Exploring Contact Toxicity of Essential Oils against Sitophilus zeamais through a Meta-Analysis Approach
Abstract
:1. Introduction
2. Results
2.1. Scientific Articles Selection
2.2. Descriptive Analysis
2.3. Direct Contact Meta-Analysis
2.4. Indirect Contact Meta-Analysis
3. Discussion
4. Materials and Methods
4.1. Search Strategy
4.2. Study Selection
4.3. Statistical Analyses
5. Conclusions
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Family | Plant species | EO main components (%) | Ref. |
---|---|---|---|
Amaranthaceae | Cananga odorata | linalool (21.1), linalool acetate (16.1), α-pinene (12.7) | [29] |
Chenopodium ambriosioides | (Z)-ascaridole (29.7), isoascaridole (13.0), ρ-cymene (12.7) | [30,31] | |
Anacardiaceae | Schinus molle | β-pinene (15.4), α-phellandrene (14.9), ϱ-cimene (10.8) | [32] |
Annonaceae | Monodora myristica | p-cymene (31.5), α-phellandrene (18.1), α-pinene (6.1) | [33] |
Apiaceae | Anethum graveolens | (S)-carvone (66.4), β-phellandrene+limonene (24.7) | [34] |
Carum carvi | (R)-carvone (37.9), limonene (26.5), α-pinene (5.2) | [35] | |
Cuminum cyminum | cuminaldehyde (39.4), γ-terpinene (15.8), β-pinene (12.4) | [34] | |
Foeniculum vulgare | limonene (41.8), (E)-anethole (17.9), α-pinene (11.1) | [36] | |
Heracleum moelledorffii | apiol (11.0), β-pinene (9.2), α-terpineol (7.5) | [37] | |
Ligusticum chuanxiong | 3-butylidenephthalide (20.6), Z-ligustilide (19.6), 4-terpineol (8.8) | [38] | |
Ostericum grosseserratum | limonene (16.2), 4-terpineol (13.5), myristicin (11.3) | [39] | |
Ostericum sieboldii | myristicin (30.3), α-terpineol (9.9), α-cadinol (7.2) | [40] | |
Petroselinum crispum | myristicin (31.5), α-pinene (16.2), apiole (15.9) | [34] | |
Steganotaenia araliacea | α-pinene, α-copaene | [41] | |
Apocynaceae | Periploca sepium | 2-hydroxy-4-methoxy-benzaldehyde (78.8), linalool (2.8), α-terpineol (2.7) | [42] |
Asteraceae | Ainsliaea fragrans | myristicin (41.3), elemicine (11.9), cis-isosafrole (11.5), borneol (9.1) | [43] |
Artemisia capillaris | β-pinene (12.6), germacrene D (8.3), γ-terpinene (8.1) | [44] | |
Artemisia eriopoda | germacrene D (21.6), | [45] | |
Artemisia frigida | cis-p-menth-2-en-1-ol (20.8), 1,8-cineole (14.2)1,8-cineole (12.0) | [46] | |
Artemisia giraldii | β-pinene (13.1), isoelemicin (10.0), germacrene D (5.6) | [47] | |
Artemisia igniaria | 1,8-cineole (14.3), camphor (13.3), germacrene D (8.7) | [48] | |
Artemisia lavandulaefolia | caryophyllene (15.5), β-thujone (13.8), 1,8-cineole (13.1) | [49] | |
Artemisia mongolica | 1,8-cineole (13.7), germacrene D (10.4), camphor (8.5) | [44] | |
Artemisia sieversiana | 1,8-cineole (9.2), geranyl butyrate (9.2), borneol (7.9), camphor (7.9) | [49] | |
Artemisia subdigitata | 1,8-cineole (12.2), α-curcumene (10.7), β-pinene (7.3) | [47] | |
Artemisia vestita | grandisol (40.2), 1,8-cineole (14.8), camphor (11.3) | [50] | |
Aster ageratoides | α-terpineol (10.8), β-caryophyllene (10.3), linalool (7.2) | [51] | |
Baccharis dracunculifolia | β-pinene (18.0), ledol (13.6), spathulenol (13.4) | [52,53] | |
Echinops latifolius | 1,8-cineole (19.6), (Z)-β-ocimene (18.4), β-pinene (15.5) | [54] | |
Tagetes minuta | tagetone (11.8), dihydrotagetone (10.7), ocimene (8.8) | [55,56] | |
Atherospermataceae | Laurelia sempervirens | safrole (64.7), methyl eugenol (14.6), 1,8-cineole (1.4) | [57] |
