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Review

Recent Advances and Developments in the Nematicidal Activity of Essential Oils and Their Components against Root-Knot Nematodes

by
Konstantia Sarri
1,
Snezhana Mourouzidou
1,
Nikoletta Ntalli
2 and
Nikolaos Monokrousos
1,*
1
University Center of International Programmes of Studies, International Hellenic University, 57001 Thessaloniki, Greece
2
Department of Agriculture, Crop Production and Rural Environment, University of Thessaly, Fytokou Street, 38446 Nea Ionia-Volos, Greece
*
Author to whom correspondence should be addressed.
Agronomy 2024, 14(1), 213; https://doi.org/10.3390/agronomy14010213
Submission received: 22 November 2023 / Revised: 11 January 2024 / Accepted: 17 January 2024 / Published: 18 January 2024
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Abstract

:
The Meloidogyne genus is widely recognized for its significant economic and scientific importance within the group of plant-parasitic nematodes. The chemical management of nematodes presents its challenges and heavily depends on employing soil fumigants containing toxic and costly nematicides. However, plant-derived essential oils offer promising alternatives, demonstrating a wide range of biological activities that affect nematodes through a range of mechanisms, including disrupting their nervous systems, inducing detrimental effects on plasma membrane permeability, penetrating the gelatinous matrix of nematode eggs, and disturbing intracellular redox status. Most of the extracted essential oils were predominantly sourced from the Lamiaceae family (32%), followed by Asteraceae (11%), Apiaceae (9%), and Poaceae (8%), and with genera Thymus, Mentha, Ocimum, Artemisia, Cymbopogon being the most common. The nematicidal activity of EOs primarily arises from their chemical groups, such as terpenes, phenylpropanoids, and organosulfur compounds. Among these, geraniol, carvacrol, limonene, eugenol, thymol, and pinene demonstrate the strongest nematicidal potential. The assessed EO efficacy was evaluated against 6 species belonging to the genus Meloidogyne. This review also provides knowledge of synergistic and antagonistic interactions of EO components. Synergistic interactions were identified between carvacrol and geraniol, as well as geraniol and eugenol, whereas binary combinations of carvacrol, γ-terpinene, and o-cymene exhibited reduced efficacy. Understanding how specific compounds interact can lead to the development of more potent and effective final products.

1. Introduction

Plant-parasitic nematodes (PPNs) pose a significant challenge to crop production, with root-knot nematodes (RKNs) being particularly threatening to global food security [1]. The Meloidogyne genus is widely recognized for its significant economic and scientific importance within the group of plant-parasitic nematodes. These nematodes exhibit high plasticity and adaptability, thriving in diverse geographical areas such as tropical and subtropical regions, like Africa, Asia, North and South America, and Europe [2]. According to indications from the Intergovernmental Panel for Climate Change, elevated temperature and moisture levels may result in an increased rate of infection, development, and reproduction, which, in turn, leads to the shift of their abundance and geographic distribution [3]. The Meloidogyne infect monocotyledonous and dicotyledonous plant species, inducing transcriptional reprogramming in host cells, leading to the formation of giant cells, establishing a permanent feeding site within the plant host where they obtain nutrients while completing their parasitic lifecycles [1,2,3,4]. These nematodes are sedentary endoparasites with four prevalent species (M. arenaria, M. hapla, M. incognita, and M. javanica). Recent research has revealed the existence of new species previously mistaken for one of the common four. Although the overall documented species count approaches 100, some of these species have more limited or poorly characterized host ranges [5]. Furthermore, Meloidogyne spp. can form dynamic disease complexes (MDCs) in conjunction with fungal and bacterial species, further exacerbating disease occurrences and, therefore, causing extensive damage to numerous vital crops globally, including tomato and coffee [6].
The primary focus of controlling nematodes is essentially preventive; the most reliable approaches involve implementing proper sanitation measures and selecting plant varieties that exhibit resistance. However, climatic variations induce diverse immune responses in plants, leading to the loss of resistance to pathogens in certain plant varieties under high-temperature conditions [7]. Existing infestations can be mitigated through fallowing, crop rotation, and soil solarization. However, these methods target nematodes in the top foot of the soil, providing short-term efficacy (for approximately a year) [8]. Chemical management of nematodes presents its challenges and heavily depends on employing soil fumigants containing toxic and costly nematicides. Moreover, these methods may not be suitable for some farming systems, such as organic or regenerative. Although chemical nematicides are currently necessary tools in agriculture, their extensive use has raised significant concerns regarding the enhancement of biodegradation mechanisms in the soil [9]. This could lead to reduced efficacy under field conditions. In addition, the toxicity of nematicides is of particular concern for those operating the application machinery and individuals at risk of exposure during chemical application. Moreover, pesticide residue monitoring may not always prevent the use of nematicides on crops too close to harvest, posing an additional risk [10]. Recently, the risks associated with manufacturing and utilizing these products have become evident, leading to increased regulatory scrutiny of hazardous substances (Class 1 pesticides, previously encompassing all nematicides). Consequently, several highly effective and widely used nematicides, such as methyl bromide, fenamiphos, and aldicarb, have faced severe restrictions. Furthermore, the expenses associated with introducing a novel chemical active ingredient to the US and European markets have been steadily rising each year and are presently estimated to exceed USD 250 million, marking a ten-fold increase compared to the costs observed during the 1960s [11,12]. This increase is accompanied by escalating registration costs and, as mentioned above, more stringent usage criteria. As a result, the prospect of developing conventional compounds (organophosphates or oxime carbamates) is doubtful if their toxicities are deemed to be high [13]. The convergence of these factors, coupled with a growing recognition of the importance of nematode control in agriculture, has raised awareness of the challenges posed by nematodes to crop damage. As agricultural practices intensify, soil degradation accelerates, and warmer climate conditions potentially worsen the problem, the agricultural sector is increasingly aware of the urgent need to address these issues [12].
In response to this challenge, farmers worldwide continue to adopt integrated pest management (IPM) strategies to optimize crop yield while maintaining sustainability in agriculture. Exploring natural compounds with reduced toxicity and minimal environmental impact has become necessary, including biodegradable nematicides that pose little to no harm to human health. Research has focused on biopesticides, particularly green nematicides, revealing promising prospects in pest management technology, progress, and practices that align with the pursuit of more eco-friendly and effective solutions. Benign alternative methods to chemical nematicides are anticipated to form a significant part of long-lasting crop protection strategies in the projected future [14]. In this context, the utilization of beneficial fungi (such as Trichoderma longibrachiatum and T. asperellum), beneficial bacteria (such as Pseudomonas fluorescens and Bacillus firmus), botanicals, and essential oils has gained attention as viable biological alternatives for nematode management [15]. Essential oils (EOs) exhibit a wide array of activities, including insecticidal, antifeedant, repellent, oviposition deterrent, growth regulatory, and antivector properties. They are natural, volatile substances characterized by their potent fragrance, originating from aromatic plants as plant secondary metabolites (PSMs). They are extracted through hydrodistillation and consist of diverse combinations of terpenes, terpenoids, and various aromatic and aliphatic compounds. The biological effects of the EOs result from complex interactions involving synergistic or antagonistic actions among constituents.
EOs impact nematodes through a range of mechanisms, including disrupting their nervous systems, inducing detrimental effects on plasma membrane permeability, penetrating the gelatinous matrix of nematode eggs, and disturbing intracellular redox status [16,17,18]. Due to their complex composition, essential oils can simultaneously affect multiple targets, therefore reducing the likelihood of target organisms developing resistance or adapting to the treatment. Additionally, the interspecific toxicity of individual oils and compounds varies significantly, making their effects highly idiosyncratic [19].
In a previous review conducted by Catani et al. [20], a comprehensive mapping of the extensive data on essential oils in agriculture against various species of PPNs was effectively presented, providing a thorough bibliometric analysis. In our study, our objective was to conduct a more in-depth investigation, narrowing the focus specifically to root-knot nematodes of the genus Meloidogyne. We aimed to complement their overview by providing a detailed exploration into the modes of action and interactions of EOs, with a specific examination of the nematicidal potential of their individual components. Additionally, our focus was on identifying the plant species serving as sources for each essential oil, highlighting components with the strongest nematicidal potential, exploring their mode of action, examining their synergistic and antagonistic interactions with other compounds, and discussing some limitations in EO commercialization. Through this approach, our goal was to present a holistic perspective on the potential of EOs in nematode management, acknowledging areas that warrant further investigation and development. We focus on recent advancements and new findings, as earlier literature on the subject has been thoroughly reviewed by other authors [21].

