Eghbalinejad et al. 
Environmental Sciences Europe           (2024) 36:51  
https://doi.org/10.1186/s12302-024-00879-9

RESEARCH

Nano-enabled pesticides: a comprehensive 
toxicity assessment of tebuconazole 
nanoformulations with nematodes at single 
species and community level
Mahleh Eghbalinejad1, Jakub Hofman1, Jan Kotouček2, Renato Grillo3, Zuzana Hochmanová Bílková1, 
Nicola Reiff4 and Sebastian Höss4* 

Abstract 

There is an increasing imperative to explore safer alternatives for pesticides due to their indiscriminate use and con-
sequential health impacts on the environment and humans. Nanoformulations of pesticides are being developed 
as potential alternatives due to their beneficial properties, including enhanced solubility, targeted delivery to the site 
of action, improved stability and efficacy and reduced non-target effects. Nevertheless, a comprehensive assessment 
is necessary for these emerging nanopesticides compared to existing formulations, aiming to ascertain whether their 
"nano" characteristics exacerbate toxicity for non-target organisms. This study investigated the toxicity of tebucona-
zole (TBZ) in different formulations, including nanoformulations (poly-ε-caprolactone [PCL] and nanostructured lipid 
carrier [NLC] loaded with TBZ), as well as a commercial formulation, on the reproduction of the nematode Caenorhab-
ditis elegans in both aqueous and soil matrices. Additionally, the impact of the correspondent nanocarriers with-
out TBZ on C. elegans was examined. In water, TBZ in the form of nano and commercial formulations exhibited higher 
toxicity on the nematodes’ reproduction than the TBZ (a.s.) attributable to higher freely dissolved concentrations 
of TBZ, which resulted in a toxicity order, ranging from the most to the least toxic as follows: NLC-TBZ > PCL-TBZ > com-
mercial formulation > TBZ (a.s.). For NLC-TBZ, the excess toxicity could be clearly explained by combined toxicity 
of TBZ (a.s.) and nanocarriers, with the effect addition of the separate single compounds matching the observed 
effects of the nanoformulation. For PCL-TBZ, effects were stronger than expected from the effect addition of TBZ (a.s.) 
and PCL nanocarriers, potentially due to enhanced bioavailability of encapsulated TBZ in the gut of the nematodes. In 
soil, NLC with and without loaded TBZ showed higher toxicity than other tested compounds, while PCL nanocarriers 
without TBZ did not exhibit negative effects on the reproduction of C. elegans. Microcosm experiment, where long-
term effects on native soil nematode fauna were tested, confirmed that TBZ-nanoformulations act via combined 
toxic effects of TBZ and nanocarriers. These findings contribute valuable insights to understanding nanopesticides’ 
ecotoxicity and underscore the need for harmonized regulatory assessments to evaluate these novel formulations 
adequately.

Keywords Combined toxicity, Nanotoxicity, Caenorhabditis elegans, Microcosm, Poly-ε-caprolactone, Tripalmitin

Open Access

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Environmental Sciences Europe 

*Correspondence:
Sebastian Höss
hoess@ecossa.de
Full list of author information is available at the end of the article

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Page 2 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51 

Introduction
Pesticides have played a significant role in enhancing 
agricultural yields over the last decades, primarily by 
safeguarding seeds and crops against countless pests and 
diseases [1–3]. However, pesticides, by excessive appli-
cation, have adverse environmental and human impacts 
through contamination of air, water, and soil, result-
ing in threats to biodiversity and sustainability [3–5]. In 
this regard, the European Commission recently adopted 
a strategy for sustainable pesticide use and aims to 
decrease the use and risks of chemical pesticides by 50% 
by 2030 [6]. Consequently, there is an urgent need for 
sustainable agricultural technologies. Nanotechnology 
has gained increasing attention in the field of agrochemi-
cals over the current decade, with the potential to change 
the industry significantly [7, 8]. Nano-enabled pesticides 
(called nanopesticides), incorporating nanomaterials, 
enhance the effectiveness and reduce the environmental 
impacts of active substances (a.s.) through their nano-
scale features. These innovations offer targeted delivery, 
improved efficacy and address the limitations of con-
ventional pesticides, such as low solubility and rapid 
degradation [7, 9, 10]. This advancement represents a sig-
nificant shift towards more efficient and environmentally 
friendly agricultural practices.

Different materials, such as polymers and lipids, 
are used to synthesize nanopesticides, with poly-ε-
caprolactone (PCL) and nanostructured lipid carriers 
(NLCs) being notable examples due to their biodegrada-
bility, biocompatibility [11–13]. PCL, widely used in drug 
delivery [14, 15], has shown versatile degradation rates 
[16, 17]. It has been successfully utilized to make nan-
opesticides [13, 18–20], while NLCs, originally used in 
cosmetics and pharmaceuticals [21, 22], offer advantages 
in pesticide delivery [19, 20]. These nanocarriers (NCs) 
reduce the need for a.s., minimize environmental losses, 
and lower the ecological footprint, showcasing their 
potential to enhance agricultural sustainability [23, 24].

Nanopesticides, while promising for agriculture, 
require careful evaluation due to limited data on their 
environmental and toxicological impacts [25–27]. Their 
high surface-to-volume ratios and persistence [28] raise 
concerns about their transformation in the environment, 
potentially altering their fate and effects [7, 29]. Fur-
thermore, their ability to enhance water solubility and 
bioavailability while protecting a.s. could extend environ-
mental exposure, posing risks to non-target organisms 
[30, 31]. Therefore, conducting thorough research and 
risk assessments is essential to ensure that using nanope-
sticides in agriculture is safe and sustainable in the short 
and long term, particularly for non-target organisms.

The limited data on polymeric and lipid-based nanope-
sticides’ effect on nematodes [32] stresses the pressing 

need to address this knowledge deficit in different expo-
sure routes, such as water and soil for both short- and 
long-term effects. Nematodes are the most abundant and 
species-rich metazoans in soil and are essential in food 
webs [33, 34]. Moreover, nematodes are excellent indica-
tors of chemical stress in soils and aquatic environments 
[35]. The nematode Caenorhabditis elegans, naturally 
occurring in microbe-rich habitats such as decaying plant 
material [36], is a standard test organism with lethal and 
sublethal toxicity endpoints to assess chemical toxic-
ity in different environment compartments, such as soil, 
sediments, and water [37, 38]. This invertebrate species 
is used as a model organism due to its advantages, which 
fill the gap between in vitro and in vivo tests in addition 
to the simplicity, accuracy, repeatability, and low cost of 
the experiments [35, 39]. From an ecological perspective, 
chronic tests with sublethal parameter, such as repro-
duction, are preferred to acute tests that assess mortality 
[40, 41]. Moreover, laboratory multispecies test systems 
(small-scale microcosms) with native soil nematodes [42, 
43] have been shown to be more sensitive to pesticide 
stress than single-species tests [44, 45].

Tebuconazole (TBZ) is an active substance in triazole 
fungicides widely used in agriculture to treat fungal dis-
eases that act by inhibiting sterol biosynthesis in fungi 
(demethylation inhibitor) [46, 47]. It is the 8th most 
used fungicide in the European Union, with 1230 tonnes 
annually, a 1.1% share in fungicides used in the European 
Union [48]. It has low water solubility (36 mg/L at 25 °C) 
and 2.5–5 pKa) [49]. TBZ is recognized as a highly haz-
ardous substance with broad-spectrum toxicity affecting 
cold-water, warm-water, and estuarine/marine organisms 
[50]. Its adverse effects include reproductive toxicity, liver 
tumors, metabolic abnormalities, and endocrine disrup-
tion [51–53]. Additionally, TBZ poses risks to birds and 
mammals [54]. Moreover, it is on the EU list of candi-
dates for substitution [55, 56]. Therefore, the significant 
risks associated with TBZ demand enhanced application 
practices and the development of safer pest control alter-
natives to support safe and sustainable agriculture.

This study aimed to evaluate the reproductive toxicity 
of Caenorhabditis elegans exposed to two nanoformula-
tions of tebuconazole (TBZ)—poly-ε-caprolactone (PCL-
TBZ) and nanostructured lipid carriers (NLC-TBZ)—in 
aqueous and soil matrices. Our focus was to assess both 
the chemical toxicity of TBZ and the potential physical 
toxicity of the nanocarriers. We examined the effects of 
PCL-TBZ and NLC-TBZ, TBZ (a.s.), and nanocarriers 
without TBZ (NCs), as well as a commercially available 
TBZ formulation (FOLICUR®). The analysis of freely dis-
solved concentrations (only water exposure) allowed for 
comparing effects based on the bioavailable concentra-
tion of TBZ in all formulations.



