Bioinspired gelatin based sticky hydrogel for diverse surfaces in burn wound care
Scientific Reports volume 12, Article number: 13735 (2022) Cite this article
3986 Accesses
3 Citations
Metrics details
Proper burn wound management considers patient's compliance and provides an environment to accelerate wound closure. Sticky hydrogels are conducive to wound management. They can act as a preventive infection patch with controlled drug delivery and diverse surface adherence. A hypothesis-driven investigation explores a bioinspired polydopamine property in a gelatin-based hydrogel (GbH) where polyvinyl alcohol and starch function as hydrogel backbone. The GbH displayed promising physical properties with O–H group rich surface. The GbH was sticky onto dry surfaces (glass, plastic and aluminium) and wet surfaces (pork and chicken). The GbH demonstrated mathematical kinetics for a transdermal formulation, and the in vitro and in vivo toxicity of the GbH on test models confirmed the models’ healthy growth and biocompatibility. The quercetin-loaded GbH showed 45–50% wound contraction on day 4 for second-degree burn wounds in rat models that were equivalent to the silver sulfadiazine treatment group. The estimates for tensile strength, biochemicals, connective tissue markers and NF-κB were restored on day 21 in the GbH treated healed wounds to imitate the normal level of the skin. The bioinspired GbH promotes efficient wound healing of second-degree burn wounds in rat models, indicating its pre-clinical applicability.
Humankind's quest for inspiration from nature has led to the successful creation of novel and functional hydrogels1. The biomimicking of slug-based protective mucus contributed to the development of tough, surface-sticking hydrogels of an alginate-polyacrylamide combination2,3. An effective dopamine complex in surface adhesive hydrogel design, inspired by aquatic animals, such as mussels, where dopamine acts as the main ingredient for underwater adhesion, has been recently developed4. Many bioinspired hydrogels have been designed using the biosystem as a model for understanding its diverse functions, from its molecular architecture to its macroscopic geometry5. Hydrogels are complex three-dimensional (3-D) networks of hydrophilic polymer chains and given their hydrophilic nature, they contain significant quantities of water6,7. They exhibit swelling when exposed to water, especially since the human body has water as a major component and hydrogels can contain high volumes of water. Thus, allowing them to be an excellent candidate for various biomedical uses, like tissue engineering, drug delivery, self-healing materials, biosensors, and hemostatic bandages8,9.
The largest and essential organ of our body, the skin, is an outer defensive layer. Classical wound dressing materials such as dry fabrics (absorbent gauze or cotton), have minimal medicinal benefits, involve pain, and require frequent adjustments in dressing, thus causing the patient continued distress. Hydrogels are promising as they promote healing by maintaining a proper humidity level at the wound site. Most wound care studies consider hydrogels the best candidate for wound dressings, as they have a 3-D structure that resembles the natural extracellular matrix, which guarantees the wound a humid atmosphere10,11. The epithelial fractures and connective systems underpin the human body's ability to ensure sufficient protection from external harm12. The skin seems to be the most vulnerable of all human body organs, from bruises and scratches to burns. Statistically, burn injuries are the fourth most frequently encountered debilitating form of trauma13. An ideal burn wound dressing is expected to promote recovery in shorter periods and relieve pain since burn wounds call for prolonged medical attention.
In the last decade, mussel-inspired catechol chemistry has become an intriguing part of science, especially in hydrogels14, where polyacrylamide and bis-acrylamide compositions are a common matrix for a catechol-trapped hydrogel system15. Research indicates that prolonged or frequent contact of polyacrylamide and bis-acrylamide with the skin can trigger dermatitis and cancer in animal models16. Pre-clinical findings suggest that continued exposure to polyacrylamide and bis-acrylamide compositions in animal model studies compromised reproductive and nervous systems17. Even though multiple dressings are readily available on the market, an innovative wound treatment solution must be established to deal with burn injuries. The current investigation is predicated on the hypothesis that ‘polydopamine does exhibit an adhesive property in a non-toxic composition of hydrogel formulation’. Hence, the GbH wound dressing was developed and its physical and biological performance on diverse surfaces was evaluated. Finally, an evaluation of the drug release pattern from the wound dressing hydrogel patch was assessed to understand the formulation's drug diffusion pattern in wound healing of the second-degree partial burns in rat models.
The classical optimization adopted in the present research has led to the development of the GbH with a bioinspired polydomine's sticky property2,18. The PVA hydrogels have numerous applications in the pharmaceutical and biomedical industry due to their ease of processing, biocompatibility, non-carcinogenicity, bioadhesiveness, non-toxicity and transparency nature. Blending of synthetic hydrogels such as PVA, poly-caprolactone and poly-lactic acid with starch ensures the abundance of hydroxyl groups and improve the mechanical properties19,20,21. Starch, a biopolymer abundantly available in nature, is cost-effective, widely available with thermoplastic and efficiently biodegradable property. However, a starch-based system frequently exhibits poor mechanical, brittle, and highly water-soluble properties, and a synthetic polymer modification proves to be advantageous21,22. In the current study, the PVA-starch hydrogel blend, chemically crosslinked by glutaraldehyde reagent (GA) (Fig. 1a) obtained from the solution casting process was transparent and had no adhesive or sticky property. The blend of PVA-starch hydrogel served as a base to add a sticky property. Various concentrations of polydopamine were added to the hydrogel base and then the elongation test was performed (Tables 1 and 2). The lowest concentration of 0.5% was found to be elastic and appropriately sticky (Fig. 1a.1), as desired of a hydrogel formulation since a wound dressing should withstand any external force as well as protect the wound.
Schematic and diverse performance of GbH: (a) Schematic of the developed diverse surface gelatin-based hydrogel (GbH); (a.1) The developed GbH is a two-stage process where polymers of polyvinyl alcohol (PVA) and starch, and the optimized alkali polymerized polydopamine concentration is chemically crosslinked with glutaraldehyde reagent (GA), which act as the base gel; (a.2) The excess glutaraldehyde in the semi-polymerized stage crosslinks with gelatin and forms a polymer network over the base gel. The gelatin network prevents external oxygen and inhibits the oxidation of catechol groups.; The Benedict test was used to determine excess glutaraldehyde comprised: (b) PBS, (b.1) Tris–HCl, (b.2) AlCl2 and (b.3) distilled water. The developed GbH with stabilizer on diverse surfaces: (c) chicken; (c.1) pork; (c.2) stainless steel surface; (c.3) glass surface and (c.4) plastic surface.
Incorporating gelatin and sodium metaperiodate in the semi-polymerized state ensured the desired sticky property, which persisted for four days at RT (room temperature, 22 ± 3 °C). The best combination was observed as 500 μL of gelatin with a ratio of 1:5 of polydopamine and sodium metaperiodate. Previous research on mussel-inspired polydopamine-polyacrylamide hydrogel maintained sufficient free catechol groups in the hydrogel and prevented overoxidation of polydopamine4. The polyacrylamide in the mussel-inspired hydrogel obstructed the external oxygen and inhibited the oxidation of catechol groups by framing a polymer network. Mussels, in nature, prevent the overoxidation of the catechol group by secreting reductive cysteine-rich proteins, thus maintaining strong adhesiveness4. In the current research, the gelatin network prevented overoxidation and hindered the immediate oxidation of the catechol group, thus providing a prolonged sticky property to the hydrogel catechol. The base gel is formed by the crosslinked chain of PVA-starch (Fig. 1a.2). The crosslinking agent GA reacts with the adjacent O–H groups of the PVA, forming cyclic glyoxal23. The same crosslinking happens between starch and PVA. The strong H-bonding interactions between PVA-starch also aided the network formation. The polydopamine also interacts with the base gel-forming hydrogen bonds with the N–H present in the structure groups. The excess GA crosslinks the gelatin and makes the network stable24. The catechol moieties in the polydopamine can undergo various surface interactions in the normal tissue resulting in the formation of interfacial covalent bonds25.
The GbH was subjected to a washing process to eliminate excess GA. Thus, a suitable buffer to promote the removal of an excess of the C–H–O functional group was determined by the Benedict test26. The change in colour from dark green to crystal blue in the Benedict test is indicative of the C–H–O group being eliminated. The buffers used were Tris-HCl (3 M), aluminium chloride (AlCl2) (50 mM), phosphate-buffered saline (PBS) (0.1 M) and distilled water (Fig. 1b–b.3). The Benedict test revealed that PBS is ideal for washing purposes (Fig. 1b) where the washing was performed in three 6 h-cycles, then the buffer was discarded and the gel refilled with fresh PBS for purposes of gel preservation, which can be stored at 4 °C in the PBS or distilled water. The Fourier transform infrared spectroscopy (FT-IR) spectra of the washed gel also supports the complete removal of GA; the IR details are briefly explained in "Characterization of GbH" section. The stickiness of the GbH to the wet surface is enabled by the surface amine groups present on the hydrogel27,28. The GbH was kept on diverse surfaces (overnight at RT) and the stickiness of each hydrogel to the surface was observed (Fig. 1c–c.4). The GbH was placed onto different wet surfaces, such as chicken (Fig. 1c) and pork (Fig. 1c.1) and dry surfaces, such as stainless steel (Fig. 1c.2), glass (Fig. 1c.3) and plastic (Fig. 1c.4). The stickiness to metal, glass and pork was stronger than that of poultry meat.
