EVALUATION OF THE HEALING OF WOUNDS DRESSED WITH ZINC METAL-ORGANIC FRAMEWORKS (ZN-MOFS) IN DOGS: AN EXPERIMENTAL STUDY

This study aimed to evaluate the healing of wounds dressed with Zn-MoF in dogs. The study was conducted on fifteen clinically healthy mongrel dogs. Each dog has bilateral cutaneous excisional wounds (2 × 2 cm 2 ). Right-side wounds were dressed with Zn-MOF dressing (treated wounds) under the effect of 1 mg/kg of xylazine HCL 2% and 10 mg/kg of ketamine HCL 5% , administered in one syringe intramuscularly (IM), while left-side wounds were dressed with normal saline (control group). Wounds were undergone to histopathological evaluation 7, 15-, and 21-days post-wound induction (5 dogs each interval). Zn-MOF positively enhanced the re-epithelization of the wound area promoting the epidermal hyperplasia resulting in reduction of the wound size and epithelial gap that was completely closed and restored on day 21 post-wound induction. The control wounds were at a slower healing rate with time leaving epithelial gaps and did not completely close day 21 post-wound induction. Zn-MOF treated wounds’ dermis was pervaded with the inflammatory cells on day 7 post-wound induction that gradually reduced by time and replaced by fibroblasts 14-and 21-days post-wound induction. The dermis of control wounds was severely infiltrated with a larger number of inflammatory cells and excessive hemorrhage throughout the study. Zn-MOF treated wounds had an augment in the number and size of newly formed blood vessels in comparison to the control ones, reaching their highest point on day 14-and declining on day 21 post-wound induction. Collagen deposition increased obviously 21 days post-wounding in Zn-MOF treated wounds. Zn-MOF accelerated and enhanced the wound healing process and abundant granulation tissue formation in dogs


INTRODUCTION
Wound healing is a natural physiological process that occurs as a response to any injury to the tissue. Wounds have variable causes involving injuries, burns, and pathological conditions such as diabetes or vascular diseases. Wounds are classified into acute or chronic wounds according to their underlying causes and consequences (Karimi et al., 2017).
Successful wound management depends on understanding the healing process, as well as the properties of the various dressing materials to maximize the treatment efficiency (Weller and Sussman, 2006).
Zinc is an essential trace element and a vital micronutrient for the function of more than 10% of metalloenzymes/proteins required for cell membrane repair, cell proliferation, growth, and immune system function. Therefore, zinc deficiency can cause impairment in immune function and wound healing (Lin et al., 2017;Soliman, 2005).
Metal organic frameworks (MOFs) are among nanotechnology's most developing strategies that have been published in the last ten years (Hinks et al., 2010). MOFs are a group of crystalline, hybrid, coordinating materials made up of inorganic clusters (metal ions) connected by organic polydentate ligands/linkers (Yu et al., 2018). Currently, MOFs are getting wider attention for wound healing due to their increased drug loading capacity, controlled release of the agents/products of wound healing, lesser toxicity profile, natural angiogenic and antibacterial features in comparison to other traditional nanomaterials (Xiao et al., 2017;Chen et al., 2019;Zhang S. et al., 2020;Zhang M. et al., 2020). Zinc can be used as a central block of MOFs, which helps in the healing of wounds through its enhancement effect on proliferation of cells, collagen build-up and angiogenesis (Hinks et al., 2010;Rubin et al., 2018;Hou and Tang, 2019;Kargozar et al., 2019;Yao et al., 2020).
Recent studies demonstrated the potential of zn-based MOFs as practical drug delivery system, nontoxic, and biocompatible therapeutic agents in the biological and medical applications (Kitagawa et al., 2004;Rezwan et al., 2006;Ye et al., 2015). However, current literature lacks reports regarding use of Zn-MOF dressing for wound treatment in dogs. Therefore, this study aimed to evaluate the healing of cutaneous excisional wounds dressed with Zn-MOF dressing in dogs.

Ethical approval
The National Ethical Committee of the Faculty of Veterinary Medicine, Assiut University, Assiut, Egypt, has approved all the procedures in this study in accordance with the Egyptian bylaws and OIE animal welfare standards for animal care and use in research and education.

