Repellent activity of essential oils against mediterranean fly and their effects on postharvest quality in paluma guava

Gonzaga, Kennedy S.; de Brito, Carlos H.; Salustino, Angélica da S.; de Souza, Maria Í. A.; Santos, João P. de O.; Sousa, Francisco de A. R. da M.

doi:10.1590/1983-21252023v36n205rc

ABSTRACT

Brazil is one of the world's largest guava (Psidium guajava) producing countries, but the economic performance of this crop can be negatively affected by the damage caused by Ceratitis capitata (Diptera: Tephritidae). The main methods for controlling C. capitata are based on broad-spectrum insecticide applications. However, the negative effects of using this control method stimulate the development of sustainable alternatives, such as the use of essential oils (EO). In this sense, the objective of the present study was to evaluate the repellent activity of EO of citronella (Cymbopogon nardus), clove (Syzygium aromaticum), and copaiba (Copaifera officinalis) for repellency of C. capitata in Paluma guava fruits and determine their effects on postharvest fruit quality, under laboratory-controlled conditions. The fruits were treated with citronella, clove, and copaiba EO and placed in covered plastic containers attached to the ends of arenas of 20 cm diameter and 15 cm height. The fruit physical and chemical analysis was carried out based on the same oils applied in the repellent test. The C. nardus essential oil presented a greater repellency of C. capitata females. The EO applications proved to be a good strategy for maintaining the fruit post-harvest quality.

Keywords:
Botanical insecticides; Alternative control; Fruit flies; Postharvest fruits

RESUMO

O Brasil está entre os maiores produtores mundiais de goiaba (Psidium guajava), mas o rendimento econômico dessa cultura pode ser negativamente afetado pelos danos causados por Ceratitis capitata (Diptera: Tephritidae). Os principais métodos de controle de C. capitata são baseados em aplicações de inseticidas de amplo espectro. Porém, os efeitos negativos do uso desse controle estimulam o desenvolvimento de alternativas sustentáveis, como o uso de óleos essenciais. Nesse sentido, o presente estudo teve como objetivo avaliar a atividade repelente dos óleos essenciais de citronela (Cymbopogon nardus), cravo (Syzygium aromaticum) e copaíba (Copaifera officinalis) em fruto de goiabeiras Paluma contra C. capitata e determinar suas influências na qualidade pós-colheita desses frutos trabalhados. Em condições controladas de laboratório, os frutos foram tratados com óleos essenciais de citronela, cravo e copaíba e acondicionados em recipientes de plástico com dimensões de 20 cm de diâmetro e 15 cm de altura. A análise físico-química dos frutos foi realizada com base nos mesmos óleos aplicados no teste de repelência. O óleo essencial de C. nardus apresentou maior repelência às fêmeas de C. capitata. A aplicação de óleos essenciais, mostrou-se uma estratégia para manutenção da qualidade póscolheita.

Palavras-chave:
Inseticidas botânicos; Controle alternativo; Moscasdas-frutas; Frutos pós-colheita

INTRODUCTION

Guava (Psidium guajava L.) is a fruit species from the family Myrtaceae that is widely grown in tropical and subtropical regions. Guava fruits are used for multiple purposes, due to its pleasant taste and nutritional value (WANG et al., 2018WANG, L. et al. Impact of fermentation degree on phenolic compositions and bioactivities during the fermentation of guava leaves with Monascus anka and Bacillus sp. Journal of Functional Foods, 41: 183-190, 2018.), which allowed it to enter different market niches (MOON et al., 2018MOON, P. et al. Assessment of fruit aroma for twenty-seven guava (Psidium guajava) accessions through three fruit developmental stages. Scientia Horticulturae, 238: 375-383, 2018.). Brazil is one of the world's largest guava producing countries, with a planted area of 15,200 hectares and an average yield of 22.7 Mg ha^-1 (GOMES et al., 2017GOMES, V. M. et al. Inheritance of resistance to Meloidogyne enterolobii and individual selection in segregating populations of Psidium spp. European Journal of Plant Pathology, 148: 699-708, 2017.) This fruit tree is grown mainly in the Northeast and Southeast regions of the country (IHA et al., 2018IHA, O. K. et al. Extraction and characterization of passion fruit and guava oils from industrial residual seeds and their application as biofuels. Journal of the Brazilian Chemical Society, 29: 2089-2095. 2018.).

Guava is one of the most infested fruits by Ceratitis capitata (Wied., 1824) (Diptera: Tephritidae) in Brazil (MACIEL et al., 2017MACIEL, A. A. S. et al. Diversity and infestation indices of fruit flies (Diptera: Tephritidae) in guava (Psidium guajava L.). African Journal of Agricultural Research, 12: 2087-2092, 2017.). Damages are caused by C. capitata at adults and larval stages. Females perforate the surface of fruits for oviposition, enabling the entry of pathogenic microorganisms; the larvae then feed on the fruit pulp, compromising the commercial quality (BOULAHIA-KHEDER, 2021aBOULAHIA-KHEDER, S. Review on major fruit flies (Diptera: Tephritidae) in North Africa: Bio-ecological traits and future trends. Crop Protection, 140: 1-10, 2021a.).

The main methods for controlling C. capitata are based on broad-spectrum synthetic insecticide applications, focusing mainly on adult forms (BOULAHIA-KHEDER, 2021bBOULAHIA-KHEDER, S. Advancements in management of major fruit flies (Diptera: Tephritidae) in North Africa and future challenges: A review. Journal of Applied Entomology, 145: 939-957, 2021b.). The indiscriminate use of insecticides can often cause problems to the fauna and environment, such as death of natural enemies, since most of these products are not selective (YADAV et al., 2017YADAV, A. et al. Toxic metals in the environment: threats on ecosystem and bioremediation approaches. In: DAS, S.; DASH, H. R. (Eds.). Handbook of metal-microbe interactions and bioremediation. Boca Raton, Flórida: CRC Press, 2017. v.1, cap. 22, p. 128-141.); in addition, they lead to the development of resistant pest populations (ELFEKIH et al., 2014ELFEKIH, S. et al. Detection of the acetylcholinesterase insecticide resistance mutation (G328A) in natural populations of Ceratitis capitata. Journal of economic entomology, 107: 1965-1968, 2014.).

