Abstract
This paper reviews key aspects of phytoremediation technology and the biological mechanisms underlying phytoremediation. Current knowledge regarding the application of phytoremediation in alleviating heavy metal toxicity is summarized highlighting the relative merits of different options. The results reveal a cutting edge application of emerging strategies and technologies to problems of heavy metals in soil. Progress in phytoremediation is hindered by a lack of understanding of complex interactions in the rhizosphere and plant based interactions which allow metal translocation and accumulation in plants. The evolution of physiological and molecular mechanisms of phytoremediation, together with recently-developed biological and engineering strategies, has helped to improve the performance of both heavy metal phytoextraction and phytostabilization. The results reveal that phytoremediation includes a variety of remediation techniques which include many treatment strategies leading to contaminant degradation, removal (through accumulation or dissipation), or immobilization. For each of these processes, we review what is known for metal pollutants, gaps in knowledge, and the practical implications for phytoremediation strategies.
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1 Introduction
Heavy metals are ubiquitous environmental contaminants in industrialized societies. Soil pollution by metals differs from air or water pollution, because heavy metals persist in soil much longer than in other compartments of the biosphere (Lasat 2002). Over recent decades, the annual worldwide release of heavy metals reached 22,000 t (metric ton) for cadmium, 939,000 t for copper, 783,000 t for lead and 1,350,000 t for zinc (Singh et al. 2003). Sources of heavy metal contaminants in soils include metalliferous mining and smelting, metallurgical industries, sewage sludge treatment, warfare and military training, waste disposal sites, agricultural fertilizers and electronic industries (Alloway 1995). For example, mine tailings rich in sulphide minerals may form acid mine drainage (AMD) through reaction with atmospheric oxygen and water, and AMD contains elevated levels of metals that could be harmful to animals and plants (Stoltz 2004).
Ground-transportation also causes metal contamination. Highway traffic, maintenance, and de-icing operations generate continuous surface and groundwater contaminant sources. Tread ware, brake abrasion, and corrosion are well documented heavy metal sources associated with highway traffic (Ho and Tai 1988; Fatoki 1996; García and Millán 1998; Sánchez Martín et al. 2000). Heavy metal contaminants in roadside soils originate from engine and brake pad wear (e.g. Cd, Cu, and Ni) (Viklander 1998); lubricants (e.g. Cd, Cu and Zn) (Birch and Scollen 2003; Turer et al. 2001); exhaust emissions, (e.g. Pb) (Gulson et al. 1981; Al-Chalabi and Hawker 2000; Sutherland et al. 2003); and tire abrasion (e.g. Zn) (Smolders and Degryse 2002). The concentration ranges of metals of greatest importance in roadside soils are given in Fig. 1.
Toxic heavy metals cause DNA damage, and their carcinogenic effects in animals and humans are probably caused by their mutagenic ability (Knasmuller et al. 1998; Baudouin et al. 2002). Exposure to high levels of these metals has been linked to adverse effects on human health and wildlife. Lead poisoning in children causes neurological damage leading to reduced intelligence, loss of short term memory, learning disabilities and coordination problems. The effects of arsenic include cardiovascular problems, skin cancer and other skin effects, peripheral neuropathy (WHO 1997) and kidney damage. Cadmium accumulates in the kidneys and is implicated in a range of kidney diseases (WHO 1997). The principal health risks associated with mercury are damage to the nervous system, with such symptoms as uncontrollable shaking, muscle wasting, partial blindness, and deformities in children exposed in the womb (WHO 1997).
Metal-contaminated soil can be remediated by chemical, physical or biological techniques (McEldowney et al. 1993). Chemical and physical treatments irreversibly affect soil properties, destroy biodiversity and may render the soil useless as a medium for plant growth. These remediation methods can be costly. Table 1 summarizes the cost of different remediation technologies. Among the listed remediation technologies, phytoextraction is one of the lowest cost techniques for contaminated soil remediation. There is a need to develop suitable cost-effective biological soil remediation techniques to remove contaminants without affecting soil fertility. Phytoremediation could provide sustainable techniques for metal remediation. This paper summarizes the development of phytoremediation for metals in the past two decades.
Phytoremediation involves the use of plants to remove, transfer, stabilize and/or degrade contaminants in soil, sediment and water (Hughes et al. 1997). The idea that plants can be used for environmental remediation is very old and cannot be traced to any particular source. The concentration of metal uptake in plants is shown in Fig. 2. A series of fascinating scientific discoveries, combined with interdisciplinary research, has allowed phytoremediation to develop into a promising, cost-effective, and environmentally friendly technology.
The term phytoremediation (“phyto” meaning plant, and the Latin suffix “remedium” meaning to clean or restore) refers to a diverse collection of plant-based technologies that use either naturally occurring, or genetically engineered, plants to clean contaminated environments (Cunningham et al. 1997; Flathman and Lanza 1998). Some plants which grow on metalliferous soils have developed the ability to accumulate massive amounts of indigenous metals in their tissues without symptoms of toxicity (Reeves and Brooks 1983; Baker and Brooks 1989; Baker et al. 1991; Entry et al. 1999). The idea of using plants to extract metals from contaminated soil was re-introduced and developed by Utsunamyia (1980) and Chaney (1983). The first field trial on Zn and Cd phytoextraction was conducted by Baker et al. (1991).
Several comprehensive reviews have been written, summarizing many important aspects of this novel plant-based technology (Salt et al. 1995, 1998; Chaney et al. 1997; Raskin et al. 1997; Chaudhry et al. 1998; Wenzel et al. 1999; Meagher 2000; Navari-Izzo and Quartacci 2001; Lasat 2002; McGrath et al. 2002; McGrath and Zhao 2003; McIntyre 2003; Singh et al. 2003; Garbisu and Alkorta 2001; Prasad and Freitas 2003; Alkorta et al. 2004; Ghosh and Singh 2005; Pilon-Smits 2005). These reviews give general guidance and recommendations for applying phytoremediation, highlighting the processes associated with applications and underlying biological mechanisms. The present review is intended to give an updated, more concise version of information so far available with respect to different subsets of phyoremediation. It provides a critical overview of the present state of the art, with particular emphasis on phytoextraction and phytostabilization of soil heavy metal contaminants.
2 Categories of Phytoremediation
Depending on the contaminants, the site conditions, the level of clean-up required, and the types of plants, phytoremediation technology can be used for containment (phytoimmobilization and phytostabilization) or removal (phytoextraction and phytovolatilization) purposes (Thangavel and Subhuram 2004). The four different plant-based technologies of phytoremediation, each having a different mechanism of action for remediating metal-polluted soil, sediment, or water: (1) phytostabilization, where plants stabilize, rather than remove contaminants by plant roots metal retention; (2) phytofiltration, involving plants to clean various aquatic environments; (3) phytovolatilization, utilizing plants to extract certain metals from soil and then release them into the atmosphere by volatilization; and (4) phytoextraction, in which plants absorb metals from soil and translocate them to harvestable shoots where they accumulate. The different mechanisms of phytoremediation are summarized in Table 2.
Ecological issues also need to be evaluated when developing a phytoremediation strategy for a polluted site. In particular, one has to consider how the phytoremediation efforts might affect local ecological relationships, especially those involving other crops. Since the phytoremediation plants will be grown under contaminated soil/ water conditions, where other crops may not thrive because of contaminant toxicities, the competition problem is unlikely to arise.
2.1 Phytostabilization
Phytostabilization uses certain plant species to immobilize contaminants in soil, through absorption and accumulation by roots, adsorption onto roots or precipitation within the root zone and physical stabilization of soils. The schematic mechanism of phytostabilization is illustrated in Fig. 3. This process reduces the mobility of contaminants and prevents migration to groundwater or air. This can re-establish a vegetative cover at sites where natural vegetation is lacking due to high metal concentrations (Tordoff et al. 2000). Thorough planning is essential for successful revegetation, including physical and chemical analyses, bioassays and field trials. The main approaches to revegetation are summarized in Table 3.
Metal-tolerant species may be used to restore vegetation to such sites, thereby decreasing the potential migration of contaminants through wind, transport of exposed surface soils, leaching of soil and contamination of groundwater (Stoltz and Greger 2002). Unlike other phytoremediative techniques, phytostabilization is not intended to remove metal contaminants from a site, but rather to stabilize them by accumulation in roots or precipitation within root zones, reducing the risk to human health and the environment. It is applied in situations where there are potential human health impacts, and exposure to substances of concern can be reduced to acceptable levels by containment. The disruption to site activities may be less than with more intrusive soil remediation technologies.