2. Categorization of Studies

We conducted a comprehensive literature search spanning the last 13 years (2009–2022) using reputable scientific databases, including Scopus, Web of Science, and Google Scholar. A total of 37 relevant research papers were identified, all focusing on the use of essential oils against Meloidogyne soil nematodes. The search strings utilized for our investigation included terms such as (“Essential Oil” or “EO”) and (“control of” or “against” or “biological nematicides”) and (“nematodes” or “Meloidogyne” or ‘’RKN’’ or “root-knot nematodes”). The collected data revealed a systematic classification based on plant botanical families as primary sources of EOs. Notably, plants belonging to the Lamiaceae family predominated, comprising 32% of the sources for EOs (Figure 1). Further categorization was based on the identification of the principal chemical components within the EOs responsible for their nematicidal properties. Overall, the reviewed experiments revealed the assessment of the EO efficacy against 6 species within the Meloidogyne genus (Figure 2).

3. Essential Oils, Chemical Groups of Their Components, and Their Mode of Action

Over the last decade, there has been a particular interest in the nematicidal activity of plant EOs and their constituents [21]. The plant-derived substances have shown potential as a source of highly effective pesticidal compounds. They are regarded as an almost boundless reservoir of eco-friendly pest management solutions, with minimal impact on plant and human health, being easily biodegradable [22]. Essential oils comprise complex blends of volatile organic compounds naturally synthesized within various plant parts, forming part of the plant’s secondary metabolism. These metabolites, produced in response to various forms of biotic stress, play essential physiological roles, e.g., attracting pollinators, establishing symbiotic relationships, and providing structural components for lignified cell walls in vascular tissues. Additionally, they enhance ecological competitiveness, exerting diverse effects on the host plant and surrounding organisms [23]. A wide range of PSMs includes flavonoids, phenolic compounds, terpenes, and nitrogen-containing chemicals derived from primary compounds [24,25]. Although some PSMs are naturally produced and stored during regular plant growth, others are specifically synthesized in response to various stress conditions [22]. Essential oils are extracted from various plant parts like leaves, flowers, seeds, and bark. Extraction methods vary depending on the plant part used; steam distillation is the most common method due to its simplicity and cost-effectiveness. Other techniques include mechanical extraction, hydrodistillation, solvent extraction, supercritical CO2 extraction, and subcritical water extraction [26,27,28]. The chemical composition, toxicity, and bioactivity of the extracts, in turn, can be influenced by several factors, such as the phenological age of the plant, the percent humidity of the harvested material, and the method of extraction [19].
The nematicidal activity of EOs primarily stems from their individual components, such as specific chemical compounds or bioactive molecules (Figure 3). In various experiments, most of the components tested as nematicides are terpenes. Terpenes are formed structurally by coupling different numbers of isoprene units (5-carbon-base; C5), and they may or may not contain oxygen (terpenoids and terpenes). The main terpene classes are monoterpenes (C10), sesquiterpenes (C15), hemiterpenes (C5), diterpenes (C20), triterpenes (C30), and tetraterpenes (C40). The lipophilic nature of essential oils, including their terpenoid components, has been associated with in vitro cytotoxic activity, primarily due to the presence of phenols, aldehydes, and alcohols [29]. Terpenes exhibit nematode-targeting mechanisms by disrupting plasma membrane permeability due to their lipophilic properties. This disruption compromises barrier function and leads to the leakage of cytoplasmic macromolecules in various organisms, including plant-parasitic nematodes [30]. An alternative hypothesis regarding their impact on plant nematodes suggests a biochemical interaction mechanism where plants release compounds that exhibit toxicity towards both microorganisms and nematodes. The mode of action of each terpene is different and is inextricably linked to its chemical structure. Certain monoterpenes have been found to disrupt the structure of biomolecules like polysaccharides, fatty acids, and phospholipids and can induce depolarization of mitochondrial membranes [31,32]. Furthermore, Kalaiselvi et al. [18] mentioned another mode of action where monoterpenes of the essential oil of Artemisia nilagirica disturb the intracellular redox status, activate the central signaling pathway of apoptosis, and induce DNA damage, ultimately leading to cell death. Additionally, other components of EOs with nematicidal effects, not belonging to the terpene group, include organosulfur compounds such as allyl isothiocyanate (AITC), diallyl disulfide (DADS), and diallyl trisulfide (DATS). These compounds influence nematodes’ neurotransmission and chemosensing functions [17]. Phenylpropanoids, another group of components found in plant essential oils, show promising results against nematodes, including (e)-cinnamaldehyde, benzaldehyde, eugenol, and eugenol methyl ester. The well-characterized biosynthetic pathway of phenylpropanoids presents a promising target for enhancing nematode resistance, as enzymes involved in this pathway are induced in plants upon wounding or pathogen infection, including sedentary endoparasitic nematodes [33]. In more precise terms, oils containing phenylpropanoid aldehydes exert their effects against nematodes by impeding the activity of the V-ATPase enzyme. This enzyme, known as a vacuolar-type proton-translocating ATPase, is responsible for pumping protons across membranes and is energized by ATP hydrolysis. It plays critical roles in nematode nutrition, osmoregulation, cuticle synthesis, neurobiology, and reproduction [34]. Moreover, the presence of phenols, aldehydes, and alcohols in an EO can act against the nematode by oxidizing its cytoplasmic membranes [34].
Many of the extracted essential oils renowned for their diverse biological properties predominantly originate from the Lamiaceae family (Table 1). The Lamiaceae family encompasses 7530 species, including trees, shrubs, subshrubs, and herbs. It is globally distributed and utilized across various fields, such as medicine, pharmaceuticals, and the food industry [35,36]. Within this family, EOs derived from genera like Thymus (e.g., Thymus vulgaris), Origanum (e.g., Origanum vulgare), Salvia (e.g., Salvia rosmarinus), Mentha (e.g., Mentha spicata), and Ocimum (e.g., Ocimum basilicum), have exhibited strong insecticidal, acaricidal, fungicidal, herbicidal and nematicidal properties [36,37]. Mint (Mentha spp.) stands as one of the most extensively studied plants for EO extraction, followed by thyme (Thymus spp.) and basil (Ocimum spp.). Additionally, significant amounts of EOs were derived from Asteraceae, Apiaceae, and Poaceae botanical families, with genera like Artemisia and Cymbopogon being prominent EO sources (Table 2).
The nematicidal effect of specific substances is closely linked to their chemical profile. The results indicate that compounds featuring hydroxyl (-OH) or methoxy (OCH3) groups, such as linalool, geraniol, carvacrol, and thymol, exhibited a higher frequency of nematicidal action compared to those with an acetyl group (acetyleugenol). This finding implies that the positions of the double bond within the propenyl group and the position of the substituent in the geometrical isomer play crucial roles in determining the nematicidal activity. Furthermore, allylic alcohol and phenolic alcohols, such as carvacrol and geraniol, demonstrated more potent nematicidal properties compared to other alcoholic compounds containing a hydroxyl group [50]. To differentiate the impact of essential oils based on their specific chemical compositions, researchers conduct identification and quantification of the constituent compounds of essential oils that are responsible for nematoxicity. This analysis involves techniques such as gas chromatography–mass spectrometry (GC–MS), high-performance liquid chromatography (HPLC), and proton nuclear magnetic resonance (HNMR) alongside in vitro assays [50,65].

