Effects of Equisetum arvense Ointment on Diabetic Wound Healing in Rats

This study is designed to evaluate the effect of Equisetum arvense (EA) ointment on dermal diabetic wound healing in streptozotocin-induced diabetic rats. Methods. In this study, diabetes was induced via a single intraperitoneal injection of 65 mg/kg streptozotocin in 56 male Wistar rats. After anesthetization, a 15 mm x 15 mm wound for each rat was made by removing skin in a circle on the dorsum. A total of 56 diabetic wounds were studied in 8 groups (n = 7), 4 of which were treated with EA ointment. On the 7th and 14th days after creating the wounds, the state of the diabetic wound healing was evaluated with wound closure ratio and by performing histopathologic studies. Results. Groups treated with EA 5%-10% ointment were found to have a statistically higher wound closure ratio than control and petroleum jelly-lanolin groups (P < 0.05). On day 14, groups to which EA 5%-10% ointment was applied showed 99.71% and 99.93% wound closure ratio (P < 0.05) and higher dermal and epidermal regeneration, angiogenesis, and granulation tissue thickness after 14 days than the other groups (P < 0.05). Conclusion. These results indicate that EA ointments exhibit significant diabetic wound healing activity in excision wounds. Further clinical and experimental studies are needed to confirm these results.

Introduction

The prevalence of diabetes has increased worldwide, and diabetic complications have become a serious issue for public health. One of these complications is impaired wound healing in patients with diabetes.^1,2 The wound healing process is a complex cascade that relies on several mechanisms for tissue repair, including inflammation, granulation tissue formation, reepithelialization, and angiogenesis.³ However, with pathological conditions, such as diabetes mellitus, epithelial wound healing is delayed, resulting in persistent corneal epithelial defects and recurrent corneal erosion,^4,5 which makes the diabetic wounds a great problem for health services. The most common site for patients with diabetes to develop a wound is in the lower extremities, especially the feet.⁶ The pathogenesis of diabetic foot ulcers is complex and it is well known that a number of contributing factors working together lead to impaired healing. Several factors such as peripheral neuropathy, peripheral vascular disease, and peripheral edema have been identified as the most common factors responsible for impaired healing after trauma.⁷ Patients can undergo surgical interventions, such as peripheral bypass to improve vascular circulation, wound debridement to control the wound, and amputation, if required. However, medical therapies for wound care are limited, so development of new treatment modalities to improve wound healing in patients with diabetes is an essential and emerging field of investigation.⁸ Numerous conservative methods for treatment of diabetic wounds are reported in the literature, such as honey as a dressing solution,⁹ topical antimicrobial therapies,¹⁰ total contact casting,¹¹ wound dressings,¹² extracorporeal shock wave therapy,¹³ and vacuum-assisted closure.¹⁴ Some herbal therapies were also reported, such as Astragalus membranaceus and Rehmannia glutinosa.¹⁵ The Equisetum arvense (EA) plant has been traditionally used in Turkey for the treatment of skin wounds in animals and for oral infections in humans. In addition, EA has also been used in Europe in the form of a bath for gynecological diseases, rheumatic diseases, gout, and treatment of poorly healing wounds, tumescence, and broken bones.^16,17 Several studies have shown hypoglycemic antiseptic, antimicrobial, antioxidant, antidepressant, sedative, hepatoprotective, antinociceptive, and anti-inﬂammatory effects of the EA plant.^18-23 Less is known about the role of EA in diabetic dermal wounds. The present study was aimed to investigate the efficacy of topical application of EA ointment by morphological and histological methods in the process of wound healing in streptozotocin (STZ)-induced diabetic rats.