Phytostabilization is most effective for fine-textured soils with high organic-matter content, but it is suitable for treating a wide range of sites where large areas are subject to surface contamination (Cunningham et al. 1997; Berti and Cunningham 2000). However, some highly contaminated sites are not suitable for phytostabilization, because plant growth and survival is impossible (Berti and Cunningham 2000). Phytostabilization has advantages over other soil-remediation practices in that it is less expensive, easier to implement, and preferable aesthetically. (Berti and Cunningham 2000; Schnoor 2000). When decontamination strategies are impractical because of the extent of the contaminated area or the lack of adequate funding, phytostabilization is advantageous (Berti and Cunningham 2000). It may also serve as an interim strategy to reduce risk at sites where complications delay the selection of the most appropriate technique.
Characteristics of plants appropriate for phytostabilization at a particular site include: tolerance to high levels of the contaminant(s) of concern; high production of root biomass able to immobilize these contaminants through uptake, precipitation, or reduction; and retention of applicable contaminants in roots, as opposed to transfer to shoots, to avoid special handling and disposal of shoots.
Yoon et al. (2006) evaluated the potential of 36 plants (17 species) growing on a contaminated site and found that plants with a high bio-concentration factor (BCF, metal concentration ratio of plant roots to soil) and low translocation factor (TF, metal concentration ratio of plant shoots to roots) have the potential for phytostabilization (Fig. 2a–e). The lack of appreciable metals in shoot tissue also eliminates the necessity to treat harvested shoot residue as a hazardous waste (Flathman and Lanza 1998). In a field study, mine wastes containing copper, lead, and zinc were stabilized by grasses (Agrostis tenuis cv. Goginan for acid lead and zinc mine wastes, Agrostis tenuis cv. Parys for copper mine wastes, and Festuca rubra cv. Merlin for calcareous lead and zinc mine wastes) (Smith and Bradshaw 1992). The research of Smith and Bradshaw (1992) led to the development of two cultivars of Agrostis tenuis Sibth and one of Festuca rubra L which are now commercially available for phytostabilizing Pb-, Zn-, and Cu-contaminated soils.
Stabilization also involves soil amendments to promote the formation of insoluble metal complexes that reduce biological availability and plant uptake, thus preventing metals from entering the food chain (Adriano et al. 2004; Berti and Cunningham 2000; Cunningham et al. 1997). One way to facilitate such immobilisation is by altering the physicochemical properties of the metal-soil complex by introducing a multipurpose anion, such as phosphate, that enhances metal adsorption via. anion-induced negative charge and metal precipitation (Bolan et al. 2003). Addition of humified organic matter (O.M.) such as compost, together with lime to raise soil pH (Kuo et al. 1985), is a common practice for immobilizing heavy metals and improving soil conditions, to facilitate re-vegetation of contaminated soils (Williamson and Johnson 1981). Soil acidification, due to the oxidation of metallic sulphides in the soil, increases heavy metal bioavailability; but liming can control soil acidification; also, organic materials generally promoted fixation of heavy metals in non-available soil fractions, with Cu bioavailability being particularly affected by organic treatments (Clemente et al. 2003). The production of sulphate by sulphide oxidation increased solubility of Zn and Mn, and therefore their concentrations in plant-available (DTPA-extractable) fractions. However, the bioavailability of Cu did not decrease with either soil pH increase or with lime, indicating that the organic treatments might have had a significant effect. Revegetation of mine tailings usually requires amendments of phosphorus, even though phosphate addition can mobilize arsenic (As) from the tailings. Leachates and uptakes of As were found to be higher with an organic fertilizer amendment than superphosphate, particularly in combination with barley (Mains et al. 2006b). Active phytoremediation followed by natural attenuation, was effective for remediation of the pyrite-polluted soil (Clemente et al. 2006).
The Met PAD IM bio test was used to assess the extent of metal accumulation by plants in mining areas. Plants were identified as hyper tolerant which can be used for phytostabilization (Boularbah et al. 2006). Two plant species, Hyparrhenia hirta and Zygophyllum fabago, that have naturally colonized some parts of mine tailings in South-East Spain, have been reported to tolerate high metal concentrations in their rhizospheres. These plant species do not take up high concentrations of metals, providing a good tool to achieve surface stabilization of tailings with low risk of affecting the food chain (Conesa et al. 2006). Phytostabilization efforts in the Mediterranean region have been found to be improved by using mixtures including local metallicolous legume and grass species (Frérot et al. 2006). It is better to identify the plants spontaneously colonizing the contaminated site, since they are more ecologically adapted than introduced species. Recent research results on phytostabilization are summarized in Table 4.
2.2 Phytofiltration
Phytofiltration is the use of plant roots (rhizofiltration) or seedlings (blastofiltration) to absorb or adsorb pollutants, mainly metals, from water and aqueous-waste streams (Prasad and Freitas 2003). Plant roots or seedlings grown in aerated water absorb, precipitate and concentrate toxic metals from polluted effluents (Dushenkov and Kapulnik 2000; Elless et al. 2005). Mechanisms involved in biosorption include chemisorption, complexation, ion exchange, micro precipitation, hydroxide condensation onto the biosurface, and surface adsorption (Gardea-Torresdey et al. 2004).
Rhizofiltration uses terrestrial plants instead of aquatic plants because the former feature much larger fibrous root systems covered with root hairs with extremely large surface areas. Metal pollutants in industrial-process water and in groundwater are most commonly removed by precipitation or flocculation, followed by sedimentation and disposal of the resulting sludge (Ensley 2000). The process involves raising plants hydroponically and transplanting them into metal-polluted waters where plants absorb and concentrate the metals in their roots and shoots (Dushenkov et al. 1995; Salt et al. 1995; Flathman and Lanza 1998; Zhu et al. 1999). Root exudates and changes in rhizosphere pH may also cause metals to precipitate onto root surfaces. As they become saturated with the metal contaminants, roots or whole plants are harvested for disposal (Flathman and Lanza 1998; Zhu et al. 1999).
Dushenkov et al. (1995), Salt et al. (1995), and Flathman and Lanza (1998) contend that plants for phytoremediation should accumulate metals only in the roots. Dushenkov et al. (1995) explain that the translocation of metals to shoots would decrease the efficiency of rhizofiltration by increasing the amount of contaminated plant residue needing disposal. However, Zhu et al. (1999) suggest that the efficiency of the process can be increased by using plants with a heightened ability to absorb and translocate metals.
Several aquatic species have the ability to remove heavy metals from water, including water hyacinth (Eichhornia crassipes, Kay et al. 1984; Zhu et al. 1999), pennywort (Hydrocotyle umbellata L., Dierberg et al. 1987), and duckweed (Lemna minor L., Mo et al. 1989). However, these plants have limited potential for rhizofiltration because they are not efficient in removing metals as a result of their small, slow-growing roots (Dushenkov et al. 1995). The high water content of aquatic plants complicates their drying, composting, or incineration. In spite of limitations, Zhu et al. (1999) indicated that water hyacinth is effective in removing trace elements in waste streams. Sunflower (Helianthus annus L.) and Indian mustard (Brassica juncea Czern.) are the most promising terrestrial candidates for removing metals from water. The roots of Indian mustard are effective in capturing Cd, Cr, Cu, Ni, Pb, and Zn (Dushenkov et al. 1995), whereas sunflower removes Pb (Dushenkov et al. 1995), U (Dushenkov et al. 1997a), 137Cs, and 90Sr (Dushenkov et al. 1997b) from hydroponic solutions. A novel phytofiltration technology has been proposed by Sekhar et al. (2004) for removal and recovery of lead (Pb) from wastewaters. This technology uses plant-based biomaterial from the bark of the plant commonly called Indian sarsaparilla (Hemidesmus indicus). The target of their research was polluted surface water and groundwater at industrially contaminated sites. Cassava waste biomass was also effective in removing two divalent metal ions, Cd (II) and Zn (II), from aqueous solutions (Horsfall and Abia 2003). Modification of the cassava waste biomass by treating it with thioglycollic acid resulted in increased adsorption rates for Cd, Cu, and Zn (Abia et al. 2003). Several species of Sargassum biomass (non living brown algae) were effective biosorbents for heavy metals such as Cd and Cu (Davis et al. 2000).
Plants used for phytofiltration should be able to accumulate and tolerate significant amounts of the target metals, in conjunction with easy handling, low maintenance costs, and a minimum of secondary waste requiring disposal. It is also desirable for plants to produce significant amounts of root biomass or root surface area (Dushenkov and Kapulnik 2000). Reports on phytofiltration are summarized in Table 5.
2.3 Phytovolatilization
Some metal contaminants such as As, Hg, and Se may exist as gaseous species in the environment. In recent years, researchers have sought naturally-occurring or genetically-modified plants capable of absorbing elemental forms of these metals from the soil, biologically converting them to gaseous species within the plant, and releasing them into the atmosphere. This process is called phytovolatilization. The mechanism of phytovolatilization is shown schematically in Fig. 4. Volatilization of Se from plant tissues may provide a mechanism of selenium detoxification. As early as 1894, Hofmeister proposed that selenium in animals is detoxified by releasing volatile dimethyl selenide from the lungs, based on the fact that the odour of dimethyl telluride was detected in the breath of dogs injected with sodium tellurite. Using the same logic, it was suggested that the garlicky odour of plants that accumulate selenium may indicate release of volatile selenium compounds. This is the most controversial of phytoremediation technologies. Hg and Se are toxic (Suszcynsky and Shann 1995), and there is doubt about whether the volatilization of these elements into the atmosphere is desirable or safe (Watanabe 1997).
