# Bioconcentration

Bioconcentration is the accumulation of a chemical in or on an organism when the source of chemical is solely water.[1] Bioconcentration is a term that was created for use in the field of aquatic toxicology.[1] Bioconcentration can also be defined as the process by which a chemical concentration in an aquatic organism exceeds that in water as a result of exposure to a waterborne chemical.[2]

There are several ways in which to measure and assess bioaccumulation and bioconcentration. These include: octanol-water partition coefficients (KOW), bioconcentration factors (BCF), bioaccumulation factors (BAF) and biota-sediment accumulation factor (BSAF). Each of these can be calculated using either empirical data or measurements as well as from mathematical models.[3] One of these mathematical models is a fugacity-based BCF model developed by Don Mackay.[4]

Bioconcentration factor can also be expressed as the ratio of the concentration of a chemical in an organism to the concentration of the chemical in the surrounding environment. The BCF is a measure of the extent of chemical sharing between an organism and the surrounding environment.[5]

In surface water, the BCF is the ratio of a chemical's concentration in an organism to the chemical's aqueous concentration. BCF is often expressed in units of liter per kilogram (ratio of mg of chemical per kg of organism to mg of chemical per liter of water).[6] BCF can simply be an observed ratio, or it can be the prediction of a partitioning model.[6] A partitioning model is based on assumptions that chemicals partition between water and aquatic organisms as well as the idea that chemical equilibrium exists between the organisms and the aquatic environment in which it is found[6]

## Calculation

Bioconcentration can be described by a bioconcentration factor (BCF), which is the ratio of the chemical concentration in an organism or biota to the concentration in water:[2]

${\displaystyle BCF={\frac {Concentration_{Biota}}{Concentration_{Water}}}}$ [2]

Bioconcentration factors can also be related to the octanol-water partition coefficient, Kow. The octanol-water partition coefficient (Kow) is correlated with the potential for a chemical to bioaccumulate in organisms; the BCF can be predicted from log Kow, via computer programs based on structure activity relationship (SAR)[7] or through the linear equation:

${\displaystyle logBCF=mlogK_{OW}+b}$ [8]

Where:

${\displaystyle K_{OW}={\frac {Concentration_{octanol}}{Concentration_{water}}}={\frac {C_{O}}{C_{W}}}}$  at equilibrium

### Fugacity capacity

Fugacity and BCF relate to each other in the following equation:

${\displaystyle Z_{Fish}={\frac {P_{Fish}\times {BCF}}{H}}}$  [6]

where ZFish is equal to the Fugacity capacity of a chemical in the fish, PFish is equal to the density of the fish (mass/length3), BCF is the partition coefficient between the fish and the water (length3/mass) and H is equal to the Henry's law constant (Length2/Time2)[6]

### Regression equations for estimations in fish

Equation Chemicals Used to obtain equation Species Used
${\displaystyle logBCF=0.76logKow-0.23}$  84 Fathead Minnow, Bluegill Sunfish, Rainbow Trout, Mosquitofish
${\displaystyle logBCF=logKow-1.32}$ [4] 44 Various
${\displaystyle logBCF=2.791-0.564logS(S=watersolubility)}$  36 Brook trout, Rainbow trout, Bluegill Sunfish, Fathead minnow, Carp
${\displaystyle logBCF=3.41-0.508logS}$ [9] 7 Various
${\displaystyle logBCF=1.119logKoc-1.579}$  13 Various

## Uses

### Regulatory uses

Through the use of the PBT Profiler and using criteria set forth by the United States Environmental Protection Agency under the Toxic Substances Control Act (TSCA), a substance is considered to be not bioaccumulative if it has a BCF less than 1000, bioaccumulative if it has a BCF from 1000–5000[10] and very bioaccumulative if it has a BCF greater than 5,000.[10]

The thresholds under REACH are a BCF of > 2000 l/kg bzw. for the B and 5000 l/kg for vB criteria.[11]

