Abstracts

ORIGINAL ARTICLE

The effects of topical application of sunflower-seed oil on open wound healing in lambs¹ 1 Department of Animal Morphology and Physiology and Medicine Veterinary, Federal Rural University of Pernambuco. Brazil. How to cite this article: Marques SR, Peixoto CA, Messias JB, Albuquerque AR, Silva Jr VA. The effects of topical application of sunflower-seed oil on open wound healing in lambs. Acta Cir Bras [serial online] 2004 May-Jun;19(3). Available from URL: http://www.scielo.br/acb [also in CD-ROM].

Efeitos da aplicação tópica de óleo de semente de girassol em feridas cutâneas, em carneiros

Silvio Romero Marques^I; Christina A. Peixoto^II; Júlio Brando Messias^III; Alessandra Ribeiro de Albuquerque^IV; Valdemiro Amaro da Silva Junior^V

^IProf. Assistant of Department of Veterinary Medicine, Federal Rural University of Pernambuco. Brazil

^IIResearcher of Department of Pathology and Cellular Biology, Ageu Magalhães Research's Center, Federal University of Pernambuco. Brazil

^IIIProf. Assistant of Biological Science Center, University of Pernambuco. Brazil

^IVVeterinary autonomous

^VAssociate Prof. of Department of Animal Morphology and Physiology, Federal Rural University of Pernambuco. Brazil

^{Correspondence} Correspondence to Prof. Valdemiro Amaro da Silva Junior Departamento de Morfologia e Fisiologia Animal da Universidade Federal Rural de Pernambuco Av. D. Manoel de Medeiros, s/n. Recife - PE Tel: (81) 3302-1389 valdemiro.amaro@bol.com.br

ABSTRACT

PURPOSE: To demonstrate the effects of the use of sunflower seed oil on the treatment of skin wounds.

METHODS: Eighteen male Saint Inês lambs were divided in 3 groups according to the pos-operative (7, 14 and 21 days). After antisepsis and local anestesia, two 4cm² wounds on each side of the thoracic region, close to the scapule were surgically produced. The experimental wounds were treated with sunflower seed oil, with high concentration of linoleic acid (LA), and the control ones with sterilized Vaseline. Biopsies of the pos-operative wounds tissue were performed on the 7^th, 14^th, 21^st days and histologically evaluated.

RESULTS: Topic application of sunflower seed oil accelerated healing process at the 7th and 21st days, reducing wound area and increasing wound contraction. Granulation tissue increased faster on treated wounds. The epidermis of the treated wounds was completely recovered when compared to control wounds.

CONCLUSION: The topic use of sunflower seed oil accelerated the healing process, and it can be used as an alternative therapy on second intention wound healing.

Key words: Sunflower-seed oil. Topic use. Wound healing.

RESUMO

OBJETIVO: Demonstrar os efeitos do uso de óleo de semente de girassol no tratamento de feridas cutâneas.

MÉTODOS: Dezoito carneiros da raça Santa Inês foram divididos em 3 grupos de acordo com o pós-cirúrgico (7, 14, e 21 dias). Após antisepsia e anestesia local foram produzidas cirurgicamente duas feridas de 4 cm² em cada lado da região torácica próxima escápula. As feridas experimentais foram tratadas com óleo de semente de girassol, com alta concentração de ácido linoléico (LA) e as controles com vaselina esterilizada. Biopsias dos tecidos das feridas pós-cirúrgicas foram realizadas no 7^o, 14^o e 21^o dias e avaliadas histologicamente.

RESULTADOS: A aplicação tópica do óleo de semente de girassol acelerou o processo de cicatrização no 7^oe 21^o dias, reduzindo a área e aumentando a contração das feridas. O tecido de granulação se desenvolveu mais rapidamente em feridas tratadas. A epiderme das feridas tratadas estava completamente reconstituída em relação às feridas controle.

CONCLUSÃO: O uso tópico do óleo de semente de girassol acelerou a cicatrização, podendo ser utilizado como alternativa terapêutica na cicatrização de feridas por segunda intenção.