The volatile selenium compound released from the selenium accumulator Astragalus racemosus was identified as dimethyl diselenide (Evans et al. 1968). Selenium released from alfalfa, a selenium nonaccumulator, was different from the accumulator species and was identified as dimethyl selenide. Lewis et al. (1966) showed that both selenium nonaccumulator and accumulator species volatilize selenium. Selenium phytovolatilization has received the most attention to date (Lewis et al. 1966; Terry et al. 1992; Banuelos et al. 1993; McGrath 1998) because this element is a serious problem in many parts of the world where there are Se-rich soil (Brooks 1998). According to Brooks (1998), the release of volatile Se compounds from higher plants was first reported by Lewis et al. (1966). Terry et al. (1992) report that members of the Brassicaceae are capable of releasing up to 40 g Se ha−1 day −1 as various gaseous compounds. Some aquatic plants, such as cattail (Typha latifolia L.), have potential for Se phytoremediation (Pilon-Smits et al. 1999).
Volatile Se compounds such as dimethylselenide are 1/600 to 1/500 as toxic as inorganic forms of Se found in soil (DeSouza et al. 2000). The volatilization of Se and Hg is also a permanent site solution, because the inorganic forms of these elements are removed, and gaseous species are not likely to redeposit at or near the site (Atkinson et al. 1990; Heaton et al. 1998). Furthermore, sites that utilize this technique may not require much management after the original planting. This remediation method has the added benefits of minimal site disturbance, less erosion, and no need to dispose of contaminated plant material (Heaton et al. 1998). Heaton et al. (1998) suggest that the transfer of Hg (O) to the atmosphere would not contribute significantly to the atmospheric pool. This technique appears to be a promising tool for remediating Se- and Hg- contaminated soils.
Volatilization of arsenic as dimethylarsenite has also been postulated as a resistance mechanism in marine algae. However, it is not known whether terrestrial plants also volatilize arsenic in significant quantities. Studies on arsenic uptake and distribution in higher plants indicate that arsenic predominantly accumulates in roots and that only small quantities are transported to shoots. However, plants may enhance the biotransformation of arsenic by rhizospheric bacteria, thus increasing the rates of volatilization (Salt et al. 1998).
Unlike other remediation techniques, once contaminants have been removed via volatilization, there is a loss of control over their migration to other areas. Some authors suggest that the addition to atmospheric levels through phytovolatilization would not contribute significantly to the atmospheric pool, since the contaminants are likely to be subject to more effective or rapid natural degradation processes such as photodegradation (Azaizeh et al. 1997). However, phytovolatilization should be avoided for sites near population centres and at places with unique meteorological conditions that promote the rapid deposition of volatile compounds (Heaton et al. 1998). Hence the consequences of releasing the metals to the atmosphere need to be considered carefully before adopting this method as a remediation tool.
2.4 Phytoextraction
Phytoextraction, also called phytoaccumulation, refers to the uptake and translocation of metal contaminants in the soil by plant roots into above-ground components of the plants (Fig. 5). The typical levels of heavy metals concentration effects in plants are given in Table 6. The terms phytoremediation and phytoextraction are sometimes incorrectly used as synonyms, but phytoremediation is a concept, whereas phytoextraction is a specific clean-up technology (Prasad and Freitas 2003). Certain plants, called hyperaccumulators, absorb unusually large amounts of metals compared to other plants and the ambient metals concentration. Natural metal hyperaccumulators are plants that can accumulate and tolerate greater metal concentrations in shoots than those usually found in non-accumulators, without visible symptoms. Examples of commonly reported hyperaccumulators are given in Tables 7 and 8. According to Baker and Brooks (1989), hyperaccumulators should have a metal accumulation exceeding a threshold value of shoot metal concentration of 1% (Zn, Mn), 0.1% (Ni, Co, Cr, Cu, Pb and Al), 0.01% (Cd and Se) or 0.001% (Hg) of the dry weight shoot biomass.
Over 400 hyperaccumulator plants have been reported, including members of the Asteraceae, Brassicaceae, Caryophyllaceae, Cyperaceae, Cunouniaceae, Fabaceae, Flacourtiaceae, Lamiaceae, Poaceae, Violaceae, and Euphobiaceae. Recently Environment Canada has released a database “Phytorem” which contains a worldwide inventory of more than 750 terrestrial and aquatic plants, both wild and cultivated species and varieties, of potential value for phytoremediation. These plants are selected and planted at a site based on the metals present and site conditions. After they have grown for several weeks or months, the plants are harvested. Planting and harvesting may be repeated to reduce contaminant levels to allowable limits (Kumar et al. 1995). The time required for remediation depends on the type and extent of metal contamination, the duration of the growing season, and the efficiency of metal removal by plants, but it normally ranges from 1 to 20 years (Kumar et al. 1995; Blaylock and Huang 2000). This technique is suitable for remediating large areas of land contaminated at shallow depths with low to moderate levels of metal-contaminants (Kumar et al. 1995; Blaylock and Huang 2000).
2.4.1 Types of Phytoextraction
Two basic strategies of phytoextraction are being developed: chelate-assisted phytoextraction, which we term induced phytoextraction; and long-term continuous phytoextraction. If metal availability is not adequate for sufficient plant uptake, chelates or acidifying agents may be added to the soil to liberate them (Cunningham and Ow 1996; Huang et al. 1997; Lasat et al. 1998). However, side effects of the addition of chelate to the soil microbial community are usually neglected. It has been reported (Wu et al. 1999) that many synthetic chelators capable of inducing phytoextraction might form chemically and microbiologically stable complexes with heavy metals, threatening soil quality and groundwater contamination. Several chelating agents, such as EDTA (ethylene diamine tetra acetic acid), EGTA (ethylene glycol-O,O′-bis-[2-amino-ethyl]-N,N,N′,N′,-tetra acetic acid), EDDHA (ethylenediamine di o-hyroxyphenylacetic acid), EDDS (ethylene diamine disuccinate) and citric acid, have been found to enhance phytoextraction by mobilizing metals and increasing metal accumulation (Tandy et al. 2006; Cooper et al. 1999). The increase in the phytoextraction of Pb by shoots of Z. mays L. was more pronounced than the increase of Pb in the soil solution with combined application of EDTA and EDDS (Luo et al. 2006). Although EDTA was, in general, more effective in soil metal solubilization, EDDS, less harmful to the environment, was more efficient in inducing metal accumulation in B. decumbens shoots (Santos et al. 2006). However, there is a potential risk of leaching of metals to groundwater, and a lack of reported detailed studies regarding the persistence of metal-chelating agent complexes in contaminated soils (Lombi et al. 2001a,b).
2.4.2 Successful Factors for Phytoextraction of Heavy Metals
As a plant-based technology, the success of phytoextraction is inherently dependent on several plant characteristics, the two most important being the ability to accumulate large quantities of biomass rapidly and the capacity to accumulate large quantities of environmentally important metals in the shoot tissue (Kumar et al. 1995; Cunningham and Ow 1996; McGrath 1998; Pilon-Smits 2005). Effective phytoextraction requires both plant genetic ability and the development of optimal agronomic practices, including (1) soil management practices to improve the efficiency of phytoextraction, and (2) crop management practices to develop a commercial cropping system. Ebbs et al. (1997) reported that B. juncea, while having one-third the concentration of Zn in its tissue, is more effective at removing Zn from soil than Thlaspi caerulescens, a known hyperaccumulator of Zn. The advantage is due primarily to the fact that B. juncea produces ten-times more biomass than T. caerulescens. Plants for phytoextraction should be able to grow outside their area of collection, have profuse root systems and be able to transport metals to their shoots. They should have high metal tolerance, be able to accumulate several metals in large amounts, exhibit high biomass production and fast growth, resist diseases and pests, and be unattractive to animals, minimizing the risk of transferring metals to higher trophic levels of the terrestrial food chain (Thangavel and Subhuram 2004). Phytoextraction is applicable only to sites containing low to moderate levels of metal pollution, because plant growth is not sustained in heavily polluted soils. The land should be relatively free of obstacles, such as fallen trees or boulders, and have an acceptable topography to allow normal cultivation practices, utilizing agricultural equipment. Selected plants should be easy to establish and care for, grow quickly, have dense canopies and root systems, and be tolerant of metal contaminants and other site conditions which may limit plant growth.
