Persistent organic pollutants
- sample analysis
Jana Klánová
klanova@recetox.muni.cz

1. Environmental analytical chemistry
Specific features, general scheme
2. Sampling
Sampling plan, strategy, sampling protocol, sample size and quality, transport, storage
3. Sample preparation
Extraction of solid (Soxhlet, automatic extraction, MAE, ASE, SFE) and liquid (L-L, SPE,
SPME, head-space) samples, fractionation and clean-up (column chromatography,
gel permeation)
4. Analytical techniques
Chromatographic techniques, principals, instrumentation, HPLC, GC, GC-MS
5. Persistent organic pollutants
Priority pollutants (PCBs, PCDDs/Fs, PAHs, pesticides), emerging pollutants
(SCCPs/MCCPs, antibiotics, degradation products)
6. QA/QC
Calibration, limit of detection and quantification, internal and recovery standards, blanks,
certified reference materials, interlaboratory calibration tests, method validation and
verification, GLP

Environmental science brings together scientists from many fields to perform complex studies of
various environmental compartments, processes, and interactions.
They may include:
- water and food quality monitoring
- level of contamination of environmental compartments
- ozone depletition as a result of the presence of certain chemicals in the atmosphere
- regional contamination studies
- evaluation of the impact of local sources of pollution
- toxicity of chemical compounds as a function of their chemical structure
- impact of chemical substances on living organisms
- bioavailability
- bioaccumulation
- biotic and abiotic transformations
- transport of pollutants in the environment
- global fate of pollutants
- international directives and their impact on the global contamination
- remediation actions and their quality control
- sustainable development
Most of them involve the chemical analysis as one of necessary steps.

Environmental analytical chemistry chalenges:
- international conventions focus attention on the new groups of pollutants
- old contamination brings the problem of residue analyses
- lowering limits as well as environmental levels require low detection limits
- large-scale monitoring is crutial for the studies of the long-range transport
- development of new sampling techniques is encouraged
- increasing number of samples stresses the need for automatization
- fate studies require understanding of distribution processes and equilibria
- photochemical reaction complicate the sampling and data interpretation
- consideration of both, analytical and toxicological data is important
  for successful risk assessment
- methods of biochemistry and molecular-biology are often implemented in
  toxicological studies
- international studies require standardization of all procedures

There are several steps necessary for
environmental contamination control:
-  problem definition
- screening of the situation, data interpretation
- evaluation of the extent of the problem
- selection of the best procedure to monitor the situation
- evaluation of the present state and future development
- exposure evaluation and risk assessment
- suggestion of correcting measures or remediation activities
- new directives to control the situation
- monitoring designed to evaluate effectiveness of measures
-







Specific problems of environmental analysis
- low homogenity of samples (soil)
- low stability of samples (biota)
- various matrices (methods for extraction of analytes from matrices)
- wide range of analytes (method development)
- wide range of concentration (robust methods)
- monitoring on the levels close to the detection limits (high deviations)
- risk of secondary contamination
- price of ultra-trace analysis (instrumentation, chemicals, standards)

General scheme of environmental analysis
- Sampling - homogenization
                  - conservation
- transport
- storage
- Sample preparation - extraction
- clean-up
- selective elution
- concentration
- derivatization
-
- Sample analysis
- Data interpretation

Sampling – documentation required
- sampling plan (a goal, selection of sampling sites, analytes, sampling method,
  number of samples, sampling period and frequency, safety procedures),
  seeks the balance between the value of data and its price
- standard operational procedure for sampling various matrices (sampling devices,
  steps involved in collecting of representative sample -homogenous, of reasonable
  size and stability, quality of transport and storage)
-sampling protocols (name and number of the sample, sampling site, matrix,
 date of sampling, local conditions and measurements, methods, sample size,
 responsible person)

GPS:
49°29’48’’
17°57’14’’
         245 m
Local conditions:
Sampling site 1. DEZA

