Summary

This document covers the concepts of uptake, biotransformation, detoxification, elimination and accumulation in a chapter, along with details of chemical fate, environmental conditions, and important points for understanding the processes. It also studies weathering, degradation, and contaminant partitioning.

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UPTAKE, BIOTRANSFORMATION, DETOXIFICATION, ELIMINATION AND ACCUMULATION CHAPTER 3 Solubility is the most important - disposal, where in the env can it be Fate of Chemicals...

UPTAKE, BIOTRANSFORMATION, DETOXIFICATION, ELIMINATION AND ACCUMULATION CHAPTER 3 Solubility is the most important - disposal, where in the env can it be Fate of Chemicals found, can it be diluted, how should we test it, Research provides a basic understanding of the biologic, chemical, and hydrologic processes that affect partitioning into various environmental media (e.g. water, sediment and tissue) and chemical and microbial transformation. These processes can have a significant effect on the potential toxicity of a contaminant. Environmental Fate of contaminants Two main factors determining contaminant fate 1. Physical/chemical properties Affect persistency and distribution 2. Conditions of the surrounding ecosystem Difficult to obtain, can vary depending season & scale of the system Steps for determining the Condition of the surrounding ecosystem 1. Define the scale and boundaries organism lake atmosphere biosphere 2. Define the system under study To understand contaminant fate Processes can be important in one ecosystem and unimportant in another 3. Characterization of environmental condition To understand the fate of metals and metalloids Speciation could be affected by element chemistry and condition Contaminant accumulation Concentrations in target organs or tissues Basic Processes resulting in Bioaccumulation: Uptake Biotransformation Elimination Contaminant partitioning Contaminant Transport : Influenced by partitioning of the compound or element between the various phases or compartments. Gaseous & aqueous phases Aqueous & sediment/particulate phases Dissolved & liquid/solid phases Contaminant Partitioning When the contaminant is released to one compartment and moves to another, where it builds up in concentration Assume steady-state system & use equilibrium equations Partition coefficient (Distribution coefficient) at equilibrium X(phase a) X(phase b) Kd or Kp= X(phase b) / X(phase a) Sorption Coefficient = aqueous (a) & particulate (b) phases Adsorption if associated with surface of particulate only Analytical methods generally are rigorous & represent both adsorption & absorption, so we generally use sorption Important points Sorption coefficients are determined empirically under lab conditions for some contaminants and particulate phases. Useful tools for: comparing the relative tendency for contaminants to accumulate in sediments or soils Give insight into potential fate of contaminants Might not always be accurate predictors of concentrations of contaminants in sediment and water under environmental circumstances ( system not at equilibrium, variability of structure and quality) Factors affecting partitioning of contaminant Vapor Pressure (P) Water solubility (C) Used to calculate: Henry’s law coefficient (H or KH) aqueous & vapor phases KH = P/C H increases as P increases or C decreases High H = steady state, accumulate in atmosphere, contaminant will decrease in water & accumulate in the atmosphere & then may move globally Weathering Changes in relative concentrations of individual compounds in the mixture over time. When a group of contaminants (PAHs or PCBs) are released in mass from a source, they each partition uniquely according to their specific coefficients, changing their concentrations, can determine the ratios PCBs—unique mix to each source—if you can characterize the weathering pattern, you can determine the source of the PCBs Sewage: 1. remove large objects. 