The hydrogel synthesized from polyelectrolytes swells more due to the charge repulsion among the polymer chains29. Such property as swelling is desirable for controlled drug release30. The GbH is designed for wound care as a dressing material and therefore, the present formulation was loaded with three distinct medications, viz. ciprofloxacin (antibacterial drug), 5-flucytosine (antifungal drug), and quercetin (drug promoting wound healing) (Table 3). In the present study, the GbH was loaded with different concentrations of drug (a minimum of 5 mg/mL and a maximum of 20 mg/mL) depending on the saturation and effective concentration of drugs to be diffused. The drugs were solubilized in dimethyl sulfoxide (DMSO) and 200 μL of drugs were loaded with gelatin. A study of a combination of drugs (ciprofloxacin (100 μL) and quercetin (100 μL)) was also carried out since wound healing requires both bacterial protection and wound healing promoting drugs. The GbH without any drugs was included as a control for comparable properties.
The GbH had exhibited good swelling in various solvents and was comparable to the control (Fig. 2a). Besides, the swelling nature facilitates the absorption of exudates and promotes a suitable environment for wound healing. The GbH did not dissolve in any of the test solvents and the swelling percentage of blood-submerged GbH was observed to be more due to blood components29. In the current study the swelling capacity was negligibly compromised as the drug concentration increased. Being a candidate for wound dressing, a hydrogel with low water vapour transmission (WVT) (Table 4) value is favoured, as the fluid loss is limited and a sufficient moist atmosphere for the wound healing is maintained22. Reports indicate that an average ~ 250 g/m−2/d−1 loss of water from normal skin is experienced at 35 °C, whereas in a wound, water loss greatly rises to 5000 g/m−2/d−1, and loss will be based on the nature of the injury31. The drug-loaded GbH was found to have a comparatively low WVT and is comparable to the control. The greater the water depletion, the more impossible it is for the wound to heal32. Thus, swelling, WVT and moisture retention capacity (MRC) are essential parameters in hydrogels, which foster exudate absorption and limit the water transfer to ensure a condition conducive to wound healing, thus providing appropriate drug diffusion. There was a reasonably strong MRC in the prepared GbH (Table 4) and all MRC values showed a negligible difference from the control (Table 4) (drug unloaded GbH). The findings showed proper crosslinking even after the GbH had been exposed to 4 days of immersion in distilled water. The prepared GbH had a very strong gel fraction (GF) (Table 4) and all GF values were comparable to the control.
Characterization of the GbH: The physical evaluation of GbH: (a) the swelling behaviour of GbH in water, NaCl solution, MgCl2 solution and blood. The SEM image: (b) and (c) control GbH with pore size range from 266-393 nm; (b.1) antibacterial ciprofloxacin drug-loaded GbH; (b.2) wound healing promoting quercetin drug-loaded GbH; (b.3) antifungal drug 5-flucytosine loaded GbH; (b.4) Combination of antibacterial drug ciprofloxacin and quercetin loaded GbH. (c.1) SEM image of patch-A GbH before the release of salicylic acid; (c.2) SEM image of patch-A GbH after the release of salicylic acid (c.3) SEM image of patch-B GbH before the release of salicylic acid; (c.4) SEM image of patch-B GbH after the release of salicylic acid. Surface functional characteristics illustrated: (d) FT-IR of standard hydrogel and GbH; (e) FT-IR of GbH with antibacterial drug ciprofloxacin (C) loaded, wound healing promoting drug, quercetin loaded (Q), GbH with antifungal drug 5-flucytosine (5F) loaded, GbH with antibacterial drug ciprofloxacin and quercetin combined (Q + C) loaded and GbH with antifungal drug 5-flucytosine and quercetin combined (Q + 5F) loaded; (f) FT-IR of patch-A and -B. DSC characterization of patches: (g) GbH and (h) patch-A and -B. (i) XRD of the GbH as patch-A and -B.
The surface of the GbH was found to be dense in the scanning electron microscope (SEM) imaging and at very high magnification, few pores were visible, ranging from 266 to 393 nm (Fig. 2b, c). A dense surface benefits as a wound dressing since it does not encourage bacteria to infiltrate the injury site and cause infection easily15. A similar investigation on PVA-starch formulations found insoluble starch particles on the surface33 that were not visible on the GbH surface29. The observation of no surface change when compared with the control GbH indicates that the drugs were appropriately (uniformly/ properly) blended with the GbH, ensuring a uniform drug loading process (Fig. 2b.1–4,b.1–4). Even though the GbH is translucent in nature, its colour can be changed based on the drug-loaded. The colour of the GbH was changed to yellow and a milky turbid when quercetin and 5-flucytosine, respectively, were added.
The IR spectra of the hydrogel and GbH (Fig. 2d) displayed a broad peak in the range 3300–3500 cm−1, derived from the intermolecular hydrogen-bonded O–H stretching of the components34. The peak observed at 1636 cm−1 corresponds to N–H vibration of polydopamine (Fig. 2d), which was seen evidently in all the spectra. Since the spectra evidenced no characteristic aldehyde bands, there will not be any excess of glutaraldehyde. There was no reduction in the intensity of O–H bands even after the incorporation of drugs (Fig. 2e), indicating the abundance of hydrophilic O–H groups contributed by its components. Research indicates that the adhesives characteristics of hydrogels are mainly associated with the surface O–H groups of the hydrogel interacting with chemical groups such as hydroxyl, amino, and carboxyl on the surface of tissues27,28,35. The peak at 1141 cm−1 revealed C–O stretching arising due to the intermolecular hydrogen bonds formed between neighbouring PVA chains36. The stretching vibration exhibited by C–O bond in the C–O–C groups of the starch was found at 1025 cm−1 in the GbH, while the peaks corresponding to C–O stretching of the gelatin were found at 1080 cm−1 and 1030 cm−1 in the spectra of GbH (Fig. 2d). The peak arising due to the presence of a secondary amide group got merged with the N–H band of polydopamine at 1636 cm−1. The spectra of the GbH retained all its characteristic peaks in the respective region, revealing that no chemical interactions or structural changes occurred upon the incorporation of the drug (Fig. 2e and f).
The thermal behaviour of the GbH was studied with differential scanning calorimetry (DSC) thermogram. The melting endotherm peak for the GbH is observed at 199 °C (Fig. 2g). This can be mainly ascribed to the major component as PVA; however, the Tm observed here is lower than the literature reports for pure PVA, mainly because of the interactions between the PVA chains and other components, making it an amorphous nature of the GbH37. The GbH is thermally stable up to 200 °C, while the drug incorporated GbH exhibited higher Tm at 216 °C, attributed to the physical interaction between the drug and the GbH (Fig. 2h). The crystalline or amorphous characteristic is revealed through X-ray powder diffraction (XRD) with a peak at 2θ = 9.4°, which depicts the semi-crystalline peak of PVA38. The presence of starch in all cases was evident due to the presence of a small shoulder peak at 9° (Fig. 2i). The intensity of the peaks reduced upon the incorporation of the drugs. The diminished intensity of the peaks in patch-A and -B reveals the amorphous nature of the GbH.
The drug release profile was assessed using a 1% drug dosage of salicylic acid. Two approaches were implemented: patch-A, where the GbH was prepared and dispersed in salicylic acid; patch-B, where the GbH was immersed in 10 mL of salicylic acid solution in acetone until the solution evaporated. The elongation test of the patches indicated that the method of drug integration did not alter the GbH's elongation (Table 5). The patches displayed elongation equal to control patches, i.e., the GbH without drug.
The sequence of drug release (Fig. 3a) from the patches, represented that both patch-A and -B exhibit a controlled drug release percentage (CDR%) of 60.39 ± 2.25% and 57.08 ± 2.02%, respectively, within a period of 4 h. Patch-A and -B favourably displayed an identical pattern with slow-release; thus, a regulated drug release pattern was observed. A comparable gelatin hydrogel investigation recorded 100% of drug release in 4 h, whereas the GbH exhibited only 60% drug release. Studies suggest that the drug release was faster and the equilibrium achieved was at 3 h in an environment of sufficient dissolution media39. Patches-A and -B were observed to have a drug loading capacity of 13.48 ± 0.17 and 11.42 ± 0.15 mg, respectively. The drug loading process showed minor differences in the properties of the GbH, and patch-B showed a partial loss (Table 5) in terms of elongation. The solution casting system is efficient and has a strong potential for drug loading in the present investigation. The agar diffusion drug release investigation produced a violet/purple colour on agar plates due to a complex reaction between diffused salicylic acid and ferric chloride (Fig. 3b,c), where the graph shows the drug release zone vs. time, which determines the drug release kinetics (Fig. 2c). Based on the diameter of the zone formed due to the drug release, the controlled release characteristics of the GbH were observed. The release of salicylic acid was slow and could be observed by the expansion of the ring in a time-dependent manner. The GbH proves to be the ideal formulation for the diffusibility of the drug, which can be explained through further mathematical kinetic observations.
