Introduction
Infertility is defined as failure to obtain a clinical
pregnancy after 12 months of regular, unprotected sexual
intercourse. On average, it affects 8–12% of couples of
child-bearing age ( 1). A decline in human fertility has
prompted an increasing proportion of couples to enrol in
in vitro fertilization (IVF) programmes. Over the last 50
years, the sperm count has fallen by 32–50% in Europe
and United States ( 2, 3); this fall is too rapid to be due
to a genetic factor but might be related to one or more
environmental factors, such as exposure to pesticides.
Pesticide are substances or combinations of substances
used in many areas of agriculture and industry. They
include ( 1) phytosanitary products (also referred to as
phytopharmaceuticals) used in agricultural or non-
agricultural plant sectors to control insects (insecticides),
weeds (herbicides), fungi and moulds (fungicides), or pests
(rodenticides); (2) biocides used in industry (treatment of
wood and textiles), hospital environments (hydroalcoholic
gels), and domestic settings (disinfection); and ( 3)
antiparasitics used in human and veterinary medicine
(treatment of lice, scabies, mites, fleas, ticks, etc.) (4, 5).
The main families of pesticides by chemical
composition are as follows:
– Organophosphorus (OP) compounds, such as
chlorpyrifos, cypermethrin, malathion, and parathion
– Organochlorine (OC) compounds, such as
methoxychlor (MXC), 2,3,7,8-tetrachlorodibenzo-
pdioxin (TCDD), dichlorodiphenyldichloroethane
(DDD), dichlorodiphenyldichloroethylene
(DDE), dichlorodiphenyltrichloroethane (DDT),
polychlorinated biphenyls (PCBs), dieldrin, endosulfan,
hexachlorobenzene (HCB), hexachlorocyclohexane
(HCH), and lindane
– Carbamates, such as carbofuran, benomyl, and
mancozeb
– Pyrethroids, such as permethrin
– Triazines, such as atrazine
-20-0135
Key Words
f endocrine disruptor
f oocyte-embryo
f clinical outcome
f IVF
Endocrine Connections
(2020) 9, R134–R142
ID: 20-0135
9 6
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Many pesticides are known to be endocrine-disrupting
chemicals (EDCs), defined as ‘exogenous agents, that
are potentially capable of synthesis, secretion, transport,
binding, action, or elimination of the natural hormones
responsible for the maintenance of homeostasis,
reproduction, and developmental processes in the body’
(5). Even though the involvement of EDCs in certain
reproductive diseases is well documented, only few studies
have examined the direct impact of pesticides on fertility
(and especially in female infertility) in IVF programmes.
Hence, the objective of the present review was to assess the
impact of the most frequently used pesticides on female
fertility, oocyte-embryo quality, and clinical outcomes in
IVF programmes.
Pesticides as EDCs
A large body of evidence from animal studies and
epidemiological surveys shows that pesticides
like bisphenol A (BPA) and phthalates have an
endocrine-disrupting action and a reprotoxic impact
(5, 6, 7, 8, 9, 10, 11). Furthermore, Manikkam ( 12)
highlighted the existence of a transgenerational risk
in the rat: in utero exposure of pups to a mixture of
pesticides (administered by gavaging the pregnant
dams) was associated with changes in puberty onset,
spermatogenesis, and the development of ovarian
follicles up to the F3 generation.
The direct, toxic endocrine-disrupting effect (i.e. a
dose-response relationship) has rarely been characterized
for a single target compound. In general, the major
toxic exposure is associated with a large number of low-
dose compounds and the interactions between these
compounds. This ‘cocktail effect’ is why the presence
of even very small amounts of some specific pesticides
can perturb an organism’s hormonal balance ( 13, 14).
Indeed, some pesticides bind as agonists to hormone
receptors, which results in direct cell damage and/or the
dysregulation of one or more biochemical or genetic
pathways. In turn, this dysregulation produces toxic
metabolites and increases the level of oxidative stress (14),
which affects both male and female fertility. There are
more research data on the influence of various pesticides
on male fertility than on female fertility. However, even
the data on male fertility (with putative links between
exposure and a range of disorders), especially those
correlated with poor sperm quality and low testicular
weight (15, 16, 17), make it hard to affirm the presence of
a direct, causal effect in humans.
Compounds such as lindane, PCB, atrazine, and
mancozeb might dysregulate hormonal status in
women by decreasing LH concentrations and thus
promoting oligo-ovulation/anovulation and follicle
destruction (13, 14).