Descritores: Óleo de semente de girassol. Uso tópico. Cicatrização de feridas.

Introduction

Damage to the skin frequently provoke wounds or extensive loss of tissues, and to reestablish functional integrity a complex process of wound healing begins.^1,2 This sequence involves the migration of cells to the wound, proliferation of different cells types, and changes in the synthetic and secretory cellular activities.^3,4

Arachidonic acid is one of the most prominent polyunsaturated fatty acids in the skin, and its functional role depends largely on the generation of biologically potent oxidative metabolites.⁵ Eicosanoids, arachidonic acid derivatives, act as inflammatory mediators. They are chemotactic agents for leukocytes, stimulating vessel dilation and induce platelet aggregation. ⁶ The eicosanoid family consists of prostaglandins, thromboxanes, leukotrienes, and other hydroxy fatty acids.^7,8,9 These compounds participate in many physiological and pathological processes and are potent regulators of cell function.^10,11 According to Ziboh et al.⁵ the synthesis of pro-inflammatory mediators generated from arachidonic acid can possibly be modulated by a diet rich in linoleic acid (LA).

Working with cutaneous application of LA in rats, Hartop and Prottey, ¹² suggested that this fatty acid enhances the chemotaxis of polymorphonuclear leucocytes after tissue injury. Prottey ¹³ also observed a similar cellular migration after intraperitoneal injections of LA. Later, Moch et al.¹⁴ confirmed that LA is a potent proinflammatory mediator causing intense accumulation of leukocytes and macrophages. Furthermore, LA is an essential substance for regulation of the sequence of biochemical events that precede the fibroblastic cells mitogenesis .¹⁵

Excellent results have been obtained when the linoleic acid was applied cutaneously on wounds, pressure sores and other skin lesions to accelerate the human healing process .^16,6 Therefore, among other products whose composition has a high concentration of polyunsaturated fatty acids, sunflower-seed oil with its high concentration of LA^{16,17,18,19,6}, could be used as a new alternative for treatment of wounds.

The present work evaluates the clinical and histopathological aspects of cutaneous application of sunflower-seed oil with a high concentration of linoleic acid (65%) on the healing of surgically created open wounds on lambs.

Methods

The study protocol and procedures were reviewed and approved by the Committee of Ethics of the Department of Veterinary Medicine, Universidade Federal Rural de Pernambuco, Recife. Eighteen clinically healthy young male Saint Inês lambs weighing 10-15 kg were used in the experiment. Six animals per group were maintained in a box (9m²) with a concrete floor covered with a 20cm layer of sugar cane husks that was changed every 24 hours. Their diet was Pennisetum purpureum grass and balanced commercial food offered three times a day, along with water and mineral salt "ad libitum".

Local subcutaneous anesthesia with Lidoston^® (lidocaine 2%), using the inverted- L technique, was administered on all animals. Povidine^®(polivinil-pirrolidona-iodine), followed by alcohol at 70% was used at the operatory field. Two 4 cm² wounds close to the scapula on each side of the thoracic area were surgically produced in all animals. Animals were divided into groups according to the length of time they were observed postoperatively (7, 14, and 21 days) to evaluate subjective, planimetric and histopathologic parameters. Experimental wounds on the right side were treated with rayon gauze with sunflower-seed oil (Cocinero, Molinos - Argentina), containing a high concentration (65%) of linoleic acid (LA). On the left side, the control wounds were treated with sterilized pure petrolatum (Lafere - Recife) on rayon gauze. A bandage was placed around the animal's thoracic perimeter, with the same width as the gauze that covered the wounds. After the surgical procedures, the animals continued their normal diet, and did not receive any antibiotic or anti-inflammatory treatment.

The wounds were rinsed every 24 hours with physiologic saline solution and new rayon gauze containing sunflower-seed oil. Pure petrolatum was placed on the control wounds. This procedure was repeated for 7, 14, 21 days for the first, second and third groups respectively.

