Background
Wound healing is a natural process that involves a cascade of complicated cellular and biomolecular processes that restore damaged wound tissue into its original state when injury occurred. The fundamental biological wound repair process is comprised of inflammation, cell migration/cell proliferation, and remodelling. The orderly progression of healing events leads to rapid wound closure, and for acute wound healing a minimal or aesthetically acceptable scar with no regeneration [
1]. This process takes place at an optimal rate in healthy individuals, but it is usually delayed or impaired for patients in diabetic conditions.
Altered wound healing is one of the most common complications in Diabetes Mellitus (DM). The wound healing process in patients with DM is deteriorated due to hyperglycaemic conditions that lead to major chronic complications, such as Diabetic Foot Ulcers (DFUs) [
2]. Abnormal wound healing often leads to chronic ulcer formation, which has caused major worldwide morbidity due to various clinical and socioeconomic issues. According to Brem and Canic [
3], this is a 15% risk of getting foot ulcers for people with diabetes, of which 85% will have to undergo lower extremity amputations.
The mechanism of delayed wound healing is multifactorial, including a prolonged inflammatory stage and postponed proliferation and remodelling stages [
4]. DeClue and Shornick [
5] reported that diabetic wound healing was associated with the over release of proinflammatory cytokines such as IL-1β, IL-6, and TNF-α. Qiu et al. [
6] revealed that diabetic patients with high blood glucose showed hindered cell proliferation and declined production of collagen and growth factors during wound healing. Reduced angiogenesis is also an important cause of impaired wound healing in diabetics with low levels of the VEGF and TGF-1β growth factors [
7]. In this study, these biomarkers were selected to measure drug mechanisms during wound healing.
There have been various attempts to accelerate wound healing in diabetics, but so far only a few effective therapeutic remedies are available. Alternative therapeutic treatments using natural products are highly demanded. The Vicenin-2 (VCN-2) active compound in plants was targeted for diabetic wound healing efficacy due to its antidiabetic [
8], anti-hyperglycemic [
9,
10], anti-oxidant [
11], anti-inflammatory [
12,
13], cell proliferation, and cell migration activities [
14].
Dressings cast from hydrocolloid films are a popular wound dressing owing to their high absorption ability via strong hydrophilic gel formation [
15]. Furthermore, alginate is a natural polysaccharide found in the cell walls of brown algae that possesses high gel forming properties that are biodegradable and biocompatible in nature [
16]. Sodium alginate (SA) is usually exploited as a drug-controlled release vehicle in drug delivery systems due to the various cross-linking polymers present in it. Sodium Alginate (SA), which provide reduce hydrocolloid film swelling from water exposure (wound exudate). This is important in controlling the slow release properties of bioactive materials (i.e. drugs) from the gel and ensuring high formulation efficacy [
17].
This goal of this study was to investigate the efficacy of a new formulation of hydrocolloid dressing, a Sodium Alginate (SA) biomaterial scaffold with VCN-2, on the healing of excision wounds in a type-1 diabetic Sprague Dawley rat. This study suggests that VCN-2 hydrocolloid film hold considerable promise in diabetic wound healing, and is a potential therapeutic dressing for enhanced diabetic skin wound healing in the future.
Methodology
Chemical and reagents
Commercial standard Vicenin-2 (VCN-2) was purchased from Haihang Industrial Company (Beijing, China). Allantoin brand Fluka Analytical and Streptozotocin (STZ) were obtained from Sigma Aldrich Chemicals (St. Louis, MO, USA). Diagnostic kits for VEGF and TGF-β were bought from Bender MedSystems (Vienna, Austria) while insulin diagnostic kits were acquired from Mercodia Corporation (Uppsala, Sweden). RIPA buffer and sulphanilamide were received from Nacalai (Kyoto, Japan) and Friedman Schmidt (CT Parkwood, WA, Australia), respectively. The standard protein assay kit (Pierce™ 660 nm Protein Assay) and bicinchoninic acid (BCA) assay were bought from Thermo Fisher Scientific (Waltham, MA, USA). Primary antibodies specific to iNOS, COX-2, NF-휅B, MMP-9, VEGF, TGF-β, β-actin, and anti-rabbit and/or anti-mouse secondary antibodies conjugated into horseradish peroxidase were attained from Santa Cruz Biotechnology (Santa Cruz, CA). All the chemicals used in the experiments were of an analytical grade.