## Applications

A bioconcentration factor greater than 1 is indicative of a hydrophobic or lipophilic chemical. It is an indicator of how probable a chemical is to bioaccumulate.[1] These chemicals have high lipid affinities and will concentrate in tissues with high lipid content instead of in an aqueous environment like the cytosol. Models are used to predict chemical partitioning in the environment which in turn allows the prediction of the biological fate of lipophilic chemicals.[1]

### Equilibrium partitioning models

Based on an assumed steady state scenario, the fate of a chemical in a system is modeled giving predicted endpoint phases and concentrations.[12]

It needs to be considered that reaching steady state may need a substantial amount of time as estimated using the following equation (in hours).[13][14]

${\displaystyle t_{eSS}=0.00654\cdot K_{OW}+55.31}$

For a substance with a log(KOW) of 4, it thus takes approximately five days to reach effective steady state. For a log(KOW) of 6, the equilibrium time increases to nine months.

### Fugacity models

Fugacity is another predictive criterion for equilibrium among phases that has units of pressure. It is equivalent to partial pressure for most environmental purposes. It is the absconding propensity of a material.[1] BCF can be determined from output parameters of a fugacity model and thus used to predict the fraction of chemical immediately interacting with and possibly having an effect on an organism.

### Food web models

If organism-specific fugacity values are available, it is possible to create a food web model which takes trophic webs into consideration.[1] This is especially pertinent for conservative chemicals that are not easily metabolized into degradation products. Biomagnification of conservative chemicals such as toxic metals can be harmful to apex predators like orca whales, osprey, and bald eagles.

## Applications to toxicology

### Predictions

Bioconcentration factors facilitate predicting contamination levels in an organism based on chemical concentration in surrounding water.[12] BCF in this setting only applies to aquatic organisms. Air breathing organisms do not take up chemicals in the same manner as other aquatic organisms. Fish, for example uptake chemicals via ingestion and osmotic gradients in gill lamellae.[6]

When working with benthic macroinvertebrates, both water and benthic sediments may contain chemical that affects the organism. Biota-sediment accumulation factor (BSAF) and biomagnification factor (BMF) also influence toxicity in aquatic environments.

BCF does not explicitly take metabolism into consideration so it needs to be added to models at other points through uptake, elimination or degradation equations for a selected organism.

### Body burden

Chemicals with high BCF values are more lipophilic, and at equilibrium organisms will have greater concentrations of chemical than other phases in the system. Body burden is the total amount of chemical in the body of an organism,[12] and body burdens will be greater when dealing with a lipophilic chemical.

## Biological factors

In determining the degree at which bioconcentration occurs biological factors have to be kept in mind.The rate at which an organism is exposed through respiratory surfaces and contact with dermal surfaces of the organism, competes against the rate of excretion from an organism. The rate of excretion is a loss of chemical from the respiratory surface, growth dilution, fecal excretion, and metabolic biotransformation.[15] Growth dilution is not an actual process of excretion but due to the mass of the organism increasing while the contaminant concentration remains constant dilution occurs.

The interaction between inputs and outputs is shown here:
${\displaystyle {\frac {dC_{B}}{dt}}=(k_{1}C_{WD})-(k_{2}+k_{E}+k_{M}+k_{G})C_{B}}$ [15]
The variables are defined as:
CBis the concentration in the organism (g*kg−1).[15] t represents a unit of time (d−1).[15] k1 is the rate constant for chemical uptake from water at the respiratory surface (L*kg−1*d−1).[15] CWD is the chemical concentration dissolved in water (g*L−1).[15] k2,kE,kG,kB are rate constants that represent excretion from the organism from the respiratory surface, fecal excretion, metabolic transformation, and growth dilution (d−1).[15]

Static variables influence BCF as well. Because organisms are modeled as bags of fat, lipid to water ratio is a factor that needs to be considered.[6] Size also plays a role as the surface to volume ratio influence the rate of uptake from the surrounding water.[15] The species of concern is a primary factor in influencing BCF values due to it determining all of the biological factors that alter a BCF.[6]