Polyurethane Foam Filter PUF
Air Pump
Sampling Techniques
High-Volume sampler
Particulate Phase
Gas Phase
Glass Fiber Filter GFF
Particles
Gas

Passive sampling
Can environmental concentrations of pollutants be calculated
from the analyte levels accumulated in an integrative
passive sampler?
- Calibration conditions should approximate field conditions
- Performance Reference Compounds

Calibration of a passive sampler in a flow-through system
Peristaltic pump
30 ml/min
Peristaltic pump
100 ml/min
Exposure tank
Water
waste
water
Stirrer
Chemicals
in MeOH
Water
reservoir
Samplers
Analytes
In MeOH
B. Vrana, R. Greenwood, G. Mills

Sampling rates of PAHs
B. Vrana, R. Greenwood, G. Mills


PRCs are non-interfering compounds added to the sampler prior to exposure.
They are used for in situ calibration approach, where the rate
of PRC loss during an exposure is related to the target compound uptake.
This is accomplished by measuring PRC loss rates during calibration studies and
field exposures.
Performance reference compounds

PRC = D10-Biphenyl
Temperature = 11°C
Use of performance reference compounds
B. Vrana, R. Greenwood, G. Mills

       Preparation of the sample before extraction
Soil samples
- lyofilization or air-drying
- sieving (< 2mm) and homogenization
- appropriate storage (protected from sunlight, heat and humidity)
Sediment samples
- stone and water removal, lyofilization or air-drying
- grating and sieving (<63um), homogenization
- powder copper treatment for sulphur removal
Plant samples
- lyofilization or air-drying
- grating, homogenization

Animal samples
- lyofilization or
- homogenization of a wet sample with sodium sulphate

                         Extraction and clean-up
The goal: transfer of analytes to the chemical phase suitable for analysis,
removal of interferences and pre-concentration of the sample.
Extraction techniques:
- solvent extraction (Soxhlet, automatic Soxtec, MAE, ASE, SFE)
- liquid-liquid extraction
- solid phase extraction and microextraction (SPE, SPME)
- semipermeable membrane separation
- head space analysis
-
Clean-up techniques
- sulphuric acid treatment
- column liquid chromatography (silica gel, alumina, florisil)
- gel permeation chromatography

Solid sample extraction



Liquid sample extraction




Air samples
- filters from high volume samplers or passive samplers are extracted as solid samples
  (Soxhlet, MAE, ASE, SFE)
Water samples
- direct analysis of the samples with high concentration of pollutants
- head space, SPE, L-L
-
Soil and sediment samples
- Soxhlet, MAE, ASE, SFE
- powder copper treatment for the sulphur removal in sediment samples
-
Biotic samples
- high molecular compounds removal by gel permeation chromatography and column
  chromatography


Presence
Availability
Activity
Total mass
Fraction of
total mass
Measure that
drives diffusion
and partitioning
How much
is there?
How much is
available for ... ?
How high is the
diffusive pressure
into other media?
Exhaustive
Extraction
Depletive
Extraction/
Sampling
Equilibrium
Sampling
Devices
P. Mayer, F. Reichenberg

Supercritical Fluid Extraction (SFE)
High pressure CO2 (100 to 400 bar, 40 to 150 oC) is pumped through a sample,
and extracted analytes are collected in a suitable solvent for GC analysis.
Why to use supercritical carbon dioxide?
- CO2 is a lipophilic solvent much like biological lipids in polarity
- PAH solubilities in CO2 are proportional to those in water, but ca. 104 higher
- pressure and temperature gradients enable the extraction of both, non-polar and
  polar compounds
- mild SFE can be used to predict bioavailability of compounds

Earthworm  Mortality Depends on  Available PAHs
(measured by SFE), not on Total PAH Concentrations
Soil          Total PAH           Available         Available Total       Mortality
          (ug/g soil)       Fraction (SFE)      PAH (ug/g C)                   % Mortality
CG15 1020   0.25   1040    0
OG14    168   0.46   2720    0
CG11 15600   0.06   3280    0
CG12   3790   0.16   7880    0
OG17 17200   0.27   9720    0
OG5   1870   0.41 11100    0
OG10 42100   0.33 16300    0
CG3   4100   0.83 45700                100
OG18 17300   0.74 50100                100
S. B. Hawthorne, C. B. Grabanski, D. J. Miller

