Evaluation of Keratin/Bacterial Cellulose Based Scaffolds as Potential Burned Wound Dressing

: The study presents the preparation and characterization of new scaffolds based on bacterial cellulose and keratin hydrogel which were seeded with adipose stem cells. The bacterial cellulose was obtained by developing an Acetobacter xylinum culture and was visualized using SEM (scanning electron microscopy) and elementally determined through EDAX (dispersive X-ray analysis) tests. Keratin species ( β –keratose and γ -keratose) was extracted by hydrolytic degradation from non-dyed human hair. SEM, EDAX and conductometric titration tests were performed for physical– chemical and morphological evaluation. Cytocompatibility tests performed in vitro conﬁrmed the material non-toxic effect on cells. The scaffolds, with and without stem cells, were grafted on the burned wounds on the rabbit’s dorsal region and the grafts were monitored for 21 days after the application on the wounds. The clinical monitoring of the grafts and the histopathological examination demonstrated the regenerative potential of the bacterial cellulose–keratin scaffolds, under the test conditions.


Introduction
Extensive and deep burn wounds represent a severe pathology, altering the general balance of the patient's status. Complex general and local therapy is required for the re-equilibration of the patients and recovering the protective barrier of the organism. Deep burns occupying over 15-20% from the body surface generate a multiple organ failure with progression to post-combustion shock. The time between the accident and the hospital admission of the patient is critical for the future evolution. Any delay in providing the necessary care favors local and general complications and can lead to death [1].
Burned skin opens a huge gate for important loss of fluids, proteins, enzymes, electrolytes, altering the cardio-vascular, digestive, respiratory, and renal functions [2]. Increased blood viscosity generates a higher risk to thromboembolism and wound's bacterial invasion determines multiple organs failure and septic shock. Immediately after the injury, it is crucial to treat the pain, to restore the volume and hemodynamic balance, to correct the cellular hypoxia and prevent the main organs failure. It is equally important to excise the post burn necrosis and the challenge comes from the lack of donor zones sites, the high risk of wound deepening, and bacterial aggression [3,4]. Wound healing is a dynamic process that involves a complex series of events, lasting from the moment of injury to healing and includes increased activity of inflammatory, vascular, connective tissue, and epithelial cells. Wounds generally produce exudates that consist of fluids, cells or other substances that are slowly exuded or discharged from cells or blood vessels [5].
An important part of the clinical success is given by using a suitable biomaterial, with an appropriate mechanical resistance, which cover the wounds and prevent the fluid loss, the bacterial contamination, and stimulate the healing [6]. To cover and protect the burned wounds, usually sterile bandages are used. Recently, new possibilities were discovered such as artificial membranes for temporary wound protection. Another therapeutic solution is the use of autologous skin grafts, harvested from the patient's healthy skin donor zones. This last procedure has the main disadvantage that represents a new aggression for the skin areas and opens new gates for the bacterial invasion [7].
A useful biomaterial for burned wounds needs to respect the biocompatibility, to be able to stimulate the healing in a humid environment, to assure an efficiently antibacterial action without disturbing the biological cellular balance. Technically, a biomaterial offers the chance of biological reconstruction. It may be a scaffold, with a higher mechanical resistance, which functions like a support for skin cells. The cells will initiate the development of a keratinocytes film, which can be used to reconstruct the post burn defect [8,9].
Various hydrogels have been tested as wound dressings because of their similarity with extracellular matrices (ECM) [36]. The hydrogels are cell friendly environment and they represent an appropriate medium for proliferation, migration and differentiation of the cells. In order to improve the physical and mechanical properties of the polymeric hydrogels, while stimulating the healing process of the wounds, the hydrogels chemistry and morphology has been modified by using blends of natural and synthetic polymers, cross linkers, or drugs for preparing bioactive scaffolds and hydrogels [37][38][39].
Keratin-containing compounds have been tested, as a local therapeutic support for burned wounds, since ancient times. The choice of keratin as the second component of biomaterial is based on information from traditional Chinese medicine, which through millennial experience, has verified the therapeutic potential of using keratin as a remedy for burns. This, according to tradition, involves the removal of the hair from the patient, which, then, by burning, becomes an aseptic, opaque mass, of a dark color, and by grinding, a powder is obtained, based on keratin. The powder was deposited on the wound, the procedure being an archaic wound therapy, verified for about 2300 years in China [40]. Human hair-derived keratin protein has been recognized as biomaterial with high potential due to its excellent bioactivity and biocompatibility and keratin-based hydrogels accelerated re-epithelization and wound healing process in a full-thickness tissue [41,42]. Recently, data about a new biomaterial obtained from bacterial cellulose (BC) and keratin, efficient for stimulating the wound repair and re-epithelialization were published [43,44].
In the surgical practice of burned wounds of large surface and depth, there is a severe deficiency of grafted skin. The paper offers an alternative to solve the issue. The aim of the study was to obtain a biomaterial from BC and keratin hydrogel, and to evaluate the effect of the cells inclusion (adipose stem cells) on the biological performances. The keratin component of the biomaterial directs the tissue development of stem cells to a grafting skin. Bacterial cellulose is the second component of the biomaterial being in the form of nanometric bundles and it offers the advantage of lack of chemical contaminants; as well, it reinforces scaffold for cell growth. CB allows obtaining a mechanically resistant biomaterial for wound grafting surgery. The result was a bio artificial material, later grafted on a burned wound. The grafted wound (in an in vivo study on rabbit), was monitored daily, both clinically and anatomic pathologically, and the biocompatibility was evaluated.
For surgical proceeding the anesthesia some veterinary drugs were used: lidocaine infiltrations were performed for local anesthesia; for general anesthesia were used combinations of ketamine (35 mg/body weight), medetomidine hydrochloride (0.1 mg/body weight), butorphanol (0.5 mg/body weight).