Page 3 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51  

Several hypotheses guided our research: (1) TBZ nano-
formulations and commercial formulation are more toxic 
than TBZ (a.s.) due to additional formulation effects; 
(2) the toxicity of nanoformulations can be predicted by 
mixture toxicity models based on independent action; (3) 
combined toxic effects of TBZ and nanocarriers are also 
present in soil; (4) exposure to various TBZ formulations 
will alter the taxonomic composition of indigenous soil 
nematodes. This comprehensive approach aims to eluci-
date the environmental impact of TBZ nanoformulations 
and guide safer agricultural practices.

Materials and methods
Reagents and chemicals
The analytical standards of tebuconazole with a purity 
of > 98.0% (TBZ), poly-ε-caprolactone (PCL), polysorb-
ate 80 (Tween 80), sorbitol monostearate surfactant 
(Span 60), polyvinyl alcohol (PVA), glycerol tripalmitate, 
triglycerides of capric and caprylic acids (in the form 
of Myritol 318), silica suspension (Ludox TM50®) and 
HPLC-grade acetonitrile (ACN) were purchased from 
Sigma Aldrich (Czech Republic). Acetone (≥ 99.5%) was 
purchased from Carl Roth GmbH, Karlsruhe, Germany. 
FOLICUR® (suspoemulsion; Bayer, 25 g TBZ/L) was pur-
chased from a local supplier. Deionized water  (dH2O) 
was provided from a waters ultra-pure water system. The 
QuEChERS Extract bags (Agilent 5982-7650) were pur-
chased from Agilent Technologies, USA. All other chem-
icals and solvents were analytical grade. Lufa St. 2.2 soil 
was provided by Landwirtschaftliche Forschungs- und 
Untersuchungsanstalt Speyer, Germany.

The preparation of nanoformulations and nanocarriers
The TBZ nanoformulations (NFs) were prepared fol-
lowing the methodologies outlined by Grillo et  al. [13] 
for PCL-TBZ and Oliveira et  al. [57] for NLC-TBZ (see 
Additional file 1: S1). The nanocarriers (NCs) were pre-
pared using the same method, with the exception that 
TBZ was not added to the suspension. Physical and 
chemical properties of these NFs were rigorously ana-
lyzed, including hydrodynamic diameter, polydispersity 
index (PI), zeta (ζ) potential, and encapsulation efficiency 
of TBZ, using multi-angled dynamic light scattering 
technique (MADLS®, Zetasizer Ultra (Malvern Pana-
lytical Ltd, UK). The ζ-potential measurements were per-
formed on Zetasizer Ultra (Malvern Panalytical Ltd, UK) 
using the Electrophoretic Light Scattering (ELS) method. 
For the morphology of nanoparticles, Transmission Elec-
tron Microscopy (Philips 208 S Morgagni (FEI, Czech 
Republic)) was used. The total concentration of TBZ 
loaded in PCL-TBZ and NLC-TBZ and released TBZ 
from nanocarriers were measured by high-performance 
liquid chromatography–mass spectrometry (HPLC–MS/

MS). Details are provided in Additional file 1: S1–S4. The 
detail on HPLC–MS/MS is provided by Lopez-Cabeza 
et al. [20].

Preparation of stock solutions and spiking procedure
An overview of all experiments with information on the 
respective exposure conditions can be found in Addi-
tional file 1: Table S1.

TBZ (a.s.) in water and soil
To prepare the chemical solutions of TBZ (a.s.) for the 
experiments in water (Exp 1) and soil (Exp 2), stock solu-
tions were prepared in acetone. Based on the results of 
range-finding tests, a concentration series with ten con-
centrations (for water tests), six and three concentrations 
(for soil tests) were prepared. For water tests, acetone 
stock solutions were prepared in 200-fold concentra-
tions to achieve a final solvent concentration of 0.5% in 
the exposure medium used within the test vessels as the 
concentration of acetone was as follows for the given 
tested concentration from lowest to the highest tested 
concentration: 1.04, 1.56, 2.34, 3.51, 5.27, 7.90, 11.9, 
17.8, 26.7 and 40.0  mg/mL acetone. Spiking 3.98  mL of 
test medium with 20 µl of acetone stock solution (20 µl 
of acetone for the solvent control), aqueous, double-con-
centrated stock solutions, have been achieved. After 1:1 
dilution with the food medium (bacterial suspension), 
the final test concentrations were achieved: 0 (solvent 
control), 5.2, 7.8, 11.7, 17.6, 26.3, 39.5, 59.3, 88.9, 133, 
and 200  mg/L. Despite the limited water solubility of 
TBZ (36 mg/L [49]), higher nominal concentrations were 
tested to account for potential higher exposure concen-
trations due to bacterial-bound TBZ.

For soil tests (Exp 2; see Additional file 1: Table S1), the 
following acetone stock solutions were prepared for TBZ 
(a.s.): 0.10, 0.17, 0.29, 0.49, 0.84, 1.42 (test 1) and 0.38, 
0.75, 1.50 (test 2) mg/mL acetone. Spiking 20 g dry soil 
(Lufa standard soil St.2.2; sandy loam; 8.3% clay, 14.5% 
silt, 77.2% sand, 1.71% TOC, pH: 5.6, WHCmax: 44.8%) 
with 10 mL of acetone (acetone stock solution and pure 
acetone (solvent control), following final soil test concen-
trations have been achieved: 0 (solvent control), 60, 100, 
173, 295, 501 and 852 (test 1) and 0 (solvent control), 188, 
355 and 750 (test 2) mg/kg dry soil. After the complete 
evaporation of acetone, solvent concentrations in the soil 
were negligible (according to our previous test).

Based on the results of tests with TBZ (a.s.), concen-
tration series for FOLICUR® (six nominal test concentra-
tions: 5.2, 11.7, 26.3, 59.3, 133 and 200 mg/L), PCL-TBZ 
and NLC-TBZ (eight nominal test concentrations: 5.2, 
7.8, 11.7, 17.6, 26.3, 38.5, 88.9, and 200 mg/L) were set up. 
To achieve maximally released TBZ (a.s.) in the medium 
from the TBZ NFs, the prepared stock solutions of all 



Page 4 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51 

compounds were slightly shaken in an incubator for 48 h 
at 20  °C. The concentrated solutions were mixed with 
food suspension (1:1) and kept in the incubator for 2 h at 
20 °C to allow for equilibrium partitioning between water 
and bacteria. After that, the prepared solutions were dis-
tributed into final glass vials for the experiments (n = 4).

For test 2, the soil was also spiked with FOLICUR®, 
PCL-TBZ and NCL-TBZ, and the respective NCs. As for 
TBZ (a.s.), nominal concentrations were 188, 355, and 
750 (test 2) mg/kg dry soil. Here, dry soil was spiked with 
aqueous stock solutions and dried till complete evapora-
tion of the water.

The NCs` solutions (without TBZ) were simultaneously 
prepared based on the equivalent volume used for their 
corresponding NFs (with TBZ), which resulted in vary-
ing number of particles and concentrations of other com-
pounds (used in the preparation of nanoformulations) 
across treatments. However, due to the DLS limitations, 
the particle concentration used for mixture analysis and 
soil effect analysis (Figs. 1, 2) are calculated based on the 
measured particle concentration in stock suspensions 
(Additional file 1: Table S2).

Preparation of food medium
Bacterial suspensions (Escherichia coli. strain OP50) were 
prepared as food for C. elegans following standard pro-
cedures ISO 10872 [38]. Briefly, bacteria were grown in 
Luria–Bertani (LB) medium, centrifuged, and the pellet 
was washed and resuspended in M9-medium to achieve 
densities suitable for water and soil tests. The detailed 
preparation process, including growth conditions, cen-
trifugation, compositions of LB and M9 media, and 
resuspension, is provided in Additional file 1: S6.

Chemical analysis
Water
Chemical analyses were conducted for all tested com-
pounds including TBZ (a.s.), FOLICUR®, PCL-TBZ, 
and NLC-TBZ two times. Firstly, after incubating the 
solutions for 48 h, the chemical analysis was done as an 
aliquot of the solution was taken to measure TBZ con-
centration by HPLC–MS–MS (n = 3). The last chemical 
analysis was at the end of the tests, after 146 h. PCL-TBZ 
and NLC-TBZ were analyzed for both total concentra-
tion (Ctot) and released concentration of TBZ (freely 
dissolved TBZ in media which is not associated with 
nanocarriers (Cfree)). The method for chemical analysis 
was the same used for the method explained in the chem-
ical characterization of nanoformulations section (Addi-
tional file 1: S4). The chemical analysis of water samples 
was conducted separately from the toxicity tests due to 
infrastructure limitations. However, it is important to 

note that these analyses were meticulously performed to 
reflect the conditions of the toxicity tests accurately.