Animal models
In this study, 84 healthy male adult Sprague Dawley rats (7–8 weeks old), weighing between 150 and 250 g, were kept in polypropylene cages at the animal house of the Faculty of Medicine and Health Sciences, Universiti Putra Malaysia. The animals were maintained under standard conditions: temperature (25 ± 2 °C), relative room humidity (55%) and alternating light-dark cycle (12 h/12 h), with access to standard pellets and water ad libitum for the entire experimental period. The animal experiments were approved by the Institutional Animal Care and Use Committee (IACUC) of Universiti Putra Malaysia (authorization number UPM/IACUC/AUP-R079/2016) in accordance with the recommendations for handling animals for research. In this experiment, rats were divided into six groups on day 7 and day 14, with each group having six animals. On day 0, rats were only divided into normal and diabetes groups (n = 6).
Induction of diabetes
To induce the diabetes mellitus experimental model, 66 animals were injected via single intraperitoneal injection with STZ (50 mg/kg) freshly prepared in a cold 0.1 M sodium citrate buffer (pH 4.5) prior to fasting for approximately 16 h, with only water provided ad libitum. The rats in the normal group were injected intraperitoneally with sodium citrate buffer (pH 4.5) [
18,
19]. Three days after induction, a drop of blood (~ 1.5 μl) from the tail vein of each rat was obtained using a lancet. The blood was tested using a commercial glucometer (ACCU-CHECK Active Glucose Monitor, Roche, Germany) to determine hyperglycemia development. The fasting rats with a blood glucose level > 11 mmol/L on day 7 after injection were considered diabetic and were used in further experiments in this study [
20].
Induction of wound
All animals were anaesthetised with 90 mg/kg ketamine and 10 mg/kg xylazine intraperitoneally following confirmation of diabetes. Prior to wound infliction, the dorsal fur of the animals was shaved with an electric clipper and disinfected with 70% ethanol. A standardized full thickness open excision wound was created using a biopsy punch (Cat no.12–460-412, Thermo Fischer Scientific, USA) that was 6 mm in diameter and 2 mm in depth [
21]. The wound was left uncovered for 24 h. Rats with an open wound were kept in a polypropylene cage.
Treatment of wound
Various concentrations of formulated VCN-2 hydrocolloid film was applied topically to the rats every day for 14 days, beginning 24 h after the wound was inflicted. Based on Table
1, there were 6 animal treatment groups: normal rats treated with blank film (Group I), diabetic rats treated with blank film (Group II), diabetic rats treated with 12.5, 25, and 50 μM VCN-2 film (Group III-V); and diabetic rats treated with 316 μM allantoin film (Group VI). Wounds were treated by applying a 0.8 cm
2 film dressing and adhesive-permeable bandage wrapping. Allantoin film was used as the positive drug control for this experiment.
Table 1
Division of animal according to groups
I | Normal | 18 | Normal rat (N) + Wound (W) + Blank film |
II | Diabetic | 18 | Diabetic rat (D) + W + Blank film |
III | 12.5 μM VCN-2 | 12 | D + W + 12.5 μM VCN-2 film |
IV | 25 μM VCN-2 | 12 | D + W + 25 μM VCN-2 film |
V | 50 μM VCN-2 | 12 | D + W + 50 μM VCN-2 film |
VI | 316 μM ALN | 12 | D + W + 316 μM ALC film |
Determination of blood glucose, insulin level and measurement of body weight, pellet and fluid intake
Biochemical determinations (blood glucose and insulin level) and physiological measurements (body weight, pellet and fluid intake) were measured on day 7 and day 14 for all groups. Blood glucose readings for each rat was obtained using a glucometer. The harvested animal group blood samples were collected via cardiac puncture and clotted at room temperature for 15 to 30 min, before being centrifuged at 2200 to 2500 rpm for 15 min to create a blood serum. A quantitative determination of serum insulin for all the rats was done using a rat insulin ELISA kit in accordance with manufacturer instructions. Body weight as well as pellet and fluid intake for all animal groups was monitored on a daily basis for 2 weeks using a balance and measuring cylinder. Fixed amounts of standard pellets and fluids were given to the rats and both were replenished on the next day.