Bacterial Cellulose (BC) Production
Pure bacterial culture of Komagataeibacter xylinum (sin. Acetobacter xylinum) where used for BC synthesis. Two special culture mediums were prepared: one in liquid form, for BC synthesis; another, in a solid form, for the bacterial species' conservation. The tested mediums were: YPM (yeast peptone-mannitol extract): 5 g yeast extract; 3 g peptone; 25 g mannitol; 1000 mL. distilled water; 12 g Agar is added to solidify the nutritious media.
GOM, nutritious media for Gluconobacter oxydans: 100 g glucose; 10 g yeast extract; 20 g CaCO 3 , 1000 mL distilled water; 15 g Agar is added to solidify the nutritious media.
Incorporation in liquid medium and the method of depletion of the handle on the surface of solid medium have been used as bacterial seeding techniques. After the liquid medium seeding with 1 mL suspension and the rotation of the culture Petri dishes for uniform inoculum distribution, they were placed in an incubator with constant temperature of 28 • C for 21 days. These are the conditions necessary to obtain a BC layer with a desired thickness. After testing the two culture mediums, the best results regarding the growth speed and the thickness of the BC layer were obtained on YPM. On this consideration, YPM was used for BC preparation in this study.

Obtaining the Keratin Hydrogel
The keratin hydrogel was prepared according to the Siller-Jackson et al. [45], with slightly modifications. Carefully selected undyed hair (origin from men, around 30 years old, provided by a hairdressing unit) was harvested, by cutting into segments of 2-5 cm length. The hair was grounded using a ball mill (Retsch PM 100, Retsch GmbH, Haan, Germany) at 100 rpm, for 30 min and transformed in pieces smaller than 1 mm; then, the samples were cleaned in a mixture CHCl 3 -CH 3 OH (2:1; v/v) for 24 h at boiling point, using a Soxhlet extraction. The hair segments were then dried at 40 • C, for 24 h. Then, the hair was placed in distilled water, inside a stainless-steel sealed capsule, at a solid/liquid ratio = 2:35 (w/v). The capsule was maintained 2 h at 150 • C. After thermal treatment and cooling, the compound was centrifuged 10 min. at 10.000 rot/min. Two phases were separated: one solid, insoluble in water, considered a β-keratose, and one soluble in water, γ-keratose [46,47].
To prepare the β-keratose hydrogel, 2 g of solid phase were oxidized for 3 h, by boiling in a 3% H 2 O 2 solution, with a liquor ratio of 1:11 (w/v). The solid compound obtained was cleaned in ethanol 96% and drained, by pressing with a filtering paper. The resulted solid was treated with 0.7% NaOH solution (in 70% ethanol), at a temperature of 70 • C. To keep the protein in a swollen state along the treatment, the pH was adjusted to 8. The compound was boiled for 3 h and then, maintained under stirring at 20 • C for 5 h. The product was filtered and washed with 100 mL distilled water; the purification was repeated 5 times.