Basic et al. (2006a,b) investigated the parameters influencing the Cd concentration in plants, as well as the biological implications of Cd hyperaccumulation in nine natural populations of T. caerulescens. Cd concentrations in the plant were positively correlated with plant Zn, Fe and Cu concentrations. The physiological and/or molecular mechanisms for uptake, transport and/or accumulation of these four heavy metals interact with each other. They specified a measure of Cd hyperaccumulation capacity by populations and showed that T. caerulescens plants originating from populations with high Cd hyperaccumulation capacity had better growth, by developing more and bigger leaves, taller stems, and produced more fruits and heavier seeds. Liu et al. (2006) conducted a survey of Mn mine tailing soils and eight plants growing on Mn mine tailings. The concentrations of soil Mn, Pb, and Cd and the metal-enrichment traits of these eight plants were analyzed. It was found that Poa pratensis, Gnaphalium affine, Pteris vittata, Conyza Canadensis and Phytolacca acinosa possessed specially good metal-enrichment and metal-tolerant traits. In spite of the high concentration of Mn in P. pratensis, its lifecycle was too short, and its shoots were too difficult to collect for it to be suitable for soil remediation.
The effectiveness of phytoextraction of heavy metals in soils also depends on the availability of metals for plant uptake (Li et al. 2000). The rates of redistribution of metals and their binding intensity are affected by the metal species, loading levels, aging and soil properties (Han et al. 2003). Generally, the solubility of metal fractions is in the order: exchangeable > carbonate specifically adsorbed > Fe–Mn oxide > organic sulfide > residual (Li and Thornton 2001). Ammonium nutrition of higher plants results in rhizosphere acidification due to proton excretion by root cells. Ammonium-fed sunflowers induced a strong acidification of the solution and, compared to the nitrate-fed sunflowers, a small modification in mineral nutrition and different Cd partitioning between root and shoot. Moreover, ammonium nutrition was found to induce a great mobilisation of a sparingly soluble form of cadmium (CdCO3) (Zaccheo et al. 2006). A lipid-transfer protein isolated from a domestic cultivar of brewer’s barley grain, Hordeum vulgare has the affinity to bind Co (II) and Pb (II), but not Cd (II), Cu (II), Zn (II) or Cr (III). This suggests a new possible role of barley lipid-transfer protein for phytoextraction (Gorjanovic et al. 2006).
The slow desorption of heavy metals in soils has been a major impediment to the successful phytoextraction of metal contaminated sites. Except for Hg, metal uptake into roots occurs from the aqueous phase. In soil, easily mobile metals such as Zn and Cd occur primarily as soluble or exchangeable, readily bioavailable form. Cu and Mo predominate in inorganically bound and exchangeable fractions. Slightly mobile metals such as Ni and Cr are mainly bound in silicates (residual fraction). Soluble, exchangeable and chelated species of trace elements are the most mobile components in soils, facilitating their migration and phytoavailability (Williams et al. 2006). Other species such as Pb occur as insoluble precipitates (phosphates, carbonates and hydroxyl-oxides) which are largely unavailable for plant uptake (Pitchel et al. 1999).
Understanding the mechanisms of rhizosphere interaction, uptake, transport and sequestration of metals in hyperaccumulator plants will lead to designing novel transgenic plants with improved remediation traits (Eapen and D’Souza 2005). Moreover, the selection and testing of multiple hyperaccumulator plants could enhance the rate of phytoremediation, giving this process a promise one for bioremediation of environmental contamination (Suresh and Ravishankar 2004). Some of the recent reports on phytoextraction are summarized in Table 9. Phytoremediation has been combined with electrokinetic remediation, applying a constant voltage of 30 V across the soil. The combination of both techniques could represent a very promising approach to the decontamination of metal-polluted soils (O’Connor et al. 2003).
3 Handling of Hazardous Plant Biomass after Phytoremediation
Phytoextraction involves repeated cropping of plants in contaminated soil until the metal concentration drops to an acceptable level. Each crop is removed from the site. This leads to accumulation of huge quantities of hazardous biomass, which must be stored or disposed appropriately to minimize environmental risk. After harvesting, the methods of disposal of contaminated plants include approved secure landfills, surface impoundments, deep well injection, ocean dumping or incineration. The waste volume can be reduced by thermal, microbial, physical or chemical means.
In one study, the dry weight of B. juncea for induced phytoextraction of lead amounted to 6 tons/ha containing 10,000–15,000 mg/kg metal on a dry weight basis (Blaylock et al. 1997). Composting and compaction can provide post-harvest treatment (Raskin et al. 1997 and Kumar et al. 1995). Even though composting can significantly reduce the volume of the harvested biomass, metal-contaminated biomass still requires treatment prior to disposal. In the case of compaction, care should be taken to collect and dispose of the leachate. A conventional and promising route to utilize biomass produced by phytoremediation is through thermo-chemical conversion processes such as combustion, gasification and pyrolysis.
If phytoextraction could be combined with biomass generation and its commercial utilization as an energy source, then it could be turned into a profitable operation, with the residual ash available to be used as an ore (Brooks 1998; Comis 1996; Cunningham and Ow 1996). Phytomining includes the generation of revenue by extracting soluble metals produced by the plant biomass ash, also known as bio-ore. With some metals like Ni, Zn, Cu, etc., the value of reclaimed metal may provide an additional incentive for phytoremediation (Chaney et al. 1997, Watanabe 1997, Thangavel and Subhuram 2004).
4 Conclusions
Phytoremediation is still in its research and development phase, with many technical issues needing to be addressed. The results, though encouraging, suggest that further development is needed. Phytoremediation is an interdisciplinary technology that can benefit from many different approaches. Results already obtained have indicated that some plants can be effective in toxic metal remediation. The processes that affect metal availability, metal uptake, translocation, chelation, degradation, and volatilization need to be investigated in detail. Better knowledge of these biochemical mechanisms may lead to: (1) Identification of novel genes and the subsequent development of transgenic plants with superior remediation capacities; (2) Better understanding of the ecological interactions involved (e.g. plant-microbe interactions); (3) Appreciation of the effect of the remediation process on ecological interactions; and (4) Knowledge of the entry and movement of the pollutant in the ecosystem. In addition to being desirable from a fundamental biological perspective, findings will help improve risk assessment during the design of remediation plans, as well as alleviation of risks associated with the remediation. It is important that public awareness of this technology be considered, with clear and precise information made available to the general public to enhance its acceptability as a global sustainable technology. So far, most phytoremediation experiments have taken place on a laboratory scale, with plants grown in hydroponic settings fed heavy metal diets. Both agronomic management practices and plant genetic abilities need to be optimized to develop commercially useful practice.
References
Abia, A. A., Horsfall, M., & Didi, O. (2003). The use of chemically modified and unmodified cassava waste for the removal of Cd, Cu and Zn ions from aqueous solution. Bioresource Technology, 90, 345–348.
Adriano, D. C., Wenzel, W. W., Vangronsveld, J., & Bolan, N. S. (2004). Role of assisted natural remediation in environmental cleanup. Geoderma, 122, 121–142.
Albasel, N., & Cottenie, A. (1985). Heavy metal contamination near major highways, industrial and urban areas in Belgium grassland. Water, Air and Soil Pollution, 24, 103–109.
Al-Chalabi, A. S., & Hawker, D. (2000). Distribution of vehicular lead in roadside soils of major roads of Brisbane, Australia. Water, Air and Soil Pollution, 118, 299–310.
Alloway, B. J. (1995). Soil processes and the behavior of metals. In: Alloway B. J. (Ed), Heavy metals in soils (pp. 38–57). London: Blackie.
Alkorta, I., Herna´ndez-Allica, J., Becerril, J. M., Amezaga, I., Albizu, I., & Garbisu, C. (2004). Recent findings on the phytoremediation of soils contaminated with environmentally toxic heavy metals and metalloids such as zinc, cadmium, lead, and arsenic. Reviews in Environmental Science and Bio/Technology, 3, 71–90.
Atkinson, R., Aschmann, S. M., Hasegawa, D., Eagle-Thompson, E. T., & Frankenberger, J. R. (1990). Kinetics of the atmospherically important reactions of dimethylselenide. Environmental Science and Technology, 24, 1326–1332.
Azaizeh, H. A., Gowthaman, S., & Terry, N. (1997). Microbial selenium volatilization in rhizosphere and bulk soils from a constructed wetland. Journal of Environmental Quality, 26(3), 666–672.
Baker, A. J. M., & Brooks, R. R. (1989). Terrestrial higher plants which hyper accumulate metallic elements – Review of their distribution, ecology, and phytochemistry. Biorecovery, 1, 81–126.
Baker, A. J. M., Reeves, R. D., & McGrath, S. P. (1991). In situ decontamination of heavy metal polluted soils using crops of metal accumulating plants – A feasibility study. In R. E. Hinchee & R. F. Olfenbuttel (Eds.), In-situ bioremediation (pp. 539–544). Stoneham, M. A: Butterworth-Heinemann.
