Acute Toxicity and Dermal and Eye Irritation of the Aqueous and Hydroalcoholic Extracts of the Seeds of “Zapote” Pouteria mammosa (L.) Cronquist

The common use of Pouteria mammosa (L.) Cronquist, “Mamey or Zapote,” in food and ethnobotanic medicine shows its low or absent toxicity as fruit extracts prepared from seeds. However, it is essential to conduct security trials to scientifically support their use in drug therapy. This study evaluated the aqueous and hydroalcoholic extract (25%) Acute Oral Toxicity, obtained from the seeds of P. mammosa, in Sprague Dawley rats and dermal and eye irritability in New Zealand rabbits. The 404 and 405 acute dermal and eye irritation/corrosion guidelines were used, as well as the 423 Acute Oral Toxicity guideline, Acute Toxic Class Method of the Organization for Economic Cooperation and Development (OECD). The aqueous extract was located in the following category: not classified as toxic (CTA 5), while hydroalcoholic extract at 25% was classified as dangerous (CTA 4). Both extracts can be used without side reaction that irritates the skin which permitted classification as potentially not irritant. P. mammosa in the two extracts caused mild and reversible eye irritation, and it was classified as slightly irritating.


Introduction
It is believed that the word "Zapote" has as origin the Aztec word "tzapotl," which was generally applied to all sweet and soft fruits. For a long time this has been the common name for Pouteria mammosa (L.) Cronquist. This plant fruit has been traditionally used for its medicinal properties against fever, inflammation, skin rashes, ulcers, nausea, vomiting, and diabetes, besides being a rich source of nutrients [1]. In Cuba, the milky bark juice has been used since at least 1864 to destroy warts, while the extract of the seeds is used as emollient in painful skin diseases [2]. Also, infusions of the seed are used to treat cough and bronchitis, not only in Cuba but also in Costa Rica [3]. 2 The Scientific World Journal Species from the Sapotaceae family have been well studied for their insecticidal and larvicidal actions such as the case of Pouteria venosa (Mart.) Baehni. In this species, four isolated triterpenes (taraxerol, ursolic acid, 3 ,19 ,23-trihydroxyurs-12-en-28-oic acid, and 2 ,3 ,19 ,23-tetrahydroxyurs-12-en-28-oic acid) and a phytosteroid (spinasterol) were active against 4th instar larvae of Aedes aegypti [4]. In wood and bark extracts of Pouteria guianensis Aubl. chemical compounds with repellent properties against Nasutitermes sp. were identified [5]. Pouterin, a lectin-like protein isolated from Pouteria torta (Mart.) Radlk. seeds, caused 50% mortality in larvae of the insect Callosobruchus maculatus F. (Coleoptera) when incorporated in the diet [6]. It is also known that this protein presents an insecticidal effect against Anagasta kuehniella (Lepidoptera: Pyralidae) larvae [7]. These insects are recognized as a major cause of loss in stored grains throughout the world. Recently the activity of Pouteria mammosa (L.) Cronquist aqueous extract in the postembryonic development of the blowfly Chrysomya putoria (Calliphoridae) was evaluated [8]. The results revealed a 47.5% decrease in the viability of the flies. The production of myiasis by flies and its affinity with humans and domestic animals has been known since antiquity [9,10]. These results place P. mammosa as a candidate for alternative insect control, which is currently performed almost exclusively with the use of organophosphate insecticides, which are toxic to living beings, can cause serious environmental damage, and may induce or develop resistant insects [11,12].
The ancient and common use of "Zapote" as food and/or therapeutic alternative signs it as not dangerous for human health. However, to scientifically support its use in drug therapy, it is essential to accomplish trials attesting its security. This study therefore evaluated the Acute Oral Toxicity and the Dermal and Eye Irritability tests of the aqueous and hydroalcoholic extracts (25%), obtained from the seeds of P. mammosa.

Plant
Material. Pouteria mammosa fruits were collected in February of 2012 in the town of "El Caney" Santiago de Cuba. Leaves and seeds were taxonomically identified by specialists of "Centro Oriental de Ecosistemas y Biodiversidad (BIOECO)" from the Natural History Museum Tomas Romay-Santiago de Cuba City. Desiccated specimens were deposited into the herbarium of the same institution under the registration number Hac 468.