Obtaining of Keratose-Bacterial Cellulose Scaffold
The bacterial cellulose membrane (φ = 6 cm) was immersed in a solution of keratose (25 mL, 3%) for 24 h and a membrane with a gelatinous consistency was obtained by diffusion of the keratose, which was lyophilized and sterilized. For sterilization process, the materials were first exposed to UV radiation, one hour (30 min each part) and then were immersed in a sterile alcohol of 70%, for 30 min, cleaned with sterile distilled water (30 min) and immersed in HBSS (buffer solution) for 30 min. This procedure was repeated 3 times.
The last step consists of immersing the compound in culture media DMEM (4500 mg/L glucose, L-glutamine and liquid sodium bicarbonate, filtered under sterile conditions), three hours before the application in vivo.

Scaffolds Characterization
For the analysis of the composition and morphology, a Bruker QUANTA 200-3D DUAL BEAM EDS electron microscope was used with two systems (SEM and focused ion beam). By sending an electron beam on samples, images were obtained with different magnification degrees. EDAX dispersive X-ray analysis (EDX-VEGA II LSH//TESCAN instrument) was used to identify surface characteristics and high-resolution chemical analysis.

Cytocompatibility Tests and Cells Seeding
For the cytocompatibility assessment, the direct contact method was used. Adipose stem cells isolated from rabbit have been obtained using the protocol described by Bunnell et al. [48]. The cells were cultured in Dulbecco's modified eagle medium (DMEM) with 10% fetal bovine serum (FBS) and 1% penicillin-neomycin-streptomycin (P/N/S), in a humidified atmosphere of 5% CO 2 at 37 • C. When the cells reached sub-confluence, they were trypsinized with 0.25% trypsin containing 1 mM ethylenediamine tetra acetic acid (EDTA). The stem cells (5000 cells/well) were seeded on the culture media, using DMEM + 10%CFS (calf fetal serum) + 1% P/S/N (mixture of penicillin, streptomycin, neomycin), then incubated for 24 h (5% CO 2 , 37 • C). After the procedure, the culture medium was changed and the scaffolds were distributed in direct contact with the cells.
The MTT test was performed after 24, 48, and 72 h of direct contact between scaffolds and cells. For test, the culture medium was replaced with MTT solution 5% and incubated at 37 • C, 3 h. The viable cells reduce tetrazolium bromide-MTT in a colored compound, called formazan. The formazan was solubilized using isopropyl alcohol. The absorbance of formazan solution was spectrophometrically measured at λ = 570 nm using a plate reader (Tecan SunRise Plate Reader, Tecan Ltd., Männedorf, Switzerland). The spectrophotometrically reading results from the experimental wells were compared with the control wells (culture cells incubated with a same volume of PBS, with no materials included) and the cells viability was calculated with the following equation: where Abs sample is the absorbance from the wells with scaffolds and Abs control is the absorbance in wells without scaffold.
In the aim to obtain cell seeded scaffold, a cell suspension (5000 cells, DMEM + 10% CFS medium) was incubated with scaffold (Φ = 6 cm) for 48 h and used as obtained.

