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. 2017 Oct 19;4(3):205–212. doi: 10.14744/nci.2017.94914

Evaluation of the wound healing potential of Aloe vera-based extract of Nerium oleander

Sevcan Gul Akgun 1, Sezgin Aydemir 2, Naziye Ozkan 2, Meral Yuksel 3, Semra Sardas 1,
PMCID: PMC5724913  PMID: 29270567

Abstract

OBJECTIVE:

Nerium oleander (Apocynaceae) and Aloe vera (Liliaceae) are among the widely used herbal remedies for treating skin diseases and possess numerous activities such as antibacterial, antiviral, antifungal, and antioxidant. The aim of this study was to investigate the possible wound healing effect of Aloev era-based extract of the N. oleander leaf (NAE-8®) based on its antioxidant, anti-inflammatory, and DNA repair capacity along with histological changes and to compare them with the traditional silver sulfadiazine treatment (SSD).

METHODS:

Twenty-four Wistar albino rats were randomly grouped as follows: i) control, ii) burn alone (burn), iii) burn with topical NAE-8® (burn+NAE-8®) treatment, and iv) burn with topical 1% silver sulfadiazine (burn+SSD) treatment. All groups received their related topical application twice a day for 14 consecutive days. Upon completion of the experimental protocol, trunk blood and skin tissues were collected for measuring malondialdehyde (MDA), glutathione (GSH), myeloperoxidase (MPO), tumor necrosis factor alpha (TNF-α), interleukin-1β (IL-1β), %DNA in the tail (%DNAT) levels along with histological examinations.

RESULTS:

Thermal injury-induced alterations in MDA, GSH, MPO, TNF-α, IL-1β, and %DNAT levels were significantly reversed by NAE-8® treatment. These ameliorative effects were also supported by histological findings.

CONCLUSION:

Findings of the present study suggest that NAE-8® is a promising remedy for treating skin burn injury.

Keywords: Anti-inflammatory effect, antioxidant effect, DNA damage, nerium oleander

Burn injuries constitute an important public health problem inducing numerous potentially fatal complications, including shock, anemia, electrolyte imbalances, renal failure, and metabolic disturbances [1, 2]. Initial responses to thermal injury are denaturation of proteins and destruction of membrane integrity followed by activation of the inflammatory cascade, alterations in the cytokine milieu by rapid release of various cytokines such as tumor necrosis factor alpha (TNF-a) and interleukins (IL), and secretion of reactive oxygen species (ROS) [24]. Oxidative stress emerging from tremendous production of ROS is among the most important mechanisms responsible for local and distant pathophysiological events during burn progression [5]. Recent evidences suggest that overproduced ROS triggers lipid, membrane, nucleic acid, and protein damages leading to lipid peroxidation, double-strand DNA breaks (DSB), and single-strand DNA breaks (SSB) along with apoptosis [68]. Tissue injury after thermal trauma is associated with elevated ROS levels in addition to effects of activated neutrophils and macrophages creating the need for wound treatment with agents that possess anti-inflammatory or antioxidant [9].

Nitrofurazone [10], silver sulfadiazine [11], and many other remedies have been utilized in burn control and treatment. Phytomedicines to cure burns are brought into the medical forefront during the last decades. Although herbal products are extensively preferred and have become more widely available commercially, modern scientific methods and clinical trials are needed for confirming claims about their therapeutic effects.

