Bioremediation: A Strategy for Addressing Superfund Chemicals
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Transcript of Bioremediation: A Strategy for Addressing Superfund Chemicals
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Bioremediation: A Strategy for Addressing Superfund Chemicals
Michael D. AitkenDepartment of Environmental Sciences & Engineering
Gillings School of Global Public HealthUniversity of North Carolina at Chapel Hill
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What are the chemicals of concern at contaminated sites?
• Metals (arsenic, cadmium, lead, etc.)• Organic compounds
– chlorinated solvents (e.g., trichloroethylene)– other chlorinated chemicals (e.g.,
PCBs, DDT, chlorinated dioxins)
– aromatic hydrocarbons (e.g., benzene, toluene)
– polycyclic aromatic hydrocarbons (PAHs)
ClCl
Cl Cl
Cl
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Types of sites requiring remediation
• Superfund sites– subject to cleanup under the Comprehensive
Environmental Response, Compensation andLiability Act (CERCLA)
– sites must be placed on the National Priority List (NPL); ~1,300 sites currently (37 in North Carolina)
• Private industrial sites– e.g., former manufactured-gas plants (MGP sites)
• Government sites– military (bases, contractors)– National Labs (Department of Energy sites)– other (civilian) government sites
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Process for cleanup at Superfund sites• preliminary assessment/site inspection
– scoring based on standard criteria• listing on NPL• remedial investigation/feasibility study (RI/FS)• record of decision
– selection of remediation strategy• remedial design/remedial action (RD/RA)• construction completion• post-construction completion
– long-term actions– O&M– institutional controls– eventual removal from NPL
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Remediation options
• On-site containment• Excavate and dispose off site• On-site treatment
– soil, groundwater, or both?– above ground (ex situ) or in place (in situ)?
• Off-site treatment• note bioremediation is only one form of
treatment
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Source: USEPA (2010) Superfund Remedy Report (Thirteenth Edition)
source containment withcap and “slurry walls”
source treatment by in situsoil vapor extraction
in situ groundwatertreatment by chemical
oxidation
groundwater pumpand treat (P&T)
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MGP site in Greenville, SC undergoing excavation
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Excavated soil from MGP site in Charlotte, NC
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source: USEPA (2007) Treatment Technologies for Site Cleanup: Annual Status Report (Twelfth Edition)
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Source control treatment projects, 1982-2005
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Source: USEPA (2010) Superfund Remedy Report (Thirteenth Edition)
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What is bioremediation?
• bioremediation ≡ the application of microbial processes to treat contaminated soil, sediment, or groundwater
• the term “biodegradation” is often used to describe what happens in bioremediation. But what is biodegradation?– making a contaminant go away?– reducing the impact of the contaminant?
• on the environment• on human health
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How do microorganisms make acontaminant “go away”?
• Many contaminants are organic compounds that serve as carbon and energy sources for growth(i.e., “food”) – many are naturally occurring compounds
(e.g., hydrocarbons, including PAHs)• Some contaminants are electron acceptors used for
respiration, in the same way that oxygen is used for aerobic respiration (e.g., chlorinated hydrocarbonssuch as TCE)– this process is coupled to growth of the organism on an organic
compound as a carbon and energy source• Some contaminants are neither
– may be transformed fortuitously (cometabolized) during metabolism of another compound
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Outcomes of biodegradation mechanisms• complete metabolism (generally associated with growth)
– mineralization of a fraction of the initial compound mass to CO2, H2O, Cl-, SO42-,
etc.; e.g., aerobic metabolism of benzene:
C6H6 + 7.5O2 → 6CO2 + 3H2O
– assimilation of a fraction of the initial compound mass intocellular biomass
• incomplete metabolism (fortuitous transformation to dead-end metabolites, unrelated to growth)– e.g., transformation of TCE to TCE epoxide by methanotrophic bacteria,
catalyzed by the enzyme methane monooxygenase (MMO)
C2HCl3 + O2 + NADH + H+ → C2HCl3O + NAD+ + H2O
mineral (inorganic) products
MMO
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Incomplete metabolism is “biodegradation,”but is it necessarily good?
p,p'-DDE
p,p'-DDDp,p'-DDT
C
CCl Cl
Cl Cl
HCl
C
C Cl
Cl
H
H
Cl ClC
C Cl
Cl
Cl
H
Cl ClHCl
2H+, 2e-
reductivedechlorination
dehydrochlorination(abiotic?)
EPA regulates the sum of DDT + DDE + DDD (assumes equal risk), so a single-step transformation of DDT does not reduce risk from a regulatory perspective (i.e., would not be considered acceptable treatment)
Consider the anaerobic transformation of DDT
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HOH
H OHOH
OH
HOH
H OHOH
OH
OHOH
OHOH
OO
pyrene-4,5-dione (pyrene quinone)
veryfast
Incomplete aerobic metabolism of PAHs canform toxic products
Pyrene transformation to apyrene quinone
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Why does incomplete metabolism matter?• Because microbial enzymes can have broad specificity for
related chemicals, incomplete metabolism is inevitable in complex contaminated environments
• Can products be degraded by other organisms?• If products accumulate, what is their effect?