Essential oils (EO), or their chemical compounds, can attract beneficial insects or repel unwanted ones (LIU et al., 2019LIU, S. et al. Identification of attractants from plant EOs for Cyrtorhinus lividipennis, an important predator of rice planthoppers. Journal of Pest Science, 92: 769-780, 2019.). In addition, these materials are biodegradable, leaving no toxic waste, denoting that they are potentially suitable for use in integrated pest management programs (LÓPEZ et al., 2011LÓPEZ, S. B. et al. Composition and anti-insect activity of EOs from Tagetes L. species (Asteraceae, Helenieae) on Ceratitis capitata Wiedemann and Triatoma infestans Klug. Journal of Agricultural and Food Chemistry, 59: 5286-5292, 2011.).

Some studies on the insecticidal properties of EO have reported the repellent activity of EO of Allium tuberosum Rottler ex Sprengel (Amaryllidaceae) (GAO et al., 2019GAO, Q. et al. Repellent action and contact toxicity mechanisms of the essential oil extracted from Chinese chive against Plutella xylostella larvae. Archives of Insect Biochemistry and Physiology, 100: e21509. 2019.), Cinnamomum zeylanicum Blume (Lauraceae) and Syzygium aromaticum (L.) Merr. & L.M.Perry (Myrtaceae) (PLATA-RUEDA et al., 2018PLATA-RUEDA, A. et al. Terpenoid constituents of cinnamon and cloves EOs cause toxic effects and behavior repellency response on granary weevil, Sitophilus granarius. Ecotoxicology and Environmental Safety, 156: 263-270, 2018.), and lethal action of Artemisia absinthium L. (Asteraceae) (RIZVI et al., 2018RIZVI, S. A. H. et al. Toxicity and enzyme inhibition activities of the essential oil and dominant constituents derived from Artemisia absinthium L. against adult Asian citrus psyllid Diaphorina citri Kuwayama (Hemiptera: Psyllidae). Industrial Crops and Products, 121: 468-475, 2018.) against many agricultural pests. López et al. (2011)LÓPEZ, S. B. et al. Composition and anti-insect activity of EOs from Tagetes L. species (Asteraceae, Helenieae) on Ceratitis capitata Wiedemann and Triatoma infestans Klug. Journal of Agricultural and Food Chemistry, 59: 5286-5292, 2011. found repellent effect of Tagetes minuta L. (Asteraceae) and Tagetes filifolia L. (Asteraceae) EO against C. capitata.

EO are recognized for their fruit quality maintenance properties (SIVAKUMAR; BAUTISTA-BAÑOS, 2014SIVAKUMAR, D.; BAUTISTA-BAÑOS, S. A review on the use of EOs for postharvest decay control and maintenance of fruit quality during storage. Crop Protection, 64: 27-37, 2014.). Botelho et al. (2016)BOTELHO, L. N. S. et al. Quality of guava cv.‘Pedro Sato’ treated with cassava starch and cinnamon essential oil. Scientia Horticulturae, 209: 214-220, 2016. found that the combination of cassava starch and cinnamon EO were efficient in maintaining the quality of guava fruits at room temperature and under modified atmosphere, prolonging their shelf-life. However, studies evaluating the quality of fruits treated with EO with insecticidal effect are scarce. In this sense, the objective of the present study was to evaluate the repellent activity of citronella (Cymbopogon nardus), clove (Syzygium aromaticum), and copaiba (Copaifera officinalis) EO against C. capitata in Paluma guava fruits and determine their effects on postharvest fruit quality.

MATERIAL AND METHODS

The Mediterranean fruit flies (Ceratitis capitata) used in the experiment were from culture stocks maintained by Invertebrate Zoology Laboratory of the Department of Biological Sciences of the Federal University of Paraiba (LABZOO/CCA/UFPB), at an average temperature of 25±2 ºC, 70±10% relative humidity, and photophase of 12 hours.

Insects at larval stage were fed an artificial diet consisting of 400 g of carrot, 4 g of nipagin, and 80 g of brewer's yeast (BRITO et al., 2009BRITO, C. H. et al. Uso do tratamento térmico no controle de mosca-das-frutas (Ceratitis capitata). Tecnologia & Ciência Agropecuária, 3: 29-36, 2009.); and with a 10% honey solution during the adult stage. The oils used in the study were obtained from local stores.

The repellency of the essential oils (EO) against C. capitata was evaluated through EO application on guava fruits and the effect of the treatments on fruit quality was evaluated through physical-chemical analysis.

The guava (Psidium guajava L. cv. Paluma) fruits used were at early physiological maturation stage (green to yellow fruits); they were acquired in a local market, cleaned with water and 0.1% sodium hypochlorite for 10 minutes, and dried on absorbent paper at room temperature (25 ºC). The EO used were: citronella, Cymbopogon nardus (L.) Rendle (1899), (Poaceae); clove, Syzygium aromaticum (L.) Merrill and Perry (1939) (Myrtaceae); and copaiba, Copaifera officinalis L. (1762) (Fabaceae). They were diluted in distilled water at concentrations of 0 (control), 100, 200, 300, 400, and 500 mg mL^-1, composing the treatments. The guava fruits were immersed in the treatments for one minute and left to dried in plastic trays for one hour. The fruits were then placed in covered plastic containers, coupled at the ends of the arenas, covered with sheer fabric at the top and with plastic at the bottom, similar to the procedures described by Botelho et al. (1973)BOTELHO, P. S. M. et al. Teste de atração de Musca domestica L. com luzes de diferentes comprimentos de onda. O Solo, 65: 42-45, 1973. (Figure 1). Forty newly mated five-day-old females were released in the central region of the arenas at one day after the starting of oviposition.

Figure 1
Dimensions of the arena used for confinement of adult Mediterranean fruit flies (Ceratitis capitata) (Diptera: Tephritidae).

EO repellency test

The number of individuals (females) with the treated fruits in the containers was counted at each evaluation. The insects were counted every hour after their release for first six hours and then at 12, 24, 48, and 72 hours after the release of the females inside the arenas.