Baker, A. J. M., & Walker, P. L. (1989). Ecophysiology of metal uptake by tolerant plants. In A. J. Shaw (Ed.), Heavy metal tolerance in plants: Evolutionary aspects (pp. 155–177). Boca Raton, FL: CRC.
Banuelos, G. S., Cardon, G., Mackey, B., Ben-Asher, J., Wu, L. P., Beuselinck, P., et al. (1993). Boron and selenium removal in B-laden soils by four sprinkler irrigated plant species. Journal of Environmental Quality, 22(4), 786–797.
Basic, N., Keller, C., Fontanillas, P., Vittoz, P., Besnard, G., & Galland, N. (2006a). Cadmium hyperaccumulation and reproductive traits in natural Thlaspi caerulescens populations. Plant Biology, 8, 64–72.
Basic, N., Salamin, N., Keller, C., Galland, N., & Besnard, G. (2006b). Cadmium hyperaccumulation and genetic differentiation of Thlaspi caerulescens populations. Biochemical Systematics and Ecology, 34(9), 667–677.
Baudouin, C., Charveron, M., Tarrouse, R., & Gall, Y. (2002). Environmental pollutants and skin cancer. Cell Biology and Toxicology, 18, 341–348.
Beath, O. A., Eppsom, H. F., & Gilbert, G. S. (1937). Selenium distribution in and seasonal variation of vegetation type occurring on seleniferous soils. Journal of the American Pharmaceutical Association, 26, 394–405.
Belimov, A. A., Hontzeas, N., Safronova, V. I., Demchinskaya, S. V., Piluzza G., Bullitta, S., et al. (2005). Cadmium-tolerant plant growth-promoting bacteria associated with the roots of Indian mustard (Brassica juncea L. Czern.). Soil Biology & Biochemistry, 37, 241–250.
Berti, W. R., & Cunningham, S. D. (2000). Phytostabilization of metals. In I. Raskin & B. D. Ensley (Eds.), Phytoremediation of toxic metals: Using plants to clean-up the environment (pp. 71–88). New York: Wiley.
Bidwell S. D., Woodrow, I. E., Batianoff, G. N., & Sommer-Knudsen, J. (2002). Hyperaccumulation of manganese in the rainforest tree Austromyrtus bidwillii (Myrtaceae) from Queensland, Australia. Functional Plant Biology, 29, 899–905.
Birch, G. E., & Scollen, A. (2003). Heavy metals in road dust, gully pots and parkland soils in a highly urbanised sub-catchment of Port Jackson, Australia. Australian Journal of Soil Research, 41, 1329–1342.
Blaylock, M. J., & Huang, J. W. (2000). Phytoextraction of metals. In I. Raskin & B. D. Ensley (Eds.), Phytoremediation of toxic metals: Using plants to clean-up the environment (pp. 53–70). New York: Wiley.
Blaylock, M. J., Salt, D. E., Dushenkov, S., Zakharova, O., Gussman, C., Kapulnik, Y., et al. (1997). Enhanced accumulation of Pb in Indian mustard by soil-applied chelating agents. Environmental Science and Technology, 31(3), 860–865.
Bolan, N. S., Adriano, D. C., & Naidu, R. (2003). Role of phosphorus in (im)mobilization and bioavailability of heavy metals in the soil-plant system. Reviews of Environmental Contamination and Toxicology, 177, 1–44.
Boonyapookana, B., Parkplan, P., Techapinyawat, S., DeLaune, R. D., & Jugsujinda, A. (2005). Phytoaccumulation of lead by sunflower (Helianthus annuus), tobacco (Nicotiana tabacum), and vetiver (Vetiveria zizanioides). Journal of Environmental Science and Health A, 40, 117–137.
Boularbah, A., Schwartz, C., Bitton, G., Aboudrar, W., Ouhammou, A., & Morel, J. L. (2006). Heavy metal contamination from mining sites in South Morocco: 2. Assessment of metal accumulation and toxicity in plants. Chemosphere, 63(5), 811–817.
Broadhurst, C. L., Chaney, R. L., Angle, J. S., Maugel, T. K., Erbe, E. F., & Murphy, C. A. (2004). Simultaneous hyperaccumulation of nickel, manganese, and calcium in Alyssum leaf trichomes. Environmental Science & Technology, 38, 5797–5802.
Brooks, R. R. (ed) (1998). Plants that hyperaccumulate heavy metals (p. 384). Wallingford: CAB International.
Caille, N., Swanwick, S., Zhao, F. J., & McGrath, S. P. (2004). Arsenic hyperaccumulation by Pteris vittata from arsenic contaminated soils and the effect of liming and phosphate fertilisation. Environmental Pollution, 132, 113–120.
Chandra Sekhar, K., Kamala, C. T., Chary, N. S., Balaram, V., & Garcia, G. (2005). Potential of Hemidesmus indicus for phytoextraction of lead from industrially contaminated soils. Chemosphere, 58, 507–514.
Chaney, R. L. (1983). Plant uptake of inorganic waste constitutes. In J. F. Parr, P. B. Marsh, & J. M. Kla (Eds.), Land treatment of hazardous wastes (pp. 50–76). Park Ridge, NJ: Noyes Data Corp.
Chaney, R. L., Malik, M., Li, Y. M., Brown, S. L., Brewer, E. P., Angle, J. S., et al. (1997). Phytoremediation of soil metals. Current Opinion in Biotechnology, 8, 279–283.
Chaudhry, T. M., Hayes, W. J., Khan, A. G., & Khoo, C. S. (1998). Phytoremediation – Focusing on accumulator plants that remediate metal-contaminated soils. Australasian Journal of Ecotoxicology, 4, 37–51.
Chen, Y. X., Wang, Y. P., Wu, W. X. Lin, Q., & Xue, S. G. (2006). Impacts of chelate-assisted phytoremediation on microbial community composition in the rhizosphere of a copper accumulator and non-accumulator. Science of the Total Environment, 356(1–3), 247–255.
Clemente, R., Almela, C., & Bernal, P. M. (2006). A remediation strategy based on active phytoremediation followed by natural attenuation in a soil contaminated by pyrite waste. Environmental Pollution, 143(3), 397–406.
Clemente, R., Walker, J. D., Roig, A., & Bernal, P. M. (2003). Heavy metal bioavailability in a soil affected by mineral sulphides contamination following the mine spillage at Aznalc´ollar (Spain). Biodegradation, 14, 199–205.
Comis, D. (1996). Green remediation: Using plants to clean the soil. Journal of Soil and Water Conservation, 51(3), 184–187.
Conesa, M. H., Faz, A., & Arnaldos, R. (2006). Initial studies for the phytostabilization of a mine tailing from the Cartagena–La Union Mining District (SE Spain). Chemosphere, 66(1), 38–44.
Cooper, E. M., Sims, J. T., Cunningham, S. D., Huang, J. W., & Berti, W. R. (1999). Chelate-assisted phytoextraction of lead from contaminated soil. Journal of Environmental Quality, 28, 1709–1719.
Cunningham, S. D., & Ow, D. W. (1996). Promises and prospects of phytoremediation. Plant Physiology, 110(3), 715–719.
Cunningham, S. D., Shann, J. R., Crowley, D. E., & Anderson, T. A. (1997). Phytoremediation of contaminated water and soil. In E. L. Kruger, T. A. Anderson, & J. R. Coats (Eds.), Phytoremediation of soil and water contaminants. ACS Symposium series 664 (pp. 2–19). Washington, DC: American Chemical Society.
Davis, T. A., Volesky, B., & Vieira, R. H. S. F. (2000). Sargassum seaweed as biosorbent for heavy metals. Water Research, 34, 4270–4278.
Desouza, M. P., Pilon-Smits, E. A. H., & Terry, N. (2000). The physiology and biochemistry of selenium volatilization by plants. In I. Raskin, & B. D. Ensley (Eds.), Phytoremediation of toxic metals: Using plants to clean-up the environment (pp. 171–190). New York: Wiley.
Dierberg, F. E., Débuts, T. A., & Goulet, J. R. N. A. (1987). Removal of copper and lead using a thin-film technique. In K. R. Reddy & W. H. Smith (Eds.), Aquatic plants for water treatment and resource recovery (pp. 497–504). Magnolia.
Dushenkov, S., & Kapulnik, Y. (2000). Phytofilitration of metals. In I. Raskin & B. D. Ensley (Eds.), Phytoremediation of toxic metals – Using plants to clean-up the environment (pp. 89–106). New York: Wiley.
Dushenkov, V., Kumar, P. B. A. N., Motto, H., & Raskin, I. (1995). Rhizofiltration: The use of plants to remove heavy metals from aqueous streams. Environmental Science and Technology, 29, 1239–1245.