Methods

Albino Wistar male rats weighing 200 g - 250 g were obtained from the central animal house of Dumlupinar University and used for the study. Rats were housed individually in cages, maintained under standard conditions (12 hour light/12 hour dark cycle at 25ºC ± 3ºC), and fed with standard pellet and water ad libitum. Animal studies were performed after approval from Animal Care and Ethics Committee of Dumlupinar University. The EA plant was collected in Mersin, Turkey. The plant was identified in the Department of Biology in Dumlupinar University Faculty of Arts and Sciences. Air-dried leaves of the plant were turned into a powder using a grinder. An ointment base was formulated using a 1:1 mixture of petroleum jelly and lanolin. For 10% and 5% EA ointment, EA powder was mixed with the ointment base during ointment-forming process (eg, for 10% EA ointment, 5 g of EA powder was mixed into 45 g of the ointment base).²⁴ Diabetes was induced by a single dose intraperitoneal (IP) injection of STZ (65 mg/kg, Sigma-Aldrich, St. Louis, MO) freshly prepared in saline.²⁵ Three days after the STZ injection, glycemia was confirmed, and rats showing fasting blood glucose > 250 mg/dl were considered diabetic rats. Animals were randomly divided into 8 groups, each of them consisting of 7 rats. Capillary blood glucose was determined by glucose meter (Optium Xceed, Abbott, Diabetes Care Ltd, Oxon, UK). A deep skin ulcer model was created using diabetic rats as follows.²⁴ The rats were anesthetized by IP injection of xylazin hydrochloride (10 mg/kg) and ketamine hydrochloride (25 mg/ kg), their back hair was shaved, and application field was outlined with a marking pen just before removing the skin. Full-thickness skin wounds in each rat were prepared by removing skin in a circle with 1.5 cm diameter on the dorsum. A total of 56 diabetic wounds were studied in 8 groups (n = 7). No treatment was administered in the first and second groups, which lasted for 7 days and 14 days, respectively. The third and fourth groups consisted of diabetic rats that were administered a 1:1 mixture of petroleum jelly and lanolin therapy for 7 days and 14 days, respectively. A 5% EA plus 1:1 mixture of petroleum jelly and lanolin was used in the fifth and sixth groups for 7 days and 14 days, respectively; and in the seventh and eighth groups, 10% EA plus 1:1 mixture of petroleum jelly and lanolin therapy was used for 7 days and 14 days, respectively. All wounds were cleaned daily with sterile normal saline solution. After cleaning, ointment base and EA ointments were applied to the wounds. All ointments were applied evenly in sufficient amounts to cover all wound areas. After treatment started, the animals were euthanized by ether inhalation at appropriate intervals (on days 7 or 14) and the tissues, including the wound and its surrounding skin and muscle, were excised. Wound healing was examined by measuring the reduction of the wound surface area with a stereomicroscope (SZX-ILLD2-200, Olympus, Center Valley, PA) and photographed using a digital camera (Spot Insight QE, Diagnostic Instruments, Sterling Heights, MI). The ratio of healing was calculated using the following equation: Healing ratio (%) = 100 x (1-wound area/initial wound area) After macroscopic evaluation, the excised tissue was fixed with 10% buffered formalin. Each specimen was embedded in a paraffin block, sliced into thin 2.5-µm sections, and stained with hematoxylin-eosin. Then, the specimens were assessed for severity of histopathologic changes, under light microscopy by a pathologist who was unaware of the experimental procedure. Epidermal and dermal regeneration, granulation tissue thickness, and angiogenesis were scored as described by Altavilla et al²⁶ according to the criteria as shown in Table 1.

Statistical Analysis

The results were expressed as mean ± SD and statistical differences between several treatments and their respective control were determined by one-way analysis of variance (ANOVA) followed by Tukey test, using SPSS 14.0 software. The level of significance was set at P < 0.05.

Results

Animal weight and glucose results for the 7th and 14th days are shown in Table 2. Accordingly, in the multiple comparisons, the rates of wound healing were found to be significantly higher in the diabetic rat groups administered 5% EA and 10% EA ointment compared with those administered a mixture of petroleum jelly and lanolin (PL) and the untreated group (for comparison, the level of significance was set at P < 0.05). Macroscopic view and wound closure ratio are presented in Figure 1(A and B) and Figure 2. On the 7th day wound closure ratios were observed -1.78% ± 30.14% in control group, 11.7% ± 10.38% in PL group, 76.74% ± 7.93% in 5% EA group, and 85.1±8.44% in 10% EA group. The EA groups were found statistically more significant than PL and control groups (P < 0.05). On the 14th day, wound closure ratios observed were 14.37% ± 28.51% in the control group, 40.04% ± 9.93% in the PL group, 99.7% ± 0.24% in the 5% EA group, and 99.9% ± 0.19% in the 10% EA group (P < 0.05). The authors think the efficacy of the EA ointment is more related to treatment time rather than dosage because there were no significant differences in wound healing in the 5% EA group and the 10% EA group during day 7 and day 14 (P > 0.05). The results of histopathologic studies are presented in Table 3 and Figure 3. At the end of the first week the histopathologic scores were found to be higher in the EA groups of dermal regeneration, granulation tissue thickness, and angiogenesis levels than in the control and PL groups (P < 0.05). In the second week, all histopathologic scores were observed higher in the EA groups than the other groups (P < 0.05), which also supports the conclusion about the efficacy of treatment time and inefficacy of EA ointments dosage percentage. The authors did not find significant difference in histopathologic scores within either the EA or control groups (P > 0.05) (Table 3).

