SIST EN ISO 23611-3:2020

SLOVENSKI STANDARD
oSIST prEN ISO 23611-3:2018
01-april-2018
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Soil quality - Sampling of soil invertebrates - Part 3: Sampling and extraction of
enchytraeids (ISO/DIS 23611-3:2018)
Bodenbeschaffenheit - Probenahme von Wirbellosen im Boden - Teil 3: Probenahme
und Bodenextraktion von Enchytraeen (ISO/DIS 23611-3:2018)
Qualité du sol - Prélèvement des invertébrés du sol - Partie 3: Prélèvement et extraction
des enchytréides (ISO/DIS 23611-3:2018)
Ta slovenski standard je istoveten z: prEN ISO 23611-3
ICS:
13.080.30 Biološke lastnosti tal Biological properties of soils
oSIST prEN ISO 23611-3:2018 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST prEN ISO 23611-3:2018

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oSIST prEN ISO 23611-3:2018
DRAFT INTERNATIONAL STANDARD
ISO/DIS 23611-3
ISO/TC 190/SC 4 Secretariat: AFNOR
Voting begins on: Voting terminates on:
2018-03-01 2018-05-25
Soil quality — Sampling of soil invertebrates —
Part 3:
Sampling and extraction of enchytraeids
Qualité du sol — Prélèvement des invertébrés du sol —
Partie 3: Prélèvement et extraction des enchytréides
ICS: 13.080.05; 13.080.30
THIS DOCUMENT IS A DRAFT CIRCULATED
This document is circulated as received from the committee secretariat.
FOR COMMENT AND APPROVAL. IT IS
THEREFORE SUBJECT TO CHANGE AND MAY
NOT BE REFERRED TO AS AN INTERNATIONAL
STANDARD UNTIL PUBLISHED AS SUCH.
IN ADDITION TO THEIR EVALUATION AS
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BEING ACCEPTABLE FOR INDUSTRIAL,
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USER PURPOSES, DRAFT INTERNATIONAL
STANDARDS MAY ON OCCASION HAVE TO
BE CONSIDERED IN THE LIGHT OF THEIR
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WHICH REFERENCE MAY BE MADE IN
Reference number
NATIONAL REGULATIONS.
ISO/DIS 23611-3:2018(E)
RECIPIENTS OF THIS DRAFT ARE INVITED
TO SUBMIT, WITH THEIR COMMENTS,
NOTIFICATION OF ANY RELEVANT PATENT
RIGHTS OF WHICH THEY ARE AWARE AND TO
©
PROVIDE SUPPORTING DOCUMENTATION. ISO 2018

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COPYRIGHT PROTECTED DOCUMENT
© ISO 2018
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Contents Page
Foreword .iv
Introduction .v
1 Scope . 1
2 Terms and definitions . 1
3 Principle . 1
4 Reagents . 2
5 Apparatus . 2
6 Procedure. 3
6.1 Soil sampling . 3
6.2 Extraction of the enchytraeids . 3
6.3 Microscopic identification . 4
6.4 Preservation of Enchytraeidae . 4
6.5 Validity of the extraction process. 4
6.6 Determination of biomass . 5
7 Data assessment. 5
8 Test report . 5
Annex A (informative) Relevant publications for the identification of enchytraeid species .7
Annex B (informative) Quick extraction of enchytraeids . 8
Annex C (informative) Examples of the use of soil invertebrates in soil monitoring
programmes (including presentation of their results) .10
Bibliography .13
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Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards
bodies (ISO member bodies). The work of preparing International Standards is normally carried out
through ISO technical committees. Each member body interested in a subject for which a technical
committee has been established has the right to be represented on that committee. International
organizations, governmental and non-governmental, in liaison with ISO, also take part in the work.
ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of
electrotechnical standardization.
The procedures used to develop this document and those intended for its further maintenance are
described in the ISO/IEC Directives, Part 1. In particular the different approval criteria needed for the
different types of ISO documents should be noted. This document was drafted in accordance with the
editorial rules of the ISO/IEC Directives, Part 2 (see www.iso.org/directives).
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of
any patent rights identified during the development of the document will be in the Introduction and/or
on the ISO list of patent declarations received (see www.iso.org/patents).
Any trade name used in this document is information given for the convenience of users and does not
constitute an endorsement.
For an explanation on the meaning of ISO specific terms and expressions related to conformity assessment,
as well as information about ISO's adherence to the World Trade Organization (WTO) principles in the
Technical Barriers to Trade (TBT) see the following URL: www.iso.org/iso/foreword.html.