Pesticide exposure and female fertility
In 1994, De Cock et al. ( 18) investigated the impact of
pesticide exposure in market gardeners in the Netherlands
and found that the fecundability ratio fell as the
intensity of pesticide exposure increased. In this study,
28% of couples in the ‘high exposure’ group and 8% of
the couples in ‘low exposure’ group requested assisted
reproductive technology (ART) support. Other studies
have emphasized this effect of pesticide exposure in
women, with lengthening of the time required to conceive
(19, 20, 21, 22). A risk of spontaneous miscarriage has also
been observed, particularly in Bretveld et al.’s (23) study
of female farmers (odds ratio (95% CI) = 4.0 (1.14–14.01).
Data from the Agricultural Health Study cohort
showed that menstrual cycles of women exposed to
pesticides increased in length, although no distinction
was made between occupational exposure and domestic
exposure (24).
These results clearly converge on an impact of
pesticide use (especially in an occupational setting) on
female reproductive capacity and certain female infertility
diseases, such as premature ovarian failure (POF),
polycystic ovarian syndrome (PCOS), and endometriosis.
Furthermore, pesticide exposure might have direct or
indirect effects on oocyte/embryo quality and the clinical
outcomes of IVF.
The association between pesticide exposure and
certain female infertility diseases
The negative impact of pesticides has been investigated
in animal experiments. Many deficiencies have been
described, such as low ovarian weight ( 25, 26), impaired
folliculogenesis ( 27), a high aneuploidy rate, and the
acceleration of follicular atresia (25, 26, 27).
Indeed, women exposed to some endocrine-disrupting
pesticides (such as atrazine, lindane, and maneb) have
an elevated risk of long menstrual cycles or anovulation
(13). Conversely, high blood levels of DDE ( 28) and DDT
(29) are associated with luteal phase deficiency and short
menstrual cycles. The most serious consequence is POF
(Premature Ovarian failure), defined as the cessation
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R Cabry et al. Endocrine disruptors and
oocyte/embryo quality
R1369:6
of menstrual cycles before the age of 40 years and
characterized by very low blood levels of anti-Müllerian
hormone (AMH). The prevalence of POF is around 1%,
as a result of genetic or autoimmune/metabolic factors or
cancer therapy ( 1). Nonetheless, POF might sometimes
be caused by environmental factors, including pesticide
exposure. Indeed, a few studies have linked exposure to
HCH, mirex (30), pyrethroids (31), and their metabolites
(especially 3-phenoxybenzoic acid ( 32)), PCB, and DDT
(33) to ovarian ageing and menopause at an earlier average
age. Interestingly, low AMH levels were associated with
the presence of DDT in the serum (detected in more than
40% of samples from patients with POF ( 33)) and with
high concentrations of pyrethroids and their metabolites
with 25–26% reduction (31, 32).
The presence of DDE, MXC, or simazine (a triazine
herbicide) was associated with follicular atresia (34). Given
that MXC, simazine, and other pesticides (as atrazine,
endosulfan, and chlordecone) are oestrogen receptor
agonists (in contrast to DDE, DDT, and vinclozolin),
they may have oestrogenic and/or antiandrogenic
effects ( 5, 10, 35, 36). This implicitly explains why
some specific pesticides could be responsible for various
female reproductive diseases to differing extents and
why the effects of some pesticide compounds (such as
DDE, PCB, and MXC) depend on the patient’s genetic
predisposition. Indeed, these pesticides were associated
with abnormally high AMH levels and a high number of
small antral follicles – reflecting the presence of PCOS (37,
38, 39). Polycystic ovarian syndrome is a heterogeneous
condition that affects 5–10% of women. According to
the Rotterdam diagnostic criteria for PCOS, two of the
following three criteria must be met: infrequent or absent
ovulation (oligospaniomenorrhea), an abnormal ovarian
morphology on ultrasound, and hyperandrogenism (1).
Moreover, some pesticides (such as TCDD ( 40, 41,
42), PCB ( 43), and permethrin ( 44)) have a documented
impact on the endometrium by increasing vascularization,
cell proliferation, VEGF levels, and thus endometriosis
(with prevalence of 0.8–6%) (1). However, other pesticides
(cypermethrin ( 45), chlorpyrifos, malathion, diazinon,
lindane, DDT, and pyrethroids ( 46)) have the opposite
effect by indirectly inhibiting endometrial proliferation
or causing oxidative damage to the uterus.