– on organisms that produce them – on other organisms– on overall toxicity
• Overall toxicity or genotoxicity of soil or sediment after cleanup is usually not taken into account
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Effects of biological treatment on (geno)toxicity
From Hu et al. (2012) Environmental Science & Technology 46: 4607-4613
Feed 0 8 hr 1 d 3 d 7 d0.0
0.2
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0.6
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1.0
1.2
1.4
LD50
(mg
soil/
mL)
DT40Rad54
samples from bioreactor
Feed 0 8 hr 1 d 3 d 7 d0.0
0.1
0.2
0.3
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0.5
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Rel
ativ
e LD
50 (R
ad54
/DT4
0)samples from bioreactor
Use of a bioassay with chicken lymphocyte cells (DT40) and a mutant of DT40 deficient in DNA repair (Rad54) on PAH-contaminated soil from an MGP site treated in a lab-scale bioreactor
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What microorganisms are involved in bioremediation?
• all bioremediation applications rely onnaturally occurring microorganisms– all involve complex microbial communities – most rely on bacteria, but some may involve
archaea or fungi– all systems are open (anyone can join the party!)
• for naturally occurring compounds, expect ubiquity and broad diversity
• for xenobiotics, expect high specializationand more restricted distribution of therelevant organisms
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Microbial diversity: an underexplored universe• estimated to be ~ 5 x 106 prokaryotic species (bacteria
and archaea) on Earth– we know nothing about most of them
• for example: soil can contain thousands of species of prokaryotes per gram– at ~ 3 Mbp per prokaryotic genome,
> 1010 bp in “metagenome” of aone-gram soil sample
– human genome ~ 3 x 109 bp one gram of soil is genetically morecomplex than the human genome
– abundances range over several orders of magnitude
Julian Davies (2006): “once the diversity of the microbial world is catalogued, it will make astronomy look like a pitiful science”
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Underlying principles of microbial ecology• every organism has a unique range of capabilities, some
of which might be useful in bioremediation (or any form of biological treatment of wastes)
• every organism has a unique range of conditions under which it will grow or at least survive
• environmental systems are likely to be characterized by relatively few dominant species and a large number of low-abundance species
• open environments permit the growth ofheterogeneous communities
therefore a diverse community of microorganisms can be expected in a given environmental system, each species with its own “niche”
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Factors that influence microbial communities
• environmental conditions govern which organisms dominate (which organisms are selected)
– major energy and carbon sources– dissolved oxygen availability and concentration
• aerobes• microaerophiles• anaerobes
– presence of electron acceptors other than oxygen (e.g., NO3-, SO4
2-, Fe3+, chlorinated hydrocarbons, perchlorate)
– pH (e.g., acidophiles thrive at low pH)– temperature (e.g., thermophiles thrive at high temperature)– salinity– availability of nutrients (e.g., sorbed to a surface or within
a non-aqueous matrix vs. dissolved in water)
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Influencing microbial communities • native organisms are almost always better adapted to local
environmental conditions than added organisms would be– creates problems for applications of genetically engineered
“superbugs” or commercial cultures• biological process engineering involves control of the
microbial community’s immediate environment– dissolved oxygen– pH– temperature (unusual for bioremediation)– reactor design to control availability and/or concentration of
contaminants and other compounds (ex situ treatment)
Therefore we have control, to a large extent, over microbial selection. This is the key to success in bioremediation or other biological processes for waste treatment
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Putting microbial ecology into practice• The science: which organisms do which functions?
what conditions do they require to grow and be competitive?
• The art: providing conditions to select for the microorganisms that carry out the desired function
• The engineeringhow much? how fast? how big? how good?
stoichiometry kinetics design analysis
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Postulates for biodegradation• a biochemical mechanism for transformation
or complete metabolism of the compoundmust exist
• organism(s) possessing the relevant gene(s) must be present in the system– indigenous organisms– organisms inoculated into system (bioaugmentation)
• gene(s) coding for the relevant enzyme(s)must be expressed– induced by the compound itself– induced by some other means
• the mechanism must be manifested
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Why biodegradation mechanisms might not be manifested
• limited bioavailability (generally an issue for hydrophobic chemicals, particularly in the subsurface)
• concentration effects– inhibition by the contaminant at high concentration– concentration too low to support growth
• inhibition by other chemicals in the system• other conditions not favorable
– pH– inorganic nutrient (N, P) limitations– electron acceptor limitations
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Types of bioremediation
• In situ– monitored natural attenuation– biostimulation (injection of
nutrients and/or oxygen)– reactive barrier
• Ex situ–pump-and-treat groundwater–biofiltration of air removed by
soil vapor extraction–excavated soil
• landfarm• composting• slurry bioreactor
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Technical challenges
• challenges are much greater for in situ treatment• if the source is intimately associated with soil,
can the soil be excavated?• if the required process is aerobic, how difficult
is it to provide oxygen?• how difficult is it to provide any other substance
needed (e.g., other electron acceptors; inorganic nutrients such as N and P)?
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