ARTICULOS

 

Phytochemical determination of Solanum lycopersicum L. fruits irrigated with water treated with static magnetic field

 

Determinación fitoquímica de frutos de Solanum lycopersicum L. Irrigados con agua tratada con campo magnético estático

 

 

Dra. C. Albys E. Ferrer-Dubois^I, Dra. C. Yilan Fung-Boix^I, Dra. C. Elizabeth Isaac-Alemán^I, Dra. C. Natalie Beenaerts^II, Dra. C. Ann Cuypers^II

 

^ICentro Nacional de Electromagnetismo Aplicado, Universidad de Oriente, Santiago de Cuba, Cuba, albys@uo.edu.cu
^IICenter for Environmental Sciences. Hasselt University. Belgium

 

 

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ABSTRACT

The phytochemical compounds of Solanum lycopersicum L. fruits from irrigated plants under the action of water treated with a static magnetic field (SMF), between 20 and 200 mT were determined. Two experimental groups with 25 plants each were used. The control group received irrigation with untreated water and the other group was irrigated with water treated with SMF. The ripe fruits were harvested and aqueous and ethanolic extracts were prepared. These extracts were subjected to phytochemical screening. The aqueous extracts prepared from the irrigated fruits of the group with SMF showed qualitatively a marked presence of carotenoids, phenols, tannins, carbohydrates and flavonoids. These results showed that the SMF used favors the greater extraction of these metabolites which have a high nutritional value and antioxidant potential, which contributes to the pharmacological properties of the fruits of S. lycopersicum L.

Keywords: tomato, phytochemical screening, extracts, magnetic fields, metabolites.

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RESUMEN

Se determinaron los compuestos fitoquímicos de los frutos de Solanum lycopersicum L. provenientes de plantas irrigadas bajo la acción de agua tratada con un campo magnético estático (CME), entre 20 y 200 mT. Se utilizaron dos grupos experimentales con 25 plantas cada uno. El grupo control recibió el riego con agua no tratada y el otro grupo fue irrigado con agua tratada con CME. Se cosecharon los frutos maduros y se prepararon extractos acuosos y etanólicos. A estos extractos se les realizó el tamizaje fitoquímico. Los extractos acuosos preparados a partir de los frutos irrigados del grupo con CME revelaron cualitativamente una marcada presenciade carotenoides, fenoles, taninos, carbohidratos y flavonoides . Estos resultados mostraron que el CME utilizado favorece la mayor extracción de estos metabolitos los cuales tienen un gran valor nutricional y potencial antioxidante, lo que contribuye a las propiedades farmacológicas de los frutos de S. lycopersicum L.

Palabras clave: tomate, tamizaje fitoquímico, extractos, campos magnéticos, metabolitos.

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INTRODUCTION

Dietary recommendations in recent years suggest an increase in the consumption of foods containing phytochemicals. They provide beneficial effects for human health and play an important role in the prevention of chronic diseases [1].

One of the world's most consumed plants is Solanum lycopersicum L. (tomato), which is considered to nutraceuticaldue to their antioxidant activity [2]. It is an important source of chemical compounds, specifically secondary metabolites with antioxidant action, such as polyphenols, hydroxycinnamic acids, carotenoids and vitamins, among others. These compounds modulate metabolic processes in the human body and show recognized beneficial effects on human health. In turn, they can prevent the generation of reactive species that affect, among other causes, the onset of cardiovascular diseases and neurodegenerative diseases [3] and some types of cancer [4].

 

MATERIALS AND METHODS

The research was carried out at the National Center for Applied Electromagnetism (CNEA, Spanish acronym) in Santiago de Cuba and at the Center for Environmental Sciences at the Hasselt University, Belgium. The Tomato, Solanum lycopersicum L., Aegean hybrid, was used as biological model.

Seeds with good phytosanitary status and certified by the Provincial Laboratory of Seeds attached to the Ministry of Agriculture (MINAGRI, Spanish acronym) in Santiago de Cuba, were used. The plants were cultivated under semicontrolled conditions at the "Veguita" greenhouses (a suburban area of Santiago de Cuba) and all care required for the cultivation of tomato wasgiven in compliance with MINAGRI specifications [9] .The temperature in the experimental growth area were in the ranged from 27 to 30 °C. The approximate value of precipitation was 68.04 mm and the relative humidity 70.32 % during the entire period of the experiment.A Voucher species was deposited and stored at the Eastern Center for Ecosystems and Biodiversity (BIOECO, Spanish acronym), Santiago de Cuba, with registration: BSC 21509.

Experimental design

A completely randomized experimental design including two experimental groups were used:

WMT (control): S. lycopersicum L. irrigated with water without treatment with MF

WTSMF: S. lycopersicum L. irrigated with non-uniform or heterogeneous SMF (20-200 mT)

A magnetic device composed of permanent magnets wereused to apply the magnetic treatment to the irrigation water during plant cultivation. This equipment was designed, constructed and characterized in CNEA [10]. Thetotal sample size was 50 plants, 25 from each experimental group, in a completely randomized experimental design with three replicates for each determination.