Mathematical modelling for transdermal drug delivery system: Time-dependent evaluation of salicylic acid release from GbH: (a) graphical illustration of spectrophotometric analysis of controlled drug release profile of patch-A and -B for salicylic acid; (b) illustration of agar well diffusion test for controlled drug release profile of patch-A and -B; (c) graphical illustration of controlled drug release profile of patch-A and -B for salicylic acid agar well diffusion test. Mathematical model representation of drug release from GbH: (d) zero-order, (e) first-order and (f) Higuchian release kinetics. Agar diffusion of GbH: (g.A) UV-sterile GbH performance against E.coli; (g.B) Control plate of UV-sterile GbH performance against E.coli; (g.C) UV-sterile GbH performance against S. aureus; (g.D) Control plate of UV-sterile GbH performance against S. aureus; (g.E) Non-sterile GbH performance against E.coli; (g.F) Control plate of non-sterile GbH performance against E.coli; (g.G) Non-sterile GbH performance against S. aureus; (g.H) Control plate of non-sterile GbH performance against S. aureus; (g.I) UV-sterile GbH performance against C. albicans; (g.J) Control plate of UV-sterile GbH performance against C. albicans; (g.K) Non-sterile GbH performance against C. albicans and (g.L) Control plate of non-sterile GbH performance against C. albicans. (h) illustrate agar overlay performance of GbH where E, S and CA denote E. coli, S. aureus and C. albicans, respectively; C denotes Control plate; C(H) denotes positive control GbH; D(H) denotes test drug-loaded GbH. (i) illustrates patch agar performance of GbH where D1, D2 and D3 are Day 1, 2 and 3, respectively; E, S and CA denote E. coli, S. aureus and C. albicans, respectively; C denotes Cotton patch; D(C) denotes drug-loaded cotton patch; H denotes GbH and D(H) denotes drug-loaded GbH.
The CDR% value is further considered for the statistical model analysis of the GbH drug release pattern. The release kinetics in zero- (Fig. 3d), first-order (Fig. 3e), and Higuchian kinetics (Fig. 3f) of the drug release pattern for patch-A and -B were plotted40. The graphs reflect the statistical form of the formulation of transdermal drug release. In a zero-order model analysis, data from in vitro drug release trials are plotted as the total amount of drug released vs. time (Fig. 3d). This relationship can explain the drug diffusion of drug release forms, including transdermal systems, matrix tablets with low soluble drugs in coated forms and osmotic systems41. The first-order model represents a cumulative log percentage of the drug remaining vs. time, which will result in a straight line with a slope of − K/2303 (Fig. 3e). This association can be used to categorise drug dissolution in prescription dosage types, such as those comprising water-soluble drugs in porous matrices41. Higuchian kinetics deals only with the total percentage of drug release vs. the square root of time (Fig. 3f). This correlation can be used to explain the drug dissolution of many kinds of modified release drug dosage formulations, such as transdermal systems and matrix tablets with water-soluble drugs41.
The drug release of salicylic acid from the GbH matrix fits the concept of zero- and first-order kinetics (for patch A, r2 = 0.984 and r2 = 0.99; for patch B, r2 = 0.894 and r2 = 0.95, respectively) (Fig. 3d,e). Patch-A also follows Higuchian kinetics with a relatively close correlation coefficient (r2 = 0.952), but patch-B had a lower value than patch-A (Fig. 3f). Patch-B has a lower value in the zero-order kinetic model compared with patch-A (Fig. 3d). Similarly, A previous report on the gelatin-based hydrogel mathematical models revealed that the hydrogel developed in the same manner as patch-B has a lower drug release than patch-A due to the esterified complexes hindering the salicylic molecule release39. In accordance with the validation of the mathematical models for a transdermal drug delivery system, patch-A follows three-drug release profiles, i.e., zero-, first-order and Higuchian model, but patch-B had a lower value as compared to patch-A for the zero-order and Higuchian model. A similar drug release pattern has been observed for diclofenac sodium entrapped in polyethylene glycol- and polyethylene glycol-polycaprolactone-based hydrogels42. Patch-A and -B, as discussed, obey all three kinetic laws, where the diffusion process releases salicylic acid. The drug uses the same channel used to diffuse it into the matrix, which can be confirmed by SEM analysis before and after the drug release of patch-A (Fig. 2c.1,c.3). The rough surface observed before release is a smooth surface in the after-drug release SEM images (Fig. 2c.2,c.4) of patch-B, which is comparable to the surface of the control GbH (Fig. 2c). The IR results (mentioned in "Characterization of GbH" section and Fig. 2f) showed the prominent presence of O–H functional group on the surface of the GbH and the drug loading did not alter much surface functional groups.
Hydrogel dressings primarily maintain the wound area moist and protect it from infection. The porosity observed in the SEM analysis of the GbH (section: "Characterization of GbH" and Fig. 2b, c) are indicative of advantages like high local concentration of the active ingredient, slow release and swelling. The drug diffusion from the GbH was tested against microorganisms (Escherichia coli MTTC 443, Staphylococcus aureus MTTC 96 and Candida albicans MTTC 183) using agar-based methods such as agar diffusion, agar overlay and patch-agar. These methods showcase drug release efficiency from the GbH and its performance in controlling infections. In the present investigation, the surface-sterilized and -unsterilized GbH (Fig. 3 g.A–g.L) were tested using the agar diffusion method. The GbH demonstrates strong diffusibility in both lower and higher concentrations of drugs, i.e., 5 mg and 20 mg. The observed two distinct rings of the inhibition zone might be due to the slow diffusivity of the drug from the GbH. The sterilized or unsterilized gel has little effect on drug diffusibility via the GbH. The agar overlay system (Fig. 3h) showed strong diffusibility of the drug at lower concentrations (5 mg) and the GbH with test drugs displayed no microbial growth when compared to the controls. The GbH is thus a successful choice for wound protection against bacterial (Fig. 3g.A–g.H) and fungal infection (Fig. 3g.I–g.L).
The tests and controls, as in the patch agar investigation (Fig. 3i), were infected by a swab of gram-negative E. coli and gram-positive S. aureus for antibacterial studies incubated at 37 °C. Antifungal plates were inoculated with C. albicans and incubated at 27 °C. The study was performed over a period of three days where a swab was taken from the contaminated area and monitored for bacterial and fungal growth on nutrient agar and potato dextrose agar plates, respectively. The present findings (Fig. 3i) showed that the GbH loaded with drugs performed superior antimicrobial activity as opposed to the GbH without drugs and controls. A thick microbial growth was observed on the cotton patch drug-loaded sample from day 1. The patch agar system drug-loaded and non-drug loaded proved the GbH's ability to avoid infection due to its soft wound-dressing bandage with a strong diffusivity property.
The toxicity of the GbH was evaluated at three levels by MTT assay. The first-level assay using L929 cell lines enabled the selection of the appropriate stabilizer, making the GbH non-toxic. The second-level assays determine the cell viability during indirect) contact of the GbH (GbH leachate) with 3T6 cell lines. Finally, in the third level, the inertness of the GbH was proved for direct and indirect (GbH leachate) contact of the GbH using HaCat cells. Various stabilizers, such as quercetin (QU), eugenol (EU), vitamin C (Vc) and sodium metaperiodate (SmP), were subjected to MTT assays at different concentrations (1:0.5, 1:1, 1:1.5 and 1:2) of polydopamine-to-stabilizer ratio (Fig. 4a). Interestingly, reasonable cell viability of ~ 50% at 1:1 ratio of polydopamine to sodium metaperiodate was observed. Thus, the SmP was chosen as a stabilizer for the second-level assays using Polish standards43. The MTT evaluation of the toxicity of the biomaterial leachate medium in 3T6 cells revealed its non-toxic properties. Among the ratios of polydopamine to the stabilizer, SmP (1:1,1:2, 1:3, and 1:4) compared here, 1:4 displayed a > 80% cell viability (Fig. 4b), which was further tested in various amounts replacing 100% of the growth medium with the biomaterial leachate medium (Fig. 4c). Even though various percentages (25, 50 and 100%) of the biomaterial leachate medium were replaced, there was no major negative impact of the GbH on the viability of 3T6 cells and it was comparable to the controls, namely PVA-starch hydrogel and the GbH base. The final MTT assay was carried out on the HaCat cell line (Fig. 4d) with two different methods, direct and indirect contact of the GbH (Fig. 4d.1). The cell viability remained unaffected, i.e., 100% in both test methods and the values observed were comparable to the growth controls (Fig. 4d).