Animals were divided into groups according to postoperative observation time (7,14, and 21 days) to evaluate subjective and histopathologic parameters. Subjective observations were also made on postoperative day 3.

The wounds were evaluated according to the existence of edema, hyperemia, exsudato, granulation tissue and crust. Before biopsy, the wounds were measured with pachymeter (Stainless Hardened 708754) and photographed using a digital camera (Sony/Mavica). The wound area was estimated according to Prata et al. ²⁰, on the 7^th, 14^th, and 21^th day postoperative using the following equation:

A =p x R x r

Where "A" represents the area, "R" represents larger radius and "r" the smaller radius of the lesion.

The wounds degree of contraction was calculated by equations proposed by Ramsey et al.²¹:

Percent of contraction = 100 x (W₀ -W_i)/ W₀

Where W₀ = original area of the wound; Wi = area of the wound at the time of the evaluation (7, 14 and 21 days) and expresses in percent. The results were represented as means ± standard deviation and the statistical analysis was performed by test t of Student-Newman-Keuls where P<0,05 were considered significant.

Skin biopsies were taken on the 7^th, 14^th and 21^st days postoperatively, and in order to take tissue adjacent to the wound, fragments were extended 1cm from each margin and deepened to the muscular plane. The fragments were immersed in Bouin's fixative solution. For histological examination, the fixed specimens were processed routinely and embedded in paraffin. Sections with 5m m thickness were stained with hematoxylin and eosin.²²

Results

Effects of sunflower-seed oil on planimetric parameters of area and contraction

On the 3^rd day of the experimental period, the experimental wounds treated with sunflower-seed oil showed a statistically significant reduction (p<0,05) of the measured area (Table 1) and an increase of contraction (Table 2).

In contrast, control wounds exhibited increased areas (Tables 1, 2) and had no wound contraction (Figures 1, 2).

On the 7^th day, treated wounds presented borders with initial irregularity, and the wounds also showed a reduction of area and an increase of wound contraction that were confirmed statistically (p<0.05) (Tables 1, 2).

On one hand, statistical difference was not observed in relation to the area and contraction parameters between treated and controls (Tables 1, 2). On the other hand, very good clinical progress of treated wounds in second week was observed (14^th day).

On the 21^st day, treated wounds presented a reduction statistically significant (p<0,05) in the wound area and in the increase of wound contraction (0,09 cm² ± 0,04 cm²; 97,7 % ± 1,04%) at the end of the healing process of the experiment (Tables 1, 2). It's important to point out that some animals showed a contraction of 99% of the total area of the wound. Control wounds were in the final stage of the healing process (Table 1, 2) and exhibited small central areas of granulation tissue. However, these control wounds still needed some more time to complete healing.

Clinical evaluation

After skin excisions on day, it was possible to observe control wounds with hyperemia, necroses and highly vascularized granulation tissue (Figure 1A). Although the wound borders were geometrically well defined, edema and crust surrounding the wound margins were generally observed. In this experimental stage, the most striking feature of the treated wounds was a well-preserved vascular bed with discreet hyperemia and also the presence of edema in granulation tissue (Figure 1B). Although the treated wounds presented well-preserved borders, they had a mild alteration in the original geometric pattern, characterizing the initial contraction of wound margins.

After skin excision on the 3^rd day, the control wounds presented well-defined borders, preserved geometric shape and a little crust area on the inferior margin (Figure 1C). Furthermore, an absence of shrinkage promoting a diameter increase was detected (Table 3)

In contrast, treated wounds revealed the presence of hyperemic areas and absence of edema, due to the clear definition of wound borders (Figure 1D). In addition, the following aspects of the treated wounds were observed: no secretion on the wound bed, evident granulation tissue in its superior area, and an early shrinkage (Figure 1D).