Nerium oleander (synonym N. indicum Mill) is a well-known evergreen flowering shrub belonging to the Apocynaceae family and numerous activities including antibacterial, antiviral, antifungal, anti-inflammatory, and antioxidant [12, 13] have been attributed to the presence of alkaloids, flavonoids, phenolics, and glycosides in different parts of the plant [14]. Aloe vera, with its use in dermatological disorders, has an important role in traditional and contemporary medicine because of the occurrence of various biologically active compounds such as flavonoids, saponin, amino acids, vitamins, and minerals [1315]. On the basis of above-mentioned knowledge, the present study was undertaken to evaluate the ameliorative effect of an Aloe vera-based extract of the N. oleander leaf (NAE-8®) on wound healing in a burn induced rat model and to compare the treatment efficacy with that of silver sulfadiazine (SSD), a widely used human medicinal product in burn treatment. For this purpose, rats were randomly allocated to four groups consisting of six rats in each group: i) control, ii) burn alone (burn), iii) burn with topical NAE-8® treatment (burn+NAE-8®), and iv) burn with topical 1% SSD treatment (burn+SSD). After completion of the experimental protocol, the skin tissue and blood samples were used for conducting certain biochemical and genotoxicity assays along with histological stainings.

MATERIALS AND METHODS

Chemicals and reagents

All chemicals were purchased from Sigma-Aldrich Co. (St Louis, MO, USA), Bio-Optica (Milano, Italy). or E. Merck Co. (Darmstadt, Germany). TNF-a and IL-1b enzyme-linked immunosorbent assay (ELISA) kits were purchased from eBiosience, Bender MedSystems GmbH (Vienna, Austria). Silverdin® (1% SSD ointment) was bought from Deva Holding Drug Company (Istanbul, Turkey). NAE-8® was obtained from Nerium Biotechnology Inc (San Antonio, TX, USA).

Animals

Twenty-four Wistar albino rats weighing 200–250 g were obtained from Marmara University School of Medicine Animal House. The rats were housed in individual cages at a constant temperature (20°C±2°C) with a 12 h light–dark cycle and were fed with a standard rat chow and water ad libitum throughout the study. Ethics committee approval for all procedures was received from the Animal Care and Use Committee of Marmara University School of Medicine, Istanbul, Turkey (Approval ID: 63.2015.mar, Approval Date: 6 November 2015).

Experimental design

The dorsal part of each rat was shaved using an electric razor under brief ether anesthesia. The animals were anesthetized with ketamine (80 mg/kg, ip) and xilazyne (10 mg/kg, ip) prior to thermal injury. The shaved back of each animal was immersed in water at 90°C for 10 s to produce a partial-thickness second degree burn injury covering 30% of the total body surface area, whereas animals in the control group were immersed in 25°C water and resuscitation was achieved by subcutaneous injection of 10 ml/kg physiological saline. All groups received the respective topical application of NAE-8®, 1% SSD, or physiological saline at a dose of 2 ml/kg/day; 2 g/kg/day, or 2 ml/kg/day, respectively, twice a day for 14 consecutive days. At the end of the experiment, animals were euthanized by decapitation followed by the collection of trunk blood used for TNF-a, IL-1b, and %DNAT measurement. Skin tissue samples were kept at −20°C for biochemical assays, whereas the samples for histological examination were stored in 10% neutral buffered formalin at room temperature (25 °C).

Malondialdehyde and glutathione levels

Skin tissue samples were homogenized (w/v 10%) in 10% trichloroacetic acid and centrifuged at 3000 rpm at 4°C for 15 min. The supernatants obtained were used for determining malondialdehyde (MDA) and glutathione (GSH) levels. MDA levels were examined by monitoring the reaction between same volume of trichloroacetic acid and supernatant at 100°C [16]. Absorbance was measured at 532 nm, and the results are expressed as nmol MDA/g tissue. GSH levels were determined using a modification of the Ellman procedure [17] by measuring the absorbance at 412 nm, and the results are expressed as µmol GSH/g tissue.

Myeloperoxidase activity

Myeloperoxidase (MPO) activity was measured via a MPO-dependent reaction of o-dianisidine and hydrogen peroxide at 460 nm using a similar procedure as reported by Hillegass et al. [18] and the results are expressed as U/g tissue.

Cytokine assays

Serum TNF-a and IL-1b levels were assayed in duplicates using the commercial ELISA kits, and the results are expressed as pg/ml.