3.1. Geraniol

Geraniol, an alcohol monoterpene present in the essential oil of various herbs, has demonstrated synergistic effects when combined with other terpenes like trans-anethole, eugenol, and carvacrol, effectively reducing gall development at specific concentrations [66]. The efficacy of geraniol can be attributed to the position of the alcohol functional group, a critical factor significantly influencing the nematicidal potency of various compounds. Experiments conducted on tomato plants against M. incognita and M. javanica juveniles revealed the nematicidal potential of geraniol, causing paralysis and interrupting their biological life cycle. This effect was attributed to the high content of geraniol (44.06%) found in the EO derived from Thymus citrodorus [67]. Similarly, the EO of Cymbopogon nardus, also containing geraniol, induced mortality (LC50 within 72 h at concentrations below 50 g mL−1) and immobility in over 50% of J2s at various concentrations. This compound exhibited efficacy against M. ethiopica juveniles, rendering them immobile within 24 h of exposure and maintaining their unresponsiveness throughout the experiment. Notably, geraniol initiated a 98.1% mortality rate after 24 h, ultimately leading to complete nematode mortality in subsequent assessments [68]. Furthermore, geraniol has shown significant nematicidal activity against M. javanica; at a concentration of 500 ppm, it induced 100% paralysis of J2s and inhibited egg hatching by approximately 70%. Sublethal doses (140 and 280 ppm) in pot experiments also reduced the number of nematode females in tomato roots to 59 and 56, respectively, while the control treatment exhibited 93 females per gram of root [66].

3.2. Carvacrol

Carvacrol, categorized as a monoterpenic phenol alongside p-cymene, constitutes essential components found in essential oils extracted from plants belonging to the Lamiaceae family. This botanical group is characterized by its rich aromatic compounds [69]. Carvacrol disrupts the normal functioning of certain receptors in nematodes, impairing movement and potentially explaining its nematicidal effect. This action is achieved through interaction with nicotinic acetylcholine receptors (nAChR) within the nematodes’ neuromuscular system [69]. Meloidogyne incognita demonstrated significant sensitivity to carvacrol, the major compound in Monarda didyma and Monarda fistulosa EOs, exhibiting an LC50 value of 14.2 μg mL−1 after 24 h of treatment. This concentration resulted in an 82% mortality rate of J2 juveniles, along with a considerable inhibition of egg hatch, decreasing to just 4.1% after 48 h of exposure [40]. Carvacrol, a primary constituent of the from Satureja hellenica EO, displayed high efficacy against various developmental stages of both M. incognita and M. javanica. It induced over 80% paralysis in J2 juveniles after 24, 48, and 96 h of exposure and effectively inhibited egg differentiation even at a dose of 250 μL/L, without additional inhibition observed in higher doses [55]. Origanum onites exhibited high efficacy in inhibiting egg hatching (68.8%), which was attributed to their high carvacrol content [42]. Furthermore, Kabdal et al. (2022) reported significant outcomes of carvacrol on J2 mortality and egg hatching when testing Thymus linearis EO from two different seasons (winter season and rainy seasons) against M. incognita. Interestingly, slightly better results were observed during the winter season (showing 64% at 5 μL/mL after 72 h of exposure time) compared to the rainy season (showing 55.23% at 5 μL/mL after the same exposure time). The authors attributed the success of EO to higher percentages of carvacrol.

3.3. Eugenol

Eugenol, chemically known as 4-allyl-2-methoxyphenol (C10H12O2), serves as the primary nematicidal compound found in Ocimum sanctum L., a plant belonging to the Lamiaceae family. It is also a major constituent of clove oil—Syzygium aromaticum (Myrtacaceae), Laurus nobilis L. (Lauraceae), and Cinnamomum zeylanicum (Lauraceae) [70]. In an in vitro study on Laurus nobilis L., eugenol was identified as the major component exhibiting strong nematicidal potential. Complete inhibition of egg hatch was observed at a concentration of 1.25 mg mL−1, and at a lower concentration of 0.20 mg mL−1, more than 50% mortality of M. incognita J2 juveniles was recorded within 24 h of immersion [56]. The EO derived from Syzygium aromaticum, with eugenol as its major compound comprising 87.1% of the oil’s composition, demonstrated promising effects on the mortality of M. gramincola J2 juveniles [61]. Specifically, at a concentration of 500 ppm, the J2 mortality rate ranged from 93.75% to 98.75% over exposure durations of 24, 48, 72, and 96 h. Even when the concentration was significantly reduced to just 62.5 ppm, it still resulted in pronounced mortality rates (73.75% to 80.00%). As the predominant compound in cinnamon essential oil (Cinnamomum zeylanicum), eugenol exhibited moderate effectiveness in vitro against second-stage juveniles Meloidogyne incognita, considering the EC50 at 371 ± 70 mg/L after 24 h of exposure, and 216 ± 86 mg/L after 48 h of treatment [46]. The authors suggested that phenylpropanoid aldehydes, particularly eugenol, showed higher activity compared to acetate derivatives (acetyleugenol).

3.4. Linalool

Linalool, present in two enantiomeric forms, S-(+)- and R-(−)-linalool, is prominent in essential oils known for their diverse biological activities, including antimicrobial and antioxidant properties, as well as repellent effects on various crop-damaging insects [71]. Compared to other EO components, linalool exhibits moderate solubility in water (1590 mg L−1 at 25 °C) [72]. The tested EOs from three lavandin cultivars showed strong activity against M. incognita and M. javanica, highlighting the variation among sources and nematode species. The observed structure–activity relationships primarily depended on the chemical features of the dominant components [38]. For instance, the EO from cv Rinaldi Cerioni (65.82% of linalool) exhibited significantly higher toxicity compared to cv Abrialis (40.31%) and Sumiens (47.99%). All three varieties displayed nematicidal activity (J2 mortality exceeding 70%) following an 8-hour treatment, and it was attributed to the acyclic structure of linalool, the major component of lavandin cultivars. Coriandrum sativum EO, which was predominantly composed of linalool (81.3%), caused high mortality among Meloidogyne hapla J2 (69.3%) after 24 h. However, its effectiveness was comparatively lower than other acyclic alcohols, such as geraniol and citronellol [42].

