Freshwater Microplastic Pollution and Management PDF

Summary

This presentation provides an overview of freshwater microplastic pollution, covering its definition, classification, sources, global distribution, and environmental impacts. The presentation discusses the various sources of microplastics in freshwater systems, including household and industrial activities.

Full Transcript

Freshwater Microplastic Pollution
and Management
 MODULE ONE
SESSION 1

Introduction to Microplastics
 MODULE 1: SESSION A

This course will bring you:
The Definition and Classification of
Microplastics
The Origins of Microplastics
Global Distribution of Microplastics
 LEARNING OUTCOMES

At the end of the course, you should be able to:
1. Define and classify microplastics
2. Identify the origins of microplastics
3. Understand the global distribution of microplastics
 Introduction to Microplastics
Understanding Microplastics: Definition and Classification

Courtesy Alexander Kunz
 Shape of microplastics

Classification by
Introduction to Microplastics

GESAMP (2019)
Introduction to Microplastics
The Origins of Microplastics
Household

Use of personal care products or
cosmetics (4,594 and 94,500
microbeads per single use)
Use of washing machines and
tumble driers (12,500 t of
plastic fibres/Year)
Opening of plastic packaging
(0.46 to 250 microplastic
particles per cm per opening)
The Origins of Microplastics
Tyre abrasion
Road traffic produces tiny
rubber particles from tires
which are then washed into
rivers and from there into the
oceans.
Top emitting nations/economic
groups (Wagner et al., 2018)
are:
The European Union:
1,327,000 t/a
The USA: 1,120,000 t/a
The Origins of Microplastics
Industry
Cutting or grinding of plastic
Styrofoam is released into the
environment by the fishing
industry
Preproduction pellets are often
released due to improper
handling during packing and
shipping
Plastic pellet production sites
can release between 3 – 36
million particles annually
(Karlsson et al., 2018)
 The Origins of Microplastics
Degradation of plastic
Breakdown of larger plastic into
small particles via UV
radiation, mechanical or
chemical agents.
The largest source for
microplastic fragments
4.8 – 12.7 million t of plastic
waste is released into the
environment yearly (Jambeck et
al., 2015).
Source: IUCN (2022)
 Global Distribution of Freshwater
Microplastics

Source: Cera et al. (2020)
 Global Distribution of Microplastics

Most microplastics result
from land-based human
activities, entering
freshwater via runoff
(Horton et al., 2017).
During dry periods,
plastics linger in rivers,
degrading (Li et al.,
2020a).
Wet seasons, with intense
flows, worsen microplastic
pollution, resuspending
particles from sediment
(Hurley et al., 2018).
 Global Distribution of Microplastics

Spatial
distribution
– land cover
– proximity to
anthropogenic
activities
Temporal
distribution
– timing and
volume of
precipitation
and runoff
 Global Distribution of Microplastics

Factors affecting the
spatial distribution of
microplastics
– Anthropogenic activities
– Urban land cover
– Wastewater treatment
plants
– Agricultural land cover
– Microplastics in remote
regions
– Population density
 Global Distribution of Microplastics

Physical watershed/stream
characteristics
– Increased slope of the
riparian zone
– Less dense polymers
(polypropylene,
polyethylene) float near the
water surface in calm
conditions
– Denser polymers
(polyethylene terephthalate,
polyvinyl chloride) sink and
settle at the channel bottom
 Global Distribution of Microplastics

Factors affecting
the temporal
distribution of
microplastics
– Precipitation
seasonality
– Storm runoff
– Flow
velocity/discharg
e
 Global Distribution of Microplastics

The prevalent 'species' of
microplastics include PVC and
polyester either in pellet or fiber form
Fibrous microplastics were of
particular concern from 2018 to 2022
High fibrous microplastic levels in lab
laundry simulations and from wool
textiles in home washing
 Global Distribution of Microplastics

Studies from
Africa, Asia and
Europe revealed
that
microplastic
concentrations
in the
freshwater
range from 0.01
to 3 g/L
 Global Distribution of Microplastics

The final distribution of
microplastics in the water
column is also influenced
by
– Degree of weathering
– Sorption and
– Rate of aging
Denser microplastics may
cause more lasting
damage to the
environment.
 Global Distribution of Microplastics
Tourism contributes to
microplastic
generation (
Retama et al., 2016).
Presence rises during
the tourist season at
Wastewater
Treatment Plants
(WWTP).
Fibers dominate,
followed by
fragments, attributed
to laundry effluent
influx.
 MODULE ONE
SESSION 2