2. add O2 to encourage microbial degradation (decomposition) Degradation Environmental degradation is caused due to institutional, socio- economical and technological activities. It is the deterioration of the environment through the depletion of resources like water, air, and soil. Here both biotic and abiotic processes contribute to the degradation of the environment. Degradation Abiotic Degradation: It is a prominent process that mainly occurs under the influences of hydrolysis and photolysis. Hydrolysis: Hydrolytic reaction is the reaction of water with another chemical compound to form two or more products involving usually splitting the other compound. In simple terms when water combines with heat or light energy it can break chemical bonds, this process is known as hydrolysis. Photolysis: It mainly occurs on surface waters or in the atmosphere where the intensity of light is at its highest. Photolysis is a chemical process by which molecules are broken down into smaller parts or units through the absorption of light. Photodegredation—Photolysis—light is absorbed & bonds are broken and the contaminant is degraded, needs UV (most energy) to vis light Direct photolysis—contaminant absorbs light & degrades ( fragments or oxidizes) Indirect photolysis—other chemical absorbs light & forms a reactive species that reacts with the contaminant facilitating degradation Oxidation: direct reaction with oxygen pharmaceuticals and personal care products includes caffeine Results from these studies showed that the rate and extent of ibuprofen degradation is greatly influenced by the presence of clay particles and solar radiation. The results from the biological assays show that primary PPCP is more toxic than the mixture of secondary products. Degradation Biotic Degradation: Microorganisms such as fungi and bacteria are prime factors responsible for biotic degradation. These microorganisms degrade chemicals to obtain energy from these sources. It occurs at a highly accelerated rate, far exceeding abiotic degradation. It is a process that can completely lead to the mineralization of chemicals to carbon dioxide, water, and other basic inorganic constituents. Bioremediation is a process wherein microorganisms are used to mitigate environmental contaminants. Biotic degradation ( biologically mediated) Within organisms, catalyzed by enzymes Detoxification, activation, and elimination of contaminants Can enhance degradation due to catalytic effect of enzymes Degradation of organics Mineralization—from organics to carbon dioxide, water, and inorganic salts Complete degradation CxHxX CO2 + X Incomplete degradation CxHxX Metabolite A & B... CxHxX Metabolite C & D... Xenobiotics, not similar to natural compounds, tend to be microbially resistant, they do not degrade biologically very well, because there are no enzymes adapted to their break down Toxicity decreases biological degradation, too half life, Bioaccumulation solubility, excretion Bioaccumulation: It is a process where organisms accumulate themselves with chemicals from dietary sources or from an abiotic environment. And through passive diffusion, these organisms take in these toxic chemical substances. Bioaccumulation refers to the net accumulation of contaminants, in an organism. Some of the primary organs that uptake this toxic include the gastrointestinal tract, gills, and lungs. But other organs such as scales, skin, feathers, fur, etc. act as a protective barrier against various chemical toxic. Sources: Water, air, and solid phases( food, soil, sediment, fine particles) in the environment Mathematical model Provides only details essential to understanding and accurately predicting the behaviors or the system. Hg is the only metal that can bioaccumulate Bioconcentration and biomagnify all others bioaccumulates and bioconcentrates Bioconcentration is a related but more specific term, referring to uptake and net accumulation of a contaminant in an organism from water alone. Potential influence of microplastics on mercury bioconcentration and bioaccumulation by fish. bioaccumulation: in 1 organism over time bioconcetration: from multiple env sources Bioaccumulation Biotransformation Water Food Loss from urine & feces Loss from gills Uptake and Elimination process at saturation, all uptake is eliminated Concentration U = E Steady State U > E Duration of Exposure E2 X A 4 0 Source-to-Effect Continuum 8 Stressor Domain Receptor Domain Source/stressor Effect/outcome formation Fate and transport Biological event Environmental Target tissue Concentration dose Exposure = f (concentration, behavior, time) E3 X A 4 0 Exposure Assessment 8 Using Biomonitoring Biomonitoring data can be used to: Better estimate Reduce