The repellency of each EO against C. capitata was determined by the percentage of females that visited fruits treated with one of the oils (citronella, clove, and copaiba) at different concentrations (treatments), during the exposure time. Five replications were used for each treatment. Each replication consisted of four fruits, one for each treatment (oil-concentration), and a control (untreated group). Thus, 100 fruits were used, distributed in 25 arenas.

A complete randomized experimental design was used, in a 3×6×4 factorial arrangement, with five replications. The treatments consisted of 3 oils, 6 oil concentrations, and 4 evaluation periods.

Fruit physical and chemical analysis

The physical and chemical tests were carried out using eight guava fruits (P. guajava L. cv. Paluma) at initial maturation stage per treatment. The highest oil concentration of 500 mg mL^-1 was used to represent the repellency index for the citronella, clove, and copaiba essential oils, diluted in distilled water, to cover the fruits, consisted of concentration treatments and untreated group (control). After the preparation of the products in plastic containers at temperature of 25 ºC, a complete randomized experimental design with four replications was used, evaluating fruit skin and pulp, in a 4×5×2 factorial arrangement, consisting of four treatments and five storage periods, which were evaluated every three days for 12 days of storage at room temperature 22±2 ºC.

The analyzed parameters were:

Weight loss (%): determined by weighing all experimental units at the beginning of storage and then daily for 12 days. These data were used to calculated the weight loss percentage as a function of the difference in weight over the 12-day period (storage).

Skin color: measured through an objective, using a Minolta® Color Reader CR-10 digital colorimeter, expressing the color as the parameters: L* = luminosity; a* = green (-a*) to red (+a*); and b* = blue (-b*) to yellow (+b*) colors, in which the farther from the center (0), the more saturated the color (CALBO; CALBO, 1989CALBO, A. G.; CALBO, M. E. R. Medição e importância do potencial de parede. Revista Brasileira de Fisiologia Vegetal, 1: 41-45, 1989.).

pH: Determined using a digital pH meter, the electrode was inserted into a solution containing 5±0.5 g of the material, diluted in 50 mL of distilled water.

Total soluble solids: determined by direct reading, using a digital refractometer (Abbe, ATAGO N1) according to the analytical standards of the Instituto Adolfo Lutz - IAL (2008)IAL - Instituto Adolfo Lutz. Métodos físico-químicos para análise de alimentos. 4. ed. São Paulo, SP: Núcleo de Informação e Tecnologia - NIT/IAL, 2008. 1018 p..

Titratable acidity (g citric acid 100 g^-1 of pulp): determined by titration with 0.1 M NaOH solution with phenolphthalein indicator until a permanent pinkish color was obtained, using five g of the sample in 50 mL of distilled water according to the method of the Adolfo Lutz Institute - IAL (2008)IAL - Instituto Adolfo Lutz. Métodos físico-químicos para análise de alimentos. 4. ed. São Paulo, SP: Núcleo de Informação e Tecnologia - NIT/IAL, 2008. 1018 p..

Ascorbic acid: determined by titration, using a DCPIP solution (2,6-dichlorophenolindophenol 0.002%) and 0.5% oxalic acid as an extracting solution, as described by Strohecker and Henning (1967)STROHECKER, R.; HENNING, H. M. Analisis de vitaminas: métodos comprobados. Paz Montalvo. Madrid, 1967. 428 p..

Statistical analysis

The results found in the repellency test were subjected to analysis of variance, using the generalized linear model and considering the Beta distribution. Depending on to the significance of the F test (p≤0.05), response surface analysis was applied for the effects of the doses of each oil versus exposure time. The results found for the fruit physical and chemical analyses were subjected to analysis of variance by the F test (p≤0.05). The factor storage days and its interaction with EO was analyzed through second-order polynomial regression. Tukey test (p≤0.05) was applied for the factor EO. Both tests were carried out using the statistical software SAS® University Edition (2015)SAS Institute Inc. SAS Studio 5.1: Users Guide. Cary, NC: SAS Institute Inc. 2015..

RESULTS AND DISCUSSION

EO repellent activity against C. capitata

Significant effect was found for the different oils (p = <0.0001), concentrations (p = <0.0001), times of exposure (p = <0.0001), and interaction between oils and concentrations (p = <0.0001) (Figure 2). The application of citronella oil (Figure 2A) resulted in greater repellency of C. capitata when compared to applications of clove and copaiba oils (Figures 2B and 2C). The increase in citronella oil concentration continuously increased the repellency potential, resulting in 0% to 5% visiting flies for the concentration of 200 mg mL^-1. This effect was observed during the 72 hours of evaluation. The increase in clove oil concentrations also increased the repellency percentage (Figure 2B), but this effect was lost over time and the percentage of visiting flies became similar to that in the control treatment. Similarly, the treatment with copaiba oil had no or low effect on the number of visiting flies (Figure 2C).

Figure 2
Probability (P) of repellency of adult Mediterranean fruit flies (Ceratitis capitata) (Diptera: Tephritidae) by citronella, clove, and copaiba essential oils at concentrations of 0 (control), 100, 200, 199 300, 400, and 500 mg mL^-1, topically applied on guava fruits during different exposure times.

Citronella EO has a high insecticidal activity against fruit flies mainly due to the presence of two important bioactive compounds (citronellal and geraniol) (ARANCIBIA et al., 2013ARANCIBIA, M. et al. Biodegradable films containing cloves or citronella EOs against the Mediterranean fruit fly Ceratitis capitata (Diptera: Tephritidae). Journal Agriculture and Food Technology, 3: 1-7, 2013.). The citronellal monoterpene present in citronella oil has scientifically recognized insecticidal and repellent action, highlighting the potential of this oil for use as a pesticide in organic crops (REGNAULT-ROGER; VINCENT; ARNASON, 2012REGNAULT-ROGER, C.; VINCENT, C.; ARNASON, J. T. EOs in insect control: low-risk products in a high-stakes world. Annual Review of Entomology, 57: 405-424, 2012.). In addition to its insecticide action, citronella oil exhibits rapid volatility (ARANCIBIA et al., 2013ARANCIBIA, M. et al. Biodegradable films containing cloves or citronella EOs against the Mediterranean fruit fly Ceratitis capitata (Diptera: Tephritidae). Journal Agriculture and Food Technology, 3: 1-7, 2013.) which, combined with its great insect repellent action, resulted in the lowest percentage of individuals since the beginning of the releases.