Localized irrigation was performed by aerial and drip microjet, depending on the plants' stage of cultivation. During the first and second cultivation phase, that includ the establishment, vegetative growth and flowering, the irrigation was performed once a day for 20 min. In the third cultivation phase, which incorporates fruit ripening, the irrigation was conducted twice a day during 20 min. The irrigation schedule was completed in 120 days. Treatments were carried out at the time of irrigation of the plants during the entire crop cycle until the development of the fruits.

Irrigation was carried out twice a day through an aerial microjet system for 30 min, which has ITUR pump accessories and a distributor system, controlled by valves that ensured that the irrigation was done in sections. The characteristics of the irrigation system were as follows:

Water speed: 1,4 – 1,6 ms^-1

Pump Flow: 2,54 – 2,91 m³ h^-1

Crop natural conditions

The substrate characterization was performed, which was composed of a mixture of soil (brown without carbonate) and organic matter (3.5 %). The pH was 7.0. Pathogens, bacteria, and fungi were determined in collaboration with the Center for Industrial Biotechnology Studies (CEBI, Spanish acronym), Universidad de Oriente.

Collection and selection of fruits

In the two experimental groups the harvest of the ripe fruits was carried out in the fifth harvest according to established protocols [11]. After cultivation, 10 units of fruits were harvested at random from the two experimental groups. The fruits were dried in a stove (MWL-200, VEB, Germany) at 60 °C for 72 h. Then, they were pulverizedin an electric mill of blades (IKA M 20, China).Operations facilitated the extraction of the active principles and were carried out according to Branch Standard of the Ministry of Public Health (MINSAP, Spanish acronym) 310/91 [12].

Preparation of aqueous and ethanolic extracts

The dried fruits were weighed on a digital analytical balance (Sartorious® BS 124S, China) with an accuracy of 0,1 mg and the aqueous extracts were prepared at 50 mgL^-1 by infusions with distilled water during 5 - 10 min. The extracts were cooled at room temperature and centrifuged (2 000 rpm) for 10 min in a centrifuge (Centribio, MLW T24 D, Germany). The supernatant was filtered through a Whatman No. 4 filter paper until the clarified aqueous extracts were obtained.

The ethanolic extracts were prepared from the pulverized dried fruits. They were obtained according to the technique described in advance [13] . Solutions were prepared at a concentration of 0.1 gmL^-1 with 70 % ethanol, which were macerated in the dark for 7 days and with periodic stirring at room temperature (24 ± 2 °C). These mixtures were concentrated to total dryness in a rotary evaporator (Heidolph 4011, Canadá). With the resulting solid, infusions were prepared in distilled water until a concentration of 50 µgmL^-1 was obtained. The extracts were centrifuged (2000 rpm) for 10 min. The supernatants were filtered with Whatman No. 4 filter paper until clarified.

Phytochemical determination

The extracts were subjected to a phytochemical screening to obtain a qualitative criterion of the chemical composition, according to the protocol of Miranda et al. [14]. This method allowed to detect groups of secondary metabolites present in the extracts by specific chemical tests using different reagents, where the appearance of a certain color or precipitate colored or not, is indicative of the presence of the compound. Table 1 shows the metabolites that were determined and the tests performed for their identification.

TABLE 1. METABOLITES AND TEST EVALUATED IN THE PHYTOCHEMICAL SCREENING
PERFORMED ON AQUEOUS AND ETHANOLIC EXTRACT OF S. lycopersicum L.

 

RESULTS Y DISCUSSION

With the phytochemical screening, the qualitative determination of the chemical compounds of Solanum lycopersicum L. fruits was carried out and a high variability was found. Nine types of metabolites were identified in the aqueous and ethanolic extracts of the two experimental groups: alkaloids, quinones, saponins, essential oils and fatty substances, carotenoids, phenols, tannins, carbohydrates, flavonoids and reducing sugars (table 2).

TABLE 2. PHYTOCHEMICAL SCREENING TO AQUEOUS AND ETHANOLIC EXTRACT OF S. lycopersicum L.
FRUITS OBTAINED BY USING DIFFERENT TREATMENTS IN IRRIGATION WATER

Legend: AE: Aqueous Extract, EE: Ethanolic Extract, WMT (control): S. lycopersicum L. irrigated with water without treatment with MF. WTSMF: S. lycopersicum L. irrigated with non-uniform or heterogeneous SMF (20-200 mT). Response ++ (very positive: very marked presence of the secondary metabolite), Response + (positive: presence of the secondary metabolite), Response - (negative: absence of secondary metabolite)

In the aqueous and ethanolic extracts of both experimental groups, was evidenced the presence of all identified metabolites. Carotenoids, phenols, tannins, carbohydrates, flavonoids and reducing sugars showed a very positive response in the WSMT group, in relation to the WMT group. In the aqueous extracts of both experimental groups were demonstrated, the higher presence of saponins, that could be because they present a polar zone in their structure that consequently showed greater water solubility (table 2).

The presence of alkaloids was a positive response in the aqueous extracts of the two experimental groups. It did not occur in the same manner in the ethanolic extracts, where a weak presence of this type of secondary metabolite was obtained.

