 2005, Nature.

[23]  Zhenguo Shen,et al.  The use of vetiver grass (Vetiveria zizanioides) in the phytoremediation of soils contaminated with heavy metals , 2004 .

[24]  B. Frey,et al.  Heavy metal accumulation and phytostabilisation potential of tree fine roots in a contaminated soil. , 2008, Environmental pollution.

[25]  A. Schaeffer,et al.  Chelate assisted phytoextraction of heavy metals from soil. Effect, mechanism, toxicity, and fate of chelating agents. , 2007, Chemosphere.

[26]  Jan Mertens,et al.  Metal uptake by young trees from dredged brackish sediment: limitations and possibilities for phytoextraction and phytostabilisation. , 2004, The Science of the total environment.

[27]  D. Vélez,et al.  An engineered plant that accumulates higher levels of heavy metals than Thlaspi caerulescens, with yields of 100 times more biomass in mine soils. , 2006, Chemosphere.

[28]  Roderick Hunt,et al.  Comparative Plant Ecology: A Functional Approach to Common British Species , 1989 .

[29]  G. Brofas,et al.  Evaluation of revegetation techniques on mining spoil slopes , 2007 .

[30]  L. Kochian,et al.  Phytofiltration of arsenic from drinking water using arsenic-hyperaccumulating ferns. , 2004, Environmental science & technology.

[31]  N. Caille,et al.  Field evaluation of Cd and Zn phytoextraction potential by the hyperaccumulators Thlaspi caerulescens and Arabidopsis halleri. , 2006, Environmental pollution.

[32]  R. Maier,et al.  Phytostabilization of Mine Tailings in Arid and Semiarid Environments—An Emerging Remediation Technology , 2007, Environmental health perspectives.

[33]  Koen Oorts,et al.  Phytoextraction of metals from soils: how far from practice? , 2007, Environmental pollution.

[34]  W. Ernst,et al.  Mine vegetation in Europe. , 1990 .

[35]  Alan J. M. Baker,et al.  The possibility of in situ heavy metal decontamination of polluted soils using crops of metal-accumulating plants , 1994 .

[36]  H. Sieghardt,et al.  The response of roots of herbaceous plant species to heavy metals , 1993 .

[37]  I. Pulford,et al.  Phytoremediation of heavy metal-contaminated land by trees--a review. , 2003, Environment international.

[38]  D. Parker,et al.  Ecotypic variation in selenium accumulation among populations of Stanleya pinnata. , 2001, The New phytologist.

[39]  A. Baker,et al.  In Situ Decontamination of Heavy Metal Polluted Soils Using Crops of Metal-Accumulating Plants—A Feasibility Study , 1991 .

[40]  G. Bañuelos,et al.  Phyto-products may be essential for sustainability and implementation of phytoremediation. , 2006, Environmental pollution.

[41]  B. Muys,et al.  Earthworm biomass as additional information for risk assessment of heavy metal biomagnification: a case study for dredged sediment-derived soils and polluted floodplain soils. , 2004, Environmental pollution.

[42]  A. Ball,et al.  Soil health: a new challenge for microbiologists and chemists , 2005 .

[43]  W. Goessler,et al.  Arsenic species in an arsenic hyperaccumulating fern, Pityrogramma calomelanos: a potential phytoremediator of arsenic-contaminated soils. , 2002, The Science of the total environment.

[44]  Stephen D. Ebbs,et al.  Phytoextraction of Zinc by Oat (Avena sativa), Barley (Hordeum vulgare), and Indian Mustard (Brassica juncea) , 1998 .

[45]  C. Mulligan,et al.  Natural attenuation of contaminated soils. , 2004, Environment international.

[46]  Brent Clothier,et al.  Phytoremediation for the management of metal flux in contaminated sites , 2006 .

[47]  C. Field,et al.  Biomass energy: the scale of the potential resource. , 2008, Trends in ecology & evolution.

[48]  J. R. Sanders,et al.  Zinc, copper and nickel concentrations in soil extracts and crops grown on four soils treated with metalloaded sewage sludges. , 1987, Environmental pollution.

[49]  Luhua Wu,et al.  EDTA-enhanced phytoremediation of heavy metal contaminated soil with Indian mustard and associated potential leaching risk , 2004 .

[50]  J. Meech,et al.  A field demonstration of gold phytoextraction technology , 2005 .

[51]  Göran Berndes,et al.  Cadmium accumulation and Salix-based phytoextraction on arable land in Sweden , 2004 .

[52]  M. Wong,et al.  Enhanced uptake of As, Zn, and Cu by Vetiveria zizanioides and Zea mays using chelating agents. , 2005, Chemosphere.