Gross evaluation of wound contraction
Reductions in wound area over time has been reported to predict wound healing in diabetic foot ulcers. Wound areas on day 7 and 14 are regarded as an important indicator of wound healing [
22]. Animal wounds were evaluated macroscopically on day 0, 7, and 14 to assess the healing process and to measure the wound area. Wound closure rates were expressed as a percentage of original wound area. The wound was photographed with a digital camera to judge wound closure progress. Due to the irregular shapes of the wounds (circular), outer wound margins in this study were traced on a transparent sheet using a permanent marker. The planimetrical surface area was measured on graph paper according to the method assessed by Ponrasu and Suguna [
23]. According to Lin et al. [
24], the percentage (%) of the wound contraction was then determined using the formula below:
$$ \boldsymbol{Wound}\kern0.17em \boldsymbol{contraction}\kern0.17em \boldsymbol{rate}\;\left(\%\right)=\frac{\boldsymbol{Initial}\kern0.17em \boldsymbol{wound}\kern0.17em \boldsymbol{size}-\boldsymbol{wound}\kern0.17em \boldsymbol{size}\;\boldsymbol{on}\;\boldsymbol{specific}\;\boldsymbol{day}\;\left(\boldsymbol{mm}\mathbf{2}\right)}{\boldsymbol{Initial}\kern0.17em \boldsymbol{wound}\kern0.17em \boldsymbol{size}\;\left(\boldsymbol{mm}\mathbf{2}\right)}\boldsymbol{x}\mathbf{100}\% $$
Histological study of wound
Prior to animal sacrificed and wound tissue harvested, rats were euthanized by cervical dislocation under anesthesia using diethyl ether. Histological examinations were carried out to assess cellular responses and vascularisation of wound tissue for further wound healing evaluation. Biopsies of wounded areas were performed using histological evaluations 7 and 14 days post-wounding. The wound samples were fixed with a 10% formaldehyde buffer solution for 72 h. Samples then underwent a standard dehydration process in a series of increasing ethanol concentrations for 24 h by a processing machine. Then, the tissue was degreased with xylene, embedded in paraffin, and sectioned using a histological microtome. Sections of 5 μm thick tissue were mounted on a glass slide and stained using haematoxylin and eosin (H&E). This was followed by the visualisation of samples under a light microscope at 100 x and 400 x magnification.
A semi-quantitative method was used to examine the following histological structures and processes: epidermal regeneration (100 x), granulation tissue thickness (100 x), fibroblast proliferation (400 x), angiogenesis (400 x) and the presence of inflammatory cells (400 x). Three stained sections from 10 random fields for each group were evaluated and scored using a scale of 1–3 for epidermal regeneration and granulation tissue thickness; and a scale of 0–4 for fibroblast proliferation, angiogenesis, and the presence of inflammatory cells as summarized in Table
2. All stained images were taken by using an Olympus microscope (BX-51; Olympus, Tokyo, Japan).
Table 2
Histological features of wound healing
Epidermal Regeneration | None | Mild | Moderate | Complete | – |
Granulation tissue thickness | None | Mild | Moderate | Complete | – |
Fibroblast proliferation | Absence | Occasional presence | Light scattering | Abundance | Confluence |
Presence of neovascularization (angiogenesis) | Absence | Occasional presence | Light scattering | Abundance | Confluence |
Presence of inflammatory cells | Absence | Occasional presence | Light scattering | Abundance | Confluence |
Examination of NO production of wound through NO screening assay
One gram of wound tissue from each group was cut into pieces using a scalpel/surgical blade, and then pulverized with a mortar/pestle following tissue sample collection as described in Table
1. Under ice conditions, 3 mL RIPA buffer was added into a 10 mL centrifuge tube contained skin tissue for homogenization. Skin tissue samples were incubated on ice for 2 h, after which the homogenates were centrifuged at 10000 X g for 10 min at 4 °C. Wound lysates (supernatants) containing whole proteins was transferred into a new microtube and stored at − 20 °C for experimental analysis. To measure nitrite levels, the supernatants of wound lysates with 100 μL were mixed with 100 μL freshly prepared Griess reagent (0.1% N-(1-naphthyl) ethylenediamine dihydrochloride, 1% sulphanilamide, and 2.5% phosphoric acid). The mixture solution was incubated for 10 min and absorbance was measured at 540 nm using a microplate reader. Sodium nitrate (NaNO
2) was compared with the standard curve.