In vitro and in vivo performance of GbH as a dressing material for second-degree burn wounds: Cytotoxicity assessment of the GbH using L929 cells: (a) Cell viability of L929 when exposed to GbH for 24 h, where Hb is hydrogel base with no stabilizer and the legend denotes the concentration (mg) of each test stabilizer; (b) Cell viability of 3T6 when exposed to the GbH leachate medium for 24 h, where Ctr is the GbH base with no stabilizer and the legend denotes the ratio of polydopamine to sodium metaperiodate and (c) Cell viability of 3T6 when exposed to the GbH leachate media for 24 h at a different percentage, where Ctr is the GbH base with no stabilizer and the legend of the ratio denotes polydopamine and sodium metaperiodate ratio in the GbH. (d) Cell viability of the HaCat when the GbH is in contact with the cells (GbH placed) and leachate medium at 100% medium replacement incubated for 24 h, where Ctr denotes control, Ctr 37 °C denotes the positive control; (d.1) Observed event of healthy HaCat cells after 24 h in contact with the GbH, where white arrow denotes the GbH and black arrow denotes healthy HaCat cells in 96-well plate. Observed development of brine shrimp when exposed to the GbH for 24 h, (e) Positive control: nauplii from the aerated tank; (e.1) Control: nauplii in artificial saltwater; (e.2) and (e.4) Test: nauplii in 1:1 medium of the GbH leeched buffer and artificial saltwater; (e.3) and (e.5) Test: The GbH placed in brine shrimp in an artificial saltwater medium. Short–term toxicity test on embryo and sac-fry stages of zebrafish model: (f) Observed development of zebrafish when exposed to the GbH (GbH direct contact and 1:1 medium, i.e., the GbH leeched buffer and E3 medium) for 18–96 hpf; (f.1) Observed healthy zebrafish eggs at 48 hpf in contact with the GbH. Photomicrographs showing the histopathology of the skin in rats. Normal appearances of the epithelium in the male (g) and female (g.1) rats of the control group. Minimal acanthosis of the male (g.3) and female (g.4) rats. Normal dermis appearance in the control rat (g.2) and minimal inflammatory cell infiltration in the treated (g.5) group.
The effect of the direct and indirect contact of the GbH was explored through in vitro model-based assays using brine shrimp (Artemia salina) and zebrafish (Danio rerio) embryos. The brine shrimp lethality assay is a rapid test to evaluate cytotoxicity44. The GbH immersed in phosphate buffer, incubated at 35–37 °C for 24 h, was used as a test solution for brine shrimp assay. The 24 h hatched nauplii (n = 10) were inoculated in different ratios (1:4, 1:1 and 1:0) of the test solution and artificial seawater. The development of the active young to the naupliar stage with healthy growth in the body size and antenna hair (Fig. 4e–e.5) was indicative of the non-toxic nature of the GbH test solution. The samples of direct contact of the GbH immersed in seawater also showed a similar growth pattern of the nauplius. A 10% mortality rate was observed in 1:0 ratio used in the indirect assay, which ascribes to the presence of low saltwater content. Whereas 15% mortality rate was observed in the direct contact of the GbH immersed samples due to the nauplii tangled to the GbH. (Fig. 4e.5)45. The controls maintained in the incubated plates and aerated fish tank displayed similar naupliar growth patterns.
The fish embryo test (FET) assay using zebrafish embryos (n = 10) (Fig. 4f,f.1) was performed similarly to the brine shrimp lethality assay with slight modification using E3 medium46. The embryos were observed each day to record any development changes due to their exposure to the GbH directly and the GbH leeched test solution according to the OECD guidelines for testing chemicals No. 212: Fish, short-term toxicity test on embryo and sac-fry stages47,48. The apical observations were performed on each tested embryo (Fig. 4f, f.1) every 24 h until 96 h post-fertilization (hpf) and the severity scaling (Table 6) of the toxicity of the GbH on the development of the embryos was recorded. The other observations included eye development, movement, blood circulation and pigmentation, head-body development, pictorial fin and protruding mouth49. In addition, the beginning of hatching at ~ 72 h in both the treatment and control groups was documented (Fig. 4f,f.1). The negative results (Table 6) in the severity scaling indicated the healthy development of the zebrafish embryo upon direct and indirect contact with the GbH.
The acute dermal toxicity experiment was undertaken according to regulatory guidelines of OECD-402 for testing of chemicals50. The toxicity range-finding and confirmatory study were performed using selected healthy Wistar albino rats (n = 10) after acclimatization. The test material, GbH, neither produced mortality nor showed any clinical signs of toxicity (Table 7) in the tested in Wistar albino rats throughout the observation period (14 days). Under the test conditions of OECD-402, the experiment did not yield the dermal LD50 of the GbH in rats and the formulation was non-toxic up to 2000 mg/kg body weight (> 2000). The GbH-exposed rats survived the experimental protocol and were sacrificed, as the necropsy was not required (Table 8). Histopathological results (Fig. 4g–g.5) clearly show no sign of inflammation or abnormalities in the applied region of the GbH in the male and female groups.
The in vitro scratch wound assay demonstrated an efficient cell migration in the scratches in the HaCat cells, which were exposed to the leachate of the GbH and quercetin-loaded GbH in the medium (Fig. 5a). The cell monolayer scratch was partially closed compared with the controls within 24 h of exposure to the biomaterial leachate medium. The images captured at intervals were qualified to prove the non-toxicity nature of the GbH, which favour an efficient cell migration for the wound closure51. The observed closing of the artificial gap, ‘the scratch’, on the confluent cell monolayer of HaCat cells, where the cells on the edge of the newly created gap moved towards the opening to close the ‘scratch’. Thus, new cell–cell contacts were again established in the quercetin-loaded and non-loaded GbH (Figure. a. 24 h-Q-GbH). A similar observation of efficient wound closure of in vitro ischemic scratch assay with low levels of immune cell infiltration and cytokine due to quercetin has been reported52. Previous reports on the analysis of quercetin-loaded liposomes developed in different amounts of carbopol and gelatin led to an accelerated injury cure, substantially decreasing the wound closing time53. Numerous researchers have developed quercetin as a model drug to promote wound healing54,55.
Wound healing performance of GbH: (a) Scratch wound healing performance of HaCat cells in 100% replaced of the GbH incubated medium. (b) Changes in skin tensile strength in the Normal, Control, cream base group (Cream), quercetin loaded cream (QC), GbH base (Hydrogel), quercetin loaded GbH (QH) and silver sulfadiazine (SS) treated groups. The results are represented as the mean ± S.D. with n = 6 in each group ap < 0.05 as compared to the Normal group; bp < 0.05, as compared to Control group; cp < 0.05, as compared to Cream group, dp < 0.05, as compared to QC group, ep < 0.05, as compared to Hydrogel group, fp < 0.05, as compared to QH group, gp < 0.05, as compared to SS group. (c) The effect of treatments on burn wound contraction (%) on day 4, day 7, day 11, day 14 and day 21 was a superior and faster wound contraction compared with the control and placebo groups. (d) Changes in wound contraction of the normal, control, Cream, QC, Hydrogel, QH and SS treated groups.
The nutritional intake, water consumption and body mass of the Wistar rats having sustained burn injuries remained unaltered. Promptly after the burn injury, the skin on the dorsal region exhibited swelling. The lesions were evident in the form of red patches as of day 4 and necrotic tissues were found to be coated with a crust by day 7.
An early epithelialization of wounds (Table 9) was observed in the treated groups administered with 1% quercetin GbH-treated group (QH) and silver sulfadiazine (SS). The control group did not show proper wound healing until day 21, whereas the QH and SS exhibited early epithelialization of wounds from day 14 and 16, respectively. The placebo groups (i.e., cream-base treated group (Cream) and GbH-base treated group (Hydrogel) observed early epithelization from day 16 and 17. The placebo groups signify the positive effect of the drug-loaded GbH and -cream formulation.
The test tissue specimens were machine clamped and the maximum force generated to tear the specimens indicated the quality of the tissue. A significant difference in tissue tensile strength (Fig. 5b) between control and all treatment groups (p < 0.05) was observed. Indicating the need for burn wound care, the tensile strength of the QH and SS groups was 24.4 and 23.37 N, respectively, whereas the control group recorded 3.77 N. A better tensile strength of the QH and SS groups was of a similar range, whereas the placebo group of Cream and Hydrogel base treated showed as 10.1 N and 19.32 N with a significant difference (p < 0.05) as compared to the drug-loaded formulation, thus emphasizing the positive role of the GbH in burn wound healing. The recovery of tensile strength of the QH and SS proved the normalization of skin with a tensile strength of 28.45 N by day 21.