[53]  W. Punz Metallophytes in the Eastern Alps With Special Emphasis on Higher Plants Growing on Calamine and Copper Localities , 1995 .

[54]  K. Prach The Restoration and Management of Derelict Land: Modern Approaches , 2004 .

[55]  M. Greger,et al.  Differences in uptake and tolerance to heavy metals in Salix from unpolluted and polluted areas , 1996 .

[56]  B. A. Hunter,et al.  Ecotoxicology of copper and cadmium in a contaminated grassland ecosystem. I: Soil and vegetation contamination , 1987 .

[57]  P. Putwain,et al.  Woody biomass phytoremediation of contaminated brownfield land. , 2006, Environmental pollution.

[58]  M. Ramsey,et al.  Heterogeneity of cadmium concentration in soil as a source of uncertainty in plant uptake and its implications for human health risk assessment. , 2004, The Science of the total environment.

[59]  Use of Vetiver and Other Three Grasses for Revegetation of a Pb / Zn Mine Tailings at Lechang , Guangdong Province : A Field Experiment , 2000 .

[60]  W. Wenzel,et al.  Hydroponic screening for metal resistance and accumulation of cadmium and zinc in twenty clones of willows and poplars. , 2007, Environmental pollution.

[61]  G. A R Y B A N ˜ U E L O S, † N O R M A N T E R R Y,et al.  Field Trial of Transgenic Indian Mustard Plants Shows Enhanced Phytoremediation of Selenium-Contaminated Sediment , 2022 .

[62]  Ilya Raskin,et al.  Enhanced Accumulation of Pb in Indian Mustard by Soil-Applied Chelating Agents , 1997 .

[63]  A. Tanaka,et al.  Arsenic and heavy metal contamination of vegetables grown in Samta village, Bangladesh. , 2003, The Science of the total environment.

[64]  J. Meech,et al.  A comparative analysis of gold-rich plant material using various analytical methods , 2005 .

[65]  C. Mcleod,et al.  Mapping airborne lead contamination near a metals smelter in Derbyshire, UK: spatial variation of Pb concentration and 'enrichment factor' for tree bark. , 2001, Journal of environmental monitoring : JEM.

[66]  A. Mead,et al.  Phylogenetic variation in heavy metal accumulation in angiosperms. , 2001, The New phytologist.

[67]  Walter W. Wenzel,et al.  Role of assisted natural remediation in environmental cleanup , 2004 .

[68]  J. Draper,et al.  Phytoextraction and Accumulation of Boron and Selenium by Poplar (Populus) Hybrid Clones , 1999 .

[69]  Fang-Jie Zhao,et al.  Phytoextraction of metals and metalloids from contaminated soils. , 2003, Current opinion in biotechnology.

[70]  B. Robinson,et al.  Nickel and Cobalt Phytoextraction by the Hyperaccumulator Berkheya coddii: Implications for Polymetallic Phytomining and Phytoremediation , 2003, International journal of phytoremediation.

[71]  Rufus L. Chaney,et al.  Phytoextraction of Nickel and Cobalt by Hyperaccumulator Alyssum Species Grown on Nickel-Contaminated Soils , 2003 .

[72]  N. Dickinson,et al.  Interactions between earthworms, trees, soil nutrition and metal mobility in amended Pb/Zn mine tailings from Guangdong, China , 2003 .

[73]  Daniel Hammer,et al.  Root development and heavy metal phytoextraction efficiency: comparison of different plant species in the field , 2003, Plant and Soil.

[74]  B. Clothier,et al.  Poplar for the phytomanagement of boron contaminated sites. , 2007, Environmental pollution.

[75]  N. Caille,et al.  Arsenic hyperaccumulation by Pteris vittata from arsenic contaminated soils and the effect of liming and phosphate fertilisation. , 2004, Environmental pollution.

[76]  J. Qiu,et al.  Lead in paddy soils and rice plants and its potential health risk around Lechang lead/zinc mine, Guangdong, China. , 2004, Environment international.

[77]  Rattan Lal,et al.  Soil Science and the Carbon Civilization , 2007 .

[78]  W. Ernst,et al.  Evolutionary biology of metal resistance in Silene vulgaris. , 1990 .

[79]  S. Luyssaert,et al.  Use and abuse of trace metal concentrations in plant tissue for biomonitoring and phytoextraction. , 2005, Environmental pollution.

[80]  Jaco Vangronsveld,et al.  Potential of five willow species (Salix spp.) for phytoextraction of heavy metals. , 2007 .

[81]  K. Perttu,et al.  Salix vegetation filters for purification of waters and soils , 1997 .

[82]  M. Greger,et al.  Influence of nutrient levels on uptake and effects of mercury, cadmium, and lead in water spinach. , 2004, Journal of environmental quality.