Measurement of cytokines (IL-1β, IL-6 and TNF-α) and growth factors (VEGF and TGF-β) productions of wound through ELISA
The concentration of proinflammatory cytokines, including IL-6, IL-1 β, and TNF-α as well as healing growth factors such as VEGF and TGF-β, were detected according to manufacturer instruction using DuoSet ELISA Development (R&D Systems, MN, USA). Basically, selected standard and wound lysate samples were pipetted into antibody coated wells and incubated with assay diluents for 2 h at room temperature. The wells were then washed 5 times with a wash buffer, before being incubated with a conjugate solution for 2 h. This step was repeated for incubation with streptavidin-HRP for 1 h. TMB substrate solution with 100 μL was added into each well and allowed to stand for 30 min following the five-time washing process. Finally, 50 μL stop solution was added to stop enzyme reactions. Optical density was read using a microplate reader (BioTek Instruments Inc., VT, USA) at a 450 nm wavelength with 570 nm cytokine and 620 nm growth factor references. Protein concentrations were calculated from the standard curve.
The total protein of wound lysates was determined using a Bradford reagent assay, with bovine serum albumin reagents acting as a standard. The 10 μL of each sample and standard was added to 96 well plates and mixed with 150 μL of protein assay solution, followed by 10 min incubation. The absorbance of reaction products was measured at a 600 nm wavelength using a microplate reader. An equal amount of protein (20 μg/mL) was resolved on Sodium Dodecyl Sulfate (SDS) gels using SDS-polyacrylamide gel electrophoresis (PAGE) before being transferred to PDVF membranes. Nonspecific membrane sites were then blocked with 5% BSA, followed by primary antibody incubation (1:1000 dilution) of iNOS, COX-2, NF-κB, MMP-9, anti-HIF, VEGF, TGF-fβ, and β-actin at 4 °C overnight. Corresponding anti-rabbit, anti-goat, or anti-mouse secondary antibodies (1:5000 dilution) were conjugated with horseradish peroxidase for 1 h. Membranes were detected using a Super Signal West Femto Chemiluminescent Substrate (Thermo Scientific) and analysed using Image J software.
Statistically analysis
Experiment data is presented as mean ± Standard Error Mean (SEM) in this study. The differences between various means were calculated using IBM with SPSS 20.0 software (SPSS Inc., Chicago, USA). One-Way Analysis of Variance (ANOVA) was used to compare groups, and Tukey post-hoc tests were used for pairwise comparisons following normality and homogeneity tests. A p-value of 0.05 or less was considered to be statistically significant.
Discussion
Vicenin-2 is a type of flavonoid glycosides that is derived from various natural plants. There are several studies on the efficiency of flavonoid glycoside in a wide variety of pharmacological activities, including anti-inflammation and wound healing [
12,
28]. Pang et al. [
29] supported that the expression of biomarkers such as VEGF and TGF-β accelerated wound healing, which is attributed to the presence of flavonoids. Considering the therapeutic properties of VCN-2, in vivo tests were employed to observe the efficacy of VCN-2 hydrocolloid films on wound excision in hyperglycemic rats to reveal the underlying action mechanism of VCN-2 on wound healing.
Measuring blood glucose levels is one of the most effective ways to diagnose and monitor the development of diabetes. Hence, blood glucose levels were chosen as the main disease progression parameter in this study. 50 mg/kg STZ significantly elevated blood glucose levels in fasting rats (Table
3) and created diabetic-like syndromes. This is because STZ is a diabetogenic agent that damages the DNA of pancreatic β cells by inducing necrosis [
30]. This effectively reduces the synthesis of insulin in treated rats, which eventually gave rise to a diabetic phenotype (Table
3). This finding is supported by Monera [
31], who successfully induced diabetes in rats with low insulin levels and high glucose levels using STZ.
Topical administration of hydrocolloid films containing VCN-2 (12.5–50 μM) on diabetic wounds gradually increased host insulin levels (Table
3). One explanation for this is that the action of VCN-2, which was released from the hydrocolloid film dressing into the wound and then the bloodstream, can increase host insulin production and the insulin sensitivity of somatic cells. Previous studies have also reported similar observations, as VCN-2 isolated from
Artemisia capillaris was able to enhance insulin production and sensitivity [
8]. However, further investigation is required to confirm the precise mechanisms of how insulin is released from β cells after VCN-2 administration.