The percentage of wound contraction (Fig. 5c,d) were significantly higher (p < 0.05) for the QH and SS groups compared to the control group. The outcome of the GbH-mediated wound closure in the second-degree burn on the rat model has proven to be beneficial. The QH-treated animals displayed more substantial wound closing (45.00 ± 1.46% on day 4; 98.24 ± 3.1% on day 14) than the SS treated ones (47.67 ± 1.8% on day 4; 96.4 ± 2.2% on day 14) and the untreated control group (18.00 ± 2.5% on day 4; 54.52 ± 1.25% on day 14) on day 4 and day 14, respectively (Fig. 5,d). The gross morphological studies showed decreased inflammation and redness and limited scarring in the QH group on day 14. Also, the epidermis rejuvenated to the normal skin architecture in the QH and SS treated wounds, while signs of inflammation and premature wound closure were observed in the control groups on day 21 (Fig. 5d)
The malondialdehyde (MDA) levels (Fig. 6a) of the QH treated tissue samples were recoded as 0.814 nmoles MDA/mL and were lower than the control (p < 0.05) group with 2.147 nmoles MDA/mL, whereas normal skin was recorded as 0.705 nmoles MDA/mL. A substantial increase (p < 0.05) in the control group MDA is a sign of lipid peroxide damage, which signifies to free radical damage, leading to incomplete wound healing by day 21. The MDA levels of QH and SS treated groups were 0.814 and 0.827 nmoles MDA/mL, respectively and identical to each other and comparable to normal skin tissue. The lowered MD levels in the QH treated samples indicate the quercetin's effect in reducing the lipid peroxidation and antioxidant protection during burn wound healing. Antioxidant protection against burn-induced oxidated injury by using oral and topical treatment of Myrtle (Myrtus communis) has been previously reported56. Thus, the reversal of biochemical indices is attributed to anti-inflammatory compounds’ potential antioxidant effect.
In vivo wound healing changes in (a) MDA; (b) GSH; (c) CAT; (d) HXP; (e) HXA and (f) NF-κB levels of the Normal, Control, cream base group (Cream), quercetin loaded cream (QC), GbH base (Hydrogel), quercetin loaded GbH (QH) and silver sulfadiazine (SS) treated groups. The results are represented as the mean ± S.D. with n = 6 in each group ap < 0.05 as compared to the Normal group; bp < 0.05, as compared to Control group; cp < 0.05, as compared to Cream group, dp < 0.05, as compared to QC group, ep < 0.05, as compared to Hydrogel group, fp < 0.05, as compared to QH group, gp < 0.05, as compared to SS group. 2-D and 3-D image of quercetin interaction with: (g) and (g.4) 1SVC target interaction; (g.1) and (g.5) 3BRV target interaction; (g.2) and (g.6) 1NFI target interaction, and (g.3) and (g.7) 2E7A target interaction.
Both non-enzymatic and enzymatic antioxidants, i.e. glutathione (GSH) and catalase (CAT), respectively, play a prominent role in dynamically regulating the levels of reactive oxygen and its intended harm, favouring wound healing57,58. In the control samples, the GSH (Fig. 6b) and CAT (Fig. 6c) levels were recorded as 2.24 μ mol/g and 14.83 µ moles of hydrogen peroxide utilized/mg/tissue/min, respectively. A significant reduction in GSH (Fig. 6b) and CAT (Fig. 6c) levels were observed in the control group when compared to the treated and normal groups (p < 0.05). The QH and SS treated groups aimed at restoring regular tissue function of GSH (2.13 and 2.14 μ mol/g tissue, respectively) and CAT with (22.41 and 25.341 µ moles of hydrogen peroxide utilized/mg/tissue/min) that is comparable to that of the normal group with 2.24 μ mol/g tissue GSH and 30.182 µ moles of hydrogen peroxide utilized/mg/tissue/min of CAT (Fig. 6b and c). The QH significantly restored (p < 0.05) GSH and CAT levels by day 21, when compared with the placebos (GSH: 1.48 and 1.8 μ mol/g, and CAT: 15.533 and 18.207 µ moles of hydrogen peroxide utilized/mg/tissue/min for Cream and Hydrogel groups) and 1% quercetin cream-base treated group (QC) with 1.65 μ mol/g tissue and 28.554 µ moles of hydrogen peroxide utilized/mg/tissue/min, respectively.
The hydroxyproline (HXP) and hexosamine (HXA) levels in test tissues can be correlated to the healing observed. The HXP is the critical element of collagen, whereas the HXA is the ground substrates for constructing connective tissue components59. Thus, the HXP and HXA levels represent a perfect candidate for a connective tissue marker in wound healing. During the healing process, the HXP and HXA contents increased in all treated groups relative to the control group (Fig. 6d and e). The HXP and HXA levels of the burn group without any treatment were 38.911 and 40.477 μg/mL, respectively, which was significantly lower (p < 0.05) compared to that of the normal group with 97.546 and 107.752 μg/mL, respectively. The QH and SS groups restored their HXP and HXA functional levels to 83.053 and 76.343, and 95.698 μg/mL and 89.22 μg/mL, as observed in the normal group with 97.546 and 107.752 μg/mL by day 21. The QH substantially restored (p < 0.05) the levels of the HXP and HXA compared with the placebo groups (HXP: 52.858 and 58.729 μg/mL, and HXP: 63.559 and 66.898 μg/mL for Cream and Hydrogel groups) and QC (HXP: 68.160 and HXA: 73.785 μg/mL) groups as on day 21. Interestingly, the SS group recoded 76.343 and 89.221 μg/mL of tissue HXP and HXA levels, similar to the QH group. The substantial decrease in the HXP and HXA levels in the control tissue content indicates low collagen levels, insufficient connective tissue formation, and an inadequate wound healing process. Thus, the observation in the QH treated group highlights the intended healing property of the formulation.
The functions of the NF-κB are several in wound healing as it modulates inflammation and cell survival and promotes the remodelling of cell junctions and the assembly of a cytoskeletal structure around the wound60. The NF-κB levels of the control group were 5.88 ng/mL and were significantly high (p < 0.05) relative to the normal group with 3.95 ng/mL, implying inflammation persistence. The QH and SS treated groups restored their usual NF-κB functional levels and were observed at 3.61 and 3.52 ng/mL, similar to the normal group (Fig. 6f) tissue NF-κB levels. The QH substantially restored (p < 0.05) NF-κB levels compared with the placebos (5.11 and 4.75 ng/mL of tissue NF-κB levels of Cream and Hydrogel groups) and QC treated groups (4.46 ng/mL tissue NF-κB levels) as on day 21. Thus, the results emphasize the effect of the GbH in facilitating wound healing and restoring the expected functioning of the NF-κB akin to a normal skin tissue.
The transcription factor NF-κB and the multifunctional cytokine TNF-α are potent inflammatory mediators that actively play predominant roles in cellular events such as cell survival, proliferation, differentiation, and death61. Researchers have well-established quercetin as a model medication for improving wound healing53,56, and the current study highlights the beneficial effects of the quercetin-supplemented GbH in the recovery of second-degree burn wounds in rat models. The in silico analysis of quercetin against the potential inflammatory mediator targets (Fig. 6g–g.8 and Table 10) observed an excellent binding score and hydrogen bonding to multiple amino acids. The compound binds at the p50 domain of the protein 1SVC, which translocates to the nucleus, where it binds to the DNA (Fig. 6g,g.4). The coiled-coil region of 3BRV lies between positions 49–356 (Fig. 6g.1,g.5). Many coiled coil-type regions are involved in critical biological functions, such as the regulation of gene expression. The region between 44 and 111 of 3BRV actively participates in the interaction with CHUK/IKBKB, thus enabling IKK-mediated phosphorylation of RelA/p65, which overall actively promotes an inflammation response through NF-κB activation. The domain region of 1NFI (Fig. 6g.2,g.6) between 19 and 306 functionally regulates the RelA target gene promoter accessibility. Quercetin forms hydrogen bonds with amino acids in the 1NFI domain region, rendering it functionally inactive. Mutagenesis at positions 105 and 108 of protein 2E7A (Fig. 6g.3,g.7) has led to low activity and inactivity62. The current docking highlights the binding of quercetin in the active region of 2E7A.
The normal skin (Fig. 7a) shows an architecture with a well-defined epidermis and dermis layer in the histopathological evaluation. The epithelial layer (x) is intact with no signs of inflammation. The dermis has many sebaceous glands (b) and well-defined collagenous fibres (c) in the upper layer of the dermis. In the control group (Fig. 7a.1), there is a complete loss of the epidermis and substantial destruction of the superficial skin layers (d). Vacuolar cytoplasmic disintegration in the basal cell layer is prominent (e) along with neutrophilic infiltration to the injury site (f). The skin shows coagulation of the epidermis and dermis, and the denatured collagen appears swollen (g), homogeneous and infiltrated by exudative cells. The placebo group, Cream base treated group (Fig. 7a.2), displayed a burn healed tissue with moderate inflammation, with no signs of epithelial or dermal regeneration (h). The basal cell layer remains degenerated (i) and markedly vacuolated, indicating impeded healing. The collagen fibres remain degenerated (j) with no signs of microvascular regeneration. Similarly, the placebo group, Hydrogel base treated group (i.e., the GbH) (Fig. 7a.4), exhibits epithelium with some signs of regenerative growth (k). A marginal decrease in the vacuolization of the basal cell layer (l) indicates healing of the tissue, and a decrease in the swelling of collagen fibres is evident (m).