Soil (toxicity test and microcosm test)
Soil samples were analyzed for the total content of TBZ 
using the QuEChERS extraction method. This method 
has been used in different studies, demonstrating it is a 
fast, easy, and effective method to remove different pes-
ticides from environmental samples using salt [31, 58, 
59]. The extraction procedure was performed as follows: 
all samples were lyophilized for 48 h. Then, 0.1 g dw of 
spiked soil was shaken with 5  mL deionized water and 
10  mL acetonitrile with metolachlor added as a surro-
gate standard (10  µL of 1000  µg/mL concentration per 
sample). Samples were further amended with 6.5  g of 
QuEChERS Extract bag (4 g MgSO4, 1 g NaCl, 0.5 g diso-
dium citrate sesquihydrate, 1 g Na citrate). The mixture 
was shaken by a shaker (SPEX®SamplePrep) for 1  min 
and then centrifuged for 5  min/3000  rpm/ − 5  °C. Then 
acetonitrile layer (top layer) was transferred to clean 
20 mL glass vials. The extract was later diluted ten times 
with 50% acetonitrile to align with the HPLC–MS/MS 
detection range of 1–100 ng/mL. An aliquot of 1 mL of 
acetonitrile was taken for analysis using HPLC–MS/MS. 
Details on the analysis are provided by López-Cabeza 
et al. [20].

Toxicity test with Caenorhabditis elegans
The toxicity test with C. elegans was carried out accord-
ing to standard procedures (ISO 10872) [38]. To cultivate 
C. elegans, nematode growth medium (NGM) was used, 
which is described in detail in Additional file  1: S5. All 
agar plates were seeded with OP50, an uracil-requiring 
mutant of Escherichia coli that prevents overgrowth of 
the bacterial lawn [60] following standard procedures 
[61]. Stock culture plates containing dauer larvae of C. 
elegans were then stored at 20 °C in the dark. Three days 
before the start of a test, small pieces of a stock plate 
with dauer larvae were transferred to NGM plates with 
fresh bacterial lawn and incubated at 20  °C, resulting in 
freshly hatched juveniles (J1) that could be used for toxic-
ity testing.

Nematodes were exposed to the test items in 10  mL 
glass vials. Six C. elegans (J1) were introduced in each 
replicate vial containing either spiked aqueous medium 
or soil (moistened to 80%  WHCmax). The vials were kept 
in the incubator for 96  h at 20  °C. The experiment was 
stopped by heat-killing the nematodes in an oven (18–
20 min at 80 °C) after adding Bengal rose solution to stain 
the nematode cuticle for better recovery. The vials were 
kept in the fridge till further analysis.

For soil tests, nematodes had to be separated from soil 
particles before reproduction could be analyzed. This was 



Page 5 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51  

done by density separation using a flotation/centrifuga-
tion technique with a silica suspension (diluted with 
water to 1.13  g/mL) [38]. For water tests, this step was 
not necessary.

To measure the reproduction of C. elegans, we counted 
the number of offspring (second-generation juveniles) 
using a stereo microscope at 40-fold magnification. In 
soil experiments, the offspring were counted in a silica 
suspension after being separated from the soil. In water 
experiments, the offspring were counted directly in the 
aquatic medium. The total number of offspring was then 
divided by the number of introduced test organisms 
(n = 6), less the number of males. An effect was defined as 
inhibition of reproduction (% IR) compared to the con-
trol reproduction:

where xA, and xC are the mean values reproduction for 
sample A and control, respectively.

Microcosm test
Based on the results of the C. elegans toxicity tests, PCL-
TBZ (NF with low carrier effects) and FOLICUR® were 
selected for assessing their toxicity on a native soil nema-
tode fauna in small-scale (30  g soil) microcosms [42]. 
PCL nanocarrier (without TBZ) was tested as well. Due 
to the higher effort of the microcosm test compared to 
the single-species test, only one concentration of each 
compound was tested in four replicates in addition to 
a control treatment (only water). The test vessels were 
50 mL plastic tubes which were filled with 30 g of spiked 
soil including the native nematode fauna. Fresh soil 
(freshly sampled soil (Lufa St. 2.2).) The soil was spiked 
by mixing a dried aliquot of the Lufa soil (10% = 12 g dry 
soil) with the respective aqueous stock suspension of the 
test item (PCL-TBZ: 8.3 mL of 2 g a.s./mL; FOLICUR®; 
16.7 mL of 2.5 mg a.s./mL), drying the spiked soil aliquot 
and mixing it with 126 g of fresh soil. This resulted in a 
nominal soil concentration of 350  mg TBZ (a.s.)/kg dry 
soil. For chemical analysis at t = 0, 4 g of soil was sampled 
from each treatment and kept frozen at − 20  °C till fur-
ther analysis (see  section "Soil (toxicity test and micro-
cosm test)"). From the unspiked soil, 30  g soil was also 
sampled for nematode community analysis to identify the 
nematode genus composition at t = 0.

After an 8-week exposure period at 15  °C, micro-
cosms were processed as follows: first, 1  g of soil from 
each microcosm was collected for chemical analysis. The 
samples from the four replicates of each treatment were 
combined, resulting in 4  g per treatment, and stored at 
− 20 °C until analysis (see section "Soil (toxicity test and 
microcosm test)" for details). Secondly, the remaining 

(1)%IRA = 100−
xA

xC
× 100,

soil was mixed with a silica suspension (explained in 
section  "Toxicity test with Caenorhabditis elegans") to 
facilitate the separation of nematodes from the soil [42]. 
The mixture was centrifuged for 10  min at 800g, and 
the supernatant was filtered through a 10-µm gauze to 
remove the silica while retaining the nematodes, which 
were collected into a separate container. This flotation 
and centrifugation process was performed two times to 
ensure thorough extraction. The resulting nematode sus-
pension, a combination of all extraction steps, was fixed 
with formaldehyde (final concentration of 4%), stained 
with Bengal Rose for enhanced visibility of the nema-
todes, and stored at room temperature for subsequent 
analysis. Using a stereo microscope (40-fold magnifica-
tion), nematodes of each microcosm were counted (total 
nematode density). The first 140 individuals (124–153) 
were prepared for taxonomic identification. Nematode 
taxa were categorized into functional groups in terms of 
their feeding type [62] and life-history strategy [63] so 
that maturity indexes (MI; MI25) could be calculated to 
allow evaluation of soil health [33].

Data evaluation and statistical analysis
All the data were checked for normality and homogeneity 
in parametric analysis by GraphPad Prism 9.5.1 (Graph-
Pad Software, USA). The Kolmogorov–Smirnov test was 
applied to assess normality before conducting further 
analyses. In cases where the assumptions of normality 
and homogeneity were not met, the data underwent log 
transformation.

We calculated the mean value of the measured TBZ 
concentrations for the exposure concentration of TBZ to 
the nematodes for both total concentration and free TBZ 
concentration at the beginning and end of the toxicity 
tests. Specifically, for the aquatic tests, these measure-
ments were taken at t = 50 h and t = 146 h; for soil tests, 
at t = 0 and t = 96  h; and for microcosm studies, at t = 0 
and t = 8 weeks. Concentration–response curves were fit-
ted to data (% IR plotted versus exposure concentrations) 
using a sigmoidal logistic function (3 parameters, assum-
ing a curve plateau at 100% inhibition).

One-way ANOVA (with Dunnett post hoc tests) was 
used for testing for significant differences between 
reproduction values in TBZ or carrier treatments and 
the respective negative controls to determine the No-
Observed-Effect-Concentration (NOEC; concentration 
step below the lowest concentration that induced a sig-
nificant effect).

The  EC50 value for TBZ (a.s.) was statistically compared 
against the  EC50 values of all TBZ formulations (FOLI-
CUR®, PCL-TBZ, NLC-TBZ) with the Z-Test (Environ-
ment Canada, 2005) using Eq. 2 [64]:



Page 6 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51 

where σ represents the standard error.
Assuming independent action of TBZ and NCs, mix-

ture toxicity was modeled by effect addition and plotted 
against “Toxic units (TU) mix (=  TUcarrier +  TUTBZa.s.)” in 
order to get a dimensionless unit considering both types 
of toxic stress (for water tests).

Nematode genus composition was analyzed using mul-
tivariate statistics and ordination methods (non-metric 
multidimensional scaling [nMDS]; analysis of similarity 
[ANOSIM]) using PRIMER software (Version 6.1.5). Rel-
ative abundances of taxa were square-root transformed, 
and Bray–Curtis similarities were calculated. From this 
similarity matrix, a two-dimensional plot was generated 
so that the distance of samples is positively correlated 
with the dissimilarity in taxa composition.

Differences in univariate measures of the nematode 
community (taxa abundances, indexes) between the 
treatments and the control were statistically tested using 
one-way ANOVA (with Dunnett post hoc tests).

