148
Bioremediation for Sustainable Environmental Cleanup
Table 9.1. Metal(loid)s sources and toxicity to humans.
Metal and
Metalloids
Toxicity to human
Sources
References
Arsenic (As)
Carcinogenesis, cardiac
dysfunction, skin infection,
lung damage, gastrointestinal
problems
Paints, timber, pesticides industries, natural/
geogenic process, thermal, geothermal,
smelting operation, burning fuels
Chandra et al. 2017,
Lone et al. 2008,
Gupta and Kumar 2017
Lead (Pb)
Mental disorders, kidney
damage and affecting the
nervous system
Metal products, electronic waste, petroleum
additives, thermal power plants operated
with coal, Bengal and ceramic industries
Chandra et al. 2017,
Lone et al. 2008,
Gupta and Kumar 2017
Cadmium
(Cd)
Renal disorders, carcinogens
and bone degeneration
Electronic industries, smelting and
electroplating industries, paint industries
Chandra et al. 2017,
Lone et al. 2008,
Gupta and Kumar 2017
Copper (Cu)
Wilson disease, liver damage
and insomnia
Electroplating, mine industries, timber,
electronic waste, paint and pigment
industries
Chandra et al. 2017,
Lone et al. 2008,
Gupta and Kumar 2017
Chromium
(Cr)
Allergic reaction, dermal
infection, carcinogen, DNA
mutation, gastrointestinal
hemorrhage
Leather industries, chromium salt
industries, dye industries, pesticides, timber
Chandra et al. 2017,
Lone et al. 2008,
Gupta and Kumar 2017
Manganese
(Mn)
The steel industry, municipal
wastewater, fertilizers
industries
Cardiovascular, respiratory and central
nervous disorder
Chandra et al. 2017,
Lone et al. 2008,
Gupta and Kumar 2017
Mercury (Hg)
Mental retardation, deafness,
blindness and kidney damage
E-waste, medical waste, thermal power
plant and geothermal, fumigants
Chandra et al. 2017,
Lone et al. 2008,
Gupta and Kumar 2017
Nickel (Ni)
Cardiovascular damage,
chronic asthma, nausea
Thermal power plants, smelting operations,
e-waste, alloys, battery industries
Chandra et al. 2017,
Lone et al. 2008
contamination with meta(loids). The biosolid treatment has little effect on Ni and Cr contents in
soil (Illera et al. 2000). The occurrence of these metals in biosolids caused a significant rise in Zn,
Cd, Cu and Pb levels. It has been noticed that grazing and immobilization of soil are harmful to the
soil’s microflora. It can rise the concentration of metal(oids) Zn, Pb and Cu whereas decreasing C
and N in plants, animals and soil microbes (Haynes et al. 2009, Kao et al. 2006). Various metals and
metalloid sources and their toxicity to human beings are shown in Table 9.1.
9.3 Heavy Metal(loid)s Reaction Mechanisms
Prior knowledge of the reaction mechanism between the binder substrate and metalloid is necessary
for the development of sustainable treatment technology. The existing report confirms that the reaction
mechanism plays a vital part in metalloid removal (Park et al. 2011). These detailed mechanisms will
help in better understanding and development of technologies for real environmental applications.
The systematic research on the metalloid’s removal mechanisms is discussed below.
9.3.1 Adsorption
Adsorption, according to Sposito (1984), is the accumulation of a solute at the interface between
a liquid solution and a solid. The process of forming a chemical connection with metal ions on
the surface of adsorbents is known as adsorption. The adsorption is categorized dominantly into
two sets, i.e., specific adsorption and non-specific (Bolan et al. 2014). By using functional groups,
specific adsorption binds the solute to the adsorbents (Sposito 1984). Solutes are bound by non
specific adsorption through electrostatic attraction (Bolan et al. 2014). The adsorbent’s properties