some Measure total intake dose types of internal dose (in conjunction uncertainty with PK models) E5 X A Biomonitoring, Biomarkers, 4 0 and Body Burdens 8 Biomarker: Biologic indicator of exposure; used to measure chemical, metabolites, or product of interaction between chemical and target molecule or cell Body burden: Total amount of a contaminant in the body; a type of biomarker Biomonitoring: Method for assessing human exposure to chemicals, their metabolites, or their byproducts; the act of collecting biomarker and body burden data Concentration vs. Body Burden concentration * mass of tissue / kg individual Concentration Mass contaminant per mass organism (mg/kg tissue) only tissue of the sample fish Body burden Mass or total amount of contaminant in or on person eating the fish the individual (g/individual) whole organism consuming the concentration Body burden refers to the accumulation of synthetic chemicals – found in substances like household cleaners, fabrics, cosmetics, pest repellants, computers, cell phones – which helped “modernize” our lives in the post World War II chemical age and which are now found in our own bodies. Biomonitoring Advantages and Limitations Advantages Limitations Measures all aggregate exposure Not source- or pathway-specific (all sources, all routes) where did the individual become contaminated Reflects uptake and accumulation Requires permissions for collection of human specimens May be able to correlate internal Can be costly dose with effects Difficult to interpret potential health risks Biomarkers Used to measure: Direct amount of a compound (i.e., body burden) Biological interaction of the compound with the body Physiological changes in an organism as a result of interaction with the compound Collected using biomonitoring methods Can be used to reconstruct past exposures Reflect internal dose but may not indicate risk EXA 408 8 Modeling Uptake Uptake Movement of a contaminant into or onto an organism Involves dermis, pulmonary surfaces, gut, or gills Starts with interaction with cell of tissues Ingest ion Enters cell by Lipid route Aqueous route Endocytic route Mechanisms for uptake Mechanisms Adsorption Passive diffusion Active transport Facilitated diffusion or transport Exchange diffusion Endocytosis Pharmacokinetics The study of the time course of ADME of a substance in an organism’s body Chemical in environment into sth, as Chemical enters body Absorption opposed to adsorption on the surface Distribution Chemical in blood and tissues Metabolism Chemical impact on health is usually investigated via the concept of ADME. This is how a chemical is Absorbed, Distributed, Metabolized, or Eliminated Excretion in living systems. EXA 408 21 INTERACTIONS WITH ORGANISM SURFACE BEFORE UPTAKE 1st Step—Adsorption Can be modeled with linear adsorption equations Freundlich and Langmiur Isotherm Equations absorbent - what is the surface saturation mass of absorbant amount adsorbed/ Concentration Adsorption Isotherms Freundlich Equation - developed to describe gas adsorption on solids. q = KC1/n where q = adsorbed quantity ( amount adsorbed/ mass adsorbent) C = Concentration of solute in solution after adsorption K = distribution coefficient ( derived constant) n = correction factor ( derived constant) Freundlich Plots Adsorption Isotherms Langmuir Equation -developed to describe gas adsorption on planar surfaces q = kCb/ (1 + kC) Where q and C defined in Freundlich k = constant related to bonding strength b = adsorption maximum Langmuir Equation occurs on planar surfaces, fixed number of identical site, each site only one molecule adsorption is reversible no lateral movement of molecules on surface adsorption energy same for all site and independent of surface coverage little interaction between adsorbate molecules Langmuir Plots Adsorption isotherm This equations have been successfully used to define toxicant movement onto diverse biological surfaces: Unicellular algae Fish gills Periphyton Zooplankton 2nd Step—Across the cell Diffusion : Movement of the contaminant Active Transport down an electrochemical gradient Uses energy to move Lipophilic compound through the lipid contaminant up the bilayer electrochemical gradient Nonpolar organics or uncharged inorganics Uses carrier molecule Charged ion through a channel protein Subject to saturation kinetics