It was observed that rat blood glucose levels were lower during wound infliction compared to the initial level (Table
3). It is speculated that the presence of certain homeostasis control mechanisms, such as negative feedback loops, exists to balance deviating glucose levels during wound infliction [
32], which caused the observed behaviour. Nonetheless, rat glucose levels in this study were found to be higher than 11 mmol/L [
33], suggesting that the rats were still in a diabetic state during wound infliction.
A reduction in body weight (Table
3) was observed in rats after STZ administration. This could be attributed to polyuria, which is one of the characteristics exhibited by hyperglycemia, due to excess calories being lost in urine [
34]. According to Miao et al. [
35], polyphagia and polydipsia in rats are hallmarks of hyperglycemia. A positive correlation between changes in pellet and fluid intakes were observed in rats after STZ injection. Consistently, results showed an increased in food and water intake (Table
3) in diabetic rats compared to normal rats. Both characteristics are clinical manifestations of diabetics in rats.
Following the topical application of VCN-2-containing hydrocolloid film, the gross wound size of diabetic rats (Fig.
1) was found to be significantly reduced and was accompanied by dose-dependent wound contraction (Table
4). This suggests that VCN-2 is effective in promoting wound healing in hyperglycemic rats. Similar findings were reported in our previous studies, where topical application of
M. oleifera aqueous extract comprised of VCN-2 enhanced the healing of excision wounds in diabetic rats through improvements in wound contraction and reductions in wound size [
14,
21].
Acceleration of complete wound closure was observed following the topical administration of VCN-2 film on wounded sites (Fig.
2(a)). Re-epithelialization of the skin was initiated upon injury. Subsequently, growth factors were released by cells to induce proliferation and migration of keratinocytes, macrophages, and fibroblast cells into the wound space [
36,
37]. Interestingly, Fig.
2(b) displays notable epithelialization in diabetic wounds after VCN-2 film treatments. Granulation tissue consists of various cells, and vascular capillaries and loose connective tissues in its stroma are usually produced to fill up the injured space [
38,
39]. Similar to the epithelialization process, Fig.
2(c) also suggests accelerated wound healing through the formation of granulation tissues on diabetic skin tissue.
Yang et al. [
40] reported that fibroblast and blood vessel proliferations were compromised in diabetic wounds, resulting in impaired wound healing. The results in Fig.
3(a) demonstrate that VCN-2 treatments enhanced wound healing for rats in hyperglycemia conditions through fibroblast proliferation and angiogenesis. Meanwhile, higher wound recovery rates supported by fibroblast proliferation are shown in Fig.
3(b). Our results showed that fibroblast proliferation is one of the earliest events in the development of granulation tissue [
41,
42].
New blood capillary formation in wound sites is crucial to the delivery of oxygen, cytokines, and essential nutritients to cells as well as the removal of waste products from proliferating cells [
43]. Figure
3(c) shows a marked increase in angiogenesis in diabetic wounds treated with VCN-2 film. These findings are in accordance with Kant et al. [
44], who observed that curcumin enhanced wound healing by stimulating fibroblast proliferation and promoting new blood vessel formation in diabetic rats.
Diabetic wounds showed sustained production of inflammatory cells in wound sites, which limited the effectiveness of wound closure [
45]. Our data demonstrated reduction of inflammatory cells in diabetic wound sites treated with VCN-2 film (Fig.
3(d). This is consistent with Moura et al. [
46], who reported that the application of neurotensin loaded collagen enhanced the diabetic wound healing of mice by reducing the creation of inflammatory cells in the wound site.
Nitrogen Oxide (NO) was detected in the wounds of normal rats. However, NO levels were significantly higher in the wounds of diabetic rats. An optimum release of NO can enhance wound healing, but the overproduction of NO over an extended period will lead to the formation of sustained chronic wounds. NO is not only a mediator involved in the inflammation of cells (macrophages, fibroblasts, and keratinocytes), but it also plays an important role in intercellular communication to modulate cell proliferation, collagen development, and wound restoration [
47]. In this study, a concentration dependent decrease of NO in diabetic wound lysates after treatment with VCN-2 (Fig.
4) was observed. Our results are similar to Badr et al. [
48], who successfully promoted diabetic excisional wound healing in mice by suppressing NO synthesis with bee venom treatments.