Caprifoliaceae | Dipsacus japonicus | linalool (11.7), (E)-geraniol (8.5), 1,8-cineole (7.9), β-caryophyllene (5.5) | [58] |
Lonicera japonica | estragole (80.1), linalool (6.0), germacrene D (3.1) | [21] | |
Nardostachys jatamansi | calerene (25.9), patchoulol (10.6), α-gurjunene (7.5) | [59] | |
Cupressaceae | Cupressus lusitanica | umbellulone (18.4), α-pinene (10.0), sabinene (8.2) | [60] |
Cupressus sempervirens | α-pinene (17.6), 3-carene (25.9), limonene (10.5), sabinene (9.4), terpinen-4-ol (4.7) | [30] | |
Ericaceae | Rhododendron anthopogonoides | 4-phenyl-2-butanone (27.2), nerolidol (8.0), 1,4-cineole (7.8) | [61] |
Euphorbiaceae | Croton pulegiodorus | p-cymene (23.1), ascaridole (22.5), α-terpinene (9.3) | [62,63] |
Mallotus apelta | β-eudesmol (18.6), β-caryophyllene (9.8), β-selinene (6.5) | [64] | |
Geraniaceae | Pelargonium hortorum | 1,8-cineole (23.0), α-terpineol (13.2), α-pinene (8.1) | [65] |
Lamiaceae | Amethystea caerulea | morrilol (25.1), 4-vinylguaiacol (14.3), 2-acetoanisole (14.3) | [66] |
Caryopteris incana | estragole (24.8), linalool (14.0), 1,8-cineole (5.2) | [67] | |
Dracocephalum moldavica | 1,8-cineole (31.2), 4-terpineol (22.8), cumyl alcohol (4.2) | [68] | |
Hyssopus cuspidatus | thymol (19.6), (E)-pinocamphone (15.3), γ-terpinene (14.6) | [69] | |
Mentha longifolia | 1-8-cineole (25.5), menthone (17.9), pulegone (29.9) | [70] | |
Mosla soochowensis | β-caryophyllene (12.8), spathulenol (6.3), β-eudesmol (6.2) | [71] | |
Ocimum basilicum | linalool (62.5), methyl chavicol (30.9) | [36,72] | |
Ocimum gratissimum | (E)-anethole (35.0), limonene (15.6), eugenol (9.1) | [36] | |
Phlomis umbrosa | geranial (16.5), linalool (13.3), cis-geraniol (7.4) | [73] | |
Plectranthus glandulosus | cis-piperitone oxide (18.5), fenchone (18.3), piperitone epoxide (17.7), terpinolene (8.7), piperitone oxide (8.9) | [74] | |
Salvia umbratica | 1,8-cineole (16.7), β-caryophyllene (8.4), α-thujone (7.8) | [75] | |
Schizonepeta multifida | menthone (40.3), pulegone (26.9) | [76] | |
Lauraceae | Cinnamomum camphora | camphor (68.0), linalool (9.0) | [77] |
Cryptocarya alba | (E)-β-bergamotene (15.6), viridiflorol (8.5), germacrene-D (7.7) | [78] | |
Lindera aggregata | α-longifolene (15.1), bornyl acetate (11.4), α-eudesmol (9.1) | [79] | |
Ocotea odorifera | camphor (43.0), safrole (42.0), spathulenol (2.0) | [80] | |
Meliaceae | Azadirachta indica | hexadecanoic acid (34.0), oleic acid (15.7) | [81,82] |
Monimiaceae | Laureliopsis philippiana | safrole (39.6), linalool (34.5), 1,8-cineole (8.3) | [83] |
Peumus boldus | ascaridole (24.4), 1,8-cineole (14.9), trans-β-ocimene (12.9) | [83] | |
Myrtaceae | Corymbia citriodora | citronellal (61.8), isopulegol (15.5), β-citronelol (7.9) | [84] |
Eucalyptus benthamii | α-pinene (54.0), viridiflorol (17.0) 1,8-cineole (10.0) | [85] | |
Eucalyptus dunni | 1,8-cineole (53.5), α-pinene (21.5), viridiflorol (8.3) | [85] | |
Eucalyptus globulus | 1,8-cineole (77.5), α-pinene (14), α-terpineol (1.3) | [85] | |
Eucalyptus saligna | 1,8-cineole (45.2), p-cymene (34.4) α-pinene (12.8) | [85] | |
Eucalyptus staigeriana | limonene (28.7), geranial (15.2), neral (12.2) | [36] | |
Eucalyptus viminalis | 1,8-cineole (77.0), α-pinene (15.0), viridiflorol (2.3) | [85] | |
Piperaceae | Piper aduncum | dilapiol (74.0), safrol (3.9), sarisan (2.8) | [86] |