Burn wound histopathological assessment on day 21: Standard morphology of the epidermis, dermis and hypodermis was found during photomicrographs of a histopathological examination of the Normal group (a). The Control group (a.1) was observed to have marked characteristics of burn crust development in the dermis and epidermis, extreme leukocyte aggregation, congestion of the blood vessels, hair follicles, and the sebaceous glands. Moderate leukocytes, blood vessel destruction, and degenerating degeneration of hair follicles and sebaceous glands were observed in the topical application of the Cream and the GbH (Hydrogel) placebo group (a.2) and (a.3). The quercetin drug-treated cream and the GbH group (QC, QH) and silver sulfadiazine (SS) (a.4), (a.5) and (a.6) displayed no symptoms of leukocyte accumulation, favoured by epithelium regeneration. The restored skin architecture refelects the regeneration of the epidermis upon the topical application of quercetin loaded GbH, which is in accordance with normal skin.
The drug-loaded cream-treated group, i.e., QC (Fig. 7a.3), aimed at regenerating the epidermis and dermis layers, where their differentiation is evident (q). Significant architectural restoration of the basal cell layer is seen in the form of markedly reduced oedema and negligible signs of vacuolization (r). However, healing of the dermis layer remains incomplete with the presence of small vacuoles in collagen fibres (s). A significant epithelium regeneration can be observed in the drug-assisted GbH treatment group, i.e., QH (Fig. 7a.5). The differentiation in the epidermis and dermis layers appear almost restored to a normal histological architecture (t). The presence of sebaceous glands (u) indicates a physiological restoration of skin tissue function. The basal cell layer appears normal in shape and architecture, with no signs of inflammation (v). The collagenous fibres in the dermis show no signs of swelling or other inflammatory characteristics (w). The positive control of the SS cream-treated group (Fig. 7a.6) shows evident epithelium regeneration (n). The basal cell layer displays restorative changes, evidenced by a significantly decreased vacuolization (o). However, swelling and oedema in collagen fibres (p) can still be observed at low levels.
The skin is the largest and essential organ of our body, which is an outer defensive layer. Damage to the skin affects the various functions and compromises the patient's working capacity and independence. A burn injury is a traumatic experience and depending on the severity of the wound, slow wound healing, infection, pain, and hypertrophic scarring remain a major challenge in burn research and management63. A burn wound experiences high capillary permeability due to direct exposure to heat, which causes the plasma to leak out to the interstitial place from the capillaries. During a burn condition, an increased plasma leak and capillary permeability persist till 48 h and is maximum in the initial 8 h. Burn wounds are sensitive and the patient experiences pain depending upon the severity of the wound. The advent of plasma leak and generalized capillary permeability is a phenomenon specific to burn wounds64. The current research focuses on soft wound dressing that is sticky due to the bioinspired property of polydopamine. Such soft wound dressing can be beneficial for treating burn wounds since the stickiness of the hydrogel is not extreme adhesive and tough. For many marketed gelatin-based sealants, tissue adhesives can be beneficial for tissue repairs1,8,18. Such tissue injuries call for immediate attention to restore standard organ functionality. In major injuries associated with trauma or surgeries, tissue adhesives are expected to be strong, robust, elastic, non-toxic and perform diverse surface adhesion8.
The hydrogel blend prepared by the solution casting method was translucent and exhibited no sticky property (Fig. 8a). The blend of PVA-starch and crosslinked with GA served as a base to further incorporate the sticky property. The recent bioinspired research tends to modify the polymeric properties of hydrogels2,18. The practice of using alkali polymerized dopamine65 to induce diverse surface sticky properties in a polyacrylamide and bis-acrylamide hydrogel system has been previously reported4, even though various researchers have established its carcinogenic effect66. The present research aims at a highly biocompatible composition and a cost-effective bioinspired hydrogel that can be sticky onto diverse surfaces using alkali polymerized dopamine. The physical property estimates of the GbH showed the good swelling property in different solvents that mimicked the physiological condition of the wound (Fig. 8a). Polyelectrolyte-based hydrogels, due to charge repulsion on the polymer chains, prove beneficial for achieving controlled drug release29,30. Burn wounds exhibit more significant fluid loss of 5000 g/m−2/d−1 compared to normal wounds. The current composition of the GbH reports low WVT and high MRC values and is comparable to the control31. The essential parameters of swelling percentage WVT, MRC and GF enable exudate absorption and reduce the water transfer from the wound. Thus, ensuring a condition for effective wound healing by providing proper drug diffusion.
Highlights of the GbH in the current research: (a) Development of bioinspired gelatin-based diverse surface sticky hydrogel for second-degree burn wound care; (b) Schematic of the surface interaction of the catechol group with the burn wound area; (c) soft wound patch interaction with wound tissue; soft wound patch; (d) QH placed on second-degree burn wound; (e) Observable wound repair on day 3 (arrow) of dressing and (f) Absorption of exudates: a hallmark of the ideal hydrogel.
In vivo dermal wound dressing, the GbH (Table 11) demonstrated accelerated skin tissue regeneration. The GbH could be easily removed without leaving any residue or pain on the rat model. The sticky GbH confirms its diverse surface performance. The free catechol group of polydopamine interacts with amine groups of the tissue surface (Fig. 8b)25. Burn wound healing remained constant in the control group from day 1 to day 7. On the other hand, the scale of healing was prevalent in the majority of burn wound treated groups as of day 3. The histopathological analysis of almost every treatment group showed healing of burn wounds, but the QH demonstrated a better and faster healing process than the cream formulation treatment group and was similar to the SS treated group. The GbH formulations have an advantage over the cream formulations since the former can be replaced by new formulations every third day, whereas the cream formulation must be applied daily. The GbH as a soft wound dressing (Fig. 8c) was not painful to the rats and there was no significant redness or change in the dietary routine of the rats owing to the infliction of a second-degree burn wound or GbH dressing (Fig. 8d).
A remarkable finding of the present investigation is the development of pink and fresh cells (Fig. 8e) along the wound boundary on day 3 with the quercetin supplemented GbH treatment (QH group), which was not the case with any other treated group. A recent finding of the quercetin dosage in promoting wound healing favoured an inhibition of mitogen-activated protein kinase and NF-κB activation in the in vitro cell scratch assay, which was conducive to the healing of pressure lesions52. Similarly, the placebo group also confirmed the significant effect of the quercetin-loaded GbH on healing the second-degree burn wound in the present research work. Previous reports on an analysis of quercetin-loaded liposomes developed in different amounts of carbopol and gelatin led to an accelerated injury cure, substantially decreasing the wound closing time53. Numerous researchers have developed quercetin as a model drug to promote wound healing54,55. Likewise, the current research also emphasizes the positive impact of quercetin-supplemented GbH in healing second-degree burn wounds in rat models. In order to promote the healing of wounds, the properties of hydrogel to absorb exudates and maintain a clean, moist, healing environment (Fig. 8f) were some of the other highlights of the GbH in the present investigation.
It is essential to consider that wound healing is a complex process that involves various factors, such as a moist and warm environment. Thus, as centred on the ‘wet wound healing theory’, a moist healing condition is ideal for the development of granulation tissue and fostering the separation of dermal cells. The GbH formulation recognizes such crucial elements and facilitates rapid wound healing by absorbing excess exudates and allowing for the exchange of oxygen and water vapour. It also guards against microbial invasions. The GbH, formulated in the present investigation, is non-toxic, non-allergenic, convenient and cost-effective. It has a controlled drug delivery feature and properties enabling it to stick onto different surfaces, like medical implants and wet or dry wound surfaces. The GbH may be used as a preventive anti-infection patch to control bacterial or fungal infections on the skin. The developed GbH was validated as an ideal wound dressing material for second-degree partial burn wounds in rat models. The above findings culminate in the fact that the bioinspired formulation of the GbH can improve wound healing and skin repair of second-degree burn wounds in rat models, thus validating its pre-clinical use.
A detailed description of the materials and methods is available in SI Materials and Methods.
The experiment was carried out at the Institute for Industrial Research & Toxicology, F-209, U.P.S.I.D.C., M.G. road, Ghaziabad-201302, India and the experiment was labelled as Project No.: 202112-25; Report No: IIRT/TOX/202112/ADT/0112; Date: 14–12-2021. All methods were carried out in accordance with guidelines and regulations of Committee for the Purpose of Control and Supervision of Experiments on Animals (CPCSEA), New Delhi, India. The methods implemented in the current study are in accordance with ARRIVE Guidelines 2.067. A protocol detailing the acute dermal toxicity studies, treatment groups and design of the experiment is mentioned in SI Materials and Methods. The protocol for dermal toxicity study was for 14 days and animals were euthanized by isoflurane overdose using small animal anesthesia system.
Rats (either sex), weighing between 250 and 300 g, were procured from the Disease-Free Small Animal House Facility (DFSAH) of Lala Lajpat Rai University of Veterinary and Animal Sciences (LUVAS), Hisar, Haryana, India. All methods were carried out in accordance with guidelines and regulations of Committee for the Purpose of Control and Supervision of Experiments on Animals (CPCSEA), New Delhi, India. The methods implemented in the current study are in accordance with ARRIVE Guidelines 2.067. The animals were quarantined and housed at the Central Animal House Facility (CPCSEA Registration no. 1753 Wistar /PO/E/S/14/CPCSEA) for acclimatization for seven days before experimentation. The experimental animals were divided into seven groups (n = 6), and the protocol duration was 21 days. After 21 days the animals were euthanized by isoflurane overdose using small animal anesthesia system. A protocol detailing the induction of second-degree burn injuries, treatment groups and design of the experiment is mentioned in SI Materials and Methods.