Results
Characterization of the nanoformulations and nanocarriers
The stock suspensions of the prepared NFs loaded with 
TBZ and the corresponding NCs (without TBZ) were 
chemically and physically characterized by measuring 
the total concentration of TBZ, hydrodynamic diameter 
(HDD), polydispersity index (PI), ζ potential, particle 
concentration and encapsulation efficiency (EE) (Addi-
tional file  1: Table  S2). Total TBZ concentrations in the 
test medium were comparable to the expected nominal 
concentrations for PCL-TBZ (2000 µg/mL was expected, 
and 1660  µg/mL was measured) but slightly lower for 
NLC-TBZ (800 µg/mL was expected and 571 µg/mL was 
measured) (Additional file 1: Table S2). Physical charac-
terization shows that PCL nanoparticles were smaller 
on average than NLC nanoparticles, with no significant 
size difference between NCs (with and without TBZ) 
(p > 0.05).

The chemical and physical characterizations of the 
stock suspensions used for the experiment in soil were 
similar to the stock suspension used for the experiment 
in water. However, the unloaded NLC was slightly dif-
ferent (Additional file  1: Table  S2). The HDD for NLC 
nanoparticles was bigger than particles in other tested 
compounds at 328 ± 6 nm. The differences were not sta-
tistically significant (p > 0.05).

The relative differences in the physical characteri-
zation of the stock suspensions used for the micro-
cosm study, the PCL, and PCL-TBZ (Additional file 1: 

(2)Z =

logEC50TBZa.s. − logEC50TBZformulation
√

σ
2
logEC50TBZa.s.+σ

2
logEC50TBZformulation

,
Table S2) were not statistically significant (p > 0.05). The 
results suggest that the presence of TBZ does not sig-
nificantly influence the stability and size properties of 
the PCL nanoparticles.

Based on the morphological characteristics of nano-
formulations (stock) depicted in Additional file 1: Fig. S1, 
a remarkable alignment between transmission electron 
microscopy (TEM) analysis and dynamic light scattering 
(DLS) results is observed, validating the reliability of our 
observations. This correlation enhances confidence in the 
documented morphological and dimensional features of 
TBZ-loaded nanoparticles. Furthermore, the combined 
use of TEM and DLS contributes to a comprehensive 
understanding of the particulate system.

In general, the NLC samples demonstrate substantial 
polydispersity, showcasing a diverse range of particle 
sizes, including both larger and relatively smaller par-
ticles, as confirmed by TEM observations (Additional 
file  1: Fig. S1). The particle size distribution analysis 
reveals a prominent fraction of larger particles in the 
NLC samples (for distribution analysis, see Additional 
file  1: Figs. S2, S3), leading to a bigger size (average 
hydrodynamic diameter) compared to the more mono-
disperse PCL. It is noteworthy that the PI for all samples 
was relatively small, indicating an optimal level of uni-
formity despite the observed polydispersity in size (Addi-
tional file 1: Table S2, Additional file 1: Figs. S2, S3).

For tests with TBZ (a.s.) and NLC-TBZ in water, the 
measured TBZ freely dissolved concentrations  (Cfree) 
at the beginning of the toxicity test (T0) were consider-
ably lower than the aimed nominal concentrations, even 
for values below the reported water solubility of TBZ 
(36 mg/L), showing 53–64% and 42–55% of the nominal 
concentrations for TBZ (a.s.) and NLC-TBZ, respectively 
(3.0–14.1  mg/L and 2.6–11.0  mg/L, respectively; Addi-
tional file 1: Table S3). For nominal concentrations above 
the water solubility, measured  Cfree expectedly showed 
only 23–56% and 12–32% of the nominal concentra-
tions for TBZ (a.s.) and NLC-TBZ, respectively (21.8–
45.4  mg/L and 12.8–24.8  mg/L, respectively; Additional 
file 1: Table S3). For tests with FOLICUR® and PCL-TBZ 
in water, the measured TBZ freely dissolved concen-
trations  (Cfree) at the beginning of the toxicity test (T0) 
corresponded well with the aimed nominal concentra-
tions below the water solubility (74–113% of the nomi-
nal concentration). For nominal concentrations above 
the water solubility, measured  Cfree expectedly showed 
only 15–71% and 11–47% of the nominal concentra-
tions for FOLICUR® and PCL-TBZ, respectively (27.5–
31.4  mg/L and 18.4–22.2  mg/L, respectively; Additional 
file  1: Table  S3). Within the test duration of 96  h, how-
ever, the  Cfree of TBZ did not change substantially in any 
of the tests in water (average absolute change: 1 ± 14.4%), 



Page 7 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51  

ensuring constant exposure concentrations for the nema-
todes (Additional file 1: Table S3).

For toxicity tests of TBZ (a.s.) and FOLICUR® in soil, 
measured total soil concentrations at the beginning 
of the test (T0) matched well the aimed nominal con-
centrations, showing 91–151% and 78–159%, respec-
tively, of the nominal concentrations (Additional file  1: 
Table S4). For toxicity tests of the TBZ nanoformulations 
in soil, measured total soil concentrations for PCL-TBZ 
and NLC-TBZ at the beginning of the test (T0) mostly 
exceeded the aimed nominal concentrations, showing 
130–226% and 126–187%, respectively, of the nominal 
concentrations (Additional file  1: Table  S4). Soil con-
centrations only slightly decreased in the course of the 
experiment (96 h; average decrease by 13. ± 17.9%). In the 
microcosm experiment, TBZ concentrations were slightly 
higher at the beginning of the experiment for FOLICUR® 
and PCL-TBZ (148 and 163% of nominal concentration; 
Additional file  1: Table  S5). However, in the course of 
the experiment (8 weeks), TBZ concentrations consider-
ably decreased for FOLICUR® (44% decrease), whereas 
the concentrations stayed constant for PCL-TBZ (6% 
decrease).

Response of C. elegans to TBZ (a.s.) and formulations 
in water and soil
Toxicity of TBZ (a.s.) and TBZ formulations in water and soil
TBZ (a.s.) showed a dose-dependent inhibitory effect on 
the reproduction of C. elegans in water and soil (Fig. 1a), 
with considerably high toxicity in water (Table 1). Repro-
duction in control and solvent control was not signifi-
cantly different, neither in water (72.8 ± 18.5 vs. 70.4 ± 9.5 
offspring/test organism for control and solvent control, 
respectively) nor in soil tests (61.1 ± 10.5 vs. 63.1 ± 21.3 
offspring/test organism for control and solvent con-
trol, respectively) (p > 0.05; one-way ANOVA). In water, 
effects did not exceed 63% inhibition at the highest con-
centration (measured  Cfree; 43 mg/L), which was already 
slightly higher than the reported water solubility of TBZ 
(36 mg/L). In soil, TBZ induced a maximum effect of 68% 
inhibition at a mean exposure concentration of 745 mg/
kg dry soil.

All three TBZ formulations (FOLICUR®, PCL-TBZ, 
and NLC-TBZ) showed clear dose-dependent toxicity 
on the reproduction of C. elegans in water, with signifi-
cantly stronger effects than could be expected from the 
measured freely dissolved concentrations of TBZ (Fig. 1b; 
Z-Test: Z > 1.96). While the no observed effect concen-
tration (NOEC) values showed to be comparable or even 
higher than observed for TBZ tested as an a.s.,  EC50 val-
ues were considerably lower for the TBZ formulations 
(1.9, 2.5, and 4.5-fold for FOLICUR®, PCL-TBZ, and 
NLC-TBZ, respectively), if based on TBZ  Cfree (Table 1). 

Moreover, at  Cfree of TBZ (a.s.) < 30  mg/L (below the 
water solubility limit), maximal effects (94–100% inhibi-
tion of reproduction) of the three formulations could be 
observed (Fig. 1b), but not for the exposure in TBZ (a.s.; 
Fig. 1a).

In soil, C. elegans showed a similar response to FOLI-
CUR® and PCL-TBZ as for TBZ (a.s.) if referring to the 
measured soil concentrations, with pronounced effects 
only occurring for TBZ soil concentrations exceeding 
the  EC50 values derived from the soil tests with TBZ (a.s.; 
Fig. 1c). NLC-TBZ, however, showed considerably higher 
toxicity, with pronounced effects already at the lowest 
tested concentration (25% of  EC50; Fig. 1c).

Effects of NCs in water
Both types of NCs used for the TBZ NFs showed dose-
dependent effects on the reproduction of C. elegans in 
the concentration range applied for NFs, while NLC 
nanocarriers exhibited considerably stronger effects 
than PCL nanocarriers (Fig.  1d). However, comparing 
the effects of NCs (without TBZ) with NCs in NFs (with 
TBZ) based on particle concentration, carriers in NFs 
still showed significantly stronger effects (Table 1; Z-Test: 
Z > 1.96).