Physical and chemical analysis of guava treated with EO

The treatments and storage periods had significant effect on weight loss (Figure 3). Control fruits presented the highest weight loss percentages, with decreases of approximately 24%. This result is consistent with those found by Botelho et. al. (2016)BOTELHO, L. N. S. et al. Quality of guava cv.‘Pedro Sato’ treated with cassava starch and cinnamon essential oil. Scientia Horticulturae, 209: 214-220, 2016., who evaluated post-harvest responses of guava fruits of the cultivar Pedro Sato subjected to several treatments, including EO, and found similar weight losses for control fruits.

Figure 3
Weight loss of guava fruits treated with citronella, clove, and copaiba essential oils during different storage p eriods.

Fruits under treatments with EO presented lower weight loss. This variable is mainly connected to respiration and moisture exchanges through the fruit surface (JOSHI et al., 2017JOSHI, A. V. et al. Gum ghatti based edible coating emulsion with an additive of cloves oil improves the storage life and maintains the quality of papaya (Carica papaya L., cv. Madhu bindu). International Journal of Current Microbiology and Applied Sciences, 6: 160-174, 2017.). EO are hydrophobic and compatible with the outer layer of fruit, thus, they can form a protective barrier against water loss, reducing weight loss (SANGSUWAN et al., 2016SANGSUWAN, J. et al. Effect of chitosan beads incorporated with lavender or red thyme EOs in inhibiting Botrytis cinerea and their application in strawberry packaging system. LWT-Food Science and Technology, 74: 14-20, 2016.).

Fruits coated with clove and copaiba EO presented weight losses from 5% to 13%. Joshi et al. (2017)JOSHI, A. V. et al. Gum ghatti based edible coating emulsion with an additive of cloves oil improves the storage life and maintains the quality of papaya (Carica papaya L., cv. Madhu bindu). International Journal of Current Microbiology and Applied Sciences, 6: 160-174, 2017. also found good results for clove oil regarding storage maintenance and postharvest quality of papaya: treatments using this oil had the lowest weight losses.

The skin brightness (L*) of guava fruits was significantly affected (p <0.001) only by the storage periods (Figure 4A). The highest L* values were found after 9 days of storage (69), with a decrease after 10 days (66). These values were higher than those found by Murmu and Mishra (2018)MURMU, S. B.; MISHRA, H. N. The effect of edible coating based on Arabic gum, sodium caseinate and essential oil of cinnamon and lemon grass on guava. Food Chemistry, 245: 820-828, 2018., who evaluated guava fruits of the cultivar Baruipur after 21 days under different coatings based on Arabic gum, sodium caseinate, and cinnamon and lemongrass essential oils, and found L* values between 41.23 and 60.29.

Figure 4
(A) Skin color (L*) of Paluma guava fruits treated with essential oils against adult Mediterranean fruit flies (Ceratitis capitata) (Diptera: Tephritidae) as a function of storage time. (B) Skin color (a*) of guava fruits as a function of storage time.

Isolated effects of storage periods and the treatments used were found on green to red color transition (a*) (Figure 4B and 5A). The fruits showed losses in green color and yellowing from the sixth day onwards. Similar results were reported by Rodrigues et al. (2018)RODRIGUES, A. A. M. et al. Physiology and postharvest conservation of ‘Paluma’ guava under coatings using Jack fruit seed-based starch. Revista Brasileira de Fruticultura, 40: 1-8, 2018., who observed this color transition on the fourth day in Paluma guava fruits coated with jackfruit seed starch.

Figure 5
(A) Skin color (a*) of guava fruits as a function of storage time (5-A) and treatments with citronella, clove, and copaiba essential oils against adult Mediterranean fruit flies (Ceratitis capitata) (Diptera: Tephritidae) (5-B). (B) Skin color (b*) of guava fruits treated with citronella, clove, and copaiba essential oils against adult C. capitata.

The control reached the yellowish color more quickly than the other treatments, presenting the highest a* values (Figure 5A). Copaiba and clove oils were the treatment that most delayed the color transition, leading to a slower evolution of a*. These results confirm the positive effect of using EO on maintaining guava fruit quality.

Similarly, Choi, Singh, and Lee (2016)CHOI, W. S.; SINGH, S.; LEE, Y. S. Characterization of edible film containing EOs in hydroxypropyl methylcellulose and its effect on quality attributes of ‘Formosa’plum (Prunus salicina L.). LWT-Food Science and Technology, 70: 213-222, 2016. found delay in color change in plums subjected to treatments with hydroxypropyl methylcellulose coating incorporated with oregano and tangerine (Citrus reticulata) EO, thus increasing the post-harvest quality.

The b* parameter of skin color was significantly affected by the treatments (Figure 5B). The copaiba oil resulted in the lowest values, although statistically similar to the other oils. The application of copaiba oil resulted in a longer delay in fruit ripening, with a slower yellowing.

Guava is a climacteric fruit, thus the use of coatings such as EO can delay its ripening process by changing the internal gas composition due to changes in the fruit skin permeability, leading to changes in O₂, CO₂, and ethylene productions (SIVAKUMAR; BAUTISTA-BAÑOS, 2014SIVAKUMAR, D.; BAUTISTA-BAÑOS, S. A review on the use of EOs for postharvest decay control and maintenance of fruit quality during storage. Crop Protection, 64: 27-37, 2014.). Shirzadeh and Kazemi (2012)SHIRZADEH, E.; KAZEMI, M. Effect of salicylic acid and EOs treatments on quality characteristics of apple (Malus domestica Var. Granny Smith) fruits during storage. Asian Journal of Biochemistry, 7: 165-170, 2012. evaluated mint essential oil in apple fruits and found reduction in ethylene production rates due to the oil application, which directly affected the guava fruit shelf-life.

The skin pH varied from 4 to 5, and the highest values were found in the control (Figure 6A). The pH parameter peaked on the sixth day in all treatments. A strong reduction in pH was found on the twelfth day, mainly for citronella oil, indicating a possible effect of the components of this essential oil on the fruit metabolic activity (PERDONES et al., 2012PERDONES, A. et al. Effect of chitosan - lemon essential oil coatings on storage - keeping quality of strawberry. Postharvest Biology and Technology, 70: 32-41, 2012.).