Charged metals & protons and competitive inhibition Depends on ion charge & size (including Cation transport with ATP-ase hydration sphere) (adenosine triphosphate) Gated & ungated channels, influenced by chemistry of cell Ions & hydrophilic compounds Facilitated diffusion Endocytosis Down electrochemical gradient through a carrier protein without energy Brought into cell alone or in Faster than simple diffusion particulate Subject to saturation kinetics Pinocytosis & phagocytosis Exchange diffusion Exchange ions across the membrane Across the Cell Membrane Reaction Order—Kinetics of Uptake & Elimination imp because: how was is its metabolism and elimination, what is its fate Reaction rate equation dC/dt=kCn Zero Order Reaction, n=0 First Order Reaction, n=1 Michaelis-Menten Kinetics Saturation kinetics Enzyme-mediated processes Active transport Facilitated diffusion Above threshold concentration, Zero Order Reaction Rate (Vmax) Below threshold concentration, First Order Reaction Rate Biotransformation Biotransformation is the process by which substances that enter the body are changed from hydrophobic to hydrophilic molecules to facilitate elimination from the body. This process usually generates products with few or no toxicological effects. Change in contaminant due to enzymatic catalysis Subject to saturation kinetics & competitive inhibition Detoxification Change to more hydrophilic, increases elimination Change to nontoxic form Change to form retained & sequestered Activation Change from nontoxic to more toxic form Change from less toxic to more toxic form Ex. Dichlorodiphenyltrichloroethane (DDT) an insecticide (used to help eradicate malaria) that was found to be toxic due to its transformation into Dichlorodiphenyldichloroethylene (DDE) Mechanisms of Biotransformation & Detoxification Organic Compound Metals & Metalloids hydrophobic hydrophilic Phase I Phase I Biomethylation Metabolism Metabolism or Biomineral- Biotransformation ization Phase II Binding to Metabolism Metallothionein or Another Ligand Elimination or Sequestration Compound Elimination (capture it and isolate it - causes accumulation) Metals and Metalloids Biotransformation results in elimination and sequestration Addition of methyl or ethyl groups by microbes of metal contaminated sites. Bound by amino acids Metallothioneins Phytochelatins ( metal binding polypeptides) Sequestered in bone, exoskeleton, shells, or nails in place of calcium Eliminated with molting or loss of nail Sequestered by incorporation into variety of granules or concretions Organic compounds Options: Eliminated rapidly Subjected to metabolism ( with excretion of metabolites) Phase I Reactions Make compound more hydrophilic Add –COOH, –OH, –NH2, –SH in proteins Oxidation, hydrolysis & reduction reactions MFOs (mixed function oxygenases) put Oxygen onto the compound Phase II Reactions Make compounds even more hydrophilic Bind with acetate, cysteine, sulfate, glycine, glutamine, or glutathione Enzymatic Subject to saturation kinetics, inhibition & induction smallest PAH https://www.nottingham.ac.uk/nmp/sonet/rlos/bioproc/liverdrug/page_one.html Elimination Mechanisms Excretion or biotransformation of contaminant can be Depuration—release of contaminant into clean environment transferred into other areas of Clearance—rate of contaminant movement between compartmentsthe body normalized to concentration Growth dilution—as organisms grow, concentration decreases, but body burden remains constant Plants Leaf dropping, leaching & evaporation from leaves, root exudation, herbivore grazing Animals Across gills, exhalation, secretion of bile (gall bladder), secretion from hepatopancreas, intestinal mucosa, molting, kidney excretion, egg deposition, loss in hair, feathers, skin, sweat, saliva, Main routes: gills, kidney, liver bile Elimination Mechanisms Enterohepatic Circulation In liver, compound can be excreted in bile into feces, in the small intestine, compound is reabsorbed and transported to liver Reabsorption Kidney excretion Gastrointestinal excretion Renal elimination Others VOCs in breath Deposition of lipophilic compounds Modeling Elimination First Order kinetics are the most common Zero order – less frequently Saturation kinetics – less frequently Compartment models Rate constant Clearance-volume Fugacity models consideration of all possible body