The committee responsible for this document is ISO/XXX
This second/third/. edition cancels and replaces the first/second/. edition (), [clause(s) / subclause(s)
/ table(s) / figure(s) / annex(es)] of which [has / have] been technically revised.
This document was prepared by Technical Committee ISO/TC 190, Soil quality, Subcommittee SC 4,
Biological methods.
This second edition cancels and replaces the first edition (ISO 23611-1:2006), which has been technically
revised. The main changes are:
— the addition of examples of earthworm monitoring programmes (including presentation of their
results) as an informative annex.
A list of all parts in the ISO 23611 series can be found on the ISO website.
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Introduction
This document has been drawn up since there is a growing need for the standardization of terrestrial
zoological field methods. Such methods, mainly covering the sampling, extraction and handling of soil
invertebrates, are needed for the following purposes:
[36][25] [33] [4][27]
— biological classification of soils including soil quality assessment (e.g. References , , );
[34] [15] [30] [4]
— terrestrial bioindication and long-term monitoring (e.g. References , , , , );
[18] [26][28]
— evaluation of the effects of chemicals on soil animals (References , ).
Data for these purposes are gained by standardized methods since they can form the basis for far-
reaching decisions (e.g. whether a given site should be remediated or not). In fact, the lack of such
standardized methods is one of the most important reasons why biological classification concepts in
terrestrial (i.e. soil) habitats have so far been relatively rarely used in comparison to aquatic sites.
Originally, the methods described here were developed for taxonomical and ecological studies,
investigating the role of enchytraeids in various soil ecosystems. These animals without doubt belong to
[[7]]
the most important soil invertebrates in temperate regions (mainly in acidic soils ). Their influence
[[17]], [23]
on soil functions like litter decomposition and nutrient cycling is well-known . Due to their
number which is often very high (and to their population biomass), they are also important in many
[[6]]
terrestrial food-webs . Some species have unintentionally been distributed by man in many soils of
the world.
Since it is neither possible nor useful to standardize methods for all soil organisms, the most important
ones have been selected. Microbiological parameters are already covered by existing ISO Standards
(e.g. , ISO 14240-1, ISO 14240-2), ISO 17601, ISO 29843-1, and ISO 29843-2.
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oSIST prEN ISO 23611-3:2018
DRAFT INTERNATIONAL STANDARD ISO/DIS 23611-3:2018(E)
Soil quality — Sampling of soil invertebrates —
Part 3:
Sampling and extraction of enchytraeids
1 Scope
This document specifies a method for sampling, handling and extracting enchytraeids from terrestrial
field soils as a prerequisite for using these animals as bioindicators (e.g. to assess the quality of a soil as
a habitat for organisms).
Basic information on the ecology of enchytraeids and their use as bioindicators in the terrestrial
environment are included in the Bibliography.
This document applies to all terrestrial biotopes in which enchytraeids occur. The sampling design
of field studies in general is specified in ISO 18400-101. These details can vary according to the
climatic/regional conditions of the site to be sampled and an overview on the determination of effects
[6]
of pollutants on enchytraeids in field situations is given in Reference .
Methods for some other soil organism groups such as earthworms or arthropods are specified in
ISO 23611-1, ISO 23611-2, ISO 23611-4 and ISO 23611-5.
This document is not applicable for semi-terrestrial (i.e. living in or close to the pure water) soils and
might be difficult to use under extreme climatic or geographical conditions (e.g. in high mountains).
When sampling soil invertebrates, it is highly recommendable to characterize the site (e.g. concerning
soil properties, climate and land use). However, such a characterization is not covered by this part
of ISO 23611. ISO 10390, ISO 10694, ISO 11272, ISO 11274, ISO 11277, ISO 11461 and ISO 11465 are
more suitable for measuring pH, particle size distribution, C/N ratio, organic carbon content and water
holding capacity.
2 Terms and definitions
For the purposes of this document, the following terms and definitions apply.
ISO and IEC maintain terminological databases for use in standardization at the following addresses:
— IEC Electropedia: available at http://www.electropedia.org/
— ISO Online browsing platform: available at http://www.iso.org/obp
2.1
enchytraeids
small soil-inhabiting worms (a few millimetres to several centimetres in length) belonging to the
family Enchytraeidae, class Oligochaeta, superclass Clitellata, phylum Annelida) (common name:
[35]
potworms )
EXAMPLE Species of the genera Enchytraeus, Fridericia or Cognettia.