Figure 6
Skin pH (6-A) and pulp pH (6-B) of guava fruits treated with citronella, clove, and copaiba essential oils a gainst adult Mediterranean fruit flies (Ceratitis capitata) (Diptera: Tephritidae).

According to current Brazilian legislation (BRASIL, 2018BRASIL - Ministério da Agricultura, Pecuária e Abastecimento (MAPA). Parâmetros Analíticos e Quesitos Complementares aos Padrões de Identidade e Qualidade de Polpa de Fruta. Brasília, DF: Diário Oficial da União, 2018. 23 p.), the pH of the guava pulp used in this research was within the Brazilian Identity and Quality Standard (PIQ), which determines a minimum pH of 3.5. The pulp pH (Figure 6B) was significantly affected by the treatments and storage periods; the control presented decreasing values when compared to the other treatments. The pulp from fruits coated with citronella EO presented the the lowest skin pH values. Different results were reported by Aquino, Blank, and Santana (2015)AQUINO, A. B.; BLANK, A. F.; SANTANA, L. C. L. A. Impact of edible chitosan–cassava starch coatings enriched with Lippia gracilis Schauer genotype mixtures on the shelf life of guavas (Psidium guajava L.) during storage at room temperature. Food Chemistry, 171: 108-116, 2015. for guava fruits coated with chitosan, cassava starch, and essential oil of Lippia gracilis schauer (1847), with pH significantly lower in treatments with coating application than in the control treatment, at 10 days of storage at room temperature.

In addition, pH is important for the development of some types of pests in fruit trees. Lee et al. (2016)LEE, J. C. et al. Characterization and manipulation of fruit susceptibility to Drosophila suzukii. Journal of Pest Science, 89: 771-780, 2016. evaluated the susceptibility of raspberry fruits to Drosophila suzukii Matsumura 1931 (Diptera: Drosophilidae), an important pest of small fruits, and found that the probability of oviposition increases as the analyzed fruit pH is increased. In the present study, the treatment with non-addition of EO resulted in higher pH values when compared to treatments with citronella, copaiba, and clove EO, for most of the storage periods.

The pulp pH of fruits subjected to EO application was within the limits found in other studies about guava focused on aspects of production and post-harvest improvement (AQUINO; BLANK; SANTANA, 2015AQUINO, A. B.; BLANK, A. F.; SANTANA, L. C. L. A. Impact of edible chitosan–cassava starch coatings enriched with Lippia gracilis Schauer genotype mixtures on the shelf life of guavas (Psidium guajava L.) during storage at room temperature. Food Chemistry, 171: 108-116, 2015.).

Total soluble solids (%) of fruits were significantly affected (p <0.001) only by the storage periods (Figure 7), presenting reductions at the end of the experiment.

Figure 7
Total soluble solids in guava fruits treated with citronella, clove, and copaiba essential oils against adult Mediterranean fruit flies (Ceratitis capitata) (Diptera: Tephritidae) as a function of storage time.

The pulp titratable acidity results found were mostly higher than the minimum value established by the Brazilian Identity and Quality Standard (PIQ) for guava pulp, which is 0.4 mg citric acid 100 g^-1 (BRASIL, 2018BRASIL - Ministério da Agricultura, Pecuária e Abastecimento (MAPA). Parâmetros Analíticos e Quesitos Complementares aos Padrões de Identidade e Qualidade de Polpa de Fruta. Brasília, DF: Diário Oficial da União, 2018. 23 p.). The pulp titratable acidity was affected by the storage periods (Figure 8B). The fruit titratable acidity presented a slight decrease until the sixth day, followed by an increase in the nineth and twelfth day, resulting in a similar titratable acidity to that found on the day 0 (Figure 8B). Choudhary and Jain (2018)CHOUDHARY, P.; JAIN, V. Effect of post-harvest treatments of selenium on physico-chemical quality in guava (Psidium guajava L.) fruit. Horticulture International Journal, 2: 41-44, 2018. evaluated guava fruits coated with different selenium rates and found decreases in titratable acidity as the storage period was increased.

Figure 8
(A) Titratable acidity of skin (B) and pulp of guava fruits treated with citronella, clove, and co paiba essential oils against adult Mediterranean fruit flies (Ceratitis capitata) (Diptera: Tephritidae), as a function of storage time.

The ascorbic acid levels in the skin were affected by the storage periods and treatments (Figure 9A). Although the control initially presented the lowest values, at the end of the twelfth day, it had higher levels of ascorbic acid than the treatments with EO.

Figure 9
Ascorbic acid contents in the skin (A) and pulp (B) of guava fruits treated with citronella, clove, and copa iba essential oils against adult Mediterranean fruit flies (Ceratitis capitata) (Diptera: Tephritidae).

Ascorbic acid contents, in general, decreased during the experimental period. Ascorbic acid in the skin decreased as the storage time was increased due to the instability of this compound, mainly under limiting storage conditions in terms of light, temperature, humidity, and diseases (FATEMI et al., 2011FATEMI, S. et al. Effect of EOs of Thymus vulgaris and Mentha piperita on the control of green mould and postharvest quality of Citrus Sinensis cv. Valencia. African Journal of Biotechnology, 10: 14932-14936, 2011.). In the present study, it was more pronounced in the treatment with clove essential oil. The ascorbic acid contents found were, in general, higher than the minimum required by the Brazilian Identity and Quality Standard (PIQ) for guava pulp, which is 24 g 100 g^-1 (BRASIL, 2018BRASIL - Ministério da Agricultura, Pecuária e Abastecimento (MAPA). Parâmetros Analíticos e Quesitos Complementares aos Padrões de Identidade e Qualidade de Polpa de Fruta. Brasília, DF: Diário Oficial da União, 2018. 23 p.).

The fruit pulp ascorbic acid contents were also affected by the storage time and treatments (Figure 9B). The highest pulp ascorbic acid contents on the twelfth day were found in the treatment with citronella oil, and not in the control, as found for the fruit skin. Furthermore, the ascorbic acid levels increased between the nineth and the twelfth day in all treatments, a different trend from that observed in previous days.