compartments Forward & Backward Analysis Compile data on exposure Compile data on body media concentration burdens B F A O C R Develop representative Develop representative K W profile in the media body burden profile W A A R R D D Combine media Use PK models to convert: concentrations with intake dose to body burden exposure factors to body burden to intake dose estimate intake dose EXA 408 29 Pharmacokinetic Models Pharmacokinetic (PK) models evaluate the internal dose of a compound Simple – one-compartment, first-order First-order: Rate of elimination of chemical is dependent on the amount of chemical present continued exposure from same source or exposure from multiple sources Steady state: Assuming no net change in amount of chemical one time exposure Complex – multi-compartment, physiologically-based pharmacokinetic How can PK models be used in exposure assessment? Characterize internal dose Route-to-route extrapolation of the internal dose Exposure reconstruction from epidemiological studies EXA 408 22 One-Compartment, First-Order PK Models applies to some drugs injection is fastest, followed Chemical by inhalation Compartment C sat d. Cmax = Dose - kC Digestive Tract Chemical Degradation Time Elimination/Clearance C is the pollutant concentration (mass/volume) k is the first-order elimination rate constant (time-1) EXA 408 23 Steady-State One-Compartment, First-Order PK Model ADD ln(2) ADD × t1/2 Css = k= Css = k×V t1/2 V × ln(2) Where: Css is the steady-state pollutant concentration (mg/L, ng/g-lipid weight) ADD is the average daily dose (mg/day, ng/day) standari zed k is the first-order elimination constant (day-1, sec-1) V is the volume of distribution (L) varia ble t1/2 is the half life for elimination (day, sec) EXA 408 24 k C Rate constant based models One compartment model First order rate constants Elimination of contaminant from an organism to clean environment. Elimination predicted from initial concentration (Co) dC dX dt = -kC dt = -kX Ct=Coe-kt – Biological half-life (t½) Time to reduce concentration in compartment by 50% t½ = (Ln2)/k – Mean residence time Time a particle would be in the compartment ( ) =1.44 t½ or k=1/ Non-Steady-State PK Model ADDt 1 – e-kt C(t) = C(0)e-kt + × Vt k Where: C(t) is the pollutant concentration at time, t (mg/L, ng/g-lipid weight) C(0) is the initial pollutant concentration at time, 0 (mg/L, ng/g-lipid weight) ADD is the average daily dose (mg/day, ng/day) k is the first-order elimination constant V is the volume of distribution (L) EXA 408 25 k1 1 2 k2 Modeling Elimination 2 compartment model 2nd+ order Elimination 2 or more elimination mechanisms -kit -kit Ct=Co i Xt=Xo i Effective half-life (keff) = (Ln2)/ ki The slower mechanism will control elimination kE 1 k k Modeling Elimination 2 Multiple compartment model Clearance-volume based models Apparent volume of distribution ( Vd) Used to determine the dose within the organism (Dt) Used in Pharmacokinetics & Toxicokinetics Physiologically based pharmacokinetics (PBPK) ( physiological and anatomical features in describing kinetics) Dt=CoVo + CiVi Bioaccumulation Net concentration after uptake, biotransformation & elimination processes within an individual Simplest model: 1st order uptake & 1st order elimination dC dt = kuC1-keC Bioconcentration factor (BCF) Bioaccumulation factor (BAF) Bioaccumulation factor from sediment (BSAF) Accumulation factor if not in env but present in BCF organism, assume its not coming from the env Bioconcentration factor is the concentration of a particular chemical in a tissue per concentration of chemical in water (reported as L/kg). This physical property characterizes the accumulation of pollutants through chemical partitioning from the aqueous phase into an organic phase, such as the gill of a fish. In the context of setting exposure criteria it is generally understood that the terms "BCF" and "steady-state BCF"' are synonymous. A steady-state condition occurs when the organism is exposed for a sufficient length of time that the ratio does not change substantially. does not consider the possibility of the organism eating contaminated food, only looks at is the environment contaminated lipid content - amount of fat in an organism Accumulation body burden = alpha* R Models can incorporate: Multiple uptake sources—food, water Estimated assimilation efficiency