3 Principle
Enchytraeids at a certain site are sampled from the soil by using a split soil corer (diameter usually
3 cm to 6 cm) (5.1). After sampling, the soil samples containing the enchytraeids are transported to
the laboratory. Then the enchytraeids are extracted from soil by means of a wet extraction method.
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[[13]], [20], [24]
(This approach has been well-known for a long time .) After extraction, the enchytraeids
are identified alive and, if required, preserved in such a way that they can be stored in a collection
indefinitely (e.g. for taxonomical purposes).
The determination of the biomass of enchytraeids is also described in this part of ISO 23611. The
abundance and biomass values can be recalculated to the area of the soil corer or, more rarely, volume
parameters.
NOTE 1 The sampling of enchytraeids is often included in much broader monitoring programmes which try to
cover the whole soil fauna or parts of it (e.g. the mesofauna). The design of such programmes is not included in
[3]
this part of ISO 23611 (but see e.g .).
NOTE 2 Some hints for the taxonomy of enchytraeids are given in Annex A.
4 Reagents
4.1 Tap water (without toxic properties, e.g. due to copper contamination).
4.2 Ethanol, 70 % (volume fraction).
4.3 Bengalred, 4,5,6,7-Tetrachloro-2',4',5',7'-tetraiodofluorescein formulated as a staining agent.
4.4 Bouin’s fixative, buffered solution of formaldehyde, acetic acid and picric acid.
4.5 Paracarmin, staining agent, prepared as a mixture of carmine acid, aluminium chloride and
calcium chloride solved in ethanol.
4.6 Canada-balm, natural yellowish viscous fluid containing 13 % to 14 % (volume fraction) Canadin
acid (C H O ), 48 % to 50 % (volume fraction) α- and β-Canadinol acid (C H O ) and 5 % (volume
20 38 2 19 30 2
fraction) Canadoesen (C H O).
21 40
5 Apparatus
5.1 Split soil corer (e.g. diameter 3 cm to 6 cm; extracted core length 10 cm to 30 cm); length in total
variable (depending whether or not a handle is used) and a plastic or wooden impact absorbing hammer.
5.2 Plastic bags (e.g. 1-l freezer bags); general store.
5.3 Temperature recorder or a minimum/maximum-thermometer.
5.4 Plastic bowls, diameter approximately 20 cm, height approximately 10 cm; general store.
5.5 Plastic sieves, diameter approximately 15 cm, mesh width approximately 0,5 mm; general store.
5.6 60-W bulbs as a heating device; general store.
5.7 Glassware, e.g. petri dishes (square format) with a size of 8 cm × 8 cm or small glass vessels
(e.g. 50 ml).
5.8 Sharp, large knife.
5.9 Refrigerator.
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5.10 Dissecting microscope with low magnification (10 to 40 times).
5.11 Microscope with high magnification (60 to 400 times) and equipped with an interference
lighting device.
5.12 Spring steel pincers (flat).
5.13 Transfer tool: Pasteur pipette, soft steel forceps or a hooked needle.
6 Procedure
6.1 Soil sampling
The soil samples to be used for the investigation of the enchytraeid community are taken destructively
by means of a split soil corer (5.1). The corer is carefully pressed into the soil. The depth depends on the
land use and soil type, but usually varies between 10 cm (e.g. forests) and up to 30 cm (e.g. crop sites),
i.e. those layers in which the bulk of the enchytraeids are living. In rare cases, e.g. if thick roots are
present, a plastic or wooden impact absorbing hammer can be used to take the samples. After removing
the soil corer, its valve is opened and the soil core is carefully taken out by hand. The core is divided into
cylinders (e.g. 3 cm to 4 cm height) with a knife (5.8). These soil cylinders may be stored in small plastic
bags (5.2) in a refrigerator (5.9) at approximately 4 °C to 6 °C for a period of preferably not longer than
[[9]]
one to two weeks (storage should not exceed one month in any case ). The soil corer is cleaned with
water afterwards.
6.2 Extraction of the enchytraeids
In principle, the extraction of the worms from the soil is caused by their active movement through the
water-saturated sample into the water-filled bowl (5.4).
The extraction should commence as soon as possible after the sampling (see 6.1). The bowls (5.4) are
carefully filled up with tap water (4.1) until the empty sieves (5.5) are completely covered by the water.