3.5. Limonene

Limonene, a monocyclic monoterpene (C10H16), comprises two optical isomers: R-limonene (D-limonene) and S-limonene (L-limonene), each with distinct insecticidal and antimicrobial properties [27,73]. Limonene, as the major compound of Citrus reticulata peel EO, was the primary compound responsible for egg-hatching inhibition, as well as J2 mortality in M. incognita. Results revealed 87.45% egg-hatching inhibition at 1500 μg mL−1 after 96 h of exposure and 83.31% J2 mortality at the same concentration and exposure time [16]. Furthermore, limonene was a major compound in spearmint essential oil emulsion, causing a notable increase in the mortality percentage of M. javanica juveniles in a concentration-depending manner. Specifically, at 4000 ppm, the mortality rate reached 78.9% within 24 h and 100% after 72 h of exposure [44]. Its presence was also detected in essential oils from various plants such as Achillea wilhelmsii, Tanacetum polycephalum, Rutaceae Citrus reticulata, Citrus sinensis, and Teucrium polium, and was identified as a key component responsible for their nematicidal activity when subjected to in vitro nematotoxicity tests [50]. Both concentrations of limonene (100 and 200 ppm) induced over 90% mortality in M. incognita J2 [50].

3.6. Thymol

Thymol has been found to enhance the innate immune response in nematodes, associated with specific parasitism-related signaling pathways and crucial regulatory genes [74]. Thyme EO emulsion extracted from Thymus vulgaris L. (Lamiaceae) was tested in vitro against second-stage juveniles M. javanica, and in vivo on coleus plants [43]. At a concentration of 5000 ppm, the emulsion achieved the highest mortality reduction (100%) within 24 h, primarily attributed to thymol. Thymol was also the major component of Thymus vulgaris EO (35.3%), with a relatively higher half-maximal effective concentration (EC50) of 4190 ± 816 mg/L after 72 h, suggesting a need for higher concentrations and longer exposure times for effective nematode control [46]. Extracted EO from T. linearis, mainly composed of thymol, demonstrated a dosage-dependent effect on M. incognita. At a low concentration of 2 μL/mL, it inhibited egg hatching by 38.72% after 72 h. Interestingly, higher concentrations (6 and 10 μL/mL) resulted in lower hatching percentages (36.58%) within the same exposure time. However, higher concentrations significantly increased J2 mortality, reaching 55.23% at 5 μL/mL after 72 h (from 19.80% at 1 μL/mL) [51].

3.7. Pinene

Pinene, a well-known group of monoterpenes (C10H16), is the primary constituent of turpentine extracted through resin distillation from various coniferous trees, notably those of the Pinus genus [75,76]. The two structural isomers, α-pinene and β-pinene, are also abundant in various herbs, including rosemary, parsley, basil, and even citrus peels, contributing to their distinctive aromas and properties [77,78,79]. The monoterpene hydrocarbon α-pinene was found in many essential oils when testing for the nematicidal activity of EO compounds. In vitro tests showed that α-pinene alone exhibited 79% M. incognita egg hatch inhibition at 1.50 mg mL−1 and caused over 50% J2 mortality at 0.20 mg mL−1 after 24 h. Also, it constituted a significant portion of the EO of bay leaf, which displayed high effectiveness in the same parameters (egg hatching and J2 mortality) against the same species. At a concentration of 1.00 mg mL−1 after 72 h, Laurus nobilis L. EO caused complete egg-hatching inhibition, while total J2 mortality was observed at 0.80 mg mL−1 after 96 h of immersion. It is hypothesized that the presence of α-pinene contributes to the effectiveness of bay leaf EO [56]. Similarly, being a major component of Myrtus communis (Myrtaceae) EO, α-pinene contributed to its effectiveness, showing results in J2 mortality and mobility. At a concentration of 879.40 μg mL−1, the EO exhibited LC50 within 72 h and caused immobility in over 50% of M. incognita J2s at different concentrations [48]. Pinene was also one of the main components of the EOs of Achillea wilhelmsii, Tanacetum polycephalum (Asteraceae), and Teucrium polium (Lamiaceae), causing mortality in M. incognita J2s at concentrations of 4000 and 8000 ppm. In vitro tests with α-Pinene and β-Pinene alone caused the death of, and when tested alone, at a concentration of 100 ppm, exhibits over 80% J2 mortality, and at 200 ppm, over 90% after 24 h [39]. Ridolfia segetum (Apiaceae) EO demonstrated significant nematicidal activity (LC50 at 9269 μL/mL) against Meloidogyne javanica, effectively inhibiting both egg hatch (75.35% at 16 μL/mL) and the survival of J2 juveniles (71% immobility after 72 h at 16 μL/mL) [57]. A strong nematostatic effect was also observed, resulting in temporary or permanent paralysis, particularly in the case of J2 juveniles of M. javanica, and was attributed to the presence of the bioactive compound β-pinene.

3.8. Other Compounds

The monoterpenoid carvone is an efficient acetylcholinesterase inhibitor, displaying effectiveness against nematodes by disrupting their nervous system. Reports indicate that carvone can also exert depressive effects on the central nervous system of nematodes [16]. In Felek et al.’s [42] study, the nematicidal potential of EO from various plants was assessed for its efficacy against Meloidogyne hapla. The EO extracted from Mentha piperita exhibited the highest juvenile nematode mortality rate (93.2%), with carvone identified as its primary component (39.3%). One of the key components of EOs of Eucalyptus citriodora (81.9%) and Cymbopogon nardus (95.8%) is citronellal, an acyclic monoterpene aldehyde. In vitro tests against M. incognita highlighted citronellal as one of the most effective constituents for immobilizing and eliminating nematodes. In addition, in silico analysis suggests that citronellal (along with geraniol and β-terpineol) may possess a higher binding capacity, indicating its potential role in mediating the biological effects of EOs against nematodes [48]. Another compound displaying nematicidal properties is (e)-cinnamaldehyde, found in Cinnamomum cassia EO, effectively controlling Meloidogyne incognita in soybean plants. At a concentration of 62 µg mL−1, it immobilized and killed 100% of J2 juveniles, surpassing the performance of the commercial nematicide carbofuran, which achieved only 63% nematode mortality at 173 µg mL−1 [34]. The primary component of Cinnamomum zeylanicum EO, (e)-cinnamaldehyde, exhibited substantial efficacy with an LC50/48 h value of 64 μg/mL, effectively inhibiting M. incognita hatching. This contrasts with the ineffectiveness of the chemical nematicide carbofuran, which had no impact on hatching in the same study [59]. The EO extracted from S. terebinthifolius green fruit, constituted of a high concentration of terpenes such as terpinene-4-ol, α-terpinene, γ-terpinene, and α-terpineol, led to an 82–86% reduction in M. javanica hatching and increased juvenile mortality by 300%. However, field application did not effectively control M. javanica in lettuce when infestation levels were high (555 J2/100 cm3 of soil) [54]. Laquale et al. [40] reported on the nematicidal potential of γ-terpinene, which effectively controlled M. incognita in vitro and in soil. EOs of Monarda fistulosa and M. didyma demonstrated high toxicity against J2, with LC50 values as low as 7.0 μg mL−1 after just 4 h of exposure; immersion in a 12.5 μg mL−1 solution for 24 h, resulted in over 80% mortality. Additionally, concentrations of γ-terpinene (along with o-cymene) showed significant results in reducing egg hatching, particularly during the 48-h treatment. Interestingly, in soil experiments, the suppressive outcome of both essential oils at rates of 500 and 1000 μg kg−1 was statistically comparable to that of the treatment with Oxamyl.