In Vivo Tests
For in vivo tests, 2 groups of rabbits (4 animal in each group) with a weight of 1-3.5 kg and an average age of 8 months, both sexes, were used. Rabbits of the common domestic breed were used. They were accommodated in individual cages from USAMV Biobase, Iasi; before the experiment, the animals had a period of accommodation of 7 days, while they were fed with vegetable food: cabbage, hay and carrots. The cycle light/darkness was respected. The tests on animals received the approval USAMV (University of Agricultural Science and Veterinary Medicine) Iasi, no 89/31st of January 2019 from the Ethics Commission concerning in vivo tests on animals.
Before experiment, a general anesthesia was performed, using a combination of ketamine (35 mg/body weight), medetomidine hydrochloride (0.1 mg/body weight) and butorphanol (0.5 mg/body weight). The local preparation included the hair cutting on a skin area of 3 × 3 cm, and a local asepsis using 100 mg/mL Povidone-iodine. To reduce the local post operatory pain and inflammation, xylene infiltrations in four points, for local anesthesia were performed.
For each specimen, two burned wounds were performed: in the thoracic region, near the costal rim. L-shaped metallic device (3 × 3 cm) was used to produce the burned wounds. Heated to incandescent, the device was applied on the marked skin and maintained in direct contact for 4 s, without pressure. Then, one wound was grafted using a scaffold of BC and keratin hydrogel; another wound was covered with a scaffold containing BC, β-keratose hydrogel and stem cells from rabbit adipose tissue. The scaffolds were sutured in four points, for a better adhesion.
After the grafting procedure, the animals were monitored 3 weeks. Postoperatively, the animals were treated with antibiotic (enrofloxacin 0.5 mg/kg) for 3 days. The samples for the histological examination were collected in the days 7, 14, and 21. The clinical evaluation consisted in a general exam of the habit, skin and mucosa aspect before anesthesia, repeated postoperatively. The clinical daily monitoring was performed along the whole duration of the experiment. No change in the physiology of the 8 animals was noted.

Histopathological Analysis
Samples collection, from the tissue areas of interest of the lots marked with C (control lot), K + cel (keratin and bacterial cellulose hydrogel) and K + cel + S (keratin and bacterial cellulose hydrogel seeded with stem cells) was performed in the days 7, 14, and 21 from the beginning of the experiment. Small tissue biopsies (6 mm, KRUUSE Biopsy punch sterile) were collected from the wounds' borders and fixed in 10% buffered formaldehyde for 48 h. Then, the samples were processed by the method of inclusion in paraffin (processor Leica TP 1020-Germany) and divided in pieces with 5 µm thickness. The pieces were colored trichomic Masson and examined with a Leica DM 1000 photonic microscope. A Leica 5 mpx full HD digital histological camera was used for image capturing, alongside LAS software, version 2016.