On the 7^th day, a high quantity of crust was detected surrounding the control wounds' margins, which showed granulation tissue in the central area, hyperemia and edema (Figure 2A). At the same time, treated wounds not only had no crust, but also presented well-developed granulation tissue. In addition, no secretion in the treated wound bed was observed, although the presence of a mild hyperemia and few edema areas were detected (Figure 2B). Treated wounds had a geometrical alteration characterized by approximation of borders. This process was strengthened by significant reduction in the area and increase of the contraction (Tables 1, 2; Figure 2B).

On the 14^th day, treated wounds were observed: no secretion, edema or hyperemia on the wound bed. Although the treated wounds presented better clinical evolution than the control wounds, no statistically significant difference was observed for area and shrinkage of wound parameters (Tables 1, 2; Figures 2C, 2D).

Twenty-one days after surgical excision, control wounds had small areas of central granulation tissue, though they needed more time for total healing resolution (Tables 2, 3; Figures 2E, 2F). Treated wounds showed complete epithelial resurfacing with hair follicles lining the borders of wounds characterizing a centripetal evolution of contraction. Some animals presented 99% wound contraction.

Histological evaluation

On the 7^th day after excision, the control wounds had a great presence of crust, highly infiltrated granulation tissue with inflammatory cells, and many active spindle-shaped cells, which were fibroblasts (Figures 3A, 3C). These features indicated an initial organization of the granulation tissue. In treated wounds no crust was observed between the transitional area of hyperplastic epithelium and healing tissue. Granulation tissue was also more developed with minor inflammatory infiltration, the presence of plasma cells, active fibroblasts around new formed capillaries, and abundant extracellular matrix (Figures 3B, 3D).

On the 14^th day after excision, treated wounds presented a strong epidermic hyperplasia, though, no epidermic crests moving towards the subjacent connective tissue were detected (Figures 4A, 4B). Furthermore, fibroblasts exhibited a high activity of synthesis and a mild inflammatory infiltration in the subepidermic tissue next to the transitional area between the skin and cicatricial tissue (Figure 4B). In the cicatricial area, wounds treated with sunflower-seed oil had a slight superficial crust and the granulation tissue was more evolved than that observed in control wounds (Figure 4C).

In treated wounds the epithelium still presented a hyperplastic appearance, and fibroblasts with characteristic arrangement of miofibroblasts were observed (Figure 4D). Also, the treated wounds presented a reduction of inflammatory cells in ground substance and in the newly formed vascular bed (Figures 4E, 4F).

Wounds treated with sunflower-seed oil had a better clinical and microscopic healing process, than those of control wounds at 14 days, though no statistical significance related to the area of reduction and contraction could be observed.

On the 21^st day after surgical excision, the control wounds showed a mild process of epithelialization beneath an area of crust, and highly infiltrated connective tissue with polymorphonuclear leukocytes (Figures 5C, 5E). This process needed more time to conclude epithelial resurfacing due to the evident area of epithelium discontinuity (Figure 5A). Wounds treated with sunflower-seed oil with a high concentration of linoleic acid showed total epithelial resurfacing and subjacent connective tissue very active fibroblastic cells in the synthesis of extracellular matrix, especially collagen fibers (Figures 5B, 5D). In addition, the amorphous ground substance had a mild quantity of inflammatory cells (Figure 5F).

Discussion

Essential fatty acids´ (EFA) effectiveness on problems related to skin lesions has been studied since 1929, when the first observations of skin lesions provoked by a shortage of EFA levels in foods were made.^{23, 24} Linn and Shepherd ²⁵ described the cure of those alterations by topical application of EFAs. Essential fatty acids, linolenic acid and arachidonic acid are polyunsaturated vegetable lipids that cannot be synthesized by the animal organisms, necessitating renewal by diet. ²⁶