## Environmental parameters

### Temperature

Temperature may affect metabolic transformation, and bioenergetics. An example of this is the movement of the organism may change as well as rates of excretion.[15] If a contaminant is ionic, the change in pH that is influenced by a change in temperature may also influence the bioavailability[1]

### Water quality

The natural particle content as well as organic carbon content in water can affect the bioavailability. The contaminant can bind to the particles in the water, making uptake more difficult, as well as become ingested by the organism. This ingestion could consist of contaminated particles which would cause the source of contamination to be from more than just water.[15]

## References

1. Landis WG, Sofield RM, Yu MH (2011). Introduction to Environmental Toxicology: Molecular Structures to Ecological Landscapes (Fourth ed.). Boca Raton, FL: CRC Press. pp. 117–162. ISBN 978-1-4398-0410-0.
2. ^ a b c Gobas FAPC; Morrison HA (2000). "Biococentration and biomagnification in the aquatic environment". In Boethling RS; Mackay D (eds.). Handbook of Property Estimation Methods for Chemicals: Environmental and Health Sciences. Boca Raton, FL, USA: Lewis. pp. 189–231.
3. ^ Arnot, Jon A.; Frank A.P.C. Gobas (2004). "A Food Web Bioaccumulation Model for Organic Chemicals in Aquatic Ecosystems". Environmental Toxicology and Chemistry. 23 (10): 2343–2355. doi:10.1897/03-438.
4. ^ a b Mackay, Don (1982). "Correlation of bioconcentration factors". Environmental Science and Technology. 16 (5): 274–278. doi:10.1021/es00099a008.
5. ^ "Chapter 173–333 WAC Persistent Bioaccumulative Toxins" (PDF). Department of Ecology. Retrieved 6 February 2012.
6. Hemond, Harold (2000). Chemical Fate and Transport in the Environment. San Diego, CA: Elsevier. pp. 156–157. ISBN 978-0-12-340275-2.
7. ^ EPA. "Category for Persistent, Bioaccumulative, and Toxic New Chemical Substances". Federal Register Environmental Documents. USEPA. Retrieved 3 June 2012.
8. ^ Bergen, Barbara J.; William G. Nelson; Richard J. Pruell (1993). "Bioaccumulation of PCB Congeners by Blue Mussels (Mytilus edulis) deployed in New Bedford Harbor, Massachusetts". Environmental Toxicology and Chemistry. 12: 1671–1681. doi:10.1002/etc.5620120916.
9. ^ Chiou CT, Freed VH, Schmedding DW, Kohnert RL (1977). "Partition Coefficient and Bioaccumulation of Selected Organic Chemicals". Environmental Science and Technology. 29 (5): 475–478. doi:10.1021/es60128a001.
10. ^ a b "Bioaccumulation Criteria". Archived from the original on 1 May 2016. Retrieved 3 June 2012.
11. ^
12. ^ a b c Rand, Gary (1995). Fundamentals of Aquatic Toxicology. Boca Raton: CRC Press. pp. 494–495. ISBN 978-1-56032-091-3.
13. ^ OECD GUIDELINES FOR TESTING OF CHEMICALS: Test No. 305: Bioaccumulation in Fish: Aqueous and Dietary Exposure, S. 56, doi: 10.1787/9789264185296-en
14. ^ Hawker D.W. and Connell D.W. (1988), Influence of partition coefficient of lipophilic compounds on bioconcentration kinetics with fish. Wat. Res. 22: 701–707, doi: 10.1016/0043-1354(88)90181-9.
15. Arnot, Jon A.; Gobas, Frank APC (2006). "A review of bioconcentration factor (BCF) and bioaccumulation factor (BAF) assessments for organic chemicals in aquatic organisms". Environmental Reviews. 14 (4): 257–297. doi:10.1139/a06-005.