Single-cell gel electrophoresis (Comet assay)

The alkaline comet assay was performed using on a modified procedure of that used by Singh et al. [19]. Each slide was blindly viewed by one slide reader under a fluorescence microscope (Olympus-BX51, Olympus Corporation, Tokyo, Japan) equipped with an excitation filter of 546 nm and a barrier filter of 590 nm. The percentage of DNA in the tail (%DNAT) was taken as a measure of DNA-break frequency by scoring 100 cells per sample using image analysis software (BAB Bs200Pro Image Processing and Analysis System of BAB Muh., Ankara, Turkey).

Histological examination

The excised skin stored in 10% neutral buffered formalin solution was dehydrated in ascending alcohol series, cleared in xylene, and embedded in paraffin. Paraffin sections (3 µm thick) were cut, deparaffinized, and stained with hematoxylin and eosin (H&E) or Gomori’s one step trichrome. All sections were blindly examined and photographed under a light microscope (Olympus-CX41RF, Olympus Corporation, Tokyo, Japan) by an experienced histologist. Congestion, necrosis, inflammatory cell infiltration, fibroblast proliferation, epithelization, and angiogenesis were scored semiquantitatively and ranked as none, slight, and moderate, as reported by Kwansang et al. [20].

Statistics

Statistical analyses were performed using the GraphPad InStat (GraphPad Software, San Diego, CA) program. All results are provided as means±standard error of mean; groups of data were compared using one-way analysis of variance (one-way ANOVA) followed by Tukey’s multiple comparison tests. Values of p <0.05 were considered as significant.

Results

The effect of NAE-8® on investigated parameters in each group is presented in Table 1. NAE-8® treatment significantly reduced the elevated MDA level in the burn+NAE-8® group (47.07±12.71 nmol/g; p<0.001) compared with that in the burn group (185.38±17.55 nmol/g) . Compared with the burn group, similar positive effects were also observed for skin GSH levels in the burn+NAE-8® (p<0.001) and burn+SSD groups (p<0.05).

Table 1.

Effect of NAE-8® on MPO activity and MDA, GSH, IL-1β, TNF-α, and %DNAT levels

Group MDA (nmol/g tissue) GSH (µmol/g tissue) MPO (U/g tissue) TNF-α (pg/mL) IL1-β (pg/mL) %DNAT
i) Control 15.23±1.74 3.29±0.26 0.77±0.12 25.33±2.94 30.17±3.95 25.42±0.25
ii) Burn 185.38±17.55*** 1.78±0.18*** 3.94±0.71*** 45.17±3.72*** 108.25±16.89*** 30.25±0.73***
iii) Burn+NAE-8® 47.07±12.71+++ 3.19±0.25+++ 1.58±0.08++ 30.00±2.85++ 49.50±4.46+++ 27.91±0.28++
iv) Burn+SSD 135.49±22.83 2.74±0.17+ 2.81±0.61 30.17±1.30++ 29.50±2.40+++ 25.28±0.19+++
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***

p < 0.001 compared to with the control group,

+

p<0.05,

++

p< 0.01 and

+++

p<0.001 compared to with the burn group (n=6 rats per/group).

Data are expressed as mean±standard error of mean.

GSH: Glutathione; IL-1β: Interleukin-1β; MDA: Malondialdehyde; MPO: Myeloperoxidase; NAE-8®: Aloe vera-based extract of Nerium oleander; TNF-α: Tumor necrosis factor; SSD: 1% silver sulphadiazinesulfadiazine; %DNAT: The percentages of DNA in tail.

The significant elevation in MPO activity in the burn group (3.94±0.71 U/g; p<0.001) compared with that in the control group (0.77±0.12 U/g) was abolished by NAE-8® (1.58±0.08 U/g) and SSD treatments (2.81±0.61 U/g), and only the burn+NAE-8® group showed a statistically significant difference compared with the burn group (p<0.01).