The samples (i.e. soil cylinders) are put in the sieves, and are, if necessary (e.g. in cases of heavy loam
soils), carefully broken apart by hand (see Figure 1). The bottom of the sieves should not reach the
bottom of the bowls. To ensure an extraction efficiency of Enchytraeidae from the samples of more
than 90 %, the extraction of soil should last for 2 d to 7 d and of litter for 0,5 d to 2 d at (12 ± 2) °C
(water temperature). The duration depends mainly on the organic content of the sample. These times
can be modified according to organizational requirements and the number of individuals in a sample.
However, the worms quickly die if an oxygen deficiency occurs. In order to avoid this problem, the water
should be changed after 18-24 h, and again after 48 h (if extraction period exceeds 2 d). An acceleration
of the extraction using a heat source [e.g. a 60-W bulb (5.6)] placed above the sample can be helpful, but
should be carefully used (i.e. slow temperature increase over at least 3 h), since otherwise — species-
specifically — many animals, especially juveniles and fragmentation stages, remain in the soil (see
Annex B).
NOTE 1 In order to reduce the amount of debris at the bottom of the extraction bowls, a fine wiping cloth
[[31]]
(mesh size 0,5 mm) can be put in the sieve before the soil sample is put in .
At the end of the extraction procedure, the sieves are removed, the soil is discarded and disposed
according to local waste regulations. The water is slowly and carefully decanted from the bowl. The
finest fraction of soil at the bottom of the bowls should not be disturbed (see Figure 2). A small amount
of water (up to a height of 5 mm to 10 mm) shall remain in the bowls. Subsequently, the finest fraction
of soil is suspended in the overlying water, placed in a petri dish (5.7) and briefly stored until soil
particles have settled and the water becomes clear. Since the whitish worms are heavier than water,
but are rarely able to hide themselves in the narrow soil layer, they can easily be collected out of the
petri dish under a dissecting microscope (5.10). For this transfer, a soft steel forceps, a Pasteur pipette,
soft steel forceps or a hooked needle (5.13) can be used, but in any case damaging of the worms shall be
avoided. The most convenient way of counting the total number is to divide the surface of the petri dish
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in parallel rows which are checked one after another. Due to their white colour, the worms are clearly
visible against the usually brownish soil particles. The animals are transferred to small plastic or glass
vessels (e.g. 20 ml).
The number of samples which can be extracted simultaneously is theoretically unlimited. However, due
to the size of the water bowls, space limitations can occur. Since they (i.e. at least the water) shall be
cooled, usually only up to 40 to 50 samples can be processed at one time. These limitations can be
overcome by carrying out the procedure in a cool room, e.g. in a cellar.
NOTE 2 In rare cases, the enchytraeids can be confused with Diptera larvae (which very often possess
brownish or black head capsules) or nematodes (non-peristaltic movement; usually smaller and faster moving
than oligochaetes). Additionally, fungal hyphae or fine root material can be mistaken for enchytraeids, since they
can possess the same length and colour. However, they always lack the segmentation of oligochaete worms.
Figure 1 — Extraction bowl with soil sample Figure 2 — Sediment layer
(including enchytraeids)
6.3 Microscopic identification
The microscopic identification should be done as soon as possible, because the animals die in water
after some days, even if stored in a refrigerator (5.9). A soft steel forceps, a Pasteur pipette, soft steel
forceps or a hooked needle (5.13) can be used carefully to transfer the animals with a drop of water to
a slide. If the worms are moving too fast on the slide, they can be anaesthetised with CO (e.g. by using a
2
drop of mineral water with gas, but it should be used with care, otherwise the worms are killed).
NOTE Identification of the enchytraeids is difficult. Therefore, in many cases just the number of animals
[19] [32]
is determined. Otherwise the key of Reference and is used as well as later publications (see Annex A). A
compromise can be the use of a site-specific key since usually only 3 to 25 species occur at any given site (in
this case, often worms fixed in ethanol can be identified to the species level). An overview over the information
[11]
(parameters, drawings, etc.) needed for the identification of a certain species is given in Reference .
In the case of high individual numbers (> 100) a sample partitioning can be carried out. Partitioning
must guaranty that all species (big, small etc.) are parted to a known degree. Therefore, this process
must be described in detail.