Previous studies have reported that the production of pro-inflammatory cytokines such as IL-1β, IL-6, and TNF-α as well as inflammatory cells were elevated in chronic wounds [
48‐
50], and that VEGF and TGF-β secretion from injury cells, such as macrophages and fibroblasts, were reduced in diabetic wounds [
3,
51]. In this study, VCN-2 film treatment alleviated these conditions in diabetic wounds, as the production of pro-inflammatory cytokines such as IL-1β, IL-6, and TNF-α were significantly downregulated in a dose dependent manner (Fig.
5(a)). Upregulation of growth factors such as VEGF and TGF-1β (Fig.
5(b)) were also observed in the skin wound lysate of rats in hyperglycemia conditions that were treated with VCN-2 film.
In this study, impared wound healing in diabetic rats is correlated and associated with the dysregulation of pro-inflammatory mediators and growth factor gene expressions (Fig.
6(a)). Adequate expression of proinflammatory mediators is important in producing cytokines to recruit neutrophils and removing bacteria and other contaminations from the wound site [
36]. However, the prolonged expression of these cytokines is undesired as it can lead to the development of chronic wounds. Following treatment with VCN-2 films, pro-inflammatory mediators such as iNOS and COX-2 were reduced together with the gene regulator NF-κB (Fig.
6(b)), further proving VCN-2’s effectiveness in treating diabetic wounds. These results are supported by a previous study where the application of celecoxib on pressure ulcers diminished the expression of iNOS and COX-2 and enhanced wound healing by preventing prolonged inflammation [
52]. In addition, similar results were reported by Dasu and Jialal, [
53], who found that NF-κB transcription factor activity was reduced in diabetic toll-like receptor-4 knockout mice, which promoted wound repair. Our results suggest that the inflammation phase of delayed wound healing may be mediated by the anti-inflammatory effects exhibited by VCN-2.
VCN-2 film application resulted in a downregulation of anti-HIF1α expression in all wounds as shown in Fig.
6(c). As the upredulation of HIF1α may accelerate diabetic wound restoration, our results suggest the remedial effect of VCN-2 in wound healing. HIF1α is a transcription factor that is vital to improving angiogenesis and cell mortality during wound healing [
54,
55]. Yang et al. [
40] and Liu et al. [
56] are consistent with our findings. Both studies reported that thioredoxin administration was able to overcome hyperglycemia-induced HIF-1α reduction and upregulated HIF-1α levels, which eventually enhanced wound healing by increasing blood supply to the wound site.
The role of Metalloproteinase (MMP) in wound healing is to degrade and remove damaged Extracellular Matrixes (ECM) to regulate a balanced composition of ECM that supports wound restoration [
57]. Several studies reported that the overexpression of MMP-9 was observed in delayed wound healing [
58‐
60]. Our results showed a decline in gelatinases MMP-9 levels following VCN-2 treatments on diabetic skins (Fig.
6(d)). Another study found that the inhibition of MMP-9 in diabetic mice promoted the re-epithelialization of excision wounds during the proliferation phase, which is similair to our findings [
61].
Figure
6(e) indicatess that the activation of VEGF markers was facilitated by the expression of HIF-1α following VCN-2 treatment. VEGF is an angiogenetic factors (HIF-1α) that is regulated to promote angiogenesis and revascularization [
62]. In this study, VCN-2 accelerated diabetic wound healing through the VEGF signalling pathways. Similarly, Zhou et al. [
63] revealed that the angiogenesis of diabetic rat skin ulcers was accelerated by curcumol via VEGF pathways.
Figure
6(e) demonstrates an increase in TGF-β protein expression in a dose-dependent manner after VCN-2 film application. TGF-β plays an important role in wound healing by directing inflammatory cells into the wound site during the inflammation phase [
64]; accelerating ECM deposition and granulation tissue formation during the proliferation phase [
65]; and acceerating the expedition of collagen type 1 to replace collagen type 3 during the remodeling phase [
66]. Our immunoblotting results highlighted the effectiveness of VCN-2 in enhancing diabetic wound healing, most liklely through TGF-β signalling pathways. This finding is supported by Mori et al. [
67], who demonstrated that the topical application of lavender oil can enhance wound healing by promoting granulation tissue formation via TGF-β signalling pathways.