Serum TNF-a and IL-1b levels were reduced by both NAE-8® and SSD treatment in the burn+NAE-8® and burn+SSD groups, respectively, compared with those in the burn group, as demonstrated in Table 1.

A significant (p<0.001) increase the mean %DNAT was observed in the burn group (30.25±0.73) compared with that in the control group (25.42±0.25). Treatment with NAE-8® and SSD significantly reduced the increase in the mean %DNAT triggered by burn injury, and the images of comets are shown in Figure 1.

Figure 1.

Figure 1

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Images of comets from burn injury (A), NAE-8® treatment after burn injury (B), and SSD treatment after burn injury (C).

Histological analysis revealed that skin sections from the control group showed regular tissue characteristics with intact sebaceous glands, hair follicles, and dermal collagen (Fig. 2A, Fig. 2E). Burn trauma led to severe degeneration with epidermal detachment, scabs formation of the necrotic tissue remnants, vasocongestion, and edema. There were extensive inflammatory cell infiltrations and no hair follicles or sebaceous glands in the dermis, as demonstrated in Figure 2B, F.

Figure 2.

Figure 2

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Histological evaluation of wound skin sections stained with hematoxylin and eosin (H&E) and Gomori’s one step trichrome (×100). Regular tissue with epidermis (arrow) and dermis (asterics) in the control group (A, E). Necrotic area/ crust (asterics), inflammatory cell infiltration (arrow), and collagen (c) in the burn group (B, F). Necrotic area/crust (asterics), re-epithelization (arrow), and collagen (c) in the burn+SSD group (C, G). Re-epithelization (arrow) and angiogenesis (arrowhead) in the burn + NAE-8® group (D). Re-epithelization (arrow), collagen (c), and fibroblast proliferation (arrowhead) in the burn + NAE-8® group (H).

The burn+NAE-8® and burn+SSD groups revealed remarkable healing with decreases in inflammatory cells and necrosis along with increases in fibroblast proliferation, angiogenesis, and re-epithelization compared with that in the burn group, as observed using the H&E-stained skin sections (Table 2, Figure 2C, D vs B).

Table 2.

Histological scores in burn wounds of treated groups

Group (n=6) Burn Burn+NAE-8® Burn+SSD
Congestion ++ + ++
Necrosis +++ ++ ++
Inflammatory cell infiltration +++ ++ ++
Fibroblast proliferation ++ +++ +++
Epithelization + ++ ++
Angiogenesis ++ ++ ++
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−: none; +: slight; ++: moderate; +++: marked.

NAE-8®: Aloe vera-based extract of Nerium oleander; SSD: 1% silver sulfadiazine.

Decreased inflammatory cells in the burn+SSD and burn+NAE-8® groups were also observable with the Gomori’s one step trichrome stain (Figure 2G, H). SSD treatment triggered the re-epithelization process and reduced necrosis in the burn+SSD group compared with that in the burn group. Light microscopic findings revealed that NAE-8® and SSD treatment have shown similar healing processes with clearly developed epidermis and regular collagen levels.

Discussion

Burn injury produces a burst of free radicals that interact with various biomolecules, leading to the destruction of cellular components, inflammatory reactions, increased oxidative stress in the cells, and delay in healing [21, 22]. The effects of antioxidant treatment on burn injuries have been comprehensively studied because antioxidants prevent the oxidation of biomolecules by eliminating overproduced ROS, removing inflammation products, and facilitating a quicker wound healing process [22, 23]. Lipid peroxidation, which is considered to be one of the most deleterious events occurring secondary to burn injury with excessive expression of MDA [24], has been seen in the burn group along with depletion of GSH stores [25]. NAE-8® treatment reversed these parameters, indicating that NAE-8® reduces lipid peroxidation and supports the maintenance of cellular integrity as a potent antioxidant. Similarly, Benson et al. [13] recently showed the protective effect of NAE-8® on intracellular reduced GSH stores in a study performed using human primary dermal fibroblasts. Various studies have also demonstrated the amendatory effect of Nerium on GSH and MDA because of its beneficial effect against lipid peroxidation [26, 27]. Consequently, the findings of the present study supported the anticipated antioxidant activity of NAE-8® probably because of the contribution of well-known effects of each ingredient.