The animals were anaesthetized and sacrificed by decapitation, and skin tissue samples were collected and processed according to the standard protocols. The samples used for histological observation were deposited in 10% neutral buffered formalin. Constructive pharmacological criteria, including time of epithelialization and wound contraction, have been monitored by regular protocols68. The quality of the burn-healed skin, when compared with a normal group, was evaluated using a wound stretching machine, EFG500E, EFGE digital force gauge. The histology studies began immediately on day 21, right after the induction of the burn injury.
After decapitation on day 21, the full thickness of the healed and natural skin (1 cm2) was cautiously removed. The tissue was weighed and then homogenized with a glass homogenizer at 4 °C in 1 × PBS (tissue weight (g): PBS (mL) volume = 1:9) and followed by centrifugation at 10,000 g at 4 °C for 30 min. The biochemical parameters include malondialdehyde (MDA)69, glutathione (GSH)70 and (catalase) CAT71 levels of the homogenized skin sample, according to standard protocols, which were analyzed using UV/Visible double beam spectrophotometer (Shimadzu), and expressed in nmoles MDA/ml, μ-mol/g tissue and µmoles of hydrogen peroxide utilized/mg/tissue/min, respectively.
The hydrolysate of the skin tissue was prepared according to the previously mentioned protocol of day 2172. The hydroxyproline (HXP) and hexosamine (HXA) contents of granulated tissues were estimated using UV/Visible double beam spectrophotometer, Shimadzu, according to previously mentioned protocols and expressed in μg/mg of tissue.
The nuclear factor kappa B (NF-κB) of the homogenized skin sample was measured on the basis of the Sandwich-ELISA theory using Rat NF-ŚB ELISA Package (Biolab Technology Laboratory, Shanghai Korian Biotech Co., Ltd). The sample was prepared following the operator's protocol and measured at 450 nm within 10 min using a microplate reader (Alere AM 2100).
A rat from each group was euthanized on day 21 after the wounding for histopathological examination. Samples of tissue (2 × 3 mm) placed in buffered formalin (10%), dehydrated by alcohol, have been excised and eventually inserted in paraffin wax blocks. For the assessment of pathological modifications, thin pieces of tissue samples (5 μm) were stained with hematoxylin and eosin (H and E)73. The stained slides were studied under an Olympus CX41 microscope, Olympus Life Science Solutions, using Magnus Pro Image Analysis software. Slides were investigated to determine congestion, degeneration and necrosis, neovascularization, fibroblast proliferation and epithelialization, oedema and leukocyte infiltration. All the statistical results were analyzed using a two-way ANOVA method followed by Tukey's post-hoc analysis with p ≤ 0.05 considered significant for all values on GraphPad Prism 8.4.3.686.
The research protocol for acute dermal toxicity of bio-inspired gelatin-based adhesive hydrogel in Wistar albino rats as per regulatory guidelines of "OECD 402" for testing of chemicals was carried out at Institute for Industrial Research & Toxicology, Ghaziabad, India, Project No.: 202112-25; Report No.: IIRT/TOX/202112/ADT/0112.
The research protocol for second-degree burn wound healing was approved by the Institutional Animal Ethics Committee (IAEC) of Khalsa College of Pharmacy, Amritsar, Punjab. vide approval no. IAEC/KCP/2020/008.
Suchithra T. V., Benu G, Gelatin-based adhesive hydrogel as wound dressing patch for diverse surfaces. (Application No: 202041044794, Government of India patent office, Status: Filed).
All data generated or analysed during this study are included in this published article.
Zhao, Y. et al. Supramolecular adhesive hydrogels for tissue engineering applications. Chem. Rev. https://doi.org/10.1021/acs.chemrev.1c00815 (2022).
Article PubMed PubMed Central Google Scholar
Li, J. et al. Tough adhesives for diverse wet surfaces. Science https://doi.org/10.1126/science.aah6362 (2017).
Article PubMed PubMed Central Google Scholar
Montazerian, H. et al. Stretchable and bioadhesive gelatin methacryloyl-based hydrogels enabled by in situ dopamine polymerization. ACS Appl. Mater. Interfaces https://doi.org/10.1021/acsami.1c10048 (2021).
Article PubMed Google Scholar
Han, L. et al. Tough, self-healable and tissue-adhesive hydrogel with tunable multifunctionality. NPG Asia Mater. https://doi.org/10.1038/am.2017.33 (2017).
Article Google Scholar
Zhang, W. et al. Catechol-functionalized hydrogels: biomimetic design, adhesion mechanism, and biomedical applications. Chem. Soc. Rev. https://doi.org/10.1039/c9cs00285e (2020).
Article PubMed PubMed Central Google Scholar
Ahmed, E. M. Hydrogel: preparation, characterization, and applications: a review. J. Adv. Res. https://doi.org/10.1016/j.jare.2013.07.006 (2015).
Article PubMed PubMed Central Google Scholar
Verhulsel, M. et al. A review of microfabrication and hydrogel engineering for micro-organs on chips. Biomaterials https://doi.org/10.1016/j.biomaterials.2013.11.021 (2014).
Article PubMed Google Scholar
Ghovvati, M., Baghdasarian, S., Baidya, A., Dhal, J. & Annabi, N. Engineering a highly elastic bioadhesive for sealing soft and dynamic tissues. J. Biomed. Mater. Res. Part B Appl. Biomater. https://doi.org/10.1002/jbm.b.35012 (2022).
Article Google Scholar
Nam, S. & Mooney, D. Polymeric tissue adhesives. Chem. Rev. https://doi.org/10.1021/acs.chemrev.0c00798 (2021).
Article PubMed Google Scholar
Stoica, A. E., Chircov, C. & Grumezescu, A. M. Hydrogel dressings for the treatment of burn wounds: an up-to-date overview. Materials https://doi.org/10.3390/ma13122853 (2020).
Article PubMed PubMed Central Google Scholar
George, B., Bhatia, N. & Suchithra, T. V. Burgeoning hydrogel technology in burn wound care: a comprehensive meta-analysis. Eur. Polymer J. https://doi.org/10.1016/j.eurpolymj.2021.110640 (2021).
Article Google Scholar
Chen, F. M. & Liu, X. Advancing biomaterials of human origin for tissue engineering. Prog. Polym. Sci. https://doi.org/10.1016/j.progpolymsci.2015.02.004 (2016).
Article PubMed Google Scholar
Fauerbach, J. A. et al. Psychological distress after major burn injury. Psychosom. Med. https://doi.org/10.1097/psy.0b013e31806bf393 (2007).
Article PubMed PubMed Central Google Scholar
Quan, W. Y. et al. Mussel-inspired catechol-functionalized hydrogels and their medical applications. Molecules https://doi.org/10.3390/molecules24142586 (2019).
Article PubMed PubMed Central Google Scholar
Sood, A., Granick, M. S. & Tomaselli, N. L. Wound dressings and comparative effectiveness data. Adv. Wound Care https://doi.org/10.1089/wound.2012.0401 (2014).
Article Google Scholar
Andersen, F. A. Amended final report on the safety assessment of polyacrylamide and acrylamide residues in cosmetics 1 polyacrylamide is a polymer of controllable molecular weight. Int. J. Toxicol. 24, 21–50 (2016).
Google Scholar
Smith, E. A. & Oehme, F. W. Acrylamide and polyacrylamide: a review of production, use, environmental fate and neurotoxicity. Rev. Environ. Health https://doi.org/10.1515/REVEH.1991.9.4.215 (1991).
Article PubMed Google Scholar
Baghdasarian, S. et al. Engineering a naturally derived hemostatic sealant for sealing internal organs. Mater. Today Bio https://doi.org/10.1016/j.mtbio.2021.100199 (2022).
Article PubMed Google Scholar
Avella, M. et al. Preparation and characterisation of compatibilised polycaprolactone/starch composites. Polymer (Guildf). 41, 3875–3881 (2000).
Article CAS Google Scholar
Follain, N., Joly, C., Dole, P. & Bliard, C. Properties of starch based blends. Part 2. Influence of poly vinyl alcohol addition and photocrosslinking on starch based materials mechanical properties. Carbohydr. Polym. 60, 185–192 (2005).
Article CAS Google Scholar
Baghaie, S., Khorasani, M. T., Zarrabi, A. & Moshtaghian, J. Wound healing properties of PVA/starch/chitosan hydrogel membranes with nano Zinc oxide as antibacterial wound dressing material. J. Biomater. Sci. Polym. Ed. 28, 2220–2241 (2017).
Article CAS Google Scholar
Singh, N. & Maitra, J. Antibacterial evaluation of starch and chitosan based polymeric blend. IOSR J. Appl. Chem. Ver. I(8), 26–32 (2015).