In 1954, Sinclair and Basnayeke ²⁷ described a dry skin desquamation or dermatosis provoked by the rate of transepidermal water loss related to a dietary deficiency in essential fatty acids. Later, Van Dorp ²⁸ and Prottey et al.²⁹ observed a reversion and cure of both scaly lesions and dermatosis after topical application of sunflower-seed oil with a high concentration of linoleic acid. Hartop and Prottey ³⁰ had showed that when applied cutaneously, both linoleic and g -linoleic acids, but neither dihomo-g -linoleic nor arachidonic acid, restored the epidermal permeability to normal rates in rat skin. According to Prottey¹³ linoleic and arachidonic acids are important in the maintenance of a cutaneous barrier to water loss and as precursor of prostaglandins, which are thought to be involved in both the regulation of cell division and differentiation of epidermis, and consequently in the control of skin scaliness. Elias and Brown¹⁰ showed that EFAs are precursors of pharmacologically active substances such as thromboxanes, prostaciclins, prostaglandins and others that are involved in cellular division regulation and epidermic differentiation.

Linoleic acid is a powerful pro-inflammatory mediator that causes a migration of granulocytes and macrophages as well as important changes in granulation tissue.¹⁴ According to Glasgow and Eling¹⁵ linoleic acid is essential for regulation of the biochemical events that precede the fibroblastic mitogenesis since it stimulates some factors of cellular growth.

In open wounds, epithelialization occurs after the development of a granulation bed ³¹, which is also formed when the repair process of connective tissue is necessary. ¹ By definition, this is an inflammatory growth of connective tissue characterized by synthesis and deposition of products of fibrogenic cells that can be divided in three phases: (a) cell mobilization and proliferation; and (b) synthesis and deposition of collagen products, glycosaminoglycans and extracellular matrix, and (c) a final organization or remodeling of the wound scar.^32,4

This paper evaluated the evolution of the wound healing process in young male lambs utilizing cutaneous application of sunflower-seed oil with a high concentration of linoleic acid, describing a simple methodology for wound management and the progression of wound healing.

After 3^rd day of sunflower-seed oil treatment, we observed acceleration in the evolution of the cicatricial process of the treated wounds by reductions of wound area, as an increase of 300% in wound contraction. These results confirm those obtained by Baie and Sheikh ³³, which demonstrated the efficiency of amino acids and essential fatty acids in wound healing. Although a histopathological evaluation of the wounds has not been made, morphometrical findings pointed out acceleration in the sequential biological events with a mild growth of granulation tissue and absence of edema and secretion. Macroscopical findings of the healing process on the 3^rd day, can be related to the migration, proliferation and cellular differentiation, as well as to the pathognomonics of the inflammatory phase for repairing tissue.¹⁹

By the seventh day after excision, the wounds treated were more evolved macroscopically than the control wounds due to a great development of granulation tissue, contraction in the outer edge of borders and absence of secretion. On the other hand, the control wounds had extensive areas of crust, hyperemia and edema. In that same period, treated wounds had a reduction of 10% and 20% in the diameter and area, respectively, as well as an increase of 37% in contraction in relation to the control wounds. Histopathological data in treated wounds on the seventh day indicated a more advanced repair process than control wounds, due to fewer inflammatory infiltration and presence of active fibroblasts around newly formed vessels.

The acceleration of the inflammatory process can be explained by biological and biochemical features of the linoleic acid. This polyunsaturated fatty acid (18:2n-6) is changed by desaturation and elongation of its molecule to arachidonic acid (20:4n-6) which is metabolized via the 5-lipoxygenase and clyclooxygense pathway in leukotrienes (LTB₄, LTC₄ and LTD4), prostaglandins (PGE₂, PGF_2, PGD₂ and PGI₂) and thromboxane A₂ by polymorphonuclear cells. These substances produced by LA have pro-inflammatory properties that can stimulate new vascularization locally, cell migration, proliferation and fibroblastic differentiation as well as extracellular matrix synthesis.^{1, 5, 34, 19}

While evaluating wounds on the fourteenth day of treatment, we detected no morphometrical differences between the two groups. However clinical data showed a more advanced cicatricial stage in treated wounds. These results are in accordance with findings of Baie and Sheikh ³³ who had treated rats with fish oil, and by the end of twelve days had obtained 80% of wound contraction, though our data pointed out 87% contraction in the same period.