Mixture toxicity modeling
For NLC-TBZ, observed and modeled dose–response 
curves perfectly matched, both showing an  EC50 of 
1.0 TUs, suggesting a concentration-additive mixture 
toxicity (Fig.  2). For PCL-TBZ, observed and modeled 

Table 1 EC50 and NOEC values of TBZ toxicity on C. elegans’ 
reproduction applied as active substance (TBZ a.s.) in water 
and soil, and as commercial formulation (FOLICUR®) and 
nanoformulations (PCL-TBZ and NLC-TBZ) and the respective 
nanocarriers without TBZ in water; for the TBZ NF values are 
given in both units, freely dissolved TBZ concentrations and 
carrier nanoparticle concentrations;

a Significantly different to TBZ (a.s.; water); bsignificantly different to carrier 
without TBZ (Z-Test; Z > 1.96)

Test item TBZ
(mg/L; mg/kg soil dw)

Particle 
concentration 
(particles/mL ×  109)

EC50 NOEC EC50 NOEC

TBZ (a.s.)

Water 29.7 ± 4.1  <2.7 –

Soil 711 ±  ± 12.3 501 –

FOLICUR® 16.0 ± 2.1a 5.2 –

PCL-TBZ 11.5 ± 0.6a 5.6 5.7 ± 0.06b 4.4

NLC-TBZ 6.40 ± 0.4a 2.6 8.0 ± 0.29b 4.4

PCL-carrier – 44.6 ± 4.0 8.6

NLC-carrier – 11.7 ± 0.6 6.7



Page 8 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51 

dose–response curves considerably deviated from each 
other, suggesting that the observed toxicity cannot be 
explained by the combined effects of TBZ (a.s.) and 
NCs. While with the modeled dose–response curve, 
an  EC50 of 0.94 TUs could be calculated, the dose–
response curve for the observed effects gave an  EC50 
of 0.54 TUs (Fig.  2), suggesting a synergistic effect 
and rebut the assumption that the addition of TBZ 
and carrier effects can explain the observed effect of 
PCL- TBZ. 

Microcosm study
At the beginning of the experiment, the Lufa soil showed 
a high nematode density (4472 ± 761  Ind/100  g dry soil; 
mean ± sd) and a high taxonomic diversity (22 ± 3 genera; 
Shannon–Wiener Index  (log2): 2.87 ± 0.35). The commu-
nity was clearly dominated by plant parasitic nematodes 
(Hoplolaimidae: 49 ± 10%; Coslencus: 8 ± 4%; Paratylen-
chus: 6 ± 4%; Tylenchidae: 6 ± 2%), followed by bacterial 
feeders (several taxa: 13 ± 7%), omnivorous nematodes 
(several taxa: 7 ± 3%) and fungivorous nematodes (several 

Fig. 1 Dose–response curves based on the measured TBZ concentrations for effects of TBZ (a.s.) on the reproduction of C. elegans after 96-h 
exposure to a TBZ (a.s.) in water and soil, b the commercial TBZ formulation FOLICUR® and the two nanoformulations PCL-TBZ and NLC-TBZ 
in water. Plot c shows the effects of the nanocarriers PCL and NLC with and without TBZ in soil based on the concentration of TBZ. The 
horizontal error bars stand for the standard deviation between the replicates of TBZ concentrations (n = 3). In Plot c, for each concentration 
of nanoformulations with TBZ, corresponding nanocarriers without TBZ were prepared using equivalent particle concentrations. Plot d shows 
the effects of the nanocarriers PCL and NLC with and without TBZ in water based on the number of particles; The curves were fitted with a logistic 
function (3 parameters) using SigmaPlot 12.0 (Systat Software Inc): a water: r2 = 0.90, p < 0.0001; soil: r2 = 0.998, p < 0.0001; b Folicur®: r2 = 0.91, 
p = 0.0009; PCL-TBZ: r2 = 0.96, p < 0.0001; NLC-TBZ: r2 = 0.97, p < 0.0001; c PCL-TBZ: r2 = 0.99, p < 0.0001; NLC-TBZ: r2 = 0.99, p < 0.0001; PCL-carrier: 
r2 = 0.94, p < 0.0001; NLC-carrier: r2 = 0.99, p < 0.0001



Page 9 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51  

taxa: 7 ± 4%). With 2.72 (± 0.41) and 3.30 (± 0.27), the MI 
and MI25 were relatively high.

During the course of the study (8 weeks), the nematode 
community structure changed significantly in the con-
trol treatments (Fig. 3A; ANOSIM: p < 0.05). The micro-
cosms treated with FOLICUR®, PCL-TBZ, and PCL 

nanocarriers also showed a significant change within the 
eight weeks of exposure, resulting in a significantly dif-
ferent community compared to the control treatment 
(Fig.  3A; ANOSIM: p < 0.05). Multivariate ANOSIM did 
not reveal a difference between the various treatments. 
However, the relative abundance of nematodes belong-
ing to the family of Rhabditidae was considerably higher 
in FOLICUR® and PCL-TBZ treatments (Fig.  3D), with 
a significant difference to the control for PCL-TBZ 
(p = 0.02; one-way ANOVA, post hoc Dunnett). The dif-
ference in taxonomic composition between treatments 
and control resulted in a slight increase of total densities 
in PCL treatments (PCL-TBZ and PCL carriers; Fig. 3B), 
a slight decrease in the number of genera in all treat-
ments (Fig.  3C), and a decrease of the MI in PCL-TBZ 
and FOLICUR®-treated microcosms (Fig.  3E) and an 
increase of MI25 in the PCL-TBZ treated microcosms 
(Fig.  3E). However, due to the high variability of the 
number of individuals, number of genera, and MI, these 
trends were not statistically significant (p > 0.05).

Discussion
Characteristics of nanoformulations
The physical characterizations of prepared nanoparti-
cles (in stock suspensions) confirmed that nanoparticles 
within the "nano-range" of up to several hundred nanom-
eters are consistent with nanopesticides definitions [9, 25, 

1 10
TUmix

0

PCL_TBZ observed
PCL_TBZ modeled
NLC_TBZ observed
NLC_TBZ modeled

Fig. 2 Observed and modeled toxicity of TBZ NF (PCL-TBZ 
and NLC-TBZ): % inhibition of C. elegans’ reproduction plotted 
against the sum of toxic units (TUmix =  TUcarrier +  TUTBZa.s.) calculated 
from carrier and TBZ concentrations and the respective  EC50 values 
 (TUcarrier or TBZ = [carrier or TBZ]/  EC50(carrier or TBZ)); mixture toxicity 
was modeled assuming independent action and effect addition

Fig. 3 Nematode community structure in soil microcosms treated with water (control; C), FOLICUR® (Fol), TBZ NF (PCL TBZ) and PCL nanocarriers 
(PCL carr) after 8 weeks of exposure: A nMDS-plot based on square-root transformed relative nematode genus abundances; symbols represent 
single replicate microcosms (n = 4; controls: n = 8); arrows mark significant changes of genus composition within the course of the experiment (T0 
vs Control) and differences between the control and all treated microcosms; B total nematode densities (individuals/100 g dry soil; mean ± sd; n = 4); 
C number of genera (mean ± sd; n = 4); D % Rhabditidae (mean ± sd; n = 4; * = significantly different to control); E Maturity Index (MI; mean ± sd; n = 4)



Page 10 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51 

65], aligning with previous research on nanopesticides 
with PCL (17) and NLC [57]. Other key physical proper-
ties such as PI and ζ potential were evaluated, indicating 
high uniformity and stability of the nanoparticles, with 
PI values around 0.2 and ζ potential around ( ±) 30  mV, 
signaling optimal dispersion and stability [13, 57]. Addi-
tionally, the EE of the a.s. in nanoparticles ranged from 
91 to 98%, highlighting the effective association of TBZ 
with the NCs. These findings underscore that the NCs’ 
hydrophobic composition remarkably favors the binding 
of TBZ that ended in the perfect association across all 
NFs [13, 20].

In fresh Lufa 2.2 soil, which was used for the micro-
cosm study, the unchanged TBZ concentration within 
the eight-week study, if applied as nanoformulation 
(PCL-TBZ), shows that the nanoformulation can protect 
the a.s. from degradation. The lower degradation of a.s. 
encapsulated in NCs has been demonstrated in different 
studies [31, 66]. Degradation is demonstrated as the main 
dissipation for TBZ [31].

