Maison » PFAS Bioaccumulation and Biomagnification

PFAS Bioaccumulation and Biomagnification

2000

Unlike many persistent organic pollutants that accumulate in fatty tissues, long-chain PFAS like PFOA and PFOS primarily bind to proteins in the blood serum (e.g., albumin) and accumulate in well-perfused organs like the liver. This leads to bioaccumulation within an organism and biomagnification up the food chain, resulting in higher concentrations in apex predators, including humans.

The environmental behavior of long-chain PFAS is distinct from classical persistent organic pollutants (POPs) like PCBs or DDT. While traditional POPs are lipophilic (fat-loving) and accumulate in adipose tissue, the amphiphilic nature of PFAS (having both a hydrophobic/lipophobic tail and a hydrophilic head) dictates a different biological fate. The charged functional group (e.g., carboxylate in PFOA or sulfonate in PFOS) interacts with proteins. Specifically, these compounds bind to serum albumin in the blood and fatty acid-binding proteins within cells. This protein-binding mechanism facilitates their transport throughout the body and leads to accumulation in protein-rich tissues and organs with high blood flow, such as the liver, kidneys, and blood itself. Because they are not easily metabolized or excreted, their biological half-life in humans can be several years. This persistence within a single organism is the basis for bioaccumulation. As organisms are consumed by others higher up the food web, the concentration of PFAS increases at each trophic level, a process known as biomagnification. This is why top predators like polar bears, dolphins, and humans often exhibit the highest levels of PFAS contamination.

Bioaccumulation, Génie de l'environnement, Impact environnemental, Substances per- et polyfluoroalkyles (PFAS), Pollution, Pratiques de durabilité, Contamination de l'eau

UNESCO Nomenclature: 2512

– Toxicology

Type

Processus biologique

Perturbation

Incrémentale

Utilisation

Une utilisation répandue

Précurseurs

understanding of food webs and trophic levels
development of analytical chemistry techniques (e.g., LC-MS/MS) to detect low concentrations of chemicals in biological tissues
the concept of bioaccumulation established with earlier pollutants like ddt and mercury
studies on protein binding of pharmaceuticals

Applications

development of public health advisories for fish consumption
environnement règlements limiting pfas discharge (e.g., stockholm convention)
biomonitoring programs to track human exposure levels
toxicological models to predict health risks

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Related to: bioaccumulation, biomagnification, pfas, pfoa, pfos, toxicology, persistent organic pollutants, serum albumin, environmental fate, food chain.

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