Zapote Seeds Extracts.
The endocarp from seeds of P. mammosa was removed and the endosperm pulverized in a knife mill. Aqueous and hydroalcoholic (25%) extracts in the proportion of 40 grams in 100 milliliters were prepared by maceration with agitation in a sieve for 8 hours. The extracts were filtered, bottled in amber flasks, and stored at 8 ∘ C. A qualitative phytochemical screening was carried out to determine the presence of alkaloids, triterpenes and/or steroids, quinones, coumarins, lipid and/or essential oils, mucilage, saponins, phenols and/or tannins, amino acids,  [17]. Substances ranges are set in toxic classes of not classified, dangerous, toxic, very toxic, and highly toxic as shown in Table 1. Food was suspended 12 hours before starting the study and the body mass was determined moments before the administration of the extract. Animals were randomly assigned to two groups of three rats each: a control group treated with physiological saline and another group treated with the extracts. To the first experimental group a dose of 300 mg/kg was given using an orogastric tube. Clinical observations of animals were performed four times per day, paying attention to behavior, general physical condition, nasal mucosa, changes in skin and fur, respiratory frequency, somatomotor activity, and possible occurrence of signs such as tremors, convulsions, diarrhea, lethargy, drooling, low response to stimuli, sleep, photophobia, and coma. Palpation of the abdomen was carried out as well. After 48 hours of clinical observation without any signs of toxicity, a second experimental group was carried out administering 2000 mg/kg of extract. Animals were weighed on the seventh and fourteenth days. The animals were humanely euthanized  [15] for classification of substances irritating effect on the skin.

Ranges of Dermal Irritation Score
Classification of dermal irritability Severely irritating Table 3: Ocular Irritation Scores ranges established under the Cuban method for classification of eye irritation/corrosion [16].

Ranges of Ocular Irritation Score
Classification of eye irritability Slightly irritating 20 ≤ OIS < 30 Moderately irritating 30 ≤ OIS ≤ 110 Severely irritating at the end of the study by administering an overdose of the anesthetic ketamine intraperitoneally. Internal organs were subsequently studied macroscopically.

Dermal Irritation Test.
Animals were shaved 24 hours before the application of the extracts on the back and both flanks (10% body surface). Skin was washed with sterile water and allowed to stand for 24 hours. Patches with 0.5 mL of extract were applied on an area of about 6 cm 2 of one flank, and the other flank was used as a reference. Animals were exposed to the extract for four hours after which the patches were removed and the application area was washed with sterile water. Observations were recorded at 1, 24, 48, and 72 hours after the removal of the patches. Behavior, general condition, posture and reflexes, attitude towards food, water, and hygiene were evaluated. Weights were recorded and compared at the beginning and the end of the study. Evaluation of edema and erythema was performed and the Dermal Irritation Score (DIS) was calculated by the following formula: The extracts were classified as proposed by Draize The value obtained was compared with the ranges defined in Table 3

Phytochemical Screening.
It was determined that both extracts (aqueous and hydroalcoholic at 25%) contained, in similar intensities, coumarins, saponins, phenols, and tannins, suggesting similar amounts. More flavonoids and cyanogenic glycosides were present in the aqueous extract than in the hydroalcoholic one. None of the extracts showed the presence of resins, cardiotonic glycosides, and mucilages. Metabolites which caused most differences between the two extracts were lipids and/or essential oils, amino acids, and reducing sugars that are only contained in the aqueous extract. Alkaloids, quinones and triterpenes, and steroids were evident only in the hydroalcoholic extract at 25% of P. mammosa.     other rats died at 7 and 12 hours, showing similar clinical signs of rectal bleeding. At necropsy, the animals showed no macroscopic alterations of the organs except in the case of the dead rat at the dose level of 2000 mg/kg of the aqueous extract of P. mammosa, whose stomach showed an increase in size caused by gases. Intestinal edema with fibrinous exudate and distended cecum was also observed, which can be found related to the presence of cyanogenic glycosides contained in the extract.