Toxicity of TBZ (a.s. and commercial formulation)
In the present study, TBZ was tested in relatively high 
concentration to simulate the worst-case scenario in 
cumulative release circumstances at the high application 
of TBZ [48, 50]. In the most extreme FOCUS scenario 
(Forum for the co-ordination of pesticide fate models and 
their use. D2: ditch, spray application to cereals), the esti-
mated concentration of TBZ in surface water (predicted 
environmental concentration in surface water) was found 
to be 2.47 μg/L [67, 68]. Moreover, according to the lit-
erature, TBZ levels in surface water have been reported 
to reach between 175 and 200  µg/L [69]. Furthermore, 
evidence from a study conducted between 2009 and 2012 
revealed that TBZ concentrations at a vineyard outlet in 
the Layon catchment in France peaked at 357 µg/L [70]. 
The soil  DT50 reported for TBZ is 25–365  days [49]. 
Considering the high persistence and high to medium 
mobility of TBZ in water and soil [67], the importance 
of this study is highlighted. In the present study, TBZ 
elicited 96  h-  EC50 value of 29.7  mg a.s./L in water and 
711 mg a.s./kg in soil (Table 1). Due to the limited water 
solubility of TBZ (36 mg/L, 25 ˚C), freely dissolved TBZ 
concentrations did not exceed 47 mg/L even at a nomi-
nal concentration of 200  mg/L, in spite of the presence 
of solvent (0.5% acetone; see Additional file 1: Table S3). 
Therefore, in both water and soil, the maximum effect 
could not reach 100% (< 70% inhibition of reproduction). 
Moreover, the NOEC value in water was < 2.7  mg/mL 
and 501 mg/kg in soil. In a study on C. elegans on agar 
plate, a NOEC value of 1000  μg/L and LOEC value of 
2500 μg/L were determined for C. elegans [68], indicating 
the high toxicity of TBZ.Compared to C. elegans, aquatic 

organisms like Daphnia magna and Danio rerio have 
shown higher sensitivity to TBZ. For example, D. magna 
exhibited a 48-h  EC50 between 2.37 and 6.2 mg/L and a 
more sensitive 21-day reproduction  EC50 at 0.7 mg/L [50, 
71, 72]. Danio rerio’s 96-h  LC50 values range from 0.89 to 
9.7 mg/L, indicating significant toxicity.

The EFSA report [67] on TBZ shows that for Eisenia 
fetida, the 8-week NOEC and 14-day  LC50 values are 
10  mg/kg and 1381  mg/kg dry soil, respectively. Chen 
et al. [73] reported  LC50 values for E. fetida at 746.3 mg/
kg and 287 mg/kg for 7 and 14 days. Comparatively, this 
study’s 4-day  EC50 for C. elegans is 711  mg/kg dry soil, 
aligning closely with values for E. fetida.

TBZ targets a critical site involved in cell membrane 
construction across bacteria, fungi, plants, and animals, 
indicating its potential to disrupt both biological func-
tions, such as feeding and assimilation, and broader eco-
logical processes [47, 69]. For example, TBZ significantly 
affects feeding and energy storage in Daphnia magna at 
concentrations over 410 µg/L after 24 h of exposure [74], 
highlighting its metabolic impact. Research on C. elegans 
has shown that exposure to TBZ, even at concentrations 
as low as 0.01 µg/L, can cause reproductive and develop-
mental defects, including reduced brood size [47]. This 
disruption is speculated to be due to TBZ’s interference 
with crucial enzymes such as cytochrome P450 (CYP)17, 
essential for steroid hormone synthesis in vertebrates, 
leading to decreased progesterone and estrogen levels 
[47]. Similar toxic effects, through interaction with the 
endocrine system and implications for development in 
both invertebrates and mammals, have been suggested 
[68]. Additionally, TBZ’s inhibition of CYP19a expres-
sion in zebrafish disrupts steroid hormone biosynthesis, 
reducing fertility by lowering 17β-estradiol levels [53]. 
These findings highlight TBZ’s wide-ranging effects on 
metabolism and development across different species 
and could potentially apply to C. elegans in the present 
study. The large difference between TBZ toxicity to C. 
elegans in water and soil (30 mg/L vs. 711 mg/kg) might 
be due to the binding of TBZ to organic soil particles, 
lowering the bioavailability of the compound [31]. Tak-
ing a  KOC of 1536 (EPISuite) and a  fOC of 0.0171 of the 
Lufa soil (% TOC: 1.71) the  EC50 of 711 mg/kg dw refers 
to an estimated porewater  EC50 of 28.2  mg/L [75]. The 
good agreement of the porewater-based  EC50 derived 
via soil exposure with the  EC50 derived from water expo-
sure (29.7 mg/L) confirms the assumption that the toxic-
ity of TBZ in soil was mainly caused by freely dissolved 
TBZ. Moreover, Haegerbaeumer et  al. [44] showed that 
the toxicity of the fungicide fludioxonil to C. elegans was 
comparable for soil and water exposure when referring 
to porewater concentrations, suggesting the porewater 
as the main uptake route. This finding also agrees with 



Page 11 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51  

studies on the toxicity of fludioxonil on nematodes in 
freshwater sediments [76].

Recognizing the potential for formulations to mani-
fest higher toxicities compared to their respective a.s., 
it is imperative to conduct toxicity assessments on the 
pesticide formulations for a comprehensive evalua-
tion [77]. Moreover, the use of the commercial formu-
lation is relevant because plant protection products are 
deployed in the environment as formulations, potentially 
introducing both the a.s. and their additives [69]. In Foj-
tová et  al. study [31], commercial formulation typically 
delayed degradation of a.s. (with  DT50 extending by 1.5 
to 2 times relative to a.s.) and resulted in increased soil 
residue levels in comparison to the active substance. For-
mulations contain additives (used to improve their func-
tionality, e.g., solubility) that may induce excess toxicity 
in the organism [78]. In the present study, FOLICUR® 
inhibited reproduction more than TBZ (a.s.) in water 
with 96  h-EC50 = 16  mg/L. FOLICUR® is a suspoemul-
sion, with oil being a major component of the formula-
tion (20%) as inert ingredient [79]. Although we were not 
able to test the effect of this unknown component on the 
reproduction of C. elegans, the effects of a high density 
of lipid droplets, analogous to the effects of the NCs, 
can be considered as a possible cause for the observed 
excess toxicity. It cannot be excluded that FOLICUR® 
also comprises additional biocidal components, namely 
1,2-benzisothiazol-3(2H)-one (BIT) and a combination 
of 5-chloro-2-methyl-3(2H)-isothiazolone (< 0.0015%) 
and 2-methyl-2H-isothiazol-3-one, (< 0.05%). Accord-
ing to the literature, BIT`  LC50 values for D. magna 
and zebrafish in freshwater environments are 1.03 and 
1.5  mg/L, respectively, and it could significantly reduce 
the growth of algae like Scenedesmus sp. LX1, Chlorella 
sp with 72-h  EC50 values of 1.70, 0.41 and 1.16  mg/L, 
respectively [80]. BIT’s behavior in soil shows it degraded 
quickly (t½ = 7.2  h) in terrestrial environments, with 
any resulting metabolites being short-lived and posing 
considerably less toxicological risk [81]. However, fur-
ther research is essential to gain an understanding of the 
impact of these additives on nematodes. Also, a slightly 
higher toxicity of Folicur EW 250 compared to TBZ (a.s.) 
was reported for E. fetida without any provided specula-
tion regarding the cause of this toxicity [67].

Toxicity of TBZ NFs and their corresponding NCs
The nanoformulations, PCL-TBZ and NLC-TBZ, dis-
played distinct toxicity patterns in both water and soil 
on reproduction. Compared to TBZ (a.s.), both NFs 
were considerably more toxic in water (factor 2.5 and 
4.5 for PCL-TBZ and NLC-TBZ, respectively; Fig.  1b; 
Table  1). In soil, PCL-TBZ showed no toxicity until 
the highest concentration, comparable to the toxicity 

of TBZ (a.s.) (Additional file  1: Table  S3). In contrast, 
NLC-TBZ showed considerably higher toxicity than 
TBZ (a.s.) and PCL-TBZ. However, a considerable part 
of the toxic effect of the TBZ NFs might have been 
contributed by the intrinsic toxicity of the NCs them-
selves, while C. elegans responded more sensitively to 
NLC than to PCL nanocarriers, both in water and soil 
(Table  1, Fig.  2). Different effect mechanisms might 
explain the nanocarrier effect. For both types of NCs, a 
physical particle effect can be assumed that has already 
been observed for C. elegans after exposure to high con-
centrations of polystyrene particles. Mueller et al. [82] 
suggested food depletion as a major effect mechanism, 
as the dilution of the food (bacteria) with particles of 
similar size led to a significantly lower uptake of nutri-
tious bacteria [83]. This is supported by Lu et  al. [47]. 
The authors explained that the adverse effect seen on C. 
elegans could be linked to a diminished feeding capabil-
ity necessary for securing enough nutrients for growth, 
reproduction, and sustaining metabolism. Additionally, 
Mueller et al. [82] reported  EC50 values for polystyrene 
beads at 8 and 140 ×  109 beads/mL, depending on the 
size of the beads, 0.5 to 0.1 µm diameter, respectively. 
This agrees well with the observed effects of the NLC 
and PCL nanocarriers in the present study  (EC50: 12 
and 45 ×  109 particles/mL, respectively; Table 1) with a 
size of 0.32 and 0.26 µm, respectively (Additional file 1: 
Table S2).