The treatment with citronella essential oil on day 0 presented ascorbic acid levels of 53.50 mg 100 g^-1, and despite the reduction on the twelfth day, it presented 51.97 mg 100 g ^-1. Thus, it proved to be the most efficient treatment to maintain the ascorbic acid levels, which is responsible for eliminating free radicals in the fruit, thus preventing oxidative damage and prolonging post-harvest life during storage (NAIR; SAXENA; KAUR, 2018NAIR, M. S.; SAXENA, A.; KAUR, C. Effect of chitosan and alginate based coatings enriched with pomegranate peel extract to extend the postharvest quality of guava (Psidium guajava L.). Food Chemistry, 240: 245-252, 2018.).

CONCLUSIONS

Citronella (Cymbopogon nardus) essential oil presents higher repellent activity against Ceratitis capitata females than clove (Syzygium aromaticum) or copaiba (Copaifera officinalis) essential oils, when applied on Paluma guava fruits by immersion in water solutions at concentrations of 100, 200, 300, 400, or 500 mg mL^-1. The application of the essential oil solutions at concentration of 500 mg mL^-1 had no negative effect on the analyzed post-harvest quality parameters and proved to be a promising strategy for maintaining the quality of Paluma guava fruits throughout 12 days of storage at 22±2 ºC.

ACKNOWLEDGEMENTS

The authors thank the Brazilian Coordination for the Improvement of Higher Education Personnel (CAPES) for the incentives and financing of this study; and the Graduate Program in Agronomy of the Federal University of Paraiba, Brazil.

REFERENCES

AQUINO, A. B.; BLANK, A. F.; SANTANA, L. C. L. A. Impact of edible chitosan–cassava starch coatings enriched with Lippia gracilis Schauer genotype mixtures on the shelf life of guavas (Psidium guajava L.) during storage at room temperature. Food Chemistry, 171: 108-116, 2015.
ARANCIBIA, M. et al. Biodegradable films containing cloves or citronella EOs against the Mediterranean fruit fly Ceratitis capitata (Diptera: Tephritidae). Journal Agriculture and Food Technology, 3: 1-7, 2013.
BOTELHO, L. N. S. et al. Quality of guava cv.‘Pedro Sato’ treated with cassava starch and cinnamon essential oil. Scientia Horticulturae, 209: 214-220, 2016.
BOTELHO, P. S. M. et al. Teste de atração de Musca domestica L. com luzes de diferentes comprimentos de onda. O Solo, 65: 42-45, 1973.
BOULAHIA-KHEDER, S. Review on major fruit flies (Diptera: Tephritidae) in North Africa: Bio-ecological traits and future trends. Crop Protection, 140: 1-10, 2021a.
BOULAHIA-KHEDER, S. Advancements in management of major fruit flies (Diptera: Tephritidae) in North Africa and future challenges: A review. Journal of Applied Entomology, 145: 939-957, 2021b.
BRASIL - Ministério da Agricultura, Pecuária e Abastecimento (MAPA). Parâmetros Analíticos e Quesitos Complementares aos Padrões de Identidade e Qualidade de Polpa de Fruta Brasília, DF: Diário Oficial da União, 2018. 23 p.
BRITO, C. H. et al. Uso do tratamento térmico no controle de mosca-das-frutas (Ceratitis capitata). Tecnologia & Ciência Agropecuária, 3: 29-36, 2009.
CALBO, A. G.; CALBO, M. E. R. Medição e importância do potencial de parede. Revista Brasileira de Fisiologia Vegetal, 1: 41-45, 1989.
CHOI, W. S.; SINGH, S.; LEE, Y. S. Characterization of edible film containing EOs in hydroxypropyl methylcellulose and its effect on quality attributes of ‘Formosa’plum (Prunus salicina L.). LWT-Food Science and Technology, 70: 213-222, 2016.
CHOUDHARY, P.; JAIN, V. Effect of post-harvest treatments of selenium on physico-chemical quality in guava (Psidium guajava L.) fruit. Horticulture International Journal, 2: 41-44, 2018.
ELFEKIH, S. et al. Detection of the acetylcholinesterase insecticide resistance mutation (G328A) in natural populations of Ceratitis capitata. Journal of economic entomology, 107: 1965-1968, 2014.
FATEMI, S. et al. Effect of EOs of Thymus vulgaris and Mentha piperita on the control of green mould and postharvest quality of Citrus Sinensis cv. Valencia. African Journal of Biotechnology, 10: 14932-14936, 2011.
GAO, Q. et al. Repellent action and contact toxicity mechanisms of the essential oil extracted from Chinese chive against Plutella xylostella larvae. Archives of Insect Biochemistry and Physiology, 100: e21509. 2019.
GOMES, V. M. et al. Inheritance of resistance to Meloidogyne enterolobii and individual selection in segregating populations of Psidium spp. European Journal of Plant Pathology, 148: 699-708, 2017.
IAL - Instituto Adolfo Lutz. Métodos físico-químicos para análise de alimentos 4. ed. São Paulo, SP: Núcleo de Informação e Tecnologia - NIT/IAL, 2008. 1018 p.
IHA, O. K. et al. Extraction and characterization of passion fruit and guava oils from industrial residual seeds and their application as biofuels. Journal of the Brazilian Chemical Society, 29: 2089-2095. 2018.
JOSHI, A. V. et al. Gum ghatti based edible coating emulsion with an additive of cloves oil improves the storage life and maintains the quality of papaya (Carica papaya L., cv. Madhu bindu). International Journal of Current Microbiology and Applied Sciences, 6: 160-174, 2017.
LEE, J. C. et al. Characterization and manipulation of fruit susceptibility to Drosophila suzukii Journal of Pest Science, 89: 771-780, 2016.
LIU, S. et al. Identification of attractants from plant EOs for Cyrtorhinus lividipennis, an important predator of rice planthoppers. Journal of Pest Science, 92: 769-780, 2019.
LÓPEZ, S. B. et al. Composition and anti-insect activity of EOs from Tagetes L. species (Asteraceae, Helenieae) on Ceratitis capitata Wiedemann and Triatoma infestans Klug. Journal of Agricultural and Food Chemistry, 59: 5286-5292, 2011.
MACIEL, A. A. S. et al. Diversity and infestation indices of fruit flies (Diptera: Tephritidae) in guava (Psidium guajava L.). African Journal of Agricultural Research, 12: 2087-2092, 2017.
MOON, P. et al. Assessment of fruit aroma for twenty-seven guava (Psidium guajava) accessions through three fruit developmental stages. Scientia Horticulturae, 238: 375-383, 2018.
MURMU, S. B.; MISHRA, H. N. The effect of edible coating based on Arabic gum, sodium caseinate and essential oil of cinnamon and lemon grass on guava. Food Chemistry, 245: 820-828, 2018.
NAIR, M. S.; SAXENA, A.; KAUR, C. Effect of chitosan and alginate based coatings enriched with pomegranate peel extract to extend the postharvest quality of guava (Psidium guajava L.). Food Chemistry, 240: 245-252, 2018.
PERDONES, A. et al. Effect of chitosan - lemon essential oil coatings on storage - keeping quality of strawberry. Postharvest Biology and Technology, 70: 32-41, 2012.
PLATA-RUEDA, A. et al. Terpenoid constituents of cinnamon and cloves EOs cause toxic effects and behavior repellency response on granary weevil, Sitophilus granarius Ecotoxicology and Environmental Safety, 156: 263-270, 2018.
RANA, S.; SIDDIQUI, S. Comparative effect of different individual wrappings on shelf life of guava (Psidium guajava). Journal of Food Science and Technology, 55: 2935-2944, 2018.
REGNAULT-ROGER, C.; VINCENT, C.; ARNASON, J. T. EOs in insect control: low-risk products in a high-stakes world. Annual Review of Entomology, 57: 405-424, 2012.
RIZVI, S. A. H. et al. Toxicity and enzyme inhibition activities of the essential oil and dominant constituents derived from Artemisia absinthium L. against adult Asian citrus psyllid Diaphorina citri Kuwayama (Hemiptera: Psyllidae). Industrial Crops and Products, 121: 468-475, 2018.
RODRIGUES, A. A. M. et al. Physiology and postharvest conservation of ‘Paluma’ guava under coatings using Jack fruit seed-based starch. Revista Brasileira de Fruticultura, 40: 1-8, 2018.
SANGSUWAN, J. et al. Effect of chitosan beads incorporated with lavender or red thyme EOs in inhibiting Botrytis cinerea and their application in strawberry packaging system. LWT-Food Science and Technology, 74: 14-20, 2016.
SAS Institute Inc. SAS Studio 5.1: Users Guide. Cary, NC: SAS Institute Inc 2015.
SHIRZADEH, E.; KAZEMI, M. Effect of salicylic acid and EOs treatments on quality characteristics of apple (Malus domestica Var. Granny Smith) fruits during storage. Asian Journal of Biochemistry, 7: 165-170, 2012.
SIVAKUMAR, D.; BAUTISTA-BAÑOS, S. A review on the use of EOs for postharvest decay control and maintenance of fruit quality during storage. Crop Protection, 64: 27-37, 2014.
STROHECKER, R.; HENNING, H. M. Analisis de vitaminas: métodos comprobados Paz Montalvo. Madrid, 1967. 428 p.
WANG, L. et al. Impact of fermentation degree on phenolic compositions and bioactivities during the fermentation of guava leaves with Monascus anka and Bacillus sp. Journal of Functional Foods, 41: 183-190, 2018.
YADAV, A. et al. Toxic metals in the environment: threats on ecosystem and bioremediation approaches. In: DAS, S.; DASH, H. R. (Eds.). Handbook of metal-microbe interactions and bioremediation Boca Raton, Flórida: CRC Press, 2017. v.1, cap. 22, p. 128-141.