Zinc-MOF(Metal-organic frameworks) preparation
An appropriate amount of methylimidazole (2-MIM) was dissolved in 40 ml DI water and marked as a solution (A), another 2 mmol of Zn nitrate was added to 40 ml DI water and named as a solution (B). Solution (B) was then poured into solution (A) and stirred for a few seconds. 5 cm x 5 cm carbon cloth was immersed immediately into the mixture and aged for 4 hours. The carbon cloth was then taken out and washed with (deionized water) then dry it in the drying oven (DHG-9075A) at 60 o C overnight ( Figure 1). Field-emission scanning electron microscopy (SUPRA 40 ZEISS, Germany) in the electron microscopy unit, Assiut University, was employed to examine the morphology, the distribution of Zn-MOF particles on the carbon cloth fibers, and then investigate the elemental distribution using Energy Dispersive Spectroscopy (EDX) (Hoop et al., 2017).

Wound creation
Dogs were deprived of feed for 12 hours, but not for water. Wounds were conducted under the effect of 1 mg/kg of xylazine HCL 2% (Xyla-Ject, ADWIA Co., SAE, Egypt) and 10 mg/kg of ketamine HCL 5% (Ketamine, Sigma-tec Pharmaceutical Industries, SAE, Egypt), administered in one syringe intramuscularly (IM). Dogs were positioned on the sternum, the bilateral areas of the midline were prepared for aseptic surgery; clipped, shaved, disinfected several times with betadine (BETADINE, El-Nile Co. for Pharmaceutical and Chemical Industries, Egypt), and draped except for the surgical site of wound creation. Using a sterile template, 2 × 2 cm 2 , full cutaneous excisional wounds were created bilaterally using a scalpel and scissors, 5 cm from the midline in the thorax region (Sardari et al., 2006). (Figure 2A). Hemostasis was achieved by back pressure with sterile tampon of gauze. Wounds were digitally photographed with a sterile ruler included in the photos.
Right-side wounds were dressed with a sterile Zn-MOF mesh, while left-side wounds were dressed with normal saline. Zn-MOF mesh was secured in situ by four interrupted stitches ( Figure 2B). All wounds were covered by sterile cotton pad dressing, gauze, and elastic bandage. Dogs wore Elizabeth collar to keep them away from wounds. Wound dressings were changed weekly. Dogs were administered pain medication, Carprofen (Rimadyl, 50 mg/ml, Zoetis), 4 mg/kg, intravenous (IV), daily for up to three successive days post-wound induction.

Histopathological evaluation Macroscopical evaluation
At each interval of wound evaluation (7-, 14-, and 21 days post-wound induction), wounds were grossly examined for the presence of abnormal signs e.g.: exudates, infection, or exuberant granulation tissues.

Planimetry of wounds
Each wound was photographed on days zero, one week, two weeks, and three weeks post-wound inductions. A standardized ruler was involved in each photograph to recognize the digital calibration of the photographs. pictures were taken after zooming on the shape of wounds. wound size's percentage was estimated by the ImageJ software analysis as described before by Sardari et al.

Microscopical evaluation
At the pre-determined interval of wound evaluation (7-, 14-, and 21 days postwound induction) and under the effect of the same prescribed anesthetic protocol, tissue specimens were taken from the wounds for histopathological evaluation. Skin samples were collected from each dog and were fixed in 10% neutral buffered formalin. The formalin-fixed samples were proceeded in ascending grades of ethanol for dehydration, were cleared in Xylol, and then embedded in paraffin wax for sectioning. Paraffin sections were cut at 4 μm in thickness and were stained with the following histological stains: 1. Ordinary Hematoxylin and Eosin stain for general histological examination (Fischer et al., 2008).

Mc. Picrosirius red stain for collagen identification (Bhutda et al., 2017).
The paraffin-stained sections were examined under a light microscope (Olympus, USA) by a histopathologist, who was blinded to the groups' arrangement and photos were taken by an Olympus DP72 camera adapted into the microscope. Newly formed blood vessels were counted in 5 images/wound sample Wounds were left to recuperate following the harvesting of specimens for histopathological examination.

Statistical analysis
The values were introduced as Mean + standard deviation. The data were examined by one-way ANOVA using IBM SPSS statistics 20 (SPSS Inc., Chicago, IL, USA).