Acute
According to Alemán and Gad et al., body weight is often the most sensible indicator of an adverse effect [19][20][21]. Other authors, such as Mosberg and Hayes, have argued that the data referring to body weight have a high sensitivity to alterations due to chemicals with low toxicity [22]. It is considered that among the indicators that provide more information in toxicological studies is the rapid loss of body weight (approximately 15 to 29% loss of body weight in a period of five to seven days) [23,24].
It was observed that the body weight was not affected after administration of the extracts (Figures 1 and 2), showing a normal increase, which corresponds to standard references to the use and care of laboratory animals, in relation to the species used [23,25]. When the aqueous extract was analyzed (Figure 1), in the case of the group treated with P. mammosa, weight gain was 47.40 g (21.61%) and an increase in weight of 23.97 g (representing 11.31%) was observed in the control group. These results were corroborated by statistical analysis and significant differences, < 0.05, in the unpaired " " test were found with Welch's correction. The treated group assimilated the maximum dose of 2000 mg/kg.
The hydroalcoholic extract of P. mammosa at 25% proved to have a superior level of toxicity because the maximum dose that was assimilated by the rats was 300 mg/kg (Figure 2). The control group had a 27.40 g increase until the end of study representing a 12.44% weight gain and treated group had an average increase of 34.53 g representing a 14.01% weight gain. No significant differences were found between the treated and the control groups when performing statistical analysis. When the 2000 mg/kg dose of hydroalcoholic extract of P. mammosa at 25% was administered all animals died. Weight gain was evident in all animals included in the study and was greater in those treated with extracts of P. mammosa in both forms, aqueous and hydroalcoholic 25%. This effect found for body weight is consistent with results obtained by ). They reported that saponins increased food consumption, thus resulting in increased weight gain in rats [26][27][28][29]. In phytochemical screening of P. mammosa it was determined that both extracts (aqueous and hydroalcoholic at 25%) contained saponins, in similar intensities, which could justify the same effect in this study. Coincidentally a similar result was obtained in invertebrate organisms by Carriço et al. that studied the effect of P. mammosa on immature stages of Chrysomya putoria, wherein the groups treated with the aqueous extract of leaves resulted in an increase in body weight of maggots [8].
The group treated with 25% hydroalcoholic extract of P. mammosa showed the same evidence for the three dead rats at the dose level used: distended stomach with bloody walls, edematous and hemorrhagic bowel, and cyanotic walls of the stomach and intestinal mucosa. These results could be expected considering the abundance of alkaloids observed in the chemical composition of the hydroalcoholic extract, shown by the phytochemical screening. Some alkaloids of plant substances can act on cholinergic receptors at some neuroeffector junctions (acting as cholinomimetic agent) and the myenteric plexus in the gastrointestinal tract (GI) significantly stimulating the digestive tract. They can also induce tracheobronchial secretions and stimulate bronchial smooth muscle, resulting in intense bronchoconstriction and reduced vital capacity [30].

Dermal Irritation.
Rabbits showed no signs of irritation or skin edema. The skin was intact when patches were removed and within 72 hours of the study. The Dermal Irritation Score for aqueous and hydroalcoholic 25% extracts of seedsof P. mammosa was equal to "0." Body weight in rabbits was not affected in any case after the application of extracts. A normal increase of body weight was observed corresponding to the established rules for handling laboratory animals, in relation to the species [23].

Eye
Irritation. Ocular Irritation Score was 10.5 in the aqueous and slightly higher in the hydroalcoholic 25% extract of P. mammosa (OIS = 15.3). The index for both cases is within acceptable limits as set by García-Simón et al. [16]. It was evident that the effects on the eye were reversible within 96 hours for those that occurred in the conjunctiva, 72 hours for those that occurred in the iris, and 48 hours for those on the cornea ( Table 4). The behavior of body weight in rabbits was not affected after administration of the extracts. No clinical signs or changes in the behavior of animals associated with the administration of the extracts were evident.

Conclusions
Aqueous extract of Pouteria mammosa (L.) Cronquist was located in the following category: not classified as toxic (CTA 5), established by the guideline 423 of the Organization for Economic Cooperation and Development (OECD). However, due to the occurrence of death of an animal and the manifestation of several clinical signs, the assessment of the subchronic toxicity is suggested by a toxicity test repeated dose for 28 days. The hydroalcoholic extract 25% at the dose of 2000 mg/kg showed clinical signs of toxicity and death of all animals, gross lesions in organs and organ systems. The extract was classified as dangerous (CTA 4), with a LD 50 mortality range between 300 and 2000 mg/kg. Neither extract induced any apparent adverse clinical signs in animals when applied on the skin, showing that P. mammosa can be used without side reaction on organs. Both extracts were classified as potentially not irritant, according to guideline 404 of the Organization for Economic Cooperation and Development (OECD) which evaluates acute dermal irritation/corrosion. Both extracts obtained from seeds of P. mammosa caused mild and reversible damage. They were classified as slightly irritant, according to the guideline 405 of the Organization for Economic Cooperation and Development (OECD) which evaluates acute eye irritation/corrosion.