Carotenoids were more pronounced in the ethanolic extract compared to the aqueous extract (table 2). The higher presence of the carotene in the ethanolic extract of the WSMT group could have its cause in the chemical nature of these compounds. They are apolar, therefore they dissolve better in ethanol, which is less polar than water. Ethanol has a lypophilic fragment that supports the solvation of organic substrates [16].

Phenolic compounds with a marked response in the aqueous extracts of the WSMT group were determined. It was evidenced that polyphenols are more soluble in aqueous solutions than in ethanolic [16].The polyphenol group includes flavonoids, which also had a marked presence, as did the carbohydrates and sugars in the group where extracts were obtained fromthe fruits of the WSMT group.

The absence of fats could be because S. lycopersicum L. is composed of 0,2 g per 100 g of fresh fruit approximately so it is not a considerable amount [17]. Saponins were not found either. They are glycosides, capable of producing foam, but they are not very common in fruits of this species.

In the four extracts analyzed, the aqueous extracts had a higher content of secondary metabolites in relation to the ethanolic extracts. These results are consistent with those obtained by others authors [18] . Phenols, tannins, carbohydrates and flavonoids showed a marked presence in the aqueous extract, with respect to the ethanolic extract in the experimental WSMT group. Therefore, the aqueous extract was richer in metabolites. Due to the polar nature of these compounds, using water as solvent allowed for better extractions.

Water has two hydrogen atoms that make its polarity stronger, however ethanol has two carbon atoms that do not transfer their electrons so easily. The hydrogen-oxygen bond, having greater electronegativity of oxygen. It generates a dipole moment, in the tetrahedral structure of water, which is maintained or increased. There is a lower polarity of the carbon-hydrogen bond of the carbon chain.

One of the reasons, for which a better extraction and concentration of metabolites was obtained in the aqueous extracts, could be that the applied SMF reduced the mobility of the solvent in the solution, to improve the reaction. According to other investigations, the MF reduces the volume of the solvent and increases the strength of the hydrogen bonds. By maximizing the electrostatic attraction and the interactions, caused by the changes in the radial distribution function of the solvents. The hydrogen bonding characteristics of the solvents investigated by molecular dynamics simulations were evidence of the hydrogen bond strength of oxygen with hydrogen. It is a more efficient intermolecular hydrogen bond compared to nitrogen and hydrogen [19] . In addition, it has been shown that aqueous extractions increase the content of phenolic compounds, because water can improve the turgor of the cells in the contact surface area between the plant and the solvent, with an increase in extraction yield [20].

The predominant presence of these metabolites in the aqueous extract of the WSMT group could be due to the influence of the static magnetic treatment in the irrigation water of the Solanum lycopersicum L. plants. This could contribute to favor the synthesis of these secondary metabolites, leading to its marked presence in the fruits of this experimental group.

The SMF was possibly able to alter the irrigation water and affect its physicochemical properties. Different researchers have verified that with the application of MF to water, changes occur, in addition toalterations in the hydration of the ions. When water circulates through a MF, in each charged particle a Lorentz force isexerted in the opposite direction. The fact that protons or ions hydrogen are transferred along the hydrogen ring junction chains to form a proton stream under the action of this MF force, is controversial [21].

It is suggested that this water is better assimilated or absorbed by cells, and can affect the different potentials that are generated in that process. Therefore, it was possible to favor the intensity of the flow of water and minerals to the interior of the plant, which occurred faster that it, did under normal conditions by activation of the osmosis mechanism. All of which probably favored the transport routes of nutrients and soluble substances in plants. As a result, the stimulating effect of magnetically treated water between 20 and 200 mT was evident against the active compounds.

Literature provides evidence for multiple studies that support the effects of irrigation water with SMFin different magnetic induction ranges. It was achieved an increase in the concentration of carbohydrates and phenols in leaves of Solanum lycopersicum L . , Triticum sp . (wheat) and Pisum sativum (pea), using a magnetizer (Magnetron model UT1, from Magnetic Technologies LCC) [22]. An increase in the quercetin concentration, carotenoids and ascorbic acid, it has been obtained with the influence of SMF [23].

 

CONCLUSIONS

The phytochemical screening showed that the aqueous extracts prepared from the fruits of S. lycopersicum L. irrigated with the water treated with SMF between 20 and 200 mT, revealed a marked presence of carotenoids, phenols, tannins, carbohydrates and flavonoids. The results provide scientific evidence about the positive incidence of the application of MF in the secondary metabolites of fruits. The presence of a variety of secondary metabolites in S. lycopersicum L. fruits contributes to the biological and pharmacological effects associated with the consumption of this plant.

ACKNOWLEDGEMENTS

Authors are grateful to the Center for Environmental Sciences of the Hasselt University in Belgium for the VLIR- IUC-UOs project and P1 of the Universidad de Oriente, and to the BIOECO researchers in Santiago de Cuba.

 

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Recibido: 6/11/2017
Aceptado: 10/01/2018

 

 

Dra. C. Albys E. Ferrer-Dubois, Centro Nacional de Electromagnetismo Aplicado, Universidad de Oriente, Santiago de Cuba, Cuba, albys@uo.edu.cu