Sampling
train
Rinsing of sampling
device
Extraction
Concentration
Silica
Silica
+
H2SO4
Silica
Silica
+
NaOH
Silica
Silica
+
AgNO3
Sampling
standards
Extraction
standards
Basic
Alumina
Super I
column
Active
carbon
column
Concentration
GC/MS
Syringe
standards
Flow chart of a clean-up procedure for stack emission samples
A. Kočan, Slovak Medical University

Priority pollutants
- polychlorinated biphenyls
- polychlorinated dibenzo-p-dioxins and furans
- organochlorinated pesticides and their metabolites
- polyaromatic hydrocarbons
- aromatics and nitro-aromatics
- chlorinated benzenes
- fenol and chlorinated fenols
- halogenated alkans
-

Polychlorinated biphenyls
- sulphuric acid treatment
- silica gel column chromatography
- activated carbon for non-ortho PCBs
- GC-ECD, GC-MS, GC- HRMS

Organochlorinated pesticides
HCH
          p,p’-DDT                 p,p’-DDD                  p,p’-DDE
 (DDT, HCH, hexachlorobenzene, toxaphene, aldrin, dieldrin, endrin, endosulfane, chlordane)
- analytical procedures similar to PCBs for toxaphene,
- sulphuric acid has to be omitted for aldrin or endosulfane
- GC-MS, NCI-MS, HRMS
- for HCHs and DDTs analytical procedures similar
  to PCBs
- GC-ECD, GC-MS, NCI-MS, HRMS

Polychlorinated dibenzodioxins and dibenzofurans
- combined modified silica gel clean-up
- fractionation on alumina/florisil column
- non-ortho PCBs separation on activated carbon column
- HRGC-HRMS
- kapilary columns 50-60m (DB-5, DB-17, DB-DIOXIN)
- EI, NCI
- SIM
- MS-MS
-
Polyaromatic hydrocarbons
- silica gel column chromatography
- GC-MS, FLD-HPLC

                            Sample analysis
Chromatographic separation (GC, HPLC) is the most common technique for
the analysis of environmental samples.
It is a physical method based on the distribution of compounds between two
phases (stationary and mobile). Process of continuous sorption and desorption
of compounds in contact with the stationary phase is responsible for different
migration times and for separation of analytes.
Two dimensional (GC-GC) and two modal (HPLC-GC) chromatography provide
even more sofisticated tools for environmental analysis
GC-MS, HPLC-MS and HRMS enable the trace and ultra-trace analysis




GC separation:
§Non-polar stationary phase (e.g. DB-5) – used for the samples of animal origin and higher
chlorinated congeners
§Polar phase (e.g. SP-2330) – used for environmental samples (good separation but shorter lifetime)
§Splitless, on-column or large-volume injection
§Direct connection of the column to the ion source
out of splitless injector
to mass spectrometer
A. Kočan, Slovak Medical University




Chromatogram



Ion
Source
Mass
Analyzer
Ion
Detector
Vacuum
Pumps
Inlet
Sample
Introduction
Data
System
Data
Output
Mass Spectrometer
•All the MS systems compose of the following parts:
Ionization, separation of ions
and their detection
take place in vacuum
(~ 10-4 – 10-6 Pa)
•Electron multiplier
•Photomultiplier
•Microchannel plate
•Magnetic-sector
•Quadrupole
•Ion trap
•Time-of-flight
•Ion-cyclotron resonance
•Electron impact (EI)
•Chemical ionization (CI)
•Electrospray (ESI)
•Fast-atom bombardment (FAB)
•Laser ionization (LIMS)
•Resonance ionization (RIMS)
•ˇThermal ionization (TIMS)
•Plasma-desorption ionization (PD)
•Matrix-assisted laser desorption ionization (MALDI)
•GC
•LC
•Direct inlet
A. Kočan, Slovak Medical University

