Precision Techniques for Microplastics Detection and Analysis
App Note / Case Study
Published: August 29, 2024
Credit: iStock
Microplastics pose a significant environmental challenge, contaminating aquatic ecosystems and posing severe risks to both marine and human health.
Traditional analytical methods often yield inconsistent and inconclusive results, highlighting the need for advanced techniques to accurately identify and characterize these pollutants.
This case study explores an innovative workflow using a combination of thermogravimetric analysis (TGA), Fourier-transform infrared spectroscopy (FTIR) and gas chromatography mass spectrometry (GC-MS). This workflow enhances the detection and analysis of microplastics and provides critical insights into their impact on the environment.
Download this case study to explore:
- The latest advancements in microplastics analysis and their implications for environmental research
- How the TGA-FTIR-GC/MS workflow can improve accuracy and reliability
- Solutions to overcome common challenges in microplastics research
CASE
STUDY
Customer Spotlight: Norwegian Institute
for Water Research (NIVA)
CASE
STUDY
University of Birmingham Team Uses Agile TGA-FTIR-GC/MS
Workflow to Advance Microplastics Research
Introduction
Microplastics are defined as pieces of plastic that are less than
5 mm (0.2 inch) in length. Over the past decade or so, these minute
structures have been discovered in marine, freshwater, terrestrial,
and atmospheric environments in alarming abundance.
In aquatic environments, microplastics often enter freshwater systems within which they migrate to marine environments where it
can take up to 600 years for them to degrade. They are also ingested by aquatic fauna and absorbed by aquatic flora, which can result
in their bioaccumulation within food chains. Finally, toxic chemicals
can be adsorbed by microplastics and harmful pathogens can
adhere to particle surfaces. The resulting impacts of microplastics
on aquatic ecosystems are not fully known at this time, but there is
growing interest and research focused on gaining a better understanding of this and how to address the impacts.
Aquatic biologists require comprehensive data on microplastics
chemical composition, size-distribution relationships, tissue and
cellular fates, and effects on aquatic biota. To obtain such data,
scientists rely upon analytical instrumentation and methodologies
that are able to generate accurate, sensitive, reproducible data for a
range of sample types. To-date, analytical methods used in microplastics research have been plagued by poor polymer identification
rates due to an array of issues such as polymer color, biofouling or
environmental aging. The biggest challenge is the lack of standardized methodologies that articulate best practices and approaches
to ensure high-quality, sensitive, reproducible methods within standard frameworks.
A UK-based research team is making great strides in characterizing
and understanding microplastics in aquatic environments. The team
includes experts in aquatic ecology and analytical methodology, a
perfect match for microplastics research.
The University of Birmingham Research Team
Dr. Holly Nel and Dr. Andrew Chetwynd are part of a microplastics
research team in the University of Birmingham’s (UoB) School of
Geography, Earth and Environmental Sciences in England. Their
collaboration addresses the microplastic pollution problem from
different, but complimentary, angles.
Dr. Nel is an expert at in-situ sampling and sample preparation
techniques for microplastics in fresh and marine water, sediment,
and biota. Her research focuses on understanding the movement
of plastics through aquatic systems, the drivers of and barriers to
that movement, the source-sink dynamics of a range of MP particle
sizes, and the impacts of MPs on aquatic organisms.
Dr. Nel spends a lot of time in the field collecting samples and
preparing them for analysis. The data generated from the samples
is used in conjunction with lab-based studies and models to understand various transport and fate scenarios. Generating accurate
and reliable data is, then, one of Dr. Nel’s primary goals and is crucial for developing an understanding of the movement and effects
of different particle sizes at the full ecosystem level. To gain that
understanding, she requires improved detection capabilities for a
range of particle sizes as well as identifying the effects of different
sample preparation techniques on particle detection.