Clinical evaluation
Throughout the experiment the animals were alert, exhibiting normal activity, with normal access to feed and water. There were no recorded deaths.

Morphology and elemental analysis of Zn-MOF wound dressing
From the SEM images, 2D nano-wall configuration with thickness around 150 nm in an axis direction is confirmed as shown in Figure (

Histopathological evaluation
Gross evaluation of wounds On day 7 post-wound induction, the wound started to cover with granulation tissue in both control and Zn-MOF treated wounds and the percentage of wound size reduction was non significantly different in both groups (P < 0.05) (Figure 7). It was also noticed presence of large amount of pus and smelly odor in the control wounds, while the treated ones showed less amount of pus. On day 14 post-wound induction, control wounds showed the presence of hyper-granulation tissue and a small amount of pus, while the Zn-MOF treated ones showed signs of healing, a highly significant decrease in the wound size (P < 0.0001) compared to control ones ( Figure 7) with less amount of granulation tissue and there was no pus or odor. On day 21 post-wound-induction, there were partial healing signs of control wounds, and the wounds were still covered with an unhealed scar with a lack of hair growth, while the treated wounds were healed and covered, the wound size was significantly decreased compared to control ones (P < 0.05) (Figure 7). Zn-MOF treated wounds showed new hair growth with no pus (Figure 8).