4. Synergistic and Antagonistic Interactions among Essential Oil Components

Numerous compounds found in essential oils exhibit diverse mechanisms of action. The same chemical constituent may demonstrate distinct biological activity when included within a natural mixture compared to its isolated form. Therefore, natural compounds, when combined, can either enhance, complement, or attenuate each other [80]. Consequently, the utilization of these compounds together may result in various outcomes: zero interaction, synergy (where the response is greater than expected), or antagonism (where it is less) (Figure 4) [67,81]. Understanding the interaction between molecules is particularly crucial in agriculture, where effective bioactive substances are sought [82]. More specifically, recognizing the synergism of binary mixtures is essential for formulating artificial blends and developing new nematicides. The primary compounds found in the essential oils of M. didyma and M. fistulosa, namely carvacrol, γ-terpinene, and o-cymene, were investigated for their binary combinations, revealing reduced efficacy against Meloidogyne species. Notably, the combination of o-cymene and carvacrol at a 1:2 ratio resulted in the highest mortality rate at 31.5%, while the combination of γ-terpinene and carvacrol at a 1:2 ratio resulted in a mortality rate of 36.1%. Conversely, the combination of γ-terpinene and o-cymene at a 2:1 ratio exhibited the lowest mortality rate at 20.3%. This indicates the presence of antagonistic interactions among these compounds. Furthermore, both major and minor compounds within the EOs of M. didyma and M. fistulosa showed complex synergistic and antagonistic effects, as demonstrated by their heightened toxicity against M. incognita (LC50 at 1 μg/mL for 24 h) compared to individual compound tests [40].
An additional interaction involving carvacrol is noted by Pardavella et al. [55], where the EO of Satureja Hellenica proved more effective against M. incognita than the corresponding hydrolat. One of the differences between the compounds of these two was the presence of p-cymene in the EO, which is crucial for nematicidal activity. This occurs due to its synergistic interaction with carvacrol; however, in this case, other substances, even in smaller quantities, might contribute synergistically. Furthermore, synergistic interactions were observed between carvacrol and geraniol, as well as between carvacrol and trans-anethole, showcasing the effectiveness of Thymus citriodorus EO and hydrosol against nematode paralysis [67].
Eloh et al. [46] conducted a study investigating compounds from the EOs of three plant species—Ocimum sanctum, Cymbopogon schoenanthus Speng, and Cinnamomum zeylanicum Blume. These compounds, primarily categorized as phenylpropanoids, displayed notable nematotoxicity, all exhibiting effectiveness (all showing EC50/48 h < 300 mg/L). The authors explored the synergistic potential of these compounds when combined with benzyl benzoate and carvone, a compound often associated with synergistic activities alongside EO components. Conversely, pairs that acted antagonistic were eugenol /isoeugenol, acetyl eugenol/ benzyl benzoate, cinnamyl alcohol/ eugenol, cinnamyl acetate/ acetyleugenol, cinnamyl alcohol/ isoeugenol, and acetyl eugenol/ isoeugenol. The components that showed additive effects were benzyl benzoate /eugenol, cinnamyl acetate/ eugenol, benzyl benzoate/ cinnamyl acetate, isoeugenol/ carvone, and cinnamyl alcohol/ carvone. Carvone showed synergistic activity with benzyl benzoate, methyl eugenol, and cinnamyl acetate. The synergistic nematicidal activity of carvone and phenylpropanoids may be explained by the differing modes of action between phenylpropanoids and terpenes. Although carvone effectively inhibits acetylcholinesterase, phenylpropanoids induce oxidative stress. The combination of these mechanisms has the potential to significantly enhance the nematicidal activity of the formulations [46].
Further synergy was documented in a study by Jardim et al. [83], where garlic EO displayed remarkable efficacy against J2 mortality and immobility, hatching inhibition, and reduction of eggs and galls in soil. The two main components of the oil, diallyl trisulfide (DATS) and diallyl disulfide (DADS), were found to exhibit a synergistic effect. The combination of DADS and DATS immobilized and killed a larger number of J2s compared to the sum of their individual effects. Interestingly, when DADS and DATS were tested individually, they could not match the immobility or mortality values of the essential oil at proportional concentrations. However, when combined, their activity surpassed that of the essential oil. For instance, a 56 μg mL−1 solution of DATS + DADS (14 + 42 μg mL−1, respectively) immobilized and killed 100% of J2s, while the essential oil at 62 μg mL−1 achieved 85.5% immobility and 82.3% mortality of J2s. These findings imply that other components of the EO interfere with the action of DADS and DATS against M. incognita J2.
A similar scenario was observed in the case of Cymbopogon schoenanthus, where the EO exhibited toxicity to M. incognita J2 with an EC50/72 h value of 288 mg/L after 24 h. However, its main compound, piperitone, failed to demonstrate any nematicidal activity at 500 mg/L. Hence, the nematotoxicity of the EO may be attributed to other single major components or synergistic interactions with piperitone [46]. The two major components of EO derived from black pine—α-pinene and c-verbenol—did not affect M. javanica, but the concentration of 1 μg/mL showed J2 mortality 81, 48%, indicating that synergies among the other minor components caused the nematicidal action [62].