[83]  M. Heitkamp,et al.  Phytoextraction of lead from firing range soil by Vetiver grass. , 2005, Chemosphere.

[84]  N. Lepp,et al.  Accumulation and egestion of dietary copper and cadmium by the grasshopper Locusta migratoria R & F (Orthoptera: Acrididae). , 1996, Environmental pollution.

[85]  Z. Hseu,et al.  Effects of chelators on chromium and nickel uptake by Brassica juncea on serpentine-mine tailings for phytoextraction. , 2007, Journal of hazardous materials.

[86]  G. Likens,et al.  Cadmium toxicity among wildlife in the Colorado Rocky Mountains , 2000, Nature.

[87]  H. Hasegawa,et al.  Arsenic accumulation in rice (Oryza sativa L.): human exposure through food chain. , 2008, Ecotoxicology and environmental safety.

[88]  J. Vangronsveld,et al.  Phytostabilization of a metal contaminated sandy soil. II: Influence of compost and/or inorganic metal immobilizing soil amendments on metal leaching. , 2006, Environmental pollution.

[89]  P. Tlustoš,et al.  The use of poplar during a two-year induced phytoextraction of metals from contaminated agricultural soils. , 2008, Environmental pollution.

[90]  Jiangan Yuan,et al.  Cadmium accumulation in different rice cultivars and screening for pollution-safe cultivars of rice. , 2006, The Science of the total environment.

[91]  S. McGrath,et al.  Arsenic hyperaccumulation by different fern species , 2002 .

[92]  N. Dickinson Soil Degradation and Nutrients , 2003 .

[93]  J. Eriksson,et al.  Potential of Salix as phytoextractor for Cd on moderately contaminated soils , 2003, Plant and Soil.

[94]  R. Maier,et al.  Phytoremediation of mine tailings in temperate and arid environments , 2008 .

[95]  John M. Gunn,et al.  Restoration and Recovery of an Industrial Region , 1995 .

[96]  A. Faaij,et al.  The economic value of the phytoremediation function – Assessed by the example of cadmium remediation by willow (Salix ssp) , 2006 .

[97]  D. Sparks,et al.  Improved understanding of hyperaccumulation yields commercial phytoextraction and phytomining technologies. , 2007, Journal of environmental quality.

[98]  B. Gélie,et al.  Strategies of heavy metal uptake by three plant species growing near a metal smelter. , 2000, Environmental pollution.

[99]  I. Vogeler,et al.  Plant uptake and leaching of copper during EDTA-enhanced phytoremediation of repacked and undisturbed soil , 2003, Plant and Soil.

[100]  E. Barrios Soil biota, ecosystem services and land productivity , 2007 .

[101]  P. White,et al.  Applying a solute transfer model to phytoextraction: Zinc acquisition by Thlaspi caerulescens , 2003, Plant and Soil.

[102]  T. Kuboi,et al.  Family-dependent cadmium accumulation characteristics in higher plants , 1986, Plant and Soil.

[103]  Sébastien Barot,et al.  Stability of organic carbon in deep soil layers controlled by fresh carbon supply , 2007, Nature.

[104]  J. Morel,et al.  In-situ phytoextraction of Ni by a native population of Alyssum murale on an ultramafic site (Albania) , 2007, Plant and Soil.

[105]  Mateete A. Bekunda,et al.  Indicators of soil quality : A South-South development of a methodological guide for linking local and technical knowledge , 2006 .

[106]  Alan J. M. Baker,et al.  Metal Hyperaccumulator Plants: A Review of the Ecology and Physiology of a Biological Resource for Phytoremediation of Metal-Polluted Soils , 2000 .

[107]  G. Wessolek,et al.  Standorteigenschaften und Wasserhaushalt von versiegelten Flächen , 1997 .

[108]  J. Dean,et al.  Uptake of heavy metals by vegetable plants grown on contaminated soil and their bioavailability in the human gastrointestinal tract , 2006, Food additives and contaminants.

[109]  B. A. Hunter,et al.  Ecotoxicology of copper and cadmium in a contaminated grassland ecosystem. II: Invertebrates , 1987 .

[110]  R. Kucharski,et al.  Phytoextraction crop disposal--an unsolved problem. , 2004, Environmental pollution.

[111]  B. Robinson,et al.  The potential of the high-biomass nickel hyperaccumulator Berkheya coddii for phytoremediation and phytomining , 1997 .

[112]  M. R. Savabi,et al.  MODELING THE EFFECT OF SOIL AMENDMENTS (COMPOSTS) ON WATER BALANCE AND WATER QUALITY , 2003 .

[113]  H. Marschner Mineral Nutrition of Higher Plants , 1988 .