BC and Keratose Preparation
The synthesis of cellulose by Komagataeibacter xylinum is carried out by polymerization and crystallization, both enzymatic catalysts [47,49]. The authors reported that a Komagataeibacter xylinum cell (Gram-negative, aerobic, and cylindrical bacterium) produces BC, as a result of acetic acid fermentation, developing a polymerization rate of 200,000 glucose molecules/second. Nanometric size of cellulose filaments, good mechanical strength and chemical purity determine the selection of bacterial cellulose that can be constituted from the biomaterial point of view.
Bacteria synthesize cellulose because it retains a high amount of moisture, which prevents dehydration of the bacterium, ensuring its vitality for a long period of time. Further, cellulose captures the carbon dioxide molecules resulting from cellulose synthesis, ensuring the bacteria float on the surface of the water, thus having easy access to oxygen in the air; being aerobic, this means good nutrition at the interface with atmospheric air. Due to its opaque nature, cellulose film protects the bacteria from the destructive and dangerous effect of UV radiation [49]. Alternatively, by developing cellulose in water, a barrier is formed that inhibits colonization of the environment by other bacteria which discourages unwanted competition with the host bacterium.
The obtained biomaterial consists of BC in the form of a nanofibrils and keratin veil. The procedure involves avoiding the rejection of keratin by the patient's immune system as a foreign body reaction; respectively the burning of keratin achieves the condition of sterility.
By treating with water at 150 • C, inside the capsule, a pressure of 4.9 atmospheres (about 48,10 4 Pa) is developed [50], which determines the hydrolytic degradation of keratin. After this process, β-keratose and γ-keratose are obtained. β-keratose contains high molecular weight proteins, with disulfide cross-linkages which determine its insolubility. This fraction may also contain partially oxidized peptide chains or peptides with a percentage of splinted disulfide bonds. This structure facilitates obtaining of the β-keratose hydrogel. The second fraction, γ-keratose, consists of fragments oxidized keratin and cleaved into small molecules, usually cysteine derivatives. β-keratose hydrogel and partially a γ-keratose solution were used in this study.
It has been found that γ-keratose obtained by hydrolysis of human hair has acidic pH. For the qualitative evaluation of the protein composition and dispersion of the γ-keratin, a conductometric titration with NaOH was performed. The titration curve (triplicates) is illustrated in Figure 1.
It can be observed four domains with molecular fractions. According to the equivalence formula, the calculated normality for each domain is N 1strong acids × Sample volume = N NaOH × V eq1 (2) where N 1 strong acids represents the normality of part 1 components (equiv./liter); N NaOH is the normality of the sodium hydroxide solution used in the titration (0.1 in this case); V eq1 = the graphically determined volume of equivalence in domain 1 (mL) illustrated. From Formula (2), the number of strong acid equivalents is calculated: Similarly, for the other domains respectively, the range 2 between pH = 0.75-1.7, the range 3 between 1.7 and 3.2 and the range 4 between 3.2 and 4.8 were obtained. Table 1 shows the values of equivalents/liter number obtained on the four domains.   Table 1 illustrates the values of the acid equivalents on the domains obtained by conductometric titration of γ-keratose solution, after the hydrolytic degradation treatment. These are sulfonic or other acid derivatives reaction, obtained following the keratin macromolecular chain breaks, due to the hair hydrolytic treatment, at 150 • C and 4.9 atm. According to the literature [51,52] it is considered that in domain 1 Table 1 the protein fraction has a strong acid behavior (sulfonic group), in domain 2 there are less acidic proteins, possibly acids carboxylic acids with high molecular weight, low molecular weight alcohols or aromatic alcohols having a resonance effect with increasing acidity (hydrogen atom lability). In domain 3 there are sterically hindered aliphatic alcohols. Domain 4 is characterized by the excess of NaOH that is usually identified by titration. Figure 2 illustrates schematically the hypothetical chemical transformations. Obtaining groups of protein fragments with sulfonic components is done by splitting the disulfide bond of the cysteine according to the reaction illustrated in Figure 3. The potentiometric curve of beta-keratose hydrogel is illustrated in Figure 4. The curve consists of three straight segments, one red and other two blue having two points of intersection (volumes of equivalence). The red curve is the titration of the excess of NaOH (present on obtaining the hydrogel) up to the first volume of equivalence. The second line segment is the second equivalence volume. From here to increasing values the titration of salts of other oxygenated compounds (alcohols, esters, etc.) begins.

Scaffolds Morphology
Through bacterial growth, a gelatinous mass was obtained in the form of a nanometric veil of BC filaments without any chemical contaminants. Figure 5a illustrates the microphotography of lyophilized BC film, Figure 5b the microphotography of the BC-β-keratose scaffold and, respectively, Figure 5c the microphotography of BC-γ-keratose scaffold. The BC scaffold present relatively homogeneous portions of scattered BC filaments (black dots) that probably visualize sections of the nanofiber bundles located in a quasiuniform environment, delimited on portions by separation fissures, as can noticed in Figure 5a.
As can be seen in Figure 5b, the BC-β-keratose scaffold presents both components of the biomaterial, BC and the keratinous part, organized in form of dark colored islands, probably BC bundles dispersed in a homogeneous environment of gray keratin hydrogel. The same type of organization is observed, in the form of dark zones delimited by continues white fissures.
In the Figure 5c above the BC-γ-keratose SEM image revealed a more homogeneous organization. The γ-keratose (the soluble component resulting from the hair hydrolysis) is observed on large portions, as a light dispersion medium. The material contains small molecular weight keratin fragments and favors their dispersion. The dark-colored of BC bundles appear as dots shape. Figure 6 and Table 2 below demonstrate that the BC biomass and keratose solution have the characteristic elements of protein chains: C, O, and N, and S as a specific element in the disulfide of cysteine fragments, possibly fragments with sulfonic functional groups, explaining the solubility of gamma-keratose compared to the insoluble portion of betakeratose resulting from hydrolytic cleavage. The analysis of the biomaterial consisting of the keratose range containing small molecular weight fragments and cysteine fragments with high frequency of sulfonic groups was chosen.