Many studies have found an association between
pesticide concentrations in the follicular fluid on one
hand and the number and quality of oocytes collected
for IVF ( 47, 48), endometrial thickness, and embryo
implantation rates ( 46) on the other. Studies of animal
models have shown that pesticide exposure is associated
with elevated oxidative stress, which may be responsible
for the observed alterations (49).
Impact on oocyte quality
Exposure to pesticides might cause generalized oxidative
stress (49), with the elevated production of free radicals
and impacts on superoxide dismutase, catalase,
glutathione peroxidase, glutathione reductase, and
glutathione transferase. This might explain why oocyte
quality is impacted; oocyte dysmorphisms may reflect
poor competence for development into a good embryo
for implantation.
Indeed, we have highlighted ( 50) a conclusive
link between a high prevalence (>75%) of oocytes
with centrally located cytoplasm granulation (CLCG)
and the patients’ exposure to pesticides in the highly
agricultural Picardy area of northern France (annual
pesticide consumption: ~3900 tons). As a result, ongoing
pregnancy and live birth rates were lower in couples with
a high prevalence of oocytes with CLCG than in couples
with low (<25%) prevalence (14% vs 32% for the ongoing
pregnancy rate and 13% vs 30% for the live birth rate,
respectively). Conversely, the early miscarriage rate was
higher (47%) in the high-prevalence group than in the
low-prevalence group (11%; odds ratio: 3.1). This poor
IVF outcome might be indirectly due to high levels of
pesticide exposure (over 3000 g/ha), which engenders a
higher risk of oocytes with CLCG.
In line with these results, some pesticides (e.g.
atrazine, cypermethrine, DDT, dieldrine, MCX, and
vinclozoline) affect folliculogenesis (via the granulosa
and theca cells) and thus induce meiotic aberrations
(aneuploidy) and follicular atresia ( 51). For example,
DDT stimulates aromatase and acts in synergy with FSH
to induce a premature rise in oestradiol levels, affecting
oocyte maturation ( 51). Furthermore, PCB might
damage the ovarian reserve, the follicular response to
administered gonadotropins, and oocyte maturation (51).
Indeed, exposure of immature porcine cumulus-oocyte
complexes to an organochlorine mixture ( 48) or atrazine
(52) during in vitro maturation was associated with an
elevated incidence of incompletely matured oocytes. The
researchers mentioned the following pathophysiological
mechanisms: abnormal cellular shape (disrupted spindle
morphology), abnormal mitochondrial activity, and
alterations in oocyte DNA (48, 51, 52).
The pesticides most frequently linked to defective
oocyte maturation and oocyte competence are malathion
(53), parathion ( 54), MXC ( 55), DDD/DDE/DDT/PCB
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Table 1 Summary of the negative impact of various pesticides on oocytes, embryos, the endometrium, and clinical outcomes in IVF.
Pesticide EReg
Oocyte quality
Oocyte
maturation
Oocyte
genetic
Embryo
development Endometrium IR CPR References
Organophosphorus Chlorpyrifos + + + + (71)
(46)
Cypermethrin + + (45)
Malathion + + + + (53)
(46)
Parathion + + + + (80)
(10)
(54)
(27)
Organochlorine MXC + + + + (55)
(81)
(49)
TCDD ++ + + (40)
(41)
(42)
DDD ++ (56)
DDE ++ + + ++ + (28)
(56)
(39)
(26)
DDT ++ + + ++ + + + + (29)
(56)
(31)
(20)
(47)
(51)
PCB ++ + ++ ++ +++ ++ (43)
(56)
(77)
(78)
(39)
Dieldrin + ++ (72)
(58)
(51)
Endosulfan ++ +++ (71)
(79)
HCB ++ ++ + (57)
(47)
HCH ++ + + + (30)
(47)
Lindane + ++ ++ + + + (13)
(59)
(46)
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R Cabry et al. Endocrine disruptors and
oocyte/embryo quality
R1389:6
(56, 57), dieldrin ( 58), HCB/HCH ( 47), lindane ( 59),
benomyl (60), and mancozeb (61, 62) (Table 1).