Discussion

Wound healing is a complex multifactorial process that results in the contraction and closure of the wound. The wound-healing process comprises inﬂammation, proliferation (formation of granulated tissue), and tissue remodeling. Reepithelialization of wounds begins within hours of injury and proceeds first over the margin of the residual dermis and subsequently over granulation tissue.^27,28 In diabetic wounds, the healing process is prevented by several abnormalities including prolonged inﬂammation, impaired neovasculation, decreased collagen synthesis, and defective macrophage functions.^29-31 Impaired wound healing occurs in patients with diabetes, and has been reported to be associated with high blood glucose levels.^32,33 Hence, in the present study, rats with STZ-induced diabetes were used as the model for the study diabetic wound healing. The STZ selectively destroys pancreatic β-cells, inhibits the synthesis and release of insulin, and causes the onset of diabetes mellitus.³⁴ It has been shown that blood glucose levels peak 1 to 3 days after a single high-dose injection of STZ, and then remains elevated.³⁵ Streptozotocin-induced diabetes in rodents is considered to be a model of insulin-dependent diabetes mellitus, and is widely used in the study of insulinopenia and hyperglycemia.³⁶ Diabetes that has been induced by a single high dose of STZ is typically accompanied by diabetic symptoms such as weight loss, polyuria, hyperglycemia, and neuroendocrine dysfunction.³⁷ In the present study, wound healing activity was observed in satisfactory progress when treated with ointment of EA for full-thickness skin diabetic wounds. In wounds treated with either 5% or 10% EA ointment, the period of epithelialization decreased, there were higher scores in granulation tissue thickness, angiogenesis, and wound closure ratio. In addition, both 5% and 10% EA ointment increased reepithelialization and formulated new blood vessels, especially on day 14. There are many studies about diabetic wound healing in the recent literature. Some herbs used to make ointment for diabetic foot ulcers were Radix Rehmanniae,³⁸ oak bark in conjunction with salicylic acid benzoic acid (Bensal HP, 7 Oaks Pharmaceutical Corp, Easley, NC),³⁹ and polyherbal formulations (Hippophae rhamnoides L. and Aloe vera L. and Curcuma longa L.).⁴⁰ In diabetic full-thickness skin wounds, as used in present study, Channa striatus⁴¹ and Sparassis crispa⁴² were used for treatment of the diabetic wounds. In addition, some herb extracts were used for hypoglycemic effects as shown in the plant of Strychnos pseudoquina extracts in cutaneous diabetic wound.⁴³ The referenced studies show these plants are effective for treatment of diabetic wounds. This study, with treatment results as well as with the material and methods, is concordant with these literature studies.

Conclusion

Angiogenesis plays an important role in wound healing and newly formed blood vessels comprise 60% of the repair tissue. Neovascularization helps hypoxic wounds to attain the normoxic conditions.⁴⁴ Reepithelialization plays a crucial role in cutaneous repair, depending upon the specific type of wound.^45,46 It was observed that the EA ointment increased the angiogenesis phase, and the reepithelialisation and wound healing process. Literature studies show that plants proven effective at accelerating wound healing have antimicrobial, antioxidant, and anti-inflammatory characteristics. Equisetum arvense plants comprise antioxidant components such as flavonoids (ie, quercetin-3-O-glucoside, luteolin, onitin, isoquercitrin); copper and zinc^19,22,47-50; antimicrobial components such as caffeic acid, styrylpyrone, thymol, hexahydro femmesil, trans-phytol, cis-geranyl acetone, kaempferol^18,51-53; anti-inflammatory components such as β-cytosterol, campesterol; and isofucosterol chemical elements which have induced neutrophil migration.^54,55,56,57 Because of its antioxidant, antimicrobial, and anti-inflammatory effects, the EA plant decreased processes of inﬂammation, improved neovascularization, and increased collagen synthesis and macrophage functions. Thanks to these positive effects, EA can be used for diabetic wound healing. In addition, the authors found that the dosage of EA is not important. This plant can be used effectively in low doses. Consequently, the results of present study indicates important healing effects in diabetic wounds in an animal model.

Acknowledgments

Yusuf Ozay is from the Department of Medical Biology, Faculty of Medicine, Adiyaman University, Adiyaman, Turkey. M. Kasim Cayci, PhD; and M. Sabri Ozyurt are from the Faculty of Arts and Sciences, Department of Biology, Dumlupinar University, Kutahya, Turkey. Sevda Guzel-Ozay is from the Faculty of Pharmacy, Department of Pharmacognosy, Mersin University, Mersin, Turkey. Ali Cimbiz is from the Faculty of Health Sciences, Department of Physiotherapy and Rehabilitation, Zirve University, Gaziantep, Turkey. Esra Gurlek-Olgun is from the Ministry of Health, Department of Forensic Medicine, Izmir, Turkey.

Address correspondence to: M. Kasim Cayci, PhD Dumlupinar University Faculty of Arts and Sciences Department of Biology Merkez Campus Tavsanli Yolu 10. km 43270 Kutahya/Turkey mkasim.cayci@dpu.edu.tr

Disclosure: The authors disclose no financial or other conflicts of interest.

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