5. Concluding Remarks and Future Perspectives

The tested essential oils from various botanical families, including Lamiaceae, Asteraceae, Apiaceae, Myrtaceae, and others, have demonstrated potential in nematicidal activity, particularly against RKN of the Meloidogyne genus. These effects are primarily attributed to the chemical composition of the EOs, where most of the compounds in reported experiments were mostly terpenes. Terpenes exhibit a broad occurrence across diverse plant species belonging to different plant families. Their nematicidal effect stems from their capability to disturb plasma membrane permeability, affect nematode nervous systems, disrupt intracellular redox balance, trigger apoptosis-related signaling pathways, and induce DNA damage. Studies report on nematicidal outcomes from the use of certain EOs derived from genera such as Mentha, Citrus, Cymbopogon, and Thyme, showcasing promising potential in inhibiting egg hatching, penetrating the gelatinous matrix of an egg, inducing juvenile paralysis, and increasing mortality rates. Notably, the biological activity of these EOs is often concentration-dependent, with variations influenced by the specific chemical properties of their constituents. For example, compounds like geraniol, carvacrol, linalool, pinene, eugenol, and other constituents of EOs exhibited great efficacy against Meloidogyne spp. in most experiments.
Incorporating EOs into pest management strategies, including nematode control, underscores the necessity for a nuanced understanding of their primary constituents, synergistic or antagonistic interactions, and the fundamental mechanisms that affect their effectiveness. Therefore, further knowledge is required on the synergies and antagonism of EO components, which is crucial for modifying them by adding synergistic natural compounds or blending them in optimal proportions. These modifications could lead to the development of more potent and effective final products, potentially impacting the market prices and enhancing benefits for users [46]. Interestingly, beyond the nematicidal potential, essential oils have demonstrated satisfactory results in various other parameters in a wide range of experimental settings. These oils exhibited insecticidal, antifungal, antibacterial, and herbicidal activity, as well as a positive effect on plant growth parameters. For instance, the antifungal potency of certain EOs derived from thyme, spearmint, black mustard, ginger, and fennel is attributed to their ability to penetrate and disrupt the fungal cell walls and cytoplasmic membranes, leading to their permeabilization and damage to the mitochondrial membranes, thus inhibiting fungal growth [17,44,57,64]. Moreover, EOs from Juniperus communis, Pinus nigra, Abies alba, and Douglas fir showed insecticidal activity, causing antifeedant symptoms and eventual death of aphids (Aulacorthum solani Kalt, Rhopalosiphum padi, Myzus persicae, Phyllaphis fagi) through tarsi, ingestion, or the respiratory system [57,62]. Arya et al. [64] observed that EOs of Hedychium coccineum Buch. Ham. ex Sm. (ginger) showed effects against bacteria like Staphylococcus aureus and Salmonella enterica serovar Typh, and even herbicidal activity against Raphanus raphanistrum subsp. Sativus (radish) seeds. Moreover, the EO of basil and mint increased dry weight on pepper plants [44], and lavandin EO enhanced the root system and green biomass of tomato plants [38], indicating the growth-promoting potential of EOs.
Despite substantial research on botanicals for plant protection purposes, relatively limited attention has been directed toward exploring their potential in alternative formulations (except EOs), such as hydrosols, nanoemulsions, crude extracts, water extracts, or powders for nematode control. Although observations indicate variations in their effectiveness, the results between EOs and the mentioned formulations differ significantly. This discrepancy arises from significant differences in their chemical composition, even though they originate from the same plant source. For instance, nonpolar compounds in essential oils, due to limited solubility in water, cannot be detected in their hydrosols, demonstrating the importance of these distinctions) [55]. Identifying plant-derived compounds with potent nematicidal properties that may not be part of essential oil composition is critical. Aquatic extracts of Achillea wilhelmsii, Tanacetum polycephalum, and Teucrium polium predominantly contain polyphenols (such as gallic acid, catechin, and chlorogenic acid), which exhibit nematicidal activity, while they are absent in the respective EOs [50]. Moreover, experiments with nanoemulsions demonstrated their superiority over essential oils in nematode effects, owing to improved stability derived from reduced oil particle size [43]. Essential oils, with low water solubility and larger particle sizes, encounter difficulty interacting with cell membranes compared to nanoemulsion particles, enabling better access of essential oils to nematode cell membranes, thus leading to more effective nematode hindrance and eradication [44]. Moreover, employing essential oils in nanoemulsion form offers additional advantages, including the ability to disperse in irrigation water, rapid adhesion and penetration of plant roots, long-lasting presence in the soil, and effective nematode suppression [43].
Although the aromatic plant-based biopesticide market is expanding steadily, it remains a minor fraction of the global market. This limited representation can be attributed to their inconsistent performance and the scarcity of field studies evaluating their efficacy [25]. This raises the question: can different experimental settings influence the results? Hence, effective EOs and their active components tested in vitro must be evaluated in field conditions. Investigating terpenes’ nematicidal effects proves complex due to the compounds’ mixture in plant essential oils, which contain multiple constituents rather than isolated terpenes. Determining specific terpenes responsible for nematicidal activity becomes challenging, compounded by variations in nematode species, life stages, and environmental conditions across studies [84]. Furthermore, Kotsinis et al. [84] reported that the same compound, such as geraniol, successfully controlled Meloidogyne spp., but showed incompatibility with entomopathogenic nematode species (e.g., Heterorhabditis spp.). Research on EOs requires further exploration to consider factors affecting their efficacy, such as procedural errors affecting chemical composition, color variation, and unpleasant odors, diminishing overall quality, with factors like raw materials, plant parts, solvents, temperature, pressure, and time influencing these outcomes [36,85]. Understanding the potential phytotoxicity of high EO concentrations and their impact on beneficial nematode populations is crucial. Higher EO concentrations often yield better nematicidal results; however, only a limited number of studies have reported on their potential phytotoxic effects [86,87,88,89]. Moreover, studies suggest that EOs such as cinnamon, clove, garlic, peppermint, lemongrass, thyme, pine, and eucalyptus oils might adversely affect beneficial nematodes, compromising their survival and behavior [90].
Exploring appropriate technical formulations of EO-based nematicides, such as micro- or nano-encapsulation, to achieve controlled release and gradual degradation of the EO’s active constituents is imperative. This approach would extend and enhance the nematicidal effectiveness of EO-based soil treatments while mitigating their high volatility, rapid dispersion, and degradation [40]. As a result, standardized plant culture and EO extraction processes should be considered to produce commercial products with standardized compositions and nematicidal efficacy. Understanding how different EO compounds interact with nematodes, along with the challenges posed by natural EO properties, is crucial. This knowledge could lead to the creation of more effective and targeted natural insecticides in the future that are practical and environmentally beneficial.

Author Contributions

Conceptualization, N.N. and N.M.; methodology, N.M.; investigation, K.S.; writing—original draft preparation, K.S. and S.M.; writing—review and editing, S.M., N.M. and N.N.; visualization, S.M.; supervision, N.M. and N.N. All authors have read and agreed to the published version of the manuscript.

Funding

This publication is co-financed by Greece and the European Union (European Social Fund-SF) through the Operational Program “Human Resources Development, Education and Lifelong Learning 2014–2020” in the context of the project “Support for Internationalization Actions of the International Hellenic University”, (MIS 5154651).