[114]  M. Wong,et al.  Arsenic Uptake and Accumulation in Fern Species Growing at Arsenic-Contaminated Sites of Southern China: Field Surveys , 2006, International journal of phytoremediation.

[115]  O. Bens,et al.  Water infiltration and hydraulic conductivity in sandy cambisols: impacts of forest transformation on soil hydrological properties , 2006, European Journal of Forest Research.

[116]  T. Lebeau,et al.  Performance of bioaugmentation-assisted phytoextraction applied to metal contaminated soils: a review. , 2008, Environmental pollution.

[117]  P. White,et al.  Extraordinarily high leaf selenium to sulfur ratios define 'Se-accumulator' plants. , 2007, Annals of botany.

[118]  T. Hutchings,et al.  Immobilization of Heavy Metals in Soil Using Natural and Waste Materials for Vegetation Establishment on Contaminated Sites , 2007 .

[119]  L. Ma,et al.  Effects of heavy metals on growth and arsenic accumulation in the arsenic hyperaccumulator Pteris vittata L. , 2004, Environmental pollution.

[120]  F. Batič,et al.  Vegetational and mycorrhizal successions at a metal polluted site: Indications for the direction of phytostabilisation? , 2006, Environmental pollution.

[121]  A. Baker,et al.  INDUCTION AND LOSS OF CADMIUM TOLERANCE IN HOLCUS LANATUS L. AND OTHER GRASSES , 1986 .

[122]  N. Dickinson,et al.  Beneficial effects of earthworms and arbuscular mycorrhizal fungi on establishment of leguminous trees on Pb/Zn mine tailings , 2006 .

[123]  V. Angelova,et al.  Bio-accumulation and distribution of heavy metals in fibre crops (flax, cotton and hemp) , 2004 .

[124]  Scott D. Cunningham,et al.  Phytoremediation of Lead-Contaminated Soils: Role of Synthetic Chelates in Lead Phytoextraction , 1997 .

[125]  A. Baker,et al.  Enhanced phytoextraction of Pb and other metals from artificially contaminated soils through the combined application of EDTA and EDDS. , 2006, Chemosphere.

[126]  Guillaume Echevarria,et al.  Phytoextraction of cadmium with Thlaspi caerulescens , 2003, Plant and Soil.

[127]  I. E. Woodrow,et al.  A screen of some native Australian flora and exotic agricultural species for their potential application in cyanide-induced phytoextraction of gold , 2007 .

[128]  Raskin,et al.  The role of EDTA in lead transport and accumulation by indian mustard , 1998, Plant physiology.

[129]  K. McLeod,et al.  Boron tolerance and potential boron removal by bottomland tree seedlings , 1998, Wetlands.

[130]  M. Kirkham CADMIUM IN PLANTS ON POLLUTED SOILS: EFFECTS OF SOIL FACTORS, HYPERACCUMULATION AND AMENDMENTS , 2006 .

[131]  Bernd Nowack,et al.  Critical assessment of chelant-enhanced metal phytoextraction. , 2006, Environmental science & technology.

[132]  N. Dickinson,et al.  Mobility of metals and metalloids in a multi-element contaminated soil 20 years after cessation of the pollution source activity. , 2008, Environmental pollution.

[133]  L. Ma,et al.  Phytoremediation of Arsenic-Contaminated Groundwater by the Arsenic Hyperaccumulating Fern Pteris vittata L. , 2004, International journal of phytoremediation.

[134]  A. Baker,et al.  The use of NTA and EDDS for enhanced phytoextraction of metals from a multiply contaminated soil by Brassica carinata. , 2007, Chemosphere.

[135]  P. Tlustoš,et al.  Heavy metal accumulation in trees growing on contaminated sites in Central Europe. , 2007, Environmental pollution.

[136]  N. Dickinson,et al.  Acclimation of Salix to metal stress. , 1997, The New phytologist.

[137]  T. Anderson,et al.  Phytoremediation—An Overview , 2005 .

[138]  Remedios,et al.  COMMISSION OF THE EUROPEAN COMMUNITIES , 1601 .

[139]  R. Reeves Tropical hyperaccumulators of metals and their potential for phytoextraction , 2003, Plant and Soil.

[140]  L. Kärenlampi,et al.  Differential tolerance to copper and zinc of micropropagated birches tested in hydroponics. , 1997, The New phytologist.

[141]  C. Stewart,et al.  The transport of airborne trace elements copper, lead, cadmium, zinc and manganese from a city into rural areas. , 1992, The Science of the total environment.

[142]  R. Ceulemans,et al.  Clonal variation in heavy metal accumulation and biomass production in a poplar coppice culture: I. Seasonal variation in leaf, wood and bark concentrations. , 2004, Environmental pollution.