University of Birmingham Team Uses Agile TGA-FTIR-GC/MS Workflow to Advance Microplastics Research
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Microplastics analysis has historically struggled with inconclusive
results and false identifications. The exceptional sensitivity, accuracy, and versatility of the TGA-FTIR-GC/MS hyphenated workflow
is helping Dr. Chetwynd overcome those challenges and provides
Dr. Nel with the detailed data she needs for her work. Dr. Nel also
appreciates that the workflow’s data output and analysis reports
are easy to understand for researchers like her who focus on measuring the impacts of microplastics in marine ecosystems.
Integrated Software and Polymer Reference Libraries
The PerkinElmer software specific to each instrument enable
researchers like Dr. Chetwynd and Dr. Nel to evaluate their data
efficiently and accurately. As Dr. Chetwynd describes, “the TGA’s
Pyris™ software has all the required calculations built into the different steps, so it is easy to interrogate the data and get results
quickly.” He also appreciates that “the FTIR data is easily exportable to a spreadsheet so it can be shared with colleagues in the
microplastics arena.”
The PerkinElmer GC/MS software includes a polymer reference
library that is used to confirm the identity of a polymer. The software
also acknowledges a polymer that does not correspond to any within
the existing polymer library, thus preventing false identifications. As
microplastics research expands, more polymers can be added to the
library, which is something that both Dr. Chetwynd and Dr. Nel appreciate. “The software platform is very helpful for building a plasticspecific or location-specific polymer library,” explains Dr. Nel, which
“facilitates future analyses and supports sharing and collaboration
with other scientists” says Dr. Chetwynd.
The Team’s Next Steps
The data obtained from the UoB team’s research are being used to
identify the specific plastics present in location-specific and mediaspecific samples. So far, they have found polyethylene and polypropylene to be the most dominant polymers in their samples.
Dr. Nel explains that “being able to accurately identify the specific
microplastic chemicals in our samples helps to identify hot spots
and vulnerable areas, pinpoint their sources, and aid in the development of targeted mitigation strategies.” To get to that point,
she sees the importance of developing faster sample preparation
methods and faster data availability, possibly through the use of
in-situ sensors.
Dr. Chetwynd continues to pursue analytical methods that provide
improved microplastic characterization with lower sample mass
requirements. He also anticipates moving toward methods that
can further distinguish copolymers, decipher plastic mixtures, and
quantify the components of microplastic particles. He even envisions future techniques that can be used to characterize microplastics in-situ within the original sample matrix.
After collecting field samples, Dr. Nel needs advanced analytical capabilities to extract the chemical and physical data that
will propel her research forward. That is where Dr. Chetwynd’s
work comes in. Dr. Chetwynd is an expert in the development of novel analytical methods that push the boundaries of
analyte detection and characterization. His current research
focuses on developing enhanced analytical methods for the
characterization of nanomaterials, microplastic particles, individual polymers, and proteins and metabolites that adsorb to
micro- and nanomaterials.
Dr. Chetwynd is developing methods that provide the greater
sensitivity, reproducibility, and reliability needed to advance
microplastics characterization, and to do so using less sample
mass. He is also designing methods that allow the detection
of particles within organelles—an important progression from
detecting particles within cells.
Advanced, Agile Workflows
Dr. Chetwynd uses several PerkinElmer, Inc. (PerkinElmer) instruments and software to develop and evaluate the advanced analytical methods needed for microplastics research. He describes
PerkinElmer’s modular workflow of thermogravimetric analysis
(TGA), Fourier-transform infrared spectroscopy (FTIR), and gas
chromatography/mass spectroscopy (GC/MS) as one of his
most versatile and valuable tools. “I can use each module individually or in different hyphenations,” he explains, “meaning I can
customize the platform for each specific project or analysis.”