Data Availability Statement

No new data were created.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Botanical families identified as plant sources for nematode-controlling essential oils in the dataset.
Figure 1. Botanical families identified as plant sources for nematode-controlling essential oils in the dataset.
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Figure 2. Number of nematicidal studies performed per Meloidogyne species (M. incognita, M. Javanica, M. graminicola, M. hapla, M. ethiopica, and M. enterolobii).
Figure 2. Number of nematicidal studies performed per Meloidogyne species (M. incognita, M. Javanica, M. graminicola, M. hapla, M. ethiopica, and M. enterolobii).
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Figure 3. Compounds of EOs and their mode of action against root-knot nematodes.
Figure 3. Compounds of EOs and their mode of action against root-knot nematodes.
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Figure 4. Synergistic and antagonistic interactions between the components of essential oils. Reported synergies were extracted from studies by [40,46,49,62,83].
Figure 4. Synergistic and antagonistic interactions between the components of essential oils. Reported synergies were extracted from studies by [40,46,49,62,83].
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Table 1. Plant sources of the essential oils belonging to the family Lamiaceae, their components with nematicidal action in different experimental settings against Meloidogyne spp.
Table 1. Plant sources of the essential oils belonging to the family Lamiaceae, their components with nematicidal action in different experimental settings against Meloidogyne spp.
Plant Source of the Essential OilActive ComponentsTarget Life StageMode of ActionCropExperimentMeloidogyne spp.Experiment DetailsAuthor
Lamiaceae
Lavandula Intermedia
(3 species: Abrialis, Cerioni and Sumiens)		linaloolJ2, eggsJ2 mortality, egg-hatching inhibition, reduction of galls, eggstomatoin vitro, pot, greenhouse, soilM. incognitaEO: 24.9 μg/mL−1, 1.2 μg/mL−1, 17.4 μg/mL−1.[38]
Lavandula officinalis, Mentha arvensis, Thymus serpyllum, Ocimum basilicum Galls, eggsReduction of galls and eggstomatoin vitro, potsM. incognitaEO: 3% and 5% (v/v)[39]
Monarda didyma, Monarda fistulosaγ-terpinene, o-cymene, carvacrolEggs, J2J2 mortality, egg-hatching inhibition, reduction of galls and eggs in soiltomatoin vitro, soilM. incognitaEO: 1.0 μL mL−1, 12.5 μL mL−1 for 24 h (J2 mortality)
500 and 1000 μg mL−1 for 24, 48 h (egg hatching)		[40]
Mentha longifoliapiperitone oxideJ2, eggsJ2 mortality, Egg hatch inhibition M. graminicolaEO: 15.62 to 1000 ppm for 96 h[41]
Mentha longifoliai-menthoneEggEgg hatch inhibition in vitroM. hapla [42]
Mentha spicata L.carvone, limoneneJ2, eggsJ2 mortality, reduction of galls and eggsColeusin vitro, greenhouseM. javanicaEO: 1000, 2000, 3000, 4000, and
5000 ppm (v/v) for 24 h, 48 h, 72 h		[43]
Mentha spicata L. J2J2 mortality, reduction of gallspepperin vitro, greenhouse, plastic houseM. incognitaEO: 5% (v/v) for 72 h[44]
Mentha spicatacarvoneEggEgg hatch inhibition in vitroM. hapla [42]
Menta piperitacarvoneJ2J2 mortality in vitroM. hapla [42]
Nepeta cateria J2J2 mortalitybananaorchardM. incognitaEO: 1.2 mL/L[45]
Basilicum L.sabinene, myrcene, trans-caryophylleneJ2J2 mortality, reduction of gallspepperin vitro, greenhouse, plastic houseM. incognitaEO: 5% (v/v) for 72 h[44]
Ocimum sanctum L.eugenol methyl etherJ2J2 mortality in vitroM. incognitaEO: 1230 mg/L for 24 h[46]
Ocimum basilicumi-linaloolJ2J2 mortality in vitroM. hapla [42]
Origanum onitescarvacroleggEgg hatch inhibition in vitroM. hapla [42]
Origanum onitescarvacroleggEgg hatch inhibition in vitroM. hapla [42]
Pogostemon cablin Benthα-guaiene, patchoulol, α-bulneseneJ2J2 mortality, J2 immobility in vitroM. incognitaEO: 250 μg/mL−1,
31.25 μg/mL−1 for 24 h		[47]
Pogostemon cablinα-guaieneJ2J2 mortality, paralysispepperin vitro, greenhouse, plastic houseM. incognitaEO: 387.77 μg mL−1 for 48 h[48]
Salvia officinalisthujoneeggEgg hatch inhibition in vitroM. hapla [42]
Thymus citriodorusgeraniolJ2, eggsBiological cycle arrest, J2 paralysis, J2 mortalitytomatoin vitro, potM. incognitaEO: 50 µL kg−1 soil[49]
Teucrium poliumlimonene, α-pinene, β-pineneJ2J2 mortality in vitroM. incognitaEO: 4000 and 8000 ppm (v/v) for 24 h[50]
Thymus linearis Benththymol, carvacrolJ2, eggsJ2 mortality, Egg hatch inhibition in vitroM. incognitaRainy season: 5 μL/mL for 72 h (J2 mortality), 2 μL/mL for 72 h (egg hatching)
Winter season: 8 μL/m for 72 h (J2 mortality),2 μL/mL for 72 h (egg hatching)		[51]
Thymus vulgaris L.thymol, ρ-cymeneJ2, eggsJ2 mortality, reduction of galls and eggsColeusin vitro, greenhouseM. javanicaEO: 1000, 2000, 3000, 4000, and
5000 ppm (v/v) for 24 h, 48 h, 72 h 		[43]
Zataria multiflora J2J2 mortalitybananaorchardM. incognitaEO: 1.2 mL/L[45]
Table 2. Plant sources of the essential oils belonging to different botanical families, their components with nematicidal action in different experimental settings against Meloidogyne spp.
Table 2. Plant sources of the essential oils belonging to different botanical families, their components with nematicidal action in different experimental settings against Meloidogyne spp.
Plant Source of the Essential OilActive ComponentsTarget Life StageMode of ActionCropExperimentMeloidogyne spp.Experiment DetailsAuthor
Acoraceae
Acorus calamusβ-asaroneJ2 J2 mortality, J2 paralysis in vitroM. incognitaEO: 524.45 μg mL−1 for 24 h[48]
Amaranthaceae
Dysphania ambrosioides(z)-ascaridole, e-ascaridole, p-cymeneEggs, J2J2 mortality, egg-hatching inhibition, reduction of galls and eggstomatoin vitro, potsM. incognitaEO: 500 μg mL−1 for 48 h[52]
Amaryllidaceae
Allium sativumdiallyl disulfide (DADS), diallyl trisulfide (DATS), methyl allyl trisulfideEggs, J2J2 mortality, egg-hatching inhibitionTomatoin vitro, potsM. javanicaEO: 0.025 μg mL−1 for 72 h
Hydrolat: 0.125 μg mL−1 for 72 h		[53]
Allium sativumdiallyl disulfide (DADS), diallyl trisulfide (DATS)Eggs, J2J2 mortality, egg-hatching inhibition, reduction of galls and eggsTomatoin vitro, greenhouse, potsM. incognitaEO: 500 μg mL−1
Components: 62 μg mL−1		[53]
Anacardiaceae
Schinus terebinthifoliusterpinen-4-ol, γ-terpinene, α-terpineolEggs, J2J2 mortality, egg-hatching inhibitionlettucein vitro, fieldM. javanica [54]
Apiaceae
Coriandrum sativumlinaloolJ2J2 mortality in vitro, labM. hapla [42]