Piper capense | β-pinene (59.3), sabinene (14.7), α-pinene (10.5) | [87] | |
Piper guineense | β-caryophyllene (20.8), limonene (15.8), β-pinene (12.1) | [87] | |
Piper hispidinervum | dilapiol (74.0), safrol (3.9), sarisan (2.8) | [86] | |
safrole (82.07) | [36] | ||
Piper nigrum | 3-carene (18.5), limonene (14.7), β-caryophyllene (12.8) | [87] | |
Poaceae | Cymbopogon citratus | geranial (40.1), neral (29.7) and myrcene (11.3) | [33] |
Cymbopogon nardus | citronellal (36.5), geraniol (25.6), elemol (8.2) | [84] | |
Cymbopogon winterianus | citronellal (35.5), geraniol (21.8), citronellol (10.9) | [36] | |
Rutaceae | Boenninghausenia sessilicarpa | α-cadinol (12.0), carvacrol (8.8), germacrene D (6.2), o-cymene (6.1) | [88] |
Citrus aurantiifolia | limonene (38.9), R-mentha-2,4(8)-diene (5.7), α-terpineol (5.2) | [24] | |
Citrus reticulata | limonene (80.2), myrcene (6.7), linalool (3.7) | [24] | |
Citrus x sinensis | limonene (96.1), β-myrcene (1.9), linalool (0.9) α -pinene (0.5) | [89,90] | |
Evodia lepta | α-pinene (26.6), borneol (7.2), trans-pinocarveol (6.8) | [91] | |
Glycosmis parviflora | (Z)-caryophyllene (20.6), methyl isoeugenol (11.1), (Z)-β-ocimene (8.9) | [92] | |
Murraya exotica | spathulenol (17.7), α-pinene (13.3), caryophyllene oxide (8.6) | [93] | |
Ruta graveolens | 2-undecanone (30.7), 2-nonanone (20.8), 4-hydoroxypyridine1-oxide (6.7) | [94] | |
Zanthoxylum schinifolium | linalool (12.9), α-tumerone (8.9), limonene (6.5), elixene (5.4) | [14] | |
Schisandraceae | Illicium difengpi | safrole (23.6), linalool (12.9), germacrene D (5.3) | [95] |
Illicium fargesii | α-terpineol (11.4), carvone (10.9), limonene (9.8) | [96] | |
Illicium pachyphyllum | trans-p-mentha-1(7),8-dien-2-ol (24.5), limonene (9.7) | [97] | |
Illicium simonsii | β-caryophyllene (10.3), δ-cadinene (9.5), methyl eugenol (8.9) | [98] | |
Illicium verum | anethole (77.4), estragole (5.8), p-anisaldehyde (5.6) | [90] | |
Kadsura heteroclita | α-eudesmol (17.5), 4-terpineol (9.7), δ-cadinene (9.2) | [99] | |
Taxaceae | Cephalotaxus sinensis | α-pinene (38.0) β-caryophyllene (17.0) germacrene D (11.0) | [100] |
Vataceae | Cayratia japonica | linalool (19.4), trans-α-ionene (11.4), α-terpineol (7.9) | [101] |
Verbenaceae | Lippia adoensis | geraniol (37.2), linalool (27.7), β-farnesene (10.8) | [102] |
Zingiberaceae | Zingiber officinale | α-zingiberene (28.9), β-sesquiphellandrene (13.1), Z-γ-bisabolene (12.5) | [33] |
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Achimón, F.; Peschiutta, M.L.; Brito, V.D.; Beato, M.; Pizzolitto, R.P.; Zygadlo, J.A.; Zunino, M.P. Exploring Contact Toxicity of Essential Oils against Sitophilus zeamais through a Meta-Analysis Approach. Plants 2022, 11, 3070. https://doi.org/10.3390/plants11223070
Achimón F, Peschiutta ML, Brito VD, Beato M, Pizzolitto RP, Zygadlo JA, Zunino MP. Exploring Contact Toxicity of Essential Oils against Sitophilus zeamais through a Meta-Analysis Approach. Plants. 2022; 11(22):3070. https://doi.org/10.3390/plants11223070
Chicago/Turabian StyleAchimón, Fernanda, Maria L. Peschiutta, Vanessa D. Brito, Magalí Beato, Romina P. Pizzolitto, Julio A. Zygadlo, and María P. Zunino. 2022. "Exploring Contact Toxicity of Essential Oils against Sitophilus zeamais through a Meta-Analysis Approach" Plants 11, no. 22: 3070. https://doi.org/10.3390/plants11223070