Cytocompatibility Tests
An important aim of the wound dressing's material is to achieve an appropriate and efficient way for soft tissue regeneration which often consists of a large compartment of the cells-rich medium. Figure 7 illustrates the results obtained on bacterial cellulose (BC) and BC-keratose scaffolds, all seeded with stem cells. The relative metabolic activity induced by the scaffolds was over 95% and dependent of the scaffold composition. Cell viability tests show that after 48 and 72 h, respectively, from seeding, on BC and BC-β-keratose an increase in the number of cells until comparing with control culture. The cell viability increased over 115%, indicating an effect of stimulation of cells growths and differentiation. A similar effect, but less intensive was observed for BC-γ-keratose. The result could be determined by a better distribution the β-keratose in the BC membrane because of their supramolecular structure. The data of cytotoxicity on the obtained materials are in agreement with other authors' results about BC cellulose stimulating effect on cells activity [53].

In Vivo Tests
For the clinical testing of the scaffolds, eight common breed rabbits were included. A general clinical examination was performed before anesthesia and included the assessment of the habitus, skin and mucous membranes, the examination being repeated and postintervention. The results also depend on various co-morbidities, in multicellular organisms, both health and disease are defined by means of communication patterns involving the component cells. Clinical supervision was performed daily throughout the experiment; no changes in the physiological state were reported in the rabbits included in the study [54][55][56][57]. The appearance of the wound was followed and a favorable evolution was observed after the graft. One noticed the obvious recurrence of hairs throughout the wound contour, the absence of inflammation, and after taking biological samples for anatomic-pathological tests, the revascularization of the tissue [4,58]. Palpation of the area shows a hard, normal appearance, without a painful sensation. The evolution of wound recovery is presented in the next images (Figure 8), where, M is the wound grafted with biomaterial made of BC-β-keratose and X wound grafted with biomaterial of BC-β-keratose and artificial tegument.
Histopathological evaluation was carried out on the marginal areas of wounds, in all experimental groups. The morphology of the local inflammation, the conjunctive-vascular buds' formation and the epidermis regeneration process were monitored.
At seven days after grafting the histopathological exam (after the established criteria) did not reveal any significant differences between the animal groups ( Figure 9). All the studied animals developed increased dermo-epidermal coagulation necrosis, inflammatory infiltration in the hypoderm, represented by neutrophilic leukocytes, histiocytes and macrophages, all implicated in necrotic tissue detorsion. A congestion of the blood capillaries and a pronounced local edema, with the dissociation of local structural elements, was observed in the hypoderm.  At 14 days after grafting, the sections from control group revealed an inflammatory process which slightly decreases in intensity. The influx of leukocytes was maintained. A discreet fibroblasts differentiation, connective fibers and blood vessels neogenesis were observed in hypoderm. Animals tissues grafted with BC-β-keratose developed an inflammatory process with lower intensity. The healing process is represented by important connective hyperplasia and neogenesis of blood vessels, with the formation of prominent vascular-conjunctive buds. At lot BC-β-keratose with cells, the inflammatory process is discreet; the regeneration is markedly, represented by vascular, connective buds, and fibroblast proliferation. Connective fibers and capillary neogenesis are important. At 21 days after grafting at the animals from control group the inflammatory process is considerably reduced and the skin regeneration is represented by young conjunctive and vascular buds. The buds are covered with a superficial condensed cellular layer, without a basal membrane, suggesting a future stratified young and plane epithelium cells. Animals grafted with BC-β-keratose indicated that the re-epithelialization process is more advanced. On the surface of the connective bud, a young, unorganized, and untargeted epithelium is observed, consisting of slightly flattened skin cells. On the wounds from the animals grafted with BC-β-keratose and cells, an important epidermal regeneration was noted. A young, pavements epithelium, with a well-represented basal lamina and 2-3 rows of more or less flattened epithelial cells were present.