One example of this customizability is Dr. Chetwynd’s use of
the TGA-FTIR-GC/MS hyphenated workflow to accurately distinguish polypropylene, polyethylene, and polystyrene within a
sample. He uses TGA analysis to initially determine if a sample
contains polypropylene, polyethylene, and/or polystyrene, which
have very similar TGA profiles. FTIR is then used to confirm or
rule out the presence of polystyrene, followed by GC/MS to distinguish between polypropylene and polyethylene. PerkinElmer’s
FTIR also identifies polymer additives, further helping to avoid
mischaracterization of microplastics. The hyphenated workflow
provides Dr. Chetwynd with the detailed, accurate data needed
to identify each polymer type contained in a sample.
Another successful application of the TGA-FTIR-GC/MS
hyphenated workflow is distinguishing between different
pyrolysis products of a polymer. Dr. Chetwynd explains that
polystyrene samples tend to expand in volume, limiting the size
of sample that can be loaded into TGA crucibles and, therefore, the level of detail that can be achieved from the reduced
sample mass. This is a problem in polystyrene identification
because it relies upon styrene dimer and trimer data, not just
total styrene. Styrene is distinguishable using GC/MS, but
the TGA and FTIR modules provide the detailed thermal and
chemical information needed to accurately identify the styrene
dimer and trimer. The sensitivity of the workflow provides Dr.
Chetwynd with the specificity needed to accurately identify
polystyrene in a microplastic sample.
University of Birmingham Team Uses Agile TGA-FTIR-GC/MS Workflow to Advance Microplastics Research
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Conclusion
Pairing Dr. Nel’s ecological research with Dr. Chetwynd’s analytical methodology research creates a holistic approach to
understanding the lifecycle and impacts of microplastics in
aquatic ecosystems. This research team will undoubtedly continue hammering away at the microplastics pollution problem
until real solutions are found and implemented.
Despite the pandemic of 2020, Dr. Nel and Dr. Chetwynd were
able to continue their work with the help of PerkinElmer’s
instrumentation, software, and technical support. Just before
the pandemic emerged, the team had analyzed a large collection of samples and generated a substantial amount of data.
Suddenly, they found themselves prohibited from going to the
lab to use their PerkinElmer software for data analysis.
Dr. Chetwynd reached out to PerkinElmer for help. “Within two
days, they got us the software suites we needed to continue
our data analysis at home,” he reports, “instead of having to
wait what ended up being a year to find out what the data
revealed.” They were relieved to be able to write reports of
their work for publication and present their findings at online
workshops and conferences, such as the SETAC Europe 30th
Annual Meeting in May of 2020.
The Future of Microplastics Research
The long-range goals of microplastics research are
diverse and include:
Obtaining long-term monitoring data for individual systems
so accurate trends can be identified
Determining the effects of microplastics and individual polymers, additives, and fillers on aquatic ecosystems
Being able to identify or trace the source of location-specific
microplastic contamination
Designing and implementing targeted remedial strategies for
existing contamination
Making changes in plastic production to eliminate
problematic polymers
Enabling targeted minimization of microplastic releases
from production, waste disposal, and recycling operations
As these goals are pursued and eventually achieved,
Dr. Chetwynd and Dr. Nel see the need for standardization of
methods and criteria in order to effectively address the worldwide microplastics pollution problem. Dr. Chetwynd points
to the need for standardization of analytical methods used in
microplastics research and monitoring. He believes the sample
preparation methods will differ by medium, but the subsequent
analytical methods will be consistent. Regarding regulatory
criteria for microplastics, Dr. Chetwynd sees the need for a
regulatory framework that is similar to those already in place
for drinking water, air, and so forth.
Dr. Nel explains that “standardized methods and harmonized
practices will be needed for tracking and reporting microplastic pollution so that global research can be integrated and
effective.” She sees such integration beginning to occur in
the growth of a research database that identifies researchers,
instruments, and polymer libraries that are available internationally. In her home continent of Africa, a similar database is being
developed to help unify and support microplastics research
across African nations.
PerkinElmer is proud to support the work of this dynamic
research team at the University of Birmingham.
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