alpha = amount absorbed / amount ingested from food Specific ration R = amount of food consumed/mass of organism Biotransformation Multiple elimination mechanisms fugacity model - [ ] in different compartments Molal World Volumes Air, water, sediment, soil Soil: 9x10^3 m3 substance is defined by its ability to escape a physical Air 10^3 m3 compartment Water 7 x 10^6 m3 f = c/z Sediment and biota 2x10^4 m3 z is fugacity capacity constant n = cv - mol/compartment c is concentration in given compartment nx = f Zx Vx Cx = fx zx n tot = f * (SUM ZxVx) in a compartment, C will remain the same but Z will shift f = n tot/SUM ZxVx The lifespan of an organism determiens how long they will be exposed to a contaminant Molal World Volumes A pesticide has a 96hr LC50 pf 3ppb for rainbow trout. near a lake, Soil: 9x10^3 m3 200g of pesticide are sprayed, and 35% of it leeches into the lake Air 10^3 m3 after rain. Lake is 30,000m2, depth 0.5m. does this [ ] exceed Water 7 x 10^6 m3 LC50? Sediment and biota 2x10^4 m3 FACTORS mass in water = 200*0.35 = 70g V of lake = 30,000*0.5 = 15,000 m3 mass of water = 15,000 (10^6 cm/1m3)(1g/cm3 -> density) = 1.5x10^10g INFLUENCING Lc = 70 g / 1.5x10^10 g = 4.7 ppb -> poses a risk to kill 50% at least of fish, because it is more thna LC50 BIOACCUMULATION Z air = 4x10^-4 mol/atm*m3 Chapter 4 Z water = 0.03 Z sediment = 10000 using molal world volumes, calc eqm c where 1 mol is distributed among air, water and sediment f = n tot / (SUM ZxVx) = 1 mol / ( (4x10^-4 * 10^3) + (0.03*7x10^6) + (1000*2x10^4) = 4.90 x 10^-9 atm C = f Zx air = 2.00x10^-12 mol/m3 water = 1.50x10^-10 sedi = 4.9x10^-5 if you want to analyze pcbs, look at sediments, highest [ ] Contaminant accumulation Contaminant Chemistry what partition? Organism intake and excretion Environmental conditions of interaction Temp affecting evaporation rate, pH of env affecting bioavailability habitats affecting what contaminats are even present Contaminant–solid interactions Association, Retention, or Sorption: The binding of a species without implication to the mechanism (which may include adsorption, absorption, precipitation, and surface precipitation). Adsorption: The binding of an ion or small molecule to a surface at an isolated site—a two-dimensional surface complex. Binding can be electrostatic, chemical, or hydrophobic. Absorption: The uptake of a species within another material (analogous to water uptake into a sponge).Partitioning: The distribution of a population of molecules of a given compound between any two phases, determined by the compound’s relative compatibility with each medium (Schwarzenbach et al., 1993). Precipitation: The formation of a three-dimensional structure without the association of a substrate (sorbent) material. This process occurs in solution directly and leads to discrete particles. Surface precipitation: a heterogeneous mechanism, refers to nucleation on previously existing particles. Both are important processes for metal and metalloid retention but generally do not contribute to organic compound retention in soils and sediments. Bioavailability The fraction of chemical present in the environment that is or may become available for biological uptake by passage across cell membranes. ex. Al(OH)3 (s) + acid rain -> Al 3+ which can be uptaken by plants Bioavailability relates to a series of processes, ranging from processes external of organisms, towards internal tissues, and fully internal to the biological response site. Redrawn from Ortega- Calvo et al. (2015) by Wilma IJzerman. Absolute vs Relative Bioavailability non-intravenous Intraveneously unknown how much is intaken (out of dose administered) Bioavailability Absolute Bioavailability routes of exposure—oral vs. IV AUC comparisons (area under the curve) multiple pathways Relative Bioavailability two different sources, one is the reference- food 1 vs. food 2 AUC comparisons (area under the curve) Other things to measure: urine & bile only 1 pathway Bioavailability Relative Bioavailability Compare organism concentration in different sources—eg. Filter feeders in Abu Dhabi & Dibba sediments for oil contaminants Compare different food sources for fish—measure blood concentration of individuals fed the different foods Compare exposure concentrations Effective Dose in pharmacokinetics Drugs or Toxicants: Give drug orally, measure