In the wound contraction area, miofibroblastic cells had an important role in centripetal closeness and approximation of wounds borders.¹ In lambs, our results showed that wounds treated with sunflower-seed oil had well arranged miofibroblastic cells in the contraction area while in the control wounds these cellular types were in high synthesis activity of matrix components showing little organization in wound borders.

Ono et al.³⁵ indicated the importance of cytokines and growth factors in the wound healing process. Many of these factors, such as the epidermal growth factor (EGF), fibroblastic basic growth factor (bFGF); platelet-derived growth factor (PDGF), transforming growth factor alpha (TGF-a ) and interleukin-6 (IL-6) are cytokines that stimulate keratinocyte proliferation. The topical use of bFGF, PDGF e TGF-a in wounds not only facilitates the migration of monocytes, neutrophils, macrophages and fibroblasts, but also stimulates the proliferation of the granulation tissue.³⁵ Thus, linoleic acid metabolism seems to play an important function in the EGF-regulated sequence of biochemical events leading to fibroblast mitogenesis, and consequently inducing an early formation of granulation tissue.¹⁵

By the end of the experimental period (21 days), wounds treated with sunflower-seed oil had approximately 68% area reduction, and 98% in wound contraction, although in some animals 99% wound shrinkage was observed. Hence, our data indicate that the topical use of sunflower-seed oil with high concentration of linoleic acid can be used as an efficient therapy for wound healing, confirming previous work on maturation and remodeling of wounds. ¹

The regression of the hyperplasic epidermis observed in this phase can be justified by linoleic acid's anti-inflammatory action as indicated by Ziboh ⁵ and Ziboh et al.³⁴ In this alternative pathway, the 15-lipoxygenase changes the linoleic acid in 13-hydroxyoctadecadienoic acid (13-HODE) that is catalyzed in the epidermis to 13-HODE-diacylglycerol. The epidermal concentration of 13-HODE-substituted diacylglycerol plays a role in vivo in modulating cutaneous hyperproliferation via down-regulation of protein kinase C-b (PKC-b ) and reversing the epidermical proliferation by basal levels.³⁵ According to Declair ⁴, the transforming growth factor (TGF) could be also involved in the anti-inflamatory process since it acts as an inhibitor of cell proliferation in lymphocytes and in most epithelial cells.

At the end of the experiment, on the 21^st day, a small quantity of vessels was observed in treated wounds, which could be attributed to a progressive endothelial reduction of the newly formed vessels, described by CORSI et al. ¹ as an event related to the end of the healing process.

Mat Jais et al ¹⁷, Fredalina et al. ¹⁸, and Baie and Sheikh ¹⁹ described the effects of polyunsaturated fatty acids in the wound healing process. These authors demonstrated that wounds in rats when treated with fish oil containing a high concentration of polyunsaturated fatty acid improved dermal wound healing. Moch et al. ¹⁴ observed an efficient topical action of linoleic acid on abdominal lesions produced experimentally in rats. Histological analysis of the treated tissue showed that the fish oil acted as a local immunogen causing the migration of both polymorphonuclear leucocytes and macrophages, and resulting in proliferative activity during the appearance of granulation tissue. ⁴ Declair ^36,19 observed that topical application of vegetable oil with a high concentration of linoleic acid in hospitalized humans considerably reduced pressure skin sores and accelerated wound healing.

The present work showed by morphometrical, clinical and histological assays that sunflower-seed oil improved the granulation tissue formation and epithelial resurfacing of wounds. Therefore, sunflower-seed oil or other vegetable oils containing a high concentration of linoleic acid, can be indicated as a therapeutic alternative for wound healing process by second intention in veterinary medicine.

Data do recebimento: 28/02/2004

Data da revisão: 16/03/2004

Data da aprovação: 02/04/2004

Conflict of interest: none

Financial source: none

Publication Dates

History