However, as NLC showed considerably stronger effects 
on the nematodes than PCL, in both water and soil tests, 
other effect mechanisms, such as chemical-induced tox-
icity, could also be considered. For lipid nanoparticles, 
toxicity can be influenced by the presence of toxic ele-
ments and radical species generation (reactive oxygen 
species and other free radicals) that contribute to cyto-
toxicity [84]. Glyceryl monostearate was found to be 
responsible for the cytotoxicity of solid lipid nanoparti-
cles (SLN) and NLC [84]. Moreover, the lipid composi-
tions, as well as surfactants, emulsifiers, and stabilizers 
used in NLC preparation, might be important factors 
for the toxicity of lipid nanoparticles [84]. In the current 
study, the lipid phase was made up of solid lipid (glyc-
erol tripalmitate) and liquid lipid (Myritol 318), where 
the ecotoxicity data for these two lipids are scarce con-
sidering the general belief that the lipids are biocompat-
ible [84]. In a study by Albuquerque et al. [85] different 
concentrations of SLN (with similar compositions as 
our tested NLC) with and without atrazine were tested 
on Chironomus sancticaroli larvae, where atrazine NFs 
and their corresponding NCs (without atrazine) caused 
mortality and biochemical alterations, indicating poten-
tial toxicity, while the effects of atrazine as a.s. showed no 
lethal effects.



Page 12 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51 

Similarly, the toxicity study of SLN on C. elegans dem-
onstrated comparable mortality outcomes between the 
SLN formulation encapsulating atrazine and their cor-
responding NCs. In contrast, C. elegans exposed to the 
herbicide (a.s.) exhibited no mortality, pointing to the 
nanoparticles’ composition as a key toxicity factor possi-
bly due to unique mechanisms of interaction or internali-
zation with the organisms [32]. Furthermore, research 
by Gomez et  al. [86] on the effects of nano-atrazine on 
gene transcripts involved in secretion, translocation, and 
vesicle trafficking shed light on a potential nano-specific 
pathway for uptake and cellular transport, indicating 
that the nanoparticles may facilitate a distinct mode of 
entry and distribution within cells. In the present study, 
in soil, NCs (without TBZ) likely contributed to the 
higher toxicity of NFs compared to TBZ (a.s.). We only 
observed excess toxicity for NLC-TBZ, where the car-
rier itself showed considerable inhibitory effects on the 
nematodes’ reproduction (Fig. 1c). The slow degradation 
of lipid nanoparticles in soil, as documented by Ayoubi 
et al. [87], may further contribute to the observed toxicity 
in C. elegans. In a related context, the toxicity assessment 
of NLC-TBZ (at concentrations below the TBZ solubility 
limit) revealed high toxicity on the immobilization of D. 
magna in the AdaM medium. Importantly, this toxicity 
was attributed to the release of TBZ into the test medium 
rather than the corresponding NCs [72]. Contrary to 
these results and our results of NLC, SLN incorporating a 
mixture of atrazine and simazine demonstrated a reduc-
tion in cytotoxicity to 3T3 rat fibroblast cells and phy-
totoxicity to corn plants (Zea mays) [57]. These results 
emphasize that the toxicity of nanoparticles, particularly 
lipid nanoparticles, is a complex and multifaceted issue 
that demands careful evaluation and consideration of 
various factors. The observed low toxicity of PCL-TBZ 
on C. elegans in soil may be due to slower TBZ release 
from PCL NCs [31, 88] and a slower degradation rate 
of PCL within the exposure period [16, 17, 31]. Studies 
have shown that PCL degrades more slowly in soil than 
in other environments, such as compost, with its bio-
degradation rate ranging from a few months to several 
years. This variability is largely dependent on the molecu-
lar weight of PCL and specific environmental conditions 
that influence its degradation [16, 17, 89].

Combined toxicity of TBZ (a.s.) and NCs
To test if the observed effects of both NFs are a result 
of combined toxicity of nanocarriers and TBZ (a.s.), 
mixture toxicity models using effect addition (assum-
ing independent action) were applied to the data. For 
NLC-TBZ, the mixture model perfectly predicted the 
observed effect (Fig.  2) so that the combined toxicity 
of NCs and TBZ (a.s.) could be confirmed. In contrast, 

the PCL-TBZ formulation exhibited a synergistic effect, 
where the observed toxicity was significantly higher than 
what would be expected from the combined effects of 
the nanocarriers and TBZ a.s. (with an  EC50 value of 0.54 
TUs). This suggests that the interaction between PCL 
NCs and TBZ results in enhanced toxicity beyond sim-
ple additive effects. This increased toxicity could be due 
to not only the bioavailability of freely dissolved TBZ, 
but also TBZ encapsulated within the PCL NCs, which 
might be released inside the nematodes’ gut upon inges-
tion, indicating a more complex interaction mechanism 
at play. This agrees with other studies mentioning an 
increased bioavailability of a.s. by NCs and increasing the 
uptake of a.s. and organism gut digestion [31, 90].

For the commercial TBZ formulation, FOLICUR®, 
combined toxicity of TBZ (a.s.) and the oil used for cre-
ating the emulsion could not be modeled, as it was not 
possible to test the toxicity of the exact oil emulsion on 
C. elegans. However, the slightly higher toxicity of FOLI-
CUR® on the nematodes’ reproduction compared to 
the TBZ (a.s.) might be partly induced by the emulsi-
fier. The available literature suggests that the toxicity of 
FOLICUR® on the nematodes’ reproduction compared 
to the TBZ (a.s.) might be partly induced by the emulsi-
fier. Still, the exact mechanism of action of the emulsifier 
is not specified [72, 91]. Further research may be needed 
to determine the mechanism of action of the emulsifier 
in FOLICUR® (explained broader in section "Toxicity of 
TBZ (a.s. and commercial formulation)").

These results highlight the complexity of assessing the 
toxicity of NFs and the importance of considering not 
only the a.s. but also the NCs and other components 
present in the formulations [25]. It demonstrates that 
interactions within NFs can significantly alter the toxicity 
profile, emphasizing the need for detailed toxicological 
evaluations that account for potential synergistic effects.

Long‑term effects of TBZ NF in microcosms
Although measured TBZ soil concentrations in the 
microcosm test (405 and 551  mg/kg dw for FOLICUR® 
and PCL-TBZ) were below or comparable to the NOEC 
derived for C. elegans in soil, we expected that the native 
soil nematode fauna in Lufa soil respond to TBZ with a 
significant change in the taxonomic composition, due 
to a considerably longer exposure time (8 weeks vs. four 
days) and a multispecies scenario with a larger range of 
sensitivity towards TBZ. In a similar setting, nematode 
communities were shown to respond more sensitively 
to fungicides in microcosms than C. elegans in a single-
species test [44, 45]. In the present study, the nematodes 
responded with a significant change in the taxonomic 
composition compared to the untreated control; how-
ever, this happened in all treatments, even if only NCs 



Page 13 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51  

were present without TBZ (Fig.  3a). Thus, the major 
effects seem to have been caused by the NCs or emulsi-
fier (oil in FOLICUR®), rather than by TBZ (a.s.). How-
ever, the effects of TBZ in the PCL-TBZ and FOLICUR® 
treatments cannot be excluded, as certain changes (e.g., 
the relative increase of Rhabditidae) only occurred in 
treatments containing TBZ, which also led to a slight 
decrease of the MI, a stress index for nematode com-
munities. Thus, also under more realistic settings in the 
microcosms (multispecies; long-term exposure), a com-
bined effect of TBZ and NCs might have been responsi-
ble for the observed effects on the native soil nematodes.

Gradual increase of bioaccumulation of TBZ encap-
sulated in PCL NCs within a microcosm study on 
earthworms in Lufa 2.4 (comparable TOC = 1.9% to 
the present study’ soil type TOC = 1.71%) was reported 
which was attributed to nanoformulated pesticides being 
more readily available to earthworms reflecting the 
gradual release of the a.s. from NCs into the soil’s pore 
water [31, 66]. Similarly, Firdaus et al. [92] reported a 50% 
higher bioaccumulation of nanoformulated bifenthrin 
in earthworms compared to its a.s. and commercial for-
mulations, indicating that NFs not only increase bioac-
cumulation but also modify the uptake and elimination 
dynamics in earthworms. Notably, nano-encapsulated 
bifenthrin primarily remained in the earthworms’ gut, 
unlike the conventional formulation, which was absorbed 
into their tissue. This suggests a change in the exposure 
mechanism, likely due to the a.s. being encapsulated 
within NCs that act as a protective barrier. And changes 
depend on the specific compound, soil characteristics, 
and duration of exposure [88]. Hence, the slow release of 
TBZ into the soil pore water, coupled with the bioavail-
ability of nanopesticides as a complex (pesticide within 
NCs), could explain the observed alterations in the native 
soil nematode fauna in this study.