Dushenkov, S., Vasudev, D., Kapulnik, Y., Gleba, D., Fleisher, D., Ting, K. C., et al. (1997a). Removal of uranium from water using terrestrial plants. Environmental Science and Technology, 31(12), 3468–3474.
Dushenkov, S., Vasudev, D., Kapulnik, Y., Gleba, D., Fleisher, D., Ting, K. C., et al. (1997b). Phytoremediation: A novel approach to an old problem. In D. L. Wise (Ed.), Global environmental biotechnology (pp. 563–572). Amsterdam: Elsevier.
Eapen, S., & D’Souza, S. F. (2005). Prospects of genetic engineering of plants for phytoremediation of toxic metals. Biotechnology Advances, 23, 97–114.
Ebbs, S. D., Lasat, M. M., Brandy, D. J., Cornish, J., Gordon, R., & Kochian, L. V. (1997). Heavy metals in the environment: Phytoextraction of cadmium and zinc from a contaminated soil. Journal of Environmental Quality, 26, 1424–1430.
Elless, P. M., Poynton, Y. C., Williams, A. C., Doyle, P. M., Lopez, C. A., Sokkary, A. D., et al. (2005). Pilot-scale demonstration of phytofiltration for drinking arsenic in New Mexico drinking water. Water Research, 39(16), 3863–3872.
Ensley, B. D. (2000). Rationale for use of phytoremediation. In I. Raskin, & B. D. Ensley (Eds.), Phytoremediation of toxic metals: Using plants to clean- up the environment (pp. 3–12). New York: Wiley.
Entry, J. A., Watrud, L. S., & Reeves, M. (1999). Accumulation of 137Cs and 90Sr from contaminated soil by three grass species inoculated with mycorrhizal fungi. Environmental Pollution, 104, 449–457.
Evangelou, M. W. H., Ebel, M., & Schaeffer, A. (2006). Evaluation of the effect of small organic acids on phytoextraction of Cu and Pb from soil with tobacco Nicotiana tabacum. Chemosphere, 63(6), 996–1004.
Evans, C. S., Asher, C., & Johnson, C. M. (1968). Isolation of dimethyl diselenide and other volatile selenium compounds from Astragalus racemosus (Pursh.) Aust. Journal of Biological Sciences, 21, 13–20.
Fakayode, S. O., & Olu-Owolabi, B. I. (2003). Heavy metal contamination of roadside topsoil in Osogbo, Nigeria: Its relationship to traffic density and proximity to highways. Environmental Geology, 44(2), 150–157.
Fatoki, O. S. (1996). Trace zinc and copper concentration in roadside surface soils and vegetation: A measurement of local atmospheric pollution in Alice, South Africa. Environmental Interpretation, 22, 759–762.
Flathman, P. E., & Lanza, G. R. (1998). Phytoremediation: Current views on an emerging green technology. Journal of Soil Contamination, 7(4), 415–432.
Frérot, H., Lefèbvre, C., Gruber, W., Collin, C., Dos Santos, A., & Escarre, J. (2006). Specific interactions between local metallicolous plants improve the phytostabilization of mine soils. Plant and Soil, 282, 53–65.
Garbisu, C., & Alkorta, I. (2001). Phytoextraction: A cost-effective plant-based technology for the removal of metals from the environment. Bioresource Technology, 77, 229–236.
García, R., & Millán, E. (1998). Assessment of Cd, Pb and Zn contamination in roadside soils and grasses from Gipuzkoa (Spain). Chemosphere, 37, 1615–1625.
Gardea-Torresdey, J. L., de la Rosa, G., & Peralta-Videa, J. R. (2004). Use of phytofiltration technologies in the removal of heavy metals: A review. Pure and Applied Chemistry, 76(4), 801–813.
Ghosh, M., & Singh, S. P. (2005). A review on phytoremediation of heavy metals and utilization of its by-products. Applied Ecology and Environmental Research, 3(1), 1–18.
Glass, D. J. (1999). U.S. and international markets for phytoremediation, 1999–2000 (p. 266). Needham, MA: D. Glass Associates.
Gorjanovic, S., Suznjevic, D., Beljanski, M., & Hranisavljevic, J. (2006). Barley lipid-transfer protein as heavy metal scavenger. Environmental Chemistry Letters, 2(3), 113–116.
Gulson, B. L., Tiller, K. G., Mizon, K. J., & Merry, R. H. (1981). Use of lead isotopes in soils to identify the source of lead contamination near Adelaide, South Australia. American Chemical Society, 15(6), 691–696.
Hammer, D., Keller, C., McLaughlin, M. J., & Hamon, R. E. (2006). Fixation of metals in soil constituents and potential remobilization by hyperaccumulating and non-hyperaccumulating plants: Results from an isotopic dilution study. Environmental Pollution, 143(3), 407–415.
Han, F. X., Banin, A., Kingery, W. L., Triplrtt, G. B., Zhou, L. X., Zheng, S. J., et al. (2003). New approach to studies of heavy metal redistribution in soil. Advances in Environmental Research, 8, 113–120.
Heaton, A. C. P., Rugh, C. L., Wang, N., & Meagher, R. B. (1998). Phytoremediation of mercury- and methyl mercury-polluted soils using genetically engineered plants. Journal of Soil Contamination, 74, 497–510.
Hernandez-Allica, J., Becerril, J. M., Zarate, O., & Garbisu, C. (2006). Assessment of the efficiency of a metal phytoextraction process with biological indicators of soil health. Plant and Soil, 281(1–2), 147–158.
Ho, Y. B., & Tai, K. M. (1988). Elevated levels of lead and other metals in roadside soil and grass and their use to monitor aerial metal depositions in Hong Kong. Environmental Pollution, 49(1), 37–51.
Horsfall, M., & Abia, A. A. (2003). Sorption of cadmium (II) and zinc (II) ions from aqueous solutions by cassava waste biomass (Manihot sculenta Cranz). Water Research, 37, 4913–4923.
Huang, J. W., Chen, J., Berti, W. R., & Cunningham, S. D. (1997). Phytoremediation of lead contaminated soil: Role of synthetic chelates in lead phytoextraction. Environmental Science and Technology, 31(3), 800–805.
Hughes, J. B., Shanks, J., Vanderford, M., Lauritzen, J., & Bhadra, R. (1997) Transformation of TNT by aquatic plants and plant tissue cultures. Environmental Science & Technology, 31, 266–271.
Jaffre, T., Brooks, R. R., Lee, J., & Reeves, R. D. (1976). Sebertia acumip. A nickel-accumulating plant from New Caledonia. Science, 193, 579–580.
Jain, S. K., Vasudevan, P., Jha, N. K. (1989). Removal of some heavy metals from polluted water by aquatic plants: Studies on duckweed and water velvet. Biological Wastes, 28(2), 115–126.
Kay, S. H., Haller, W. T., & Garrard, L. A. (1984). Effect of heavy metals on water hyacinths [Eichhornia crassipes (Mart.) Solms]. Aquatic Toxicology, 5, 117–128.
Keller, C., Diallo, S., Cosio, C., Basic, N., & Galland, N. (2006). Cadmium tolerance and hyperaccumulation by Thlaspi caerulescens populations grown in hydroponics are related to plant uptake characteristics in the field. Functional Plant Biology, 33(7), 673–684.
Knasmuller, S., Gottmann, E., Steinkellner, H., Fomin, A., Pickl, C., Paschke, A., et al. (1998). Detection of genotoxic effects of heavy metal contaminated soils with plant bioassays. Mutation Research, 420, 37–48.
Kobayashi, F., Asada, C., & Nakamura, Y. (2005). Phytoremediation of soil contaminated with heavy metals and recovery of valuable metals. Kagaku Kogaku Ronbunshu, 31(6), 476–480.
Kubota, H., & Takenaka, C. (2003). Arabis gemmifera is a hyperaccumulator of Cd and Zn. International Journal of Phytoremediation, 5, 197–120.
Kumar, P. B. A. N., Dushenkov, V., Motto, H., & Raskin, I. (1995). Phytoextraction: The use of plants to remove heavy metals from soils. Environmental Science and Technology, 29(5), 1232–1238.
Kuo, S., Jellum, E. J., & Baker, A. S. (1985). Effects of soil type, liming, and sludge application on zinc and cadmium availability to Swiss chard. Soil Science, 139, 122–130.
Lasat, M. M. (2002). Phytoextraction of toxic metals – A review of biological mechanisms. Journal of Environmental Quality, 31, 109–120.
Lasat, M. M., Fuhrmann, M., Ebbs, S. D., Cornish, J. E., & Kochian, L. V. (1998). Phytoremediation of a radio cesium contaminated soil: evaluation of cesium-137 bioaccumulation in the shoots of three plant species. Journal of Environmental Quality, 27(1), 165–168.