The Environmental and Health Impacts of
Microplastics
 MODULE 1: SESSION 2

This course will bring you:
Aquatic Microplastics and Human Exposure
Human Health Risks of Aquatic Microplastics
Ecological Risks of Microplastics in Aquatic
ecosystems
 LEARNING OUTCOMES

At the end of the course, you should be able to:
1. Understand human exposure to aquatic microplastics
2. Appreciate the human health risks from aquatic
microplastics
3. Appreciate the ecological risks of microplastics in
aquatic ecosystems
Aquatic Microplastics and Human
Exposure: Occurrence and Risk
Besides environmental
exposure, humans are
also directly exposed
to microplastics via
domestic products
Microfibers, plastic
foams, and microbeads
are widely used in
clothing, food
containers, and
toiletries, enhancing
the risks of personal
exposure to
microplastics.
 Aquatic Microplastics and Human
Exposure: Occurrence and Risk

The content of

Alconox (2018)
microplastics in tap water
can be as high as 4.2
pieces/L

Source:
In bottled water it can be
20 times higher: 94
pieces/L
Due to their small sizes,
microplastics are readily
accumulated in both
aquatic and terrestrial
organisms
MPs are transferred via the
food chain and finally end
Source:
up in human consumers Hongtek (2021)
Aquatic Microplastics and Human
Exposure: Occurrence and Risk
Domestic food with
additives is another origin
of microplastics (

Source: Facciolà et al., 2021
0.10–1.48 pieces/g)
Annual individual
consumption of MP reaches
52,000 microplastic pieces
from food and drink
Adding the inhalable MPs
takes the figure to
121,000 items per year.
The ubiquitous presence of
microplastics around
humans thus results in
inevitable exposure to
humans
 Aquatic Microplastics and Human
Exposure: Human Exposure Routes
Exposure routes of microplastics
to humans include
– ingestion
– inhalation, and
– dermal penetration
The ingestion of microplastics is
the primary route
Seafood is considered one main
source of microplastics by the
ingestion route
Yearly microplastics uptake per
family consuming:
Source: Pironti et al., 2021 – Mollusks: 27,825 items
– Crustaceans: 17,716 items
– Fish: 8,323 items
 Aquatic Microplastics and Human
Exposure: Human Exposure Routes

The content of microplastics in
various sources of salt:
– Sea salt: 550 items/kg
– Lake salt: 43 items/kg
– Rock/well salt: 7 items/kg
The size of MPs in tap water
from groundwater sources (50–
150 μm: Mintenig et al., 2019)
is larger than the sizes of water
packaged in bottles (6.5–20 Source: Newhart (2019)
μm: Kankanige and Babel 2020
)
The size of MPs in soft drinks,
cold teas, and energy drinks is
larger: 0.1–3 mm. (
Shruti et al., 2020)
 Aquatic Microplastics and Human
Exposure: Human Exposure Routes

MP ingestion predisposing
factors include:
– Direct release of microplastics
from food packaging
– Migration of chemical
plasticizers from food
packaging to food
For instance:
– Size of MPs directly derived
from seafood is 38.2–820 μm (
Leung et al., 2021)
– Size of MPs in canned seafood
was bigger and reached 3800
μm (Karami et al., 2018)
 Applied Microplastics and Human
Exposure: Human Exposure Routes

MP particles that
enter via the
transdermal route
pass sublayers of
epidermis
They reach
microcirculation of
the dermis and are
transported through
the human body via
the circulatory
system
 Applied Microplastics and Human
Exposure: Human Exposure Routes

Dermal absorption
occurred mostly when
people used personal care
products:
– Hand cleanser
– Facial/body scrubs
– Face masks and
– Toothpaste
Consequence: local
toxicity and possible
absorption
The human skin (Largest
Organ: surface area of
1.5–2 m2) provides an
interface with ubiquitous
MPs in the environment
 Human Health Risks of Aquatic
Microplastics

Toxic chemical
additives in plastic that
are known to affect
human health include:
– Bisphenol A (BPA)
– Phthalates
– Triclosan
– Bisphenone
– Organotins and
– Brominated flame
retardants (BFR)
 Human Health Risks of Aquatic
Microplastics

Four (4)
morphological and
chemical
characteristics of
microplastics
influence their
Source: Wang (2023)
potential hazards:
– Physical
– Chemical composition
– Metabolism or Source:
degradation to form Kang et al., 2
monomers or other 019
derivatives
– The presence of
biofilms
 Human Health Risks of Aquatic
Microplastics

Toxic effects
strongly depend on
the:
– dose
– dose rate, and
– duration of
exposure
Uptake across the
gastrointestinal Source: Anderson and Li 2020
tract (particles