Different components used in the preparation of PCL, 
in longer time exposure may negatively affect the nema-
tode community. Myritol 318 is a blend of triglycerides 
derived from caprylic and capric acids. It is considered 
a non-toxic fatty acid, but to the best of our knowledge, 
there is no specific information available on the toxicity 
of Myritol 318 to nematodes. Free fatty acids like caprylic 
and capric acids were shown to significantly reduce 
Meloidogyne incognita (root-knot nematodes) reproduc-
tion and juvenile mortality [93]. In an investigation into 
the toxicity of nonionic surfactants used in polycapro-
lactone (PCL) compositions, specifically Tween 80, it 
was found that at a concentration of 0.05% (equivalent to 
500 mg/L), there were no adverse effects observed on the 
reproduction of C. elegans. (unpublished data).

These microcosm results suggest that the toxicity 
and exposure dynamics of the treatments, potentially 

influenced by the differential release rates of a.s. in dif-
ferent environmental matrices, could impact nematode 
communities. Understanding the internal exposure of 
nematodes to nanoparticles, as highlighted by the vari-
able release rates of a.s. in different conditions (e.g., 
cellular compartments versus soil pore water: quicker 
a.s. release in cells and slower in soil pore water due 
to variations in pH levels and cellular enzyme activity), 
could provide insights into the relationship between 
nanoparticles’ properties and observed toxic effects 
[25] and may explain the significant nematode com-
munity shifts observed in the present study. This com-
plexity underlines the need for a deeper investigation 
into how PCL nanoparticles interact with nematodes.

Implications for the risk assessment of TBZ NFs
Establishing a body of knowledge related to the com-
bined effects of nanopesticides will be helpful for regu-
latory agencies in the environmental risk assessment of 
these compounds. Therefore, it is important to consider 
the risks of a combined (and potentially synergistic) 
toxicity of a.s. and formulation on non-target species to 
indicate response patterns at different levels..

In assessing mixture (combined) toxicity, the com-
mon approach involves using the concentration addi-
tion (CA) model for chemicals with similar toxicity 
mechanisms and the independent action (IA) model 
for chemicals with entirely different mechanisms. How-
ever, for environmentally realistic mixtures containing 
substances with varying modes of action, the applica-
tion of CA and IA estimates has garnered significant 
attention in the scientific literature [71]. The mixture 
analysis for NLC-TBZ revealed the concentration addi-
tion model with  EC50 TU mix = 1.0.

The results of the water test with the tested com-
pounds indicate that the NOEC of TBZ toxicity assess-
ment is lower than the NOEC for other formulations. 
This suggests that TBZ may have a greater potential to 
impact C. elegans in lower concentrations compared 
to the other tested formulations. Similar to the cur-
rent results, reported NOEC for TBZ on toxicity tests 
with D. magna and C. elegans were also low (< 0.4 and 
1 mg/L, respectively), showing the high toxicity of TBZ 
[67, 68, 71]. In the present study, the lower NOEC for 
TBZ (< 2  mg/L) was followed closely by the recorded 
NOEC for NLC-TBZ. The NOEC is an important 
parameter in ecological risk assessments, as it repre-
sents the highest tested concentration of a substance 
at which no adverse effects are observed on a specific 
organism or ecological community.



Page 14 of 16Eghbalinejad et al. Environmental Sciences Europe           (2024) 36:51 

Conclusions
This study revealed combined toxicity in the tested nan-
opesticides arising from the combination of TBZ as the 
a.s. and the NCs employed in its NFs, which led to an 
increased toxic effect of these NFs compared to TBZ 
alone. For TBZ encapsulated in NCs with high toxic-
ity potential, such as NLC, the effects of the NF can be 
explained by effect addition. However, for NCs like 
PCL, which exhibit lower toxicity, synergistic effects are 
observed on C. elegans. Our study highlights that risk 
assessments based solely on the a.s. (TBZ) are inadequate 
for its NFs, as evidenced in our studies across aqueous 
and soil matrixes and under both short- and long-term 
exposures. This underscores the necessity, as also empha-
sized by other researchers, for a comprehensive and 
robust risk assessment framework specifically for nan-
opesticides [25, 26, 94].

Overall, this study offers important perspectives on the 
ecological impacts of various TBZ formulations, with an 
emphasis on NFs. This information is crucial as it adds to 
the growing body of evidence necessary to evaluate the 
ecological safety of nanopesticides, which are increas-
ingly being considered as alternatives to their traditional 
counterparts due to their potential for lower dosages and 
targeted delivery. The outcomes presented here are based 
on laboratory-scale exposure scenario, which may differ 
under varying conditions. In addition, the toxicity of the 
formulations was assessed at high concentrations without 
accounting for the possibility that nanopesticides could 
be more effective at lower dosages. Therefore, further 
studies on the bioactivity and toxicity of nanopesticides 
are essential for their safe and sustainable integration 
into agricultural practices. This should be supported by 
harmonized testing protocols and stringent regulations 
to assess their risks accurately.

Supplementary Information
The online version contains supplementary material available at https:// doi. 
org/ 10. 1186/ s12302- 024- 00879-9.

Additional file 1. S1. Synthesis of nanopesticides. S2. Physical char-
acterization of nanoformulations and nanocarriers. S3. Morphology 
of nanoparticles. S4. Chemical characterization of nanoformulations. 
S5. Nematode growth medium. S6. Preparation of food suspension for 
nematode. Table S1. Overview of experiments with respective test condi-
tions. Table S2. Characterization of stock nanoformulations. Tables S3, S4 
and S5. Measured TBZ concentrations in water, soil, and microcosm tests, 
respectively. Figure S1. Transmission electron microscopy micrographs 
of nanoparticles. Figures S2 and S3. Size distributions of nanoparticles in 
poly-ε-caprolactone and nanostructured lipid nanocarriers, respectively.

Acknowledgements
This research was funded by GAČR project GA18-19324S. Authors thank the 
RECETOX Research Infrastructure (No LM2023069) financed by the Ministry of 
Education, Youth and Sports, and the European Union’s Horizon 2020 research 
and innovation programme under grant agreement No 857560 for supportive 
background. This publication reflects only the authors view, and the European 

Commission is not responsible for any use that may be made of the informa-
tion it contains. R. G. would like to thank the São Paulo Research Foundation 
(Grant #2022/03219-2), the National Council for Scientific and Technological 
Development (Grant #310846/2022-6), and Coordenação de Aperfeiçoamento 
de Pessoal de Nível Superior – Brasil (CAPES) – Finance Code 001. We are 
grateful for the helpful discussions on mixture toxicity with Prof. Dr. Lennart 
Weltje.

Author contributions
ME: Conceptualization, methodology, formal analysis, data curation, writ-
ing—original draft, writing—review and editing, funding acquisition. JH: 
Conceptualization, resources, writing—review and editing, supervision, fund-
ing acquisition. JK: Resources, formal analysis, writing—review and editing. 
RG: Writing—review and editing. ZHB: Formal analysis, writing—review and 
editing. NR: Formal analysis, writing—review and editing. SH: Conceptualiza-
tion, methodology, formal analysis, resources, writing—review and editing, 
supervision.

Data availability
No datasets were generated or analysed during the current study.

Declarations

Competing interests
The authors declare no competing interests.

Author details
1 RECETOX, Faculty of Science, Masaryk University, Kamenice 753/5, 625 
00 Brno, Czech Republic. 2 Department of Pharmacology and Toxicology, 
Veterinary Research Institute, Brno, Czech Republic. 3 Department of Physics 
and Chemistry, School of Engineering, São Paulo State University (UNESP), Ilha 
Solteira, SP 15385-000, Brazil. 4 Ecossa, Giselastr. 6, 82319 Starnberg, Germany. 

Received: 28 December 2023   Accepted: 28 February 2024

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	Nano-enabled pesticides: a comprehensive toxicity assessment of tebuconazole nanoformulations with nematodes at single species and community level
	Abstract 
	Introduction
	Materials and methods
	Reagents and chemicals
	The preparation of nanoformulations and nanocarriers
	Preparation of stock solutions and spiking procedure
	TBZ (a.s.) in water and soil

	Preparation of food medium
	Chemical analysis
	Water
	Soil (toxicity test and microcosm test)

	Toxicity test with Caenorhabditis elegans
	Microcosm test
	Data evaluation and statistical analysis

	Results
	Characterization of the nanoformulations and nanocarriers
	Response of C. elegans to TBZ (a.s.) and formulations in water and soil
	Toxicity of TBZ (a.s.) and TBZ formulations in water and soil
	Effects of NCs in water
	Mixture toxicity modeling

	Microcosm study

	Discussion
	Characteristics of nanoformulations
	Toxicity of TBZ (a.s. and commercial formulation)
	Toxicity of TBZ NFs and their corresponding NCs
	Combined toxicity of TBZ (a.s.) and NCs
	Long-term effects of TBZ NF in microcosms
	Implications for the risk assessment of TBZ NFs

	Conclusions
	Acknowledgements
	References