Leblanc, M., Petit, D., Deram, A., Robinson, B., & Brooks, R. R. (1999). The phytomining and environmental significance of hyperaccumulation of thallium by Iberis intermedia from southern France. Economic Geology, 94(1), 109–113.
LeDuc, D. L., Samie, M. A., Bayon, M. M., Wu, C. P., Reisinger, S. J., & Terry, N. (2006). Overexpressing both ATP sulfurylase and selenocysteine methyltransferase enhances selenium phytoremediation traits in Indian mustard. Environmental Pollution, 144(1), 70–76.
Lewis, B. G., Johnson, C. M., & Delwiche, C. C. (1966). Release of volatile selenium compounds by plants: Collection procedures and preliminary observations. Journal of Agricultural and Food Chemistry, 14, 638–640.
Li, Y. M., Chaney, R. L., Angle, J. S., & Baker, A. J. M. (2000). Phytoremediation of heavy metal contaminated soils. In D. L. Wise et al. (Eds.), Bioremediation of contaminated soils. New York: Marcel Dekker.
Li, X. D., & Thornton, I. (2001). Chemical partitioning of trace and major elements in soils contaminated by mining and smelting activities. Applied Geochemistry, 16, 1693–1706.
Liu, Y. G., Zhang, H. Z., Zeng, G. M., Huang, B. R., & Li, X. (2006). Heavy metal accumulation in plants on Mn mine tailings. Pedosphere, 16(1), 131–136.
Lombi, E., Zhao, F. J., Dunham, S. J., & MacGrath, S. P. (2001a). Phytoremediation of heavy metal-contaminated soils: Natural hyperaccumulation versus chemically enhanced phytoextraction. Journal of Environmental Quality, 30, 1919–1926.
Lombi, E., Zhao, F. J., Dunham. S. J., & McGrath, S. P. (2001b). Cadmium accumulation in populations of Thlaspi caerulescens and Thlaspi geosingense. New Phytologist, 145, 11–20.
Luo, C. L., Shen, Z. G., Li, X. D., & Baker, A. J. M. (2006). Enhanced phytoextraction of Pb and other metals from artificially contaminated soils through the combined application of EDTA and EDDS. Chemosphere, 63(10), 1773–1784.
Mains, D., Craw, D., Rufaut, C. G., & Smith, C. M. S. (2006a). Phytostabilization of gold mine tailings, New Zealand. Part 1: Plant establishment in alkaline saline substrate. International Journal of Phytoremediation, 8(2), 131–147.
Mains, D., Craw, D., Rufaut, C. G., & Smith, C. M. S. (2006b). Phytostabilization of gold mine tailings from New Zealand. Part 2: Experimental evaluation of arsenic mobilization during revegetation. International Journal of Phytoremediation, 8(2), 163–183.
McEldowney, S., Hardman, D. J., & Waite, S. (1993). Treatment technologies. In S. McEldowney, D. J. Hardman, & S. Waite (Eds.), Pollution, ecology and biotreatment (pp. 48–58). Singapore: Longman Singapore Publishers Pvt. Ltd.
McGrath, S. P. (1998). Phytoextraction for soil remediation. In R. R. Brooks (Ed.), Plants that hyperaccumulate heavy metals: Their role in phytoremediation, microbiology, archaeology, mineral exploration and phytomining (pp. 261–288). New York: CAB International.
McGrath, S. P., & Zhao, F. J. (2003). Phytoextraction of metals and metalloids. Current Opinion in Biotechnology, 14, 277–282.
McGrath, S. P., Zhao, F. J., & Lombi, E. (2002). Phytoremediation of metals, metalloids, and radionuclides. Advances in Agronomy, 75, 1–56.
McIntyre, T. (2003). Phytoremediation of heavy metals from soils. Advances in Biochemical Engineering, Biotechnology, 78, 97–123.
Meagher, R. B. (2000). Phytoremediation of toxic elemental and organic pollutants. Current Opinion in Plant Biology, 3, 153–162.
Mkandawire, M., & Dudel, E. G. (2005). Accumulation of arsenic in Lemna gibba L. (duckweed) in tailing waters of two abandoned uranium mining sites in Saxony, Germany. Science of the Total Environment, 336, 81–89.
Mo, S. C., Choi, D. S., & Robinson, J. W. (1989). Uptake of mercury from aqueous solution by duckweed: The effect of pH, copper, and humic acid. Journal of Environmental Health, 24, 135–146.
Navari-Izzo, F., & Quartacci, M. F. (2001). Phytoremediation of metals – Tolerance mechanisms against oxidative stress. Minerva Biotecnologica, 13, 73–83.
Nouairi, I., Ben Ammar, W., Ben Youssef, N., Daoud, D. B., Ghorbal, M. H., & Zarrouk, M. (2006). Comparative study of cadmium effects on membrane lipid composition of Brassica juncea and Brassica napus leaves. Plant Science, 170(3), 511–519.
O’Connor, C. S., Leppi, N. W., Edwards, R., & Sunderland, G. (2003). The combined use of electrokinetic remediation and phytoremediation to decontaminate metal-polluted soils: A laboratory-scale feasibility study. Environmental Monitoring and Assessment, 84, 141–158.
Odjegba, V. J., & Fasidi, I. O. (2004). Accumulation of trace elements by Pistia stratiotes: Implications for phytoremediation. Ecotoxicology, 13, 637–646.
Parker, D. R., Feist, L. J., Varvel, T. W., Thomason, D. N., & Zhang, Y. Q. (2003). Selenium phytoremediation potential of Stanleya pinnata. Plant Soil, 249, 157–165.
Pendergrass, A., & Butcher, D. J. (2006). Uptake of lead and arsenic in food plants grown in contaminated soil from Barber Orchard, NC. Microchemical Journal, 83(1), 14–16.
Pilon-Smits, E. A. H. (2005). Phytoremediation. Annual Review of Plant Biology, 56, 15–39.
Pilon-Smits, E. A. H., Desouza, M. P., Hong, G., Amini, A., Bravo, R. C., Payabyab, S. T., et al. (1999). Selenium volatilization and accumulation by twenty aquatic plant species. Journal of Environmental Quality, 28(3), 1011–1017.
Pitchel, J., Kuroiwa, K., & Sawyer, H. T. (1999). Distribution of Pb, Cd and Ba in soils and plants of two contaminated soils. Environmental Pollution, 110, 171–178.
Prasad, M. N. V, & Freitas, H. (2003). Metal hyperaccumulation in plants – Biodiversity prospecting for phytoremediation technology. Electronic Journal of Biotechnology, 6, 275–321.
Pugh, R. E., Dick, D. G., & Fredeen, A. L. (2002). Heavy metal (Pb, Zn, Cd, Fe and Cu) contents of plant foliage near the Anvil range lead/zinc mine, Faro, Yukon Territory. Ecotoxicology and Environmental Safety, 52, 273–279.
Quartacci, M. F., Argilla, A., Baker, A. J. M., & Navari-Izzo, F. (2006). Phytoextraction of metals from a multiple contaminated soil by Indian mustard. Chemosphere, 63(6), 918–925.
Raskin, I., Smith, R. D., & Salt, D. E. (1997). Phytoremediation of metals: using plants to remove pollutants from the environment. Current Opinion in Biotechnology, 8, 221–226.
Reeves, R. D., & Brooks, R. R. (1983). Hyperaccumulation of lead and zinc by two metallophytes from a mining area of Central Europe. Environmental Pollution Series A, 31, 277–287.
Rizzi, L., Petruzzelli, G., Poggio, G., & Vigna, G. (2004). Soil physical changes and plant availability of Zn and Pb in a treatability test of phytostabilization. Chemosphere, 57(9), 1039–1046.
Robinson, B. H., Brooks, R. R., Howes, A. W., Kirkman, J. H., & Gregg, P. E. H. (1997). The potential of the high-biomass nickel hyperaccumulator Berkheya coddii for phytoremediation and phytomining. Journal of Geochemical Exploration, 60, 115–126.
Sagiroglu, A., Sasmaz, A, & Sen, O. (2006). Hyperaccumulator plants of the Keban mining district and their possible impact on the environment. Polish Journal of Environmental Studies, 15(2), 317–325.
Salt, D. E., Blaylock, M., Kumar, P. B. A. N., Dushenkov, V., Ensley, B. D., Chet, L., et al. (1995). Phyto-remediation: a novel strategy for the removal of toxic metals from the environment using plants. Biogeochemistry, 13, 468–474.
Salt, D. E., Smith, R. D., & Raskin, I. (1998). Phytoremediation. Annual Review of Plant Physiology and Plant Molecular Biology, 49, 643–668.
Sánchez Martín, M. J., Sánchez Camazano, M., & Lorenzo, L. F. (2000). Cadmium and lead contents in suburban and urban soils from two medium-sized cities of Spain: Influence of traffic intensity. Bulletin of Environmental Contamination and Toxicology, 64, 250–257.