blood C Give drug IV, measure blood C Determines amount of drug & rate of uptake Estimation of absolute bioavailability of an ingested dose by comparison of AUCs for ingestion and intravenous injection (top panel), and relative bioavailability by AUC comparison for the same dose administered in two different foods (bottom panel). All measurements need exposure studies Statistical measurements Mean residence time Mean time of a drug residence in a compartment (MRT) Mean absorption time Tells us how quickly contaminant gets into blood after exposure (MAT) Chemical Qualities Influencing Bioavailability—inorganic From Water Water chemistry modifies the species and sites uptake Weak acids: NH3 + H+ NH4+ H+ + CN- HCN H2S HS- S-2 Water Chemistry—Metals Dissolved Metals and metalloids (affected by speciation) changing form of metals (ex. methylation) or Binding to ligands & anions Cr 3 and Cr 6 -> only hexavalent is toxic, or methyl-Hg being toxic but Hg not toxic Ligand DOC (fulvic & humic acids) & inorganic compounds Anions Anoxic waters: NH3, HS-, S2- Oxygenated waters: B(OH), B(OH)4-, Cl-, CO32-, HCO3-, F-, HPO42-, NH3, OH- , Si(OH)4, SO42- Hydration spheres Around cations Free-ion activity model (FIAM) The free ion activity model (FIAM) of metal- organism interaction was initially developed to rationalize experimental observations and to explain what was initially perceived as ‘‘the universal importance of free metal ion activities in determining the uptake, nutrition and toxicity of cationic trace metals’’ States that only free metal ions are taken up by organisms Developed in model solutions incorrect, Hg is taken in the organic (methylated) form Water Chemistry Modifies competition at uptake sites H+, Ca2+, Mg2+, Na+ concentration To model bioavailability, need to factor in competing cations, pH, ligand concentrations, temperature, & ionic strength Water chemistry of the microlayer at a biological surface is also important. Bioavailability in solids An important step that limits the bioavailability of contaminants is their retention onto solids that compose soils and sediments. A wide range of solids exists in natural systems that vary in their reactivity toward organic and inorganic contaminants Chemical Qualities Influencing Bioavailability—inorganic From Solid Phases Solids: aerosols, particulates, food, soils, sediments Aerosols & particulates Distribution within Near surface vs. distributed throughout vs. all deep within Particle size—small particles get farther into lung Bioavailability—inorganic—solids Food Particle size and chemical form Diet Middle East: chronic dwarfism due to Zn deficiency Zn is less available from Cereal diet Protein diet enhances Zn, but decreases Ca absorption sediment - bottom of water soil - dry outside Solids ( soils and sediments) Solids within both soils and sediments are a composite of inherited material termed primary minerals (which are minerals formed by geological processes) and solids developed in place (authogenic). Such solids also have a balance of inorganic and organic fractions. Bioavailability—inorganic—solids Sediments Aquatic sediments are an open, dynamic, structured biogeochemical system typically composed of an oxic zone overlying anoxic materials. Mixture of solid particles & interstitial water Sediment biota Difficult to model sediment bioavailability Used sequential extraction to determine availability Bioavailability—inorganic—solids Oxic Sediments Exchangeable metals> carbonates> Fe-Mn oxides> DOC & Sulfide bound metals Anoxic sediments AVS—acid volatile sulfide Sulfide is mostly bound to Fe or Mg in sediments, other metals have greater binding coefficients, so they tend to replace iron As metals mix with the sediments, they replace the iron Cd2+ + FeS CdS + Fe2+ Decreases interstitial water concentration of metals If SEM/AVS < 1, then metal precipitates & is unavailable Organic Contaminants Bioavailability from water Structure-activity relationship (SAR) and quantitative structure-activity relationship (QSAR) models are mathematical models that can be used to predict the physicochemical, biological and environmental fate properties of compounds from the knowledge of their chemical structure. Partitioning between water and organism Octanol/water partition coefficient is very important index in Biological, toxicological and