Early-Life PFAS Exposure in Sweden: A Study of Maternal Transfer and Prevention Through Drinking Water Treatment Technologies
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Examensarbete på kandidatnivå
Bachelor Thesis
Bachelor Thesis
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Sammanfattning
PFAS are persistent and environmentally hazardous substances that occur in drinking
water and may pose adverse health effects in humans, particularly in vulnerable
populations such as fetuses and children. Exposure can occur through drinking water
and be transferred from pregnant women to the fetus via the placenta or from
mother to child via breastmilk, making early-life exposure difficult to avoid. Such
exposure has been associated with effects on immune function, including reduced
vaccine response, as well as impacts on child development. This study aims to investigate
the potential health effects of PFAS exposure in fetuses and infants in Sweden,
and to evaluate how current water treatment methods need to be developed to meet
existing and future regulatory requirements. The study was conducted as a literature
review based on scientific articles, complemented by interviews with experts in
the field.
The findings indicate that PFAS exposure may affect children’s health even at low
concentrations, highlighting the importance of reducing exposure. At the same
time, the current state of knowledge is characterized by significant uncertainties,
particularly regarding short-chain and ultrashort-chain PFAS, where lack of data
should not be interpreted as evidence of low risk. Current treatment methods can
largely meet existing guideline values but have notable limitations, especially in that
they primarily remove rather than degrade PFAS. While conventional techniques
are generally effective for long-chain PFAS, they are less effective for short-chain
compounds. Emerging technologies such as electrochemical oxidation show potential
for destructive PFAS treatment, including degradation of shorter-chain compounds,
although challenges related to energy demand, operational costs, and large-scale
implementation remain significant.
Overall, the study shows that no optimal treatment method for PFAS currently exists,
as the most promising techniques face high cost and large-scale implementation
challenges. Future efforts should therefore focus on the development of more costeffective
methods to make advanced treatment technologies, such as electrochemical
water treatment, cost-effective for widespread municipal use. Furthermore, the need
for PFAS source control is critical, given that PFAS treatment is resource-intensive,
and reducing exposure is particularly important for vulnerable populations such as
pregnant women and children.