Cuminum cyminumγ-terpinen-7-al, α-terpinen-7-al, cumin aldehydesJ2, EggsJ2 mortality, egg-hatching inhibition, J2 paralysis, egg differentiation, reduction of nematode population in soilTomatoin vitro, potsM. javanicaEO: 62.5 μL/L,
2000 μL/L for 48 and 96 h of immersion		[55]
Daucus carotacarotol, daucol, dauceneJ2, EggsJ2 mortality, egg-hatching inhibition in vitroM. incognitaEO: 2500 ppm for 96 h[56]
Ferula oopoda J2J2 mortalityBananaOrchardM. incognitaEO: 1.2 mL/L[45]
Foeniculum vulgareanetholeJ2J2 mortality in vitro, labM. hapla [42]
Ridolfia segetum(z)-β-ocimene, β-pineneJ2, EggsJ2 mortality, J2 mobility, and egg-hatching inhibition in vitro, labM. javanicaEO: 16 μL/mL for 72 h[57]
Asteraceae
Artemisia absinthiumborneol acetate, β-terpineolJ2J2 mortality, J2 paralysis in vitroM. incognitaEO: 937.52 μg mL−1 for 48 h [48]
Artemisia absinthium-Galls, eggsReduction of galls and eggsTomatoin vitro, potsM. incognitaEO: 3% and 5% (v/v)[39]
Artemisia nilagiricaα-thujone, α-myrcene, linalyl isovalerate, camphor, caryophyllene oxide, eucalyptolJ2, EggsJ2 mortality, egg-hatching inhibition, reduction of galls, eggs, and nematodes in soilTomatoin vitro, greenhouseM. incognitaEO: 20 μg/mL for 48 h [18]
Achillea santolina J2J2 mortalityBananaOrchardM. incognitaEO: 1.2 mL/L[45]
Achillea wilhelmsii1,8-cineole, limonene, α-pinene, β-pineneJ2J2 mortality in vitroM. incognitaEO: 4000 and 8000 ppm (v/v) for 24 h[50]
Tanacetum falconeri Hook. f.cis-dehydromatricaria ester-1J2J2 mortality in vitroM. incognitaEO: 1% (w/v) for 24 h [58]
Tanacetum polium(e)-caryophyllene, limonene, α-pinene, β-pineneJ2J2 mortality in vitroM. incognitaEO: 4000 and 8000 ppm (v/v) for 24 h[50]
Brassicaceae
Brassica nigraallyl isothiocyanate (AITC)J2 J2 mortality, J2 paralysis in vitroM. incognitaEO: 47.7 μg mL−1 for 72 h[17]
Burseraceae
Commiphora myrrhafuranoeudesm-1,3-diene, curcereneJ2 J2 mortality, J2 paralysis in vitroM. incognitaEO: 1000 μg mL−1 for 24 h[48]
Fabaceae
Piptadenia viridiflorabenzaldehydeJ2J2 mortality in vitroM. incognitaEO: 1000 μg mL−1,
Component: 100 and 200 μg mL−1 for 48 h		[59]
Tephrosia toxicariaβ-caryophyllene, germacrene D, a-humulene, bicyclogermacreneEggs, J2J2 mortality, egg-hatching inhibition in vitroM. javanica/M. enterolobiiEO: 50, 100, 200, 400, 600, 800 μg mL−1 for 48 h[60]
Trifolium incarnatum(z)-3-hexenyl acetates, (Z)-3-hexane-1-ol, (E) -ocimene, furanoeudesm-1,3-dieneJ2J2 mortality, reduction of gallschili pepper (Capsicum annuum L.)in vitro, greenhouse, plastic houseM. incognitaEO: 3% and 5% (v/v) for 48 h[44]
Hypericaceae
Hypericum perforatum Galls, eggsReduction of galls and eggstomatoin vitro, potsM. incognitaEO: 3% and 5% (v/v)[39]
Lauraceae
Cinnamomum cassia(e)-cinnamaldehydeEggs, J2J2 mortality, J2 paralysis, reduction of galls and eggsSoybeanin vitro, in greenhouse potsM. incognitaEO: 62 μg/mL−1
Component: 208 μg/mL−1 for 48 h		[34]
Cinnamomum zeylanicum BlumeeugenolJ2 J2 mortality, J2 paralysis in vitroM. incognitaEO: 391 mg/L for 24 h [46]
Cinnamomum zeylanicum(e)-cinnamaldehyde, eugenolEggs, J2J2 mortality, egg-hatching inhibition, reduction of galls and eggs in vitro, potsM. incognitaEO: 49 μg/mL−1,
Components: 529 and 768 μg/mL−1 for 48 h		[59]
Laurus nobilis L.linalool, 1, 8-cineole, α-pinene, β-pinene, α-terpinyl acetateEggs, J2J2 mortality, egg-hatching inhibition in vitroM. incognitaEO: 0.80 μg/mL−1 for 96 h[56]
Myrtaceae
Eucalyptus citriodoracitronellalJ2 J2 mortality, J2 paralysis in vitroM. incognitaEO: 746.48 μg mL−1 for 24 h[48]
Eucalyptus citriodora Galls, eggsReduction of galls and eggstomatoin vitro, potsM. incognitaEO: 3% and 5% (v/v)[39]
Melaleuca alternifoliaβ-terpineol, γ-terpineneJ2 J2 mortality, J2 paralysis in vitroM. incognitaEO: 404.13 μg mL−1 for 24 h[48]
Myrtus communisα-pinene, 1,8-cineolJ2 J2 mortality, J2 paralysis in vitroM. incognitaEO: 932.65 μg mL−1 for 48 h[48]
Syzygium aromaticumeugenolJ2J2 mortality in vitroM. graminicolaComponent: 500 ppm for 48 h [61]
Pinaceae
Pinus nigraa-pinene, c-verbenolJ2J2 mortality in vitroM. javanicaEO: 1 μg mL−1
Compounds: 0.5 μg mL−1		[62]
Piperaceae
Piper nigrum Galls, eggsReduction of galls and eggstomatoin vitro, potsM. incognitaEO: 3% and 5% (v/v)[39]
Poaceae
Cymbopogon flexuosuscitralJ2J2 mortality in vitroM. graminicolaComponent: 500 ppm for 48 h[61]
Cymbopogon martiniigeraniolJ2J2 mortality in vitroM. graminicolaComponent: 500 ppm for 48 h[61]
Cymbopogon narduscitronellal, geraniolJ2 J2 mortality, J2 paralysis in vitroM. incognitaEO: 325.41 μg mL−1 for 24 h[48]
Cymbopogon schoenanthus (L.) SprengpiperitoneJ2 J2 mortality, J2 paralysis in vitroM. incognitaEO: 524 mg/L for 24 h [46]
Vetiveria zizanioides (L.)
(extract)		sesquiterpene acid 3,3,8,8-tetramethyltricyclo[5.1.0.0(2,4)]oct-5-ene-5-propanoic acid, 6-isopropenyl-4,8a-dimeth yl-1,2,3,5,6,7,8,8a-octahydronaphthalen-2-ol J2 mortality in vitroM. graminicolaEO: 0.95 mg/mL for 72 h[63]
Rutaceae
Citrus bergamia Galls, eggsReduction of galls and eggstomatoin vitro, potsM. incognitaEO: 3% and 5% (v/v)[39]
Citrus reticulatalimoneneEggs, J2J2 mortality, egg-hatching inhibition in vitroM. incognitaComponent: 1500 μg/mL−1 for 96 h [16]
Citrus sinensisl-limonene J2 J2 mortality, J2 paralysis in vitroM. incognitaEO: 353.20 μg mL−1 for 24 h[48]
Verbenaceae
Lippia citriodoracitralEgg Egg hatch inhibition in vitroM. hapla [42]
Zingibiraceae
Hedychium coccineume-neradiol, davanone B, spathulenol, eucalyptolEggs, J2J2 mortality, egg-hatching inhibition in vitroM. incognitaEO: 0.25 μg/mL for 24 h
1 μg/mL for 96 h		[64]
Zingiber officinale Galls, eggsReduction of galls and eggstomatoin vitro, potsM. incognitaEO: 3% and 5% (v/v)[39]
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Sarri, K.; Mourouzidou, S.; Ntalli, N.; Monokrousos, N. Recent Advances and Developments in the Nematicidal Activity of Essential Oils and Their Components against Root-Knot Nematodes. Agronomy 2024, 14, 213. https://doi.org/10.3390/agronomy14010213

AMA Style

Sarri K, Mourouzidou S, Ntalli N, Monokrousos N. Recent Advances and Developments in the Nematicidal Activity of Essential Oils and Their Components against Root-Knot Nematodes. Agronomy. 2024; 14(1):213. https://doi.org/10.3390/agronomy14010213

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Sarri, Konstantia, Snezhana Mourouzidou, Nikoletta Ntalli, and Nikolaos Monokrousos. 2024. "Recent Advances and Developments in the Nematicidal Activity of Essential Oils and Their Components against Root-Knot Nematodes" Agronomy 14, no. 1: 213. https://doi.org/10.3390/agronomy14010213

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