environmental area. The human body is made from water and lipids. If you know the distribution ratio of the chemicals to the octanol, you can estimate bioaccumulations. The octanol/water partition coefficient (Kow) is defined as the ratio of a chemical's concentration in the octanol phase to its concentration in the aqueous phase of a two-phase octanol/water system. Bioavailability decreases with increasing log Kow Bioconcentration factor: experimental concentration distribution = [ ] organism or sediment/ [ ] water (instead of octanol/water) Persistency of some chemicals in soil >100 days - persistent, 30-100 - moderately persistent, plants (100% of E from sun) 2nd -> herbivoes (10%) 3rd -> primary carnivores (1%) 4th -> etc Why are concentrations higher In predators than prey Predators Accumulate more Prey larger pop living for a shorter time not eating More dilution effect much contaminant cus they dont eat much food Difficulties in defining trophic status can be determined by C measurements Water or food exposure? source of contaminant? Outcomes of trophic transfer of contaminants Biomagnification Similar concentrations in predator and prey Concentration decreases as trophic level increases bioconcentration feathers - hair in human, human sample colection From Chapter 4 can also have sediment for bottom feeders no bioaccumualtion: excretion=egestion Quantifying bioaccumulation from food Assimilation from food Estimate of contaminant transfer between members of trophic levels Quantified as bioavailability from food Assimilation efficiency Steady-state concentration Twin Tracer Technique Trophic Transfer Identifying trophic level Bioaccumulation study done as a laboratory experiment controlling level In field survey Twin-tracer technique Introduces radiotracer of the substance to be assimilated simultaneously with an inert radiotracer to which assimilation is compared. A radionuclide such as 14 C is used and assumed to behave identically to its nonradioactive nuclide in chemical and biological processes. Assimilation Efficiency using radiotracer Organism is fed a radioisotope and the difference between the amount of the isotope ingested and egested over a time period gives Assimilation Efficiency. phytoplankton can determine ecosystem health Trophic Position Defining Trophic Position Changes in stable nitrogen isotope composition is the best indicator. Quantifying bioaccumulation from food Quantifying trophic status Isotopic discrimination Ratios of C, N & S isotopes changes with trophic transfers Lighter isotopes are eliminated easier than heavy 12C to 13C 32S to 34S 14N to 15N CHO meter to measure ratios 14N to 15N Discrimination Ratio ( 15N) Compare organism ratio to air ratio Changes with trophic level & animal age, but nothing else 15 N of ~3.4 o/oo per trophic transfer Allows for intermediate trophic levels Combination of N & C ratios Gives estimate of trophic level and sources of vegetable biomass tropic enrichment factor EXAMMM Quantifying bioaccumulation from food Estimating trophic transfer Simplest way Biomagnification Factor (B) B = C at level n / C at level n-1 › Bioaccumulation Factor (BF) BF= Corganism/Csource Concentration Factor (CF) CF= Cn/Cwater 15N Bowes and Thorp, 2015) trophic level using aa Fig. 1. (a) Trophic position is calculated from bulk-tissue stable isotope analysis using the producer ) 4 3.4] þ 1. (b) Trophic position using amino acid compound specific isotope analysis – 3.4) 4 7.6] þ 1. Model using trophic structure ( 15N) to determine bioaccumulation C=aeb( 15N) where C is concentration in organism in food web & b is the biomagnification power Shorter chain, less magnification Biomagnification of Contaminants Inorganic contaminants Metals and metalloids Radionuclides Organic Contaminants phytoplankton Biomagnification of PCBs 209 forms Log Kow above 6.1 subject to biomagnification Higher trophic levels had more Cl in congeners more lipophilic persistent, do not degrade, bioaccumulate, biomagnify Cod young seals polar bear & older seals 3&4 5&6 6&7 Older vs young seals: slow elimination Due to slower elimination of more highly Cl PCBs Diet of young seals Log Kow > 7-8 -> accumulate in sediment or soil (does not exclude food chain passing) log Kow between 4-7 -> accumulate in organisms log Kow < 4 -> water

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