Microscopic examination:
On day 7 following the wound induction, there was no notable difference in the rate of wound healing and epithelization of the epidermis (20 % of wound size). Reepithelization started at the wound edges but left a big epithelial gap in both control wounds and Zn-MOF treated wounds (Figure 9). Deposition of collagen fibers was more prominent in Zn-MOF treated wounds than in control ones ( Figure 10).
The dermal layer in both groups was infiltrated with inflammatory cells (neutrophils and macrophages) and hemorrhages but Zn-MOF-treated wounds were characterized by a highly notable rise in the hyperemic new blood vessels' number (P < 0.0001) (Figure 11 A, B. D, E), (Figure 12). Destroyed hair follicles appeared in the dermis of control wounds but were normal in Zn-MOF treated ones (Figure 11 C, F).    The healing process and re-epithelization of control wounds after 14 days were incomplete and reached 60 % of the wound size left also a large epithelial gap with deposition of a small amount of collagenous fiber (Figures 13 and 14 A-C). On the other side, the healing process of Zn-MOF treated wounds after 14 days was much better. The epithelization reached 80 % of the wound size and left a small epithelial gap and epidermal hyperplasia extended to the center of the wound (Figure 13 D-F). The collagen deposition was more pronounced and extended between the proliferating epidermis ( Figure 14 D-F). The dermal layer was infiltrated with a great number of acute inflammatory cells (macrophages and neutrophils or PMNL), extravasated red blood cells and a few newly formed blood capillaries. Destroyed hair follicles surrounded by inflammatory cells were seen (Figure 15 A, B). The dermal layer was infiltrated with a few acute inflammatory cells (neutrophils and macrophages), a highly significant increased number of new formed blood vessels (P < 0.0001) ( Figure 12) and most of the hair follicles appeared normal in structure (Figure 15 C, D).   On day 21 post-wound induction the healing process of control wounds was not completed, and the wounds were not totally closed with the presence of a small epithelial gap between the epidermal edges that was covered with a scar formed of destroyed tissue and inflammatory cells (Figure 16 A-C). On the contrary, the healing of Zn-MOF treated wounds on day 21 was totally completed and the epithelization and tissue remodeling reached 100 % of the wound size. The wound was completely closed and healed with no epithelial gap and the scar was completely removed (Figure 16 D-F). The collagen deposition of mature type on day 21 post-wound induction was more obvious in Zn-MOF treated wounds than in control ones ( Figure 17). The dermal layer of the control wounds was still infiltrated with acute inflammatory cells, extravasated red blood cells and hyperemic new blood vessels (Figure 18  A, B). While the dermis of Zn-MOF treated ones was characterized by the dramatic significant decrease of newly formed blood vessels (P < 0.001) ( Figure  12) and acute inflammatory cells and with the presence of newly formed hair follicles (Figure 18 C, D).  Newly formed blood vessels were more abundant in control wounds than Zn-MOF treated wounds (blue arrow).
Any impairment during the sequence of the healing phases can lead to chronic wounds, with potential impacts on the quality of life (Suarato et al., 2018). Wound persistence leads to the prolonged hospitalization time, as well as morbidity and even mortality (Ward et al., 2019). Chronic wounds are mainly related to treatment and management strategies limiting the wound healing (Borena et al., 2015). Therefore, several studies are conducted to achieve more effective wound treatments and reduce costs (Schiavon et al., 2016).
Zinc is vital for metabolism, immunity, and healing process (Roohani et al., 2013). Moreover, zinc-dependent proteins are important for DNA repair and apoptosis (Zheng et al., 2015;Cho et al., 2016), metabolic processing (Cronin and Walton, 2003), extracellular matrix (ECM) regulation (Tomlinson et al., 2008) and antioxidant effect (Pawlak et al., 2012). Studies back to 1970 and earlier have demonstrated the importance of zinc concentration in healing of thermal injuries (Henzel et al., 1970). Zinc is highly important in skin (Rosten et al., 2002). The skin content of zinc is a relatively high (about 5% of body content), mainly, present within the epidermis (50-70 µg/g dry weight) (Gupta et al., 2014). Therefore, mild zinc deficiency can lead to impairment in wound healing (Lansdown et al., 2007).
MOFs are characterized by highly porous surface area, tunable consistent pore sizes, thermal solidity, great internal capacities, no adverse effects, i.e., biocompatible, and easiness in manufacture. Therefore, they have been widely researched for application in biomedicine as drug carriers (Yu et al., 2017(Yu et al., & 2018. On the other hand, MOFs are getting wider application because of their rapid and economical wound healing (Yu et al., 2018;Ren et al., 2019;Zhang S. et al., 2020). The antibacterial and anti-inflammatory effects of zinc and the physiochemical features of MOFs, make zn-based MOFs effective to overcome difficulties in wound healing. This was similar to findings reported by Chen et al. (2022). In another study, Zn-based metal organic framework (MOF) explored antimicrobial activity against staphylococcus aureus (Restrepo et al., 2017). The antibiotics can effectively reduce the chance of bacterial infection; however, their effectiveness getting threaten yearly due to drugresistant bacteria (Levin-Reisman et al., 2017). Zn has good biocompatibility and is easy metabolized without cumulative effect, therefore, zn-based MOF can be used as an ideal antibacterial material (Zhang et al., 2013;Zhu et al., 2019).
Our findings revealed that Zn-MOF positively enhanced the reepithelization of the wound area promoting the epidermal hyperplasia that started from the wound edges toward the center leading to a reduce in the wound size and the epithelial gap that was completely closed and healed on day 21 post-wound induction. On the other side, the healing process of control wounds was at a slower rate with time leaving epithelial gaps and the wound did not entirely close on the third weeks (day 21) post-wound induction.
Zn-MOF treated wounds' dermis was pervaded with the inflammatory cells (macrophages, neutrophils,) on the first week post-wound induction which are essential for removing the dead cells, microorganisms and clean up the wound site (Ackermann, 2017;Rodrigues et al., 2019). By time, there were a gradual reduction in the inflammatory cells' numbers on the second and third weeks following the induction of wounds and replaced by fibroblasts for collagen formation. On the other side, the dermis of control wounds was severely infiltrated with a larger number of inflammatory cells and excessive hemorrhage that continued at a high level throughout the wound experiment to day 21 postwound induction.
The new blood vessels formed in the site of wound are important during the process of healing, as they supply the wound area with, nutrients, oxygen, and immune cells. additionally, they clean up toxic waste products (Logsdon et al., 2014;Honnegowda et al., 2015). Zn-MOF treated wounds, had an augment in the number and size of newly formed blood vessels that facilitated the healing process in comparison to the control ones, reaching the highest point on the second week (day 14) and afterward declining on the third week (day 21) following the induction of wound with completion of the healing process. Both Zn-MOF treated and control wounds, had less collagen during the very early stage of the process of healing, on day 7 post-wound induction due to the wounds being lately inflamed and at the start of the fibroblast proliferation. Afterward, collagen deposition quantity rose obviously on the third week (day 21) after the surgical wound induction in Zn-MOF treated wounds because of maturation of connective tissue and remodeling.

CONCLUSION
Zn-MOF accelerated and enhanced the wound healing process and abundant granulation tissue formation in dogs.