Santos, F. S., Hernández-Allica, J., Becerril, J. M., Amaral-Sobrinho, N., Mazur, N., & Garbisu, C. (2006). Chelate-induced phytoextraction of metal polluted soils with Brachiaria decumbens. Chemosphere, 65(1), 43–50.
Schnoor, J. L. (2000). Phytostabilization of metals using hybrid poplar trees. In I. Raskin & B. D. Ensley (Eds.), Phytoremediation of toxic metals: Using plants to clean-up the environment (pp. 133–150). New York: Wiley.
Schwartz, C., Echevarria, G., & Morel, J. L. (2003). Phytoextraction of cadmium with Thlaspi caerulescens. Plant Soil, 24, 27–35.
Sekhar, K. C., Kamala, C. T., Chary, N. S., Sastry, A. R. K., Rao, T. N., & Vairamani, M. (2004). Removal of lead from aqueous solutions using an immobilized biomaterial derived from a plant biomass. Journal of Hazardous Materials, 108, 111–117.
Sharma, N. C., Gardea-Torresdey, J. L., Parsons, J., & Sahi, S. V. (2004). Chemical speciation and cellular deposition of lead in Sesbania drummondii. Environmental Toxicology and Chemistry, 23, 2068–2073.
Sheng, X. F., & Xia, J. J. (2006). Improvement of rape (Brassica napus) plant growth and cadmium uptake by cadmium-resistant bacteria. Chemosphere, 64(6), 1036–1042.
Singh, O. V., Labana, S., Pandey, G., Budhiraja, R., & Jain, R. K. (2003). Phytoremediation: an overview of metallicion decontamination from soil. Applied Microbiology and Biotechnology, 61, 405–412.
Smith, R. A. H., & Bradshaw, A. D. (1992). Stabilization of toxic mine wastes by the use of tolerant plant populations. Transactions of the Institution of Mining and Metallurgy, 81, A230–A237.
Smolders, E., & Degryse, F. (2002). Fate and effect of zinc from tire debris in soil. Environmental Science and Technology, 36, 3706–3710.
Stoltz, E. (2004). Phytostabilisation:use of wet plants to treat mine tailings. Doctoral thesis, Department of Botany, Stockholm University.
Stoltz, E., & Greger, M. (2002). Accumulation properties of As, Cd, Cu, Pb and Zn by four wetland plant species growing on submerged mine tailings. Environmental and Experimental Botany, 47(3), 271–280.
Suresh, B., & Ravishankar, G. A. (2004). Phytoremediation – A novel and promising approach for environmental clean-up. Critical Reviews in Biotechnology, 24, 97–124.
Suszcynsky, E. M., & Shann, J. R. (1995). Phytotoxicity and accumulation of mercury subjected to different exposure routes. Environmental Toxicology and Chemistry, 14, 61–67.
Sutherland, R. A., Day, J. P., & Bussen, J. O. (2003). Lead concentrations, isotope ratios and source apportionment in road deposited sediments, Honolulu, Oahu, Hawaii. Water, Air and Soil Pollution, 142, 165–186.
Swaileh, K. M., Hussen, R. H., & Abu-Elhaj, S. (2004). Assessment of heavy metal contamination in road side surface soil and vegetation from the West Bank. Archives of Environmental Contamination and Toxicology, 47, 23–30.
Tandy, S., Schulin, R., & Nowack, B. (2006). The influence of EDDS on the uptake of heavy metals in hydroponically grown sunflowers. Chemosphere, 62(9), 1454–1463.
Terry, N., Carlson, C., Raab, T. K., & Zayed, A. (1992). Rates of selenium volatilization among crop species. Journal of Environmental Quality, 21, 341–344.
Thangavel, P., & Subhuram, C. V. (2004). Phytoextraction – Role of hyper accumulators in metal contaminated soils. Proceedings of the Indian National Science Academy. Part B, 70(1), 109–130.
Tian, J. L., Zhu, H. T., Yang, Y. A., & He, Y. K. (2004). Organic mercury tolerance, absorption and transformation in Spartina plants. Zhi Wu Sheng Li Yu Fen Zi Sheng Wu Xue Xue Bao (Journal of Plant Physiology and Molecular Biology), 30, 577–582.
Tordoff, G. M., Baker, A. J. M., & Willis, A. J. (2000). Current approaches to the revegetation and reclamation of metalliferous mine wastes. Chemosphere, 41(1–2), 219–228.
Turer, D., Maynard, J. B., & Sansalone, J. J. (2001). Heavy metal contamination in soils of urban highways: Comparison between runoff and soil concentrations at Cincinnati, Ohio. Water, Air, and Soil Pollution, 132, 293–314.
Utsunamyia, T. (1980). Japanese patent application no. 55-72959.
Viard, B., Pihan, F., Promeyrat, S., & Pihan, J. C. (2004). Integrated assessment of heavy metal (Pb, Zn, Cd) highway pollution: bioaccumulation in soil, Graminaceae and land snails. Chemosphere, 55(10), 1349–1359
Viklander, M. (1998). Particle size distribution and metal content in street sediments. Journal of Environmental Engineering, 124, 761–766.
Wang, A. S., Angle, J. S., Chaney, R. L., Delorme, T. A., & Reeves, R. D. (2006). Soil pH effects on uptake of Cd and Zn by Thlaspi caerulescens. Plant and Soil, 281(1–2), 325–337.
Wang, J., Zhao, F., Meharg, A. A., Raab, A., Feldmann, J., & McGrath, P. S. (2002). Mechanisms of arsenic hyperaccumulation in Pteris vittata. Uptake kinetics, interactions with phosphate, and arsenic speciation. Plant Physiology, 130, 1552–1561.
Watanabe, M. E. (1997). Phyto-remediation on the brink of commercialization. Environmental Science & Technology, 31, 182–186.
Wei, S. H., Zhou, Q. X., Wang, X., Cao, W., Ren, L. P., & Song, Y. F. (2004). Potential of weed species applied to remediation of soils contaminated with heavy metals. Journal of Environmental Science- China, 16, 868–873.
Wenzel, W. W., Adriano, D. C., Salt, D., & Smith, R. (1999). Phytoremediation: A plant–microbe-based remediation system. In SSSA (Ed.), Bioremediation of Contaminated Soils (pp. 457–508). Madison, WI, USA: Agronomy Monograph no. 37, SSSA.
WHO (1997). Health and environment in sustainable development. Geneva: WHO
Williamson, A., & Johnson, M. S. (1981). Reclamation of metalliferous mine wastes. In N. W. Lepp (Ed.), Effect of heavy metal pollution on plants, vol. 2 (pp. 185–212). Barking, Essex, UK: Applied Science Publishers.
Williams, A. C., Nascimento, W., Amarasiriwardena, D., & Xing, B. (2006). Comparison of natural organic acids and synthetic chelates at enhancing phytoextraction of metals from a multi-metal contaminated soil. Environmental Pollution, 140(1), 114–123.
Wu, J., Hsu, F. C., & Cuningham, S. D. (1999). Chelate assisted Pb phytoextraction: Pb availability, uptake, and translocation constraints. Environmental Science & Technology, 33(11), 1898–1904.
Xiong, Y. H., Yang, X. E., Ye, Z. Q., & He, Z. L. (2004). Characteristics of cadmium uptake and accumulation by two contrasting ecotypes of Sedum alfredii Hance. Journal of Environmental Science and Health. Part A, Toxic/Hazardous Substances & Environmental Engineering, 39, 2925–2940.
Xue, S. G., Chen, Y. X., Reeves, R. D., Baker, A. J., Lin, Q., & Fernando, D. R. (2004). Manganese uptake and accumulation by the hyperaccumulator plant Phytolacca acinosa Roxb. (Phytolaccaceae). Environmental Pollution, 131, 393–399.
Yoon, J., Cao, X., Zhou, Q., & Ma, L. Q. (2006). Accumulation of Pb, Cu, and Zn in native plants growing on a contaminated Florida site. Science of The Total Environment, 368(2–3), 456–464.
Zaccheo, P., Crippa, L., & Pasta, V. D. (2006). Ammonium nutrition as a strategy for cadmium mobilisation in the rhizosphere of sunflower. Plant And Soil, 283(1–2), 43–56.
Zhu, Y. L., Zayed, A. M., Quian, J. H., De Souza, M., & Terry, N. (1999). Phytoaccumulation of trace elements by wetland plants: II. Water hyacinth. Journal of Environmental Quality, 28, 339–344.
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Padmavathiamma, P.K., Li, L.Y. Phytoremediation Technology: Hyper-accumulation Metals in Plants. Water Air Soil Pollut 184, 105–126 (2007). https://doi.org/10.1007/s11270-007-9401-5
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DOI: https://doi.org/10.1007/s11270-007-9401-5