Severe burn injury represents a pathophysiological condition in which activated neutrophils and macrophages produce increased levels of proinflammatory mediators, such as TNF-a and IL-1b, contributing to cellular injury [2528]. The traditionally known anti-inflammatory activity of N. oleander [27] has recently been confirmed by Dey and Chaudhuri in a study with murine splenic lymphocytes [29]. Besides, the anti-inflammatory activity of NAE-8® accompanying the induction of certain cytokines in dermal fibroblasts of relevance to wound healing was demonstrated by recent reports [13, 30]. Our findings, which are consistent with those of previous reports, accentuated the significant downregulation of burn-related increases in TNF-a and IL-1b expressions by NAE-8® treatment. In addition to abnormal cytokine levels, burn-related significant increases in MPO activity was reduced by NAE-8® treatment, referring to its inhibitory effect of tissue neutrophil infiltration.

DNA damage including SSB, DSB, apurinic/apyrimidinic site, and strand fragmentation can occur when the balance between endogenous oxidants and antioxidant defenses is impaired because of burn injury [31]. Furthermore, the relation between DNA strand breaks and heat has been previously investigated even though the underlying mechanism has not yet been clarified [3234]. The evaluation of heat-induced production of DSBs was performed by comet assay [35]. The present study is, to the best of our knowledge, the first in vivo study examining combined effects of N. oleander and Aloe vera on thermal injury-induced genotoxicity by comet assay. DNA damage was escalated by burn injury as evidenced by the significantly increased %DNAT in the burn group. This elevation was reduced by NAE-8® treatment, which might be considered as a sign of its DNA repair capacity.

Regeneration of the epidermis, reduction in infiltrated cell levels, the role of fibroblasts and endothelial cells in repairing the dermis, and reinforcement of capillary growth and collagen development was previously underlined [36]. A study by Rout et al. [37] revealed that N. oleander extract has a remarkable wound healing activity in rats, most probably due to its antimicrobial and antioxidant activities. The enhancing effect of Aloe vera to collagen levels providing strength and integrity to the tissue matrix and playing an important role in hemeostasis along with epithelialization were also previously reported [15, 38]. In accordance with the prior studies, the present study revealed clearly developed epithelization after NAE-8® treatment along with irrefutable reductions in the extent of necrosis and inflammatory cell infiltration. Furthermore, NAE-8® treatment strongly induced migration of fibroblasts which produce matrix proteins, fibronectin, proteoglycan, hyaluronan, and collagens for wound repair [20].

In conclusion, analyzed data presented here with enhanced antioxidant and anti-inflammatory effects, DNA repair capacity, and histological findings suggest that NAE-8® is a new therapeutic remedy in skin care to manage burn wound, which offers a scientific reinforcement for future studies.

Footnotes

Conflict of Interest: None declared.

Financial Disclosure: This study was financially supported by the Commission of Scientific Investigations Projects (BAPKO) of Marmara University (Project No: SAG-C-DRP-110316-0078).

Authorship contributions: Concept: S.S., S.G.A.; Design: S.S., S.G.A.; Supervision: S.S.; Materials: S.G.A, S.A., N.O., M.Y.; Data collection &/or processing: S.G.A, S.A., N.O., M.Y.; Analysis &/or interpretation: S.G.A, S.A., N.O., M.Y.; Literature search: S.G.A.; Writing: S.G.A.; Critical review: S.S.

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Articles from Northern Clinics of Istanbul are provided here courtesy of Istanbul Northern Anatolian Association of Public Hospitals

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