6.4 Preservation of Enchytraeidae
Enchytraeidae can be preserved for further investigations (e.g. species descriptions) in 70 % (volume
fraction) ethanol (4.2). However, the preservation is accompanied by a loss of visible morphological
details. Animals difficult to identify or those selected as reference specimen may also be identified
after a fixing in Bouin (4.4) respective colouring in Paracarmin (4.5) and storing in Canada-balm (4.6)
(which can be relatively elaborate). For species identification, the use of an microscope (5.11) equipped
with differential interference contrast (DIC) is strongly recommended.
6.5 Validity of the extraction process
Extraction efficiency can be checked by fixing soil samples with ethanol (96 %), which are taken in
parallel to other field samples. The soil is spread in a thin layer on the bottom of a flat plastic vessel
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1)
(e.g. Bellaplast 16 cm × 11 cm) and then the ethanol is added. Afterwards, some drops of Bengalred
(4.3) is applied to the ethanol. After one day, the brightly red coloured worms can easily be counted.
However, this procedure is only necessary when using samples from an unknown site for the first time.
Additionally, this check shall be done with six to eight replicates since the variability of enchytraeid
numbers can be quite high.
6.6 Determination of biomass
For an estimation of the ecological role (e.g. in the soil food-web) of enchytraeids at a certain site, the
determination of their biomass is necessary. Since direct weighting is difficult due to the low individual
mass of most species, the potential corruption by changing gut content and especially the quick
desiccation, the biomass may also be indirectly estimated by the following methods:
[[1]], [2]
— creation of specific species calibration curves to the ratio of length and mass , then
measurement of the length of the animals in a sample;
— automatic calculation of the mass by computer-assisted measuring of the length-mass-ratio
of embedded individuals and following computation with the largely constant density of
[[22]]
enchytraeids .
7 Data assessment
The following measurement endpoints may be used for the bio-classification of a soil, including bio-
indication or bio-monitoring (e.g. anthropogenic stress like chemicals or land use changes):
— abundance (number of individuals per area);
— biomass (fresh or dry mass of the population per area);
— number of species or other taxonomically or ecologically defined groups;
— dominance ratio (in percentage of the population);
— age structure of the population (e.g. adult/juvenile ratio), either all species together or individual
species;
— distribution in the soil (e.g. the vertical distribution within the soil core);
— morphological, physiological or biochemical alterations in individuals (e.g. open wounds).
Usually, the total number of worms is counted and expressed as individuals per sample. This number is
then multiplied by a factor determined by the diameter of the soil corer (5.1) in order to get the number
of worms per square meter. Additionally, the age structure (juveniles and adults differentiated by the
presence of a clitellum) and the vertical distribution can be determined with the help of the dissecting
microscope (5.10) (i.e. no species determination is done). For the determination of all other endpoints, a
detailed microscopic examination is necessary, since then the species have to be identified.
8 Test report
The test report shall contain a summary of the results obtained along with the methods and variables
used during the study. It shall provide the following information:
a) a reference to this document, i.e. ISO 23611-3;
b) a full description of the study design and procedures;
c) characterization of the test site (especially soil properties);

1) Bellaplast is an example of a suitable product available commercially. This information is given for the
convenience of users of this International Standard and does not constitute an endorsement by ISO of this product.
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d) sampling method;
e) description of the sampling conditions, including date and duration of sampling in the field and
climatic parameters like air temperature;
f) number of worms caught;
g) details of fixation and preservation of the biological material;
2
h) recalculated values to 1 m or another standard size, if necessary;
i) all information, including all measured raw data and all problems which might have occurred,
developed during the study;
j) discussion of the results.
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Annex A
(informative)

Relevant publications for the identification of enchytraeid species
Abrahamsen, G., 1969: Enchytraeus norvegicus sp.nov.: A new species of Enchyraeidae (Oligochaeta)
from Norway. Nytt magasin zoologi, 17, pp. 161-164
Dozsa-Farkas, K., 1992a: List of Enchytraeid Synonyma. Newsletter on Enchytraeidae, 3, pp. 16-46
Dozsa-Farkas, K., 1992b: List of Parameters useful for the Identification of Enchytraeids. Newsletter on
Enchytraeidae, 3, pp. 49-50
Graefe, U., 1989: Systematische Untersuchungen an der Gattung Achaeta (Enchytraeidae Clitellata).
2. Beschreibung von vier neuen Arten. Mitteilungen aus dem Hamburgischen Zoologischen Museum und
Institut, , 86, pp. 127-131
Nielsen, C.O. and Christensen, B., 1959: The Enchytraeidae, critical revision and taxonomy of
E
...