Publication Dates

Publication in this collection
22 May 2023
Date of issue
Apr-Jun 2023

History

Received
23 Aug 2021
Accepted
05 Oct 2022

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] AQUINO, A. B.; BLANK, A. F.; SANTANA, L. C. L. A. Impact of edible chitosan–cassava starch coatings enriched with Lippia gracilis Schauer genotype mixtures on the shelf life of guavas (Psidium guajava L.) during storage at room temperature. Food Chemistry, 171: 108-116, 2015.

[2] ARANCIBIA, M. et al. Biodegradable films containing cloves or citronella EOs against the Mediterranean fruit fly Ceratitis capitata (Diptera: Tephritidae). Journal Agriculture and Food Technology, 3: 1-7, 2013.

[3] BOTELHO, L. N. S. et al. Quality of guava cv.‘Pedro Sato’ treated with cassava starch and cinnamon essential oil. Scientia Horticulturae, 209: 214-220, 2016.

[4] BOTELHO, P. S. M. et al. Teste de atração de Musca domestica L. com luzes de diferentes comprimentos de onda. O Solo, 65: 42-45, 1973.

[5] BOULAHIA-KHEDER, S. Review on major fruit flies (Diptera: Tephritidae) in North Africa: Bio-ecological traits and future trends. Crop Protection, 140: 1-10, 2021a.

[6] BOULAHIA-KHEDER, S. Advancements in management of major fruit flies (Diptera: Tephritidae) in North Africa and future challenges: A review. Journal of Applied Entomology, 145: 939-957, 2021b.

[7] BRASIL - Ministério da Agricultura, Pecuária e Abastecimento (MAPA). Parâmetros Analíticos e Quesitos Complementares aos Padrões de Identidade e Qualidade de Polpa de Fruta Brasília, DF: Diário Oficial da União, 2018. 23 p.

[8] BRITO, C. H. et al. Uso do tratamento térmico no controle de mosca-das-frutas (Ceratitis capitata). Tecnologia & Ciência Agropecuária, 3: 29-36, 2009.

[9] CALBO, A. G.; CALBO, M. E. R. Medição e importância do potencial de parede. Revista Brasileira de Fisiologia Vegetal, 1: 41-45, 1989.

[10] CHOI, W. S.; SINGH, S.; LEE, Y. S. Characterization of edible film containing EOs in hydroxypropyl methylcellulose and its effect on quality attributes of ‘Formosa’plum (Prunus salicina L.). LWT-Food Science and Technology, 70: 213-222, 2016.