Histopathological Results Interpretation
Inflammatory and regenerative processes for the main skin structures (hypoderm, dermis, and epidermis) were followed by histological examination. The samples were harvested from the periphery of the lesions, at the border with the unaffected tissue. The degree of proliferation and differentiation of local and migrated cells, neogenesis of connective fibers and blood capillaries, regeneration of the keratinized epidermal pavement epithelium where appreciated.
At seven days post grafting the inflammatory process was similar to the three groups of experimental animals (Control, BC-β-keratose, BC-β-keratose-cells). No significant differences in the evolution of the inflammatory process and the healing process were observed.
At 14 days post grafting the predominance of the inflammatory exudate was observed in Control group, unlike the other two batches, where the regeneration process was already initiated, well outlined. At the dermis level, vascular-conjunctives buds, constituted by fibroblast differentiation, young connective tissue and marked neoangiogenic were observed. It has also been noticed, in both experimental batches (BC-β-keratose, BC-βkeratose-cells), intensive detorsion process of necrotic areas.
At 21 days post grafting evaluation dermis regeneration was more intense and rapid at (BC-β-keratose) and (BC-β-keratose-cells), comparing with extremely low levels in Control group. Dermal regeneration in the Control-group consisted of conjunctival-vascular papilla formation, fibroblast proliferation, collagen fibers synthesis, and angiogenesis. On the surface of the papilla was noted a cellular condensation suggesting the onset of epidermal regeneration, but without a proper basal lamina.
Epidermis regeneration was quantified by evaluating the epithelialization, the formation of the basal lamina and the basal layer, with its proliferation and the restoration of the stratified keratinized pavements epithelium as shown in Table 3.
The regeneration of the epidermis was much more evident in the BC-β-keratose-cells group compared to the BC-β-keratose one. Young, stratified epithelium, undergoing reshuffle and evolution towards keratinocytes, represented by basal lamina and 2-3 layers of epithelial cells were noticed.
Following the results, we concluded that skin regeneration was much faster in BCβ-keratose and BC-β-keratose-cells batches, especially during the last two weeks of the experiment. The process of scarring, with the elimination of necrotic detriment and reconstruction of damaged structures by the action of the heat agent, was carried out much faster in experimental batches than at the control lot. This demonstrates the important role of keratin material and cellulose in the formation of a mechanical barrier with protection function.
This barrier represents, also, a support for the cells involved in necrosis detersion and tissular regeneration. In addition, in BC-β-keratose-cells group the higher capacity of skin regeneration was justified by stem cells activity. Stem cells differentiation and proliferation contribute, alongside local and immigrant cells, to the restoring process of affected structures. Legend: "+"-very low grade of epithelization; "++"-low grade of epithelization; "+++"-intermediate grade of epitheli-zation; "++++"-high grade of epithelization; "-"-absence of epthelization.

Conclusions
Scaffolds based on bacterial cellulose (as a result of the Komagataeibacter xylinum bacterial species activity) and keratin derivates were obtained and tested. The scaffolds have been seeded with stem cells isolated from the rabbit's adipose tissue. The stem cells have initiated tissular growth with an appropriate viability. The composite biomaterials were grafted on the burned wounds on rabbits of the common breed. The treated wounds presented a favorable evolution. The process of scarring, with the necrotic tissue detersion and reconstruction of damaged structures by the action of the heat agent, was carried out much faster in comparison with control, which demonstrates the important role of keratin, cellulose and stem cells. Cellulose and keratin played the role of an important barrier, with protection and support activities for the cells involved in detersion and regeneration. The stem cells, by differentiation, contributed alongside local and immigrant elements to the restoration process of the affected structures.

Conflicts of Interest:
The authors declare no conflict of interest.