Interestingly, DDT was associated with a low
proportion of diploid oocytes ( 56), while benomyl
interfered with microtubules ( 60) and lindane was
associated with cell damage (especially vacuolation
and cytoplasmic fragmentation) ( 59). It was reported
that mancozeb can strongly affect the meiotic spindle
organization of oocytes ( 61), but the degree of damage
could be decreased by treatment with resveratrol (62).
Moreover, exposure to deltamethrin (another
common insecticide) in a mouse model was linked to
cellular oxidative stress and meiotic abnormalities via
DNA damage ( 63). Liu et al. ( 49) suggested that MXC
exposure induces oxidative stress and affects mouse oocyte
meiotic maturation via the accumulation of superoxide
radicals and other reactive oxygen species (ROS),
aberrant mitochondrial distribution, a low mitochondrial
membrane potential, and elevated lipid peroxidation.
Thus, exposure to MXC can negatively affect oocyte
meiotic maturation – primarily through impairments in
cellular metabolism. In general, all these pesticide-linked
defects in oocyte quality are likely to degrade competence
for the development of a genetically undamaged embryo.
Impact on embryo development
Pesticides can affect indirectly the embryo by dysregulating
embryonic genome activation and embryonic metabolism,
which is dependent on oxygen uptake. This latter is low
at the 8-cell stage ( 64, 65, 66) and tends to increase after
the morula stage required for blastocyst expansion ( 67).
Blastocyst formation and the number of cells per blastocyst
declined with the concentration of organochlorines
(48) and atrazine ( 52). Furthermore, the association of
pesticides like deltamethrin (63) and MXC (49) with poor
metabolic and genetic status during embryo development
might be due to the impairment of various biochemical
pathways (13) and high ROS production. Moreover, high
ROS concentrations and generalized oxidative stress are
likely to affect the integrity of cellular constituents, such
as DNA and proteins (68, 69, 70).
Various pesticides (especially chlorpyrifos with
endosulfan (71), malathion (53), DDE/DDT/PCB (56, 47),
dieldrin (72), mancozeb ( 73) (Table 1), and pretilachlor/
diazinon ( 46)) may impact negatively embryonic
development. Consequently, the use of low-quality
embryos associated with pesticide exposure would give
poor clinical outcomes (e.g. an elevated risk of miscarriage)
in IVF programmes.
Carbamate Carbofuran + +++ + (82)
Benomyl + ++ + ++ (61)
(73)
(62)
Mancozeb + +++ + ++ + (60)
Pyrethroid Permethrin + + ++ (44)
(51)
Triazine Atrazine ++ + + + (13)
(36)
(52)
Vinclozoline +++ + (83)
(51)
The ‘+’ symbols indicate a negative impact: ‘+’ rarely reported, with a low level of interest; ‘++’: widely reported; ‘+++’: widely reported, with a high level of interest.
CPR: clinical pregnancy rate; DDD: dichlorodiphenyldichloroethane; DDE: dichlorodiphenyldichloroethylene; DDT: dichlorodiphenyltrichloroethane; EReg: endocrine regulation; HCB:
hexachlorobenzene; HCH: hexachlorocyclohexane; IR: implantation rate; MXC: methoxychlor; PCB: polychlorated biphenyl; TCDD: 2,3,7 ,8-te trach lorod ibenz o-p-d ioxin .
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Impact on clinical outcomes in IVF programmes
Women who consume high levels of pesticide residues
in fruits and vegetables ( 74) or who live in an area with
high pesticide exposure ( 50, 75) have an above-average
risk of miscarriage. In one study, the probability of clinical
pregnancy was 18% below average and the live birth rate
was 26% below average in the women most exposed to
pesticides (74). However, in a study in California, there
were no differences in terms of spontaneous miscarriage,
preeclampsia, and preterm birth rates between women
exposed to pesticides (occupationally or through
residence in an agricultural area) and unexposed women
(76). Pesticides associated with poor clinical outcomes
in IVF are chlorpyrifos ( 46), TCDD ( 42), DDT/PCB ( 46,
56, 77, 78), HCB/HCH ( 47, 56, 57), and endosulfan ( 79)
(Table 1). Lindane, DDT, diazinon, and chlorpyrifos were
associated with a low implantation rate but did not have a
clear impact on the clinical pregnancy and live birth rates
(46). Nevertheless, PCB and endosulfan have been linked
to repeated implantation failures (77, 79).
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Received in final form 8 April 2020
Accepted 7 May 2020
Accepted Manuscript published online 7 May 2020
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