[11] CHOUDHARY, P.; JAIN, V. Effect of post-harvest treatments of selenium on physico-chemical quality in guava (Psidium guajava L.) fruit. Horticulture International Journal, 2: 41-44, 2018.

[12] ELFEKIH, S. et al. Detection of the acetylcholinesterase insecticide resistance mutation (G328A) in natural populations of Ceratitis capitata. Journal of economic entomology, 107: 1965-1968, 2014.

[13] FATEMI, S. et al. Effect of EOs of Thymus vulgaris and Mentha piperita on the control of green mould and postharvest quality of Citrus Sinensis cv. Valencia. African Journal of Biotechnology, 10: 14932-14936, 2011.

[14] GAO, Q. et al. Repellent action and contact toxicity mechanisms of the essential oil extracted from Chinese chive against Plutella xylostella larvae. Archives of Insect Biochemistry and Physiology, 100: e21509. 2019.

[15] GOMES, V. M. et al. Inheritance of resistance to Meloidogyne enterolobii and individual selection in segregating populations of Psidium spp. European Journal of Plant Pathology, 148: 699-708, 2017.

[16] IAL - Instituto Adolfo Lutz. Métodos físico-químicos para análise de alimentos 4. ed. São Paulo, SP: Núcleo de Informação e Tecnologia - NIT/IAL, 2008. 1018 p.

[17] IHA, O. K. et al. Extraction and characterization of passion fruit and guava oils from industrial residual seeds and their application as biofuels. Journal of the Brazilian Chemical Society, 29: 2089-2095. 2018.

[18] JOSHI, A. V. et al. Gum ghatti based edible coating emulsion with an additive of cloves oil improves the storage life and maintains the quality of papaya (Carica papaya L., cv. Madhu bindu). International Journal of Current Microbiology and Applied Sciences, 6: 160-174, 2017.

[19] LEE, J. C. et al. Characterization and manipulation of fruit susceptibility to Drosophila suzukii Journal of Pest Science, 89: 771-780, 2016.

[20] LIU, S. et al. Identification of attractants from plant EOs for Cyrtorhinus lividipennis, an important predator of rice planthoppers. Journal of Pest Science, 92: 769-780, 2019.

[21] LÓPEZ, S. B. et al. Composition and anti-insect activity of EOs from Tagetes L. species (Asteraceae, Helenieae) on Ceratitis capitata Wiedemann and Triatoma infestans Klug. Journal of Agricultural and Food Chemistry, 59: 5286-5292, 2011.

[22] MACIEL, A. A. S. et al. Diversity and infestation indices of fruit flies (Diptera: Tephritidae) in guava (Psidium guajava L.). African Journal of Agricultural Research, 12: 2087-2092, 2017.

[23] MOON, P. et al. Assessment of fruit aroma for twenty-seven guava (Psidium guajava) accessions through three fruit developmental stages. Scientia Horticulturae, 238: 375-383, 2018.

[24] MURMU, S. B.; MISHRA, H. N. The effect of edible coating based on Arabic gum, sodium caseinate and essential oil of cinnamon and lemon grass on guava. Food Chemistry, 245: 820-828, 2018.

[25] NAIR, M. S.; SAXENA, A.; KAUR, C. Effect of chitosan and alginate based coatings enriched with pomegranate peel extract to extend the postharvest quality of guava (Psidium guajava L.). Food Chemistry, 240: 245-252, 2018.

[26] PERDONES, A. et al. Effect of chitosan - lemon essential oil coatings on storage - keeping quality of strawberry. Postharvest Biology and Technology, 70: 32-41, 2012.

[27] PLATA-RUEDA, A. et al. Terpenoid constituents of cinnamon and cloves EOs cause toxic effects and behavior repellency response on granary weevil, Sitophilus granarius Ecotoxicology and Environmental Safety, 156: 263-270, 2018.

[28] RANA, S.; SIDDIQUI, S. Comparative effect of different individual wrappings on shelf life of guava (Psidium guajava). Journal of Food Science and Technology, 55: 2935-2944, 2018.

[29] REGNAULT-ROGER, C.; VINCENT, C.; ARNASON, J. T. EOs in insect control: low-risk products in a high-stakes world. Annual Review of Entomology, 57: 405-424, 2012.

[30] RIZVI, S. A. H. et al. Toxicity and enzyme inhibition activities of the essential oil and dominant constituents derived from Artemisia absinthium L. against adult Asian citrus psyllid Diaphorina citri Kuwayama (Hemiptera: Psyllidae). Industrial Crops and Products, 121: 468-475, 2018.

[31] RODRIGUES, A. A. M. et al. Physiology and postharvest conservation of ‘Paluma’ guava under coatings using Jack fruit seed-based starch. Revista Brasileira de Fruticultura, 40: 1-8, 2018.

[32] SANGSUWAN, J. et al. Effect of chitosan beads incorporated with lavender or red thyme EOs in inhibiting Botrytis cinerea and their application in strawberry packaging system. LWT-Food Science and Technology, 74: 14-20, 2016.

[33] SAS Institute Inc. SAS Studio 5.1: Users Guide. Cary, NC: SAS Institute Inc 2015.

[34] SHIRZADEH, E.; KAZEMI, M. Effect of salicylic acid and EOs treatments on quality characteristics of apple (Malus domestica Var. Granny Smith) fruits during storage. Asian Journal of Biochemistry, 7: 165-170, 2012.

[35] SIVAKUMAR, D.; BAUTISTA-BAÑOS, S. A review on the use of EOs for postharvest decay control and maintenance of fruit quality during storage. Crop Protection, 64: 27-37, 2014.

[36] STROHECKER, R.; HENNING, H. M. Analisis de vitaminas: métodos comprobados Paz Montalvo. Madrid, 1967. 428 p.

[37] WANG, L. et al. Impact of fermentation degree on phenolic compositions and bioactivities during the fermentation of guava leaves with Monascus anka and Bacillus sp. Journal of Functional Foods, 41: 183-190, 2018.

[38] YADAV, A. et al. Toxic metals in the environment: threats on ecosystem and bioremediation approaches. In: DAS, S.; DASH, H. R. (Eds.). Handbook of metal-microbe interactions and bioremediation Boca Raton, Flórida: CRC Press, 2017. v.1, cap. 22, p. 128-141.

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