Electron Impact Ionization Source
~70 Volts
+
_
+
_
e-
e-
e-
+
+
+
+
+
+
_
Electron Collector (Trap)
Repeller
Extraction
Plate
Filament
to
Analyzer
Inlet
Electrons
Neutral
Molecules
Positive
Ions
10 to 20 eV out of those 70 eV are transferred to the molecules during the ionization process;
Since ~ 10 eV are enough to ionize most organic molecules the excess energy leads to extensive
fragmentation;
Hence EI is classified as a „hard“ ionization technique
The fragmentation gives structural information
A. Kočan, Slovak Medical University

Detector
Ion
Source
+
_
_
DC and AC
Voltages
resonant ion
non-resonant ion
+
Quadrupole Mass Filter
quad1
•Consists of 4 parallel metal rods.
•Two opposite rods have an applied potential combined from DC and AC voltages.
•A mass spectrum is obtained by monitoring the ions passing through the quadrupole filter as the
voltages or frequency on the rods are varied.
•For given dc and ac voltages, only ions of a certain mass-to-charge ratio pass through the filter
and all other ions are thrown out of their original path.
•The voltages affect the trajectory of ions traveling down the flight path centered between the
rods.
A. Kočan, Slovak Medical University

Ion Trap Mass Spectrometry
•The advantages of the ion-trap mass spectrometer include compact size, and the ability to trap and
accumulate ions to increase the signal-to-noise ratio of a measurement.
picture of w. paul
Wolfgang Paul
1989 Nobel Price for Physics „for the development of the ion trap technique“
•This technique can be used easily in the MS/MS (MSn) mode
•The ion-trap analyzer consists of 3 electrodes with hyperbolic surfaces to trap ions in a small
volume – the central ring electrode and 2 adjacent endcap electrodes. A mass spectrum is obtained
by changing the electrode voltages to eject the ions from the trap.
A. Kočan, Slovak Medical University

TOF MS schematic
Time-Of-Flight Mass Spectrometry (TOFMS)
•It uses differences in transit time through a drift region to separate ions of different masses
•It operates in a pulsed mode so ions must be produced or extracted in pulses
•An electric field accelerates all ions into a field-free drift region with the same initial
kinetic energy for all the ions produced
•Since the ion kinetic energy is 0.5mv2, lighter ions have a higher velocity than heavier ions and
reach the detector sooner (e.g., ions of m/z 500 arrive in ~ 15 ms and m/z 50 in ~ 4.6 ms
Schematic of gas analysis system Photo of TOF-MS for gases
•By TOF-MS, up to 50 000 full spectra can be measured in a second
•Since full spectra are available, peak deconvolution software enabling to differentiate
non-separated GC peaks may be applied
•The TOF ultra-fast scanning is suitable for fast GC where peak widths can be much less then a
second
A. Kočan, Slovak Medical University

ion trajectory
not in register
(too heavy)
Ion
Source
Detector
ion trajectory
not in register
(too light)
ion trajectory
in register
S
N
Electromagnet
Magnetic Sector Mass Analyzer
HPIM3647
A. Kočan, Slovak Medical University

Mass spectra



What is the SCAN Mode in Mass Spectrometry ?
•The scanning mode provides mass spectra. They are recorded (scanned) at regular intervals
(typically 0.5 – 1 /s; much faster if TOFMS is used) during the GC separation and stored in the
instrument data system for subsequent qualitative or quantitative evaluation.
•From mass spectra, it is often possible to deduce structural features (mass spectral
interpretation) but this requires experience and can be very time-consuming, particularly as a
complex mixture might contain hundreds of components.
•The spectra can also be compared with those stored in mass spectral libraries. Although library
searching is a very useful and timesaving technique, it is important to remember that such searches
do not identify compounds – analysts do!
A. Kočan, Slovak Medical University

What is the SIM (or MID) Mode in Mass Spectrometry ?
•SIM (Selected Ion Monitoring) or MID (Multiple Ion Detection) is much more sensitive technique
suitable for trace quantitative analysis. Here, instead of scanning a whole spectrum, only a few
ions (generally, the most abundant but characteristic selected from the mass spectrum) are detected
during the GC run.
•This can result in as much as a 500-fold increase in sensitivity, at the expense of selectivity.
Depending on the analyte, low picogram to even low femtogram amounts can be measured using this
powerful technique.
•Stable isotope-labeled internal standards can be employed.
f3
HRMS/LRMS-SIM chromatogram from the analysis of 2378-TCDD in a soil extract by the isotope dilution
method
2,3,7,8-TCDD
13C12-2,3,7,8-TCDD
M+.
A=1392 (82%)
m/z 319.9
m/z 321.9
m/z 323.9
[M+2]+.
A=1688 (100 %)
[M+4]+.
A=829 (49%)
M+.
A=1936 (80%)
m/z 331.9
m/z 333.9
m/z 335.9
[M+2]+.
A=2415 (100%)
[M+4]+.
A=1198 (50%)
A. Kočan, Slovak Medical University

•In general, more ions have the same nominal mass
•To distinguish between them certain MS resolution is needed
•For example, to separate these 2 ions we need a resolution of 5 124
R = 122 / (122.060585 – 122.036776) = 5 124
A. Kočan, Slovak Medical University

•This conversion is based on the assumption that all the 2,3,7,8-substituted PCDDs and PCDFs (17
cong.), as well as the dioxin-like PCBs (12 cong.), bind to the same receptor, the Ah receptor, and
show comparable qualitative (toxic) effects, but with different potencies
TEQ = (PCDDi × TEFi) + (PCDFi × TEFi ) + (PCBi × TEFi )
Conversion of Analytical Results
into the Toxic Equivalent (TEQ)
•These differences in toxicity are expressed in the toxic equivalency factors (TEFs)
•TEF of the most toxic 2378-TCDD = 1
Congener
I-TEF
WHO-TEF
Congener
I-TEF
WHO-TEF
2378-TCDD
1
1
2378-TCDF
0.1
0.1
12378-PeCDD
0.5
1
23478-PeCDF
0.5
0.5
123478-HxCDD
0.1
0.1
12378-PeCDF
0.05
0.05
123678-HxCDD
0.1
0.1
123478-HxCDF
0.1
0.1
123789-HxCDD
0.1
0.1
123789-HxCDF
0.1
0.1
1234678-HpCDD
0.01
0.01
123678-HxCDF
0.1
0.1
OCDD
0.001
0.0001
234678-HxCDF
0.1
0.1

1234678-HpCDF
0.01
0.01

1234789-HpCDF
0.01
0.01

OCDF
0.001
0.0001
A. Kočan, Slovak Medical University

 Quality assurance/quality control (QA/QC)
Quality assurance
Preventive measures (quality of facilities, personnel and education, equipment and service,
calibration, internal and recovery standards)

Quality control
Control measures (internal – blank and reference material analyses, external – interlaboratory
comparison, audit)
Reasons
- repeatibility of measurements
- comparison of results between laboratories
- political and economical importance of results

           Terminology
Calibration
Limit of detection and quantification
Sensitivity and specificity
Accuracy, trueness, precision
Method validation and verification
Internal standards
Recovery and surrogate recovery standards
Certified reference materials
interlaboratory calibration tests,
GLP

Standard operational procedure
- General information (terminology, principles, range of use, limitations,
   safety
   procedures, toxicology, waste treatment)
- Directives
- Consumables and chemicals (glass, standards, solvents, reference materials)
- Equipment (sampling and analytical equipment, service)
- Calibration (standards, procedures)
- Analytical scheme (method validation and verification)
- Quality control (internal - blank, reference material, external –
   intercalibration)
- Data interpretation
- Annexes