Google Scholar
Qamruzzaman, M., Ahmed, F. & Mondal, M. I. H. An overview on starch-based sustainable hydrogels: potential applications and aspects. J. Polym. Environ. https://doi.org/10.1007/s10924-021-02180-9 (2022).
Article Google Scholar
Lawrence, M. B., Joseph, J., Usapkar, T. & Azavedo, F. Swelling and dc conductivity behaviour of gelatin-based ferrogels. J. Inorg. Organomet. Polym. Mater. https://doi.org/10.1007/s10904-020-01682-8 (2021).
Article Google Scholar
Saiz-Poseu, J., Mancebo-Aracil, J., Nador, F., Busqué, F. & Ruiz-Molina, D. The chemistry behind catechol-based adhesion. Angew. Chem. 131, 706–725 (2019).
Article ADS Google Scholar
Benedict, S. R. A reagent for the detection of reducing sugars. J. Biol. Chem. https://doi.org/10.1016/s0021-9258(18)91645-5 (2002).
Article PubMed Google Scholar
Zhang, X. et al. A nucleobase-inspired super adhesive hydrogel with desirable mechanical, tough and fatigue resistant properties based on cytosine and ε-caprolactone. Eur. Polym. J. https://doi.org/10.1016/j.eurpolymj.2020.109741 (2020).
Article Google Scholar
Yan, J. et al. Nucleobase-inspired self-adhesive and inherently antibacterial hydrogel for wound dressing. ACS Mater. Lett. https://doi.org/10.1021/acsmaterialslett.0c00304 (2020).
Article Google Scholar
Hassan, A., Niazi, M. B. K., Hussain, A., Farrukh, S. & Ahmad, T. Development of anti-bacterial PVA/starch based hydrogel membrane for wound dressing. J. Polym. Environ. https://doi.org/10.1007/s10924-017-0944-2 (2018).
Article Google Scholar
Horkay, F. Polyelectrolyte gels: a unique class of soft materials. Gels https://doi.org/10.3390/gels7030102 (2021).
Article PubMed PubMed Central Google Scholar
Fansler, R. F., Taheri, P., Cullinane, C., Sabates, B. & Flint, L. M. Polypropylene mesh closure of the complicated abdominal wound. Am. J. Surg. https://doi.org/10.1016/S0002-9610(99)80244-X (1995).
Article PubMed Google Scholar
Pan, H. et al. Preparation and characterization of breathable hemostatic hydrogel dressings and determination of their effects on full-thickness defects. Polymers (Basel) https://doi.org/10.3390/polym9120727 (2017).
Article PubMed Central Google Scholar
Mussbacher, M. et al. Cell type specific roles of NF-κB linking inflamation and thrombosis. Front. Immunol. https://doi.org/10.3389/fimmu.2019.00085 (2019).
Article PubMed PubMed Central Google Scholar
Pawde, S. M. & Deshmukh, K. Characterization of polyvinyl alcohol/gelatin blend hydrogel films for biomedical applications. J. Appl. Polym. Sci. https://doi.org/10.1002/app.28454 (2008).
Article Google Scholar
Li, M., Pan, G., Zhang, H. & Guo, B. Hydrogel adhesives for generalized wound treatment: design and applications. J. Polym. Sci. https://doi.org/10.1002/pol.20210916 (2022).
Article Google Scholar
Mansur, H. S., Sadahira, C. M., Souza, A. N. & Mansur, A. A. P. FTIR spectroscopy characterization of poly (vinyl alcohol) hydrogel with different hydrolysis degree and chemically crosslinked with glutaraldehyde. Mater. Sci. Eng. C https://doi.org/10.1016/j.msec.2007.10.088 (2008).
Article Google Scholar
Abitbol, T., Johnstone, T., Quinn, T. M. & Gray, D. G. Reinforcement with cellulose nanocrystals of poly(vinyl alcohol) hydrogels prepared by cyclic freezing and thawing. Soft Matter https://doi.org/10.1039/c0sm01172j (2011).
Article Google Scholar
Zhang, Y. et al. Preparation and properties of polyacrylamide/polyvinyl alcohol physical double network hydrogel. RSC Adv. https://doi.org/10.1039/C6RA24006B (2016).
Article PubMed Google Scholar
Pal, K., Banthia, A. K. & Majumdar, D. K. Polyvinyl alcohol-gelatin patches of salicylic acid: preparation, characterization and drug release studies. J. Biomater. Appl. https://doi.org/10.1177/0885328206056312 (2006).
Article PubMed Google Scholar
Dash, S., Murthy, P. N., Nath, L. & Chowdhury, P. Kinetic modeling on drug release from controlled drug delivery systems. Acta Pol. Pharm. Drug Res. 67, 217–223 (2010).
CAS Google Scholar
Baishya, H. Application of mathematical models in drug release kinetics of carbidopa and levodopa ER tablets. J. Dev. Drugs https://doi.org/10.4172/2329-6631.1000171 (2017).
Article Google Scholar
Saidi, M., Dabbaghi, A. & Rahmani, S. Swelling and drug delivery kinetics of click-synthesized hydrogels based on various combinations of PEG and star-shaped PCL: influence of network parameters on swelling and release behavior. Polym. Bull. https://doi.org/10.1007/s00289-019-02948-z (2020).
Article Google Scholar
ISO/EN10993–5. ISO 10993–5 Biological evaluation of medical devices - Part 5: tests for cytotoxicity: in vitro methods. Int. Stand. ISO (2009).
Banti, C. & Hadjikakou, S. Evaluation of toxicity with brine shrimp assay. Bio-Protoc. https://doi.org/10.21769/bioprotoc.3895 (2021).
Article PubMed PubMed Central Google Scholar
Wu, C. An important player in brine shrimp lethality bioassay: the solvent. J. Adv. Pharm. Technol. Res. 5, 57–58 (2014).
PubMed PubMed Central Google Scholar
Tomić, S. L., Nikodinović-Runić, J., Vukomanović, M., Babić, M. M. & Vuković, J. S. Novel hydrogel scaffolds based on alginate, gelatin, 2-hydroxyethyl methacrylate, and hydroxyapatite. Polymers (Basel). https://doi.org/10.3390/polym13060932 (2021).
Article PubMed PubMed Central Google Scholar
Prášková, E. et al. Acute toxicity of acetylsalicylic acid to juvenile and embryonic stages of Danio rerio. Neuroendocrinol. Lett. 33, 72–76 (2012).
PubMed Google Scholar
OECD. Test guideline no. 212: fish, short-term toxicity test on embryo and sac-fry stages. Organisation for economic cooperation and development. OECD Publ. (1998).
von Hellfeld, R., Brotzmann, K., Baumann, L., Strecker, R. & Braunbeck, T. Adverse effects in the fish embryo acute toxicity (FET) test: a catalogue of unspecific morphological changes versus more specific effects in zebrafish (Danio rerio) embryos. Environ. Sci. Eur. https://doi.org/10.1186/s12302-020-00398-3 (2020).
Article Google Scholar
OECD. Test no. 402: acute dermal toxicity. OECD Guidel. Test. Chem. (2017).
Liang, C. C., Park, A. Y. & Guan, J. L. In vitro scratch assay: a convenient and inexpensive method for analysis of cell migration in vitro. Nat. Protoc. https://doi.org/10.1038/nprot.2007.30 (2007).
Article PubMed Google Scholar
Yin, G., Wang, Z., Wang, Z. & Wang, X. Topical application of quercetin improves wound healing in pressure ulcer lesions. Exp. Dermatol. https://doi.org/10.1111/exd.13679 (2018).
Article PubMed Google Scholar
Jangde, R., Srivastava, S., Singh, M. R. & Singh, D. In vitro and In vivo characterization of quercetin loaded multiphase hydrogel for wound healing application. Int. J. Biol. Macromol. https://doi.org/10.1016/j.ijbiomac.2018.05.010 (2018).
Article PubMed Google Scholar
Bhatia, N., Kaur, G., Soni, V., Kataria, J. & Dhawan, R. K. Evaluation of the wound healing potential of isoquercetin-based cream on scald burn injury in rats. Burn. Trauma https://doi.org/10.1186/s41038-016-0032-1 (2016).
Article Google Scholar
Mosae Selvakumar, P. Plant-derived compounds for wound healing- a Review. Org. Med. Chem. Int. J. https://doi.org/10.19080/omcij.2018.05.555653 (2018).
Article Google Scholar
Ozcan, O. et al. Protective effect of Myrtle (Myrtus communis) on burn induced skin injury. Burns https://doi.org/10.1016/j.burns.2019.07.015 (2019).
Article PubMed Google Scholar
Kurutas, E. B. The importance of antioxidants which play the role in cellular response against oxidative/nitrosative stress: current state. Nutr. J. https://doi.org/10.1186/s12937-016-0186-5 (2016).
Article PubMed PubMed Central Google Scholar
Kurahashi, T. & Fujii, J. Roles of antioxidative enzymes in wound healing. J. Dev. Biol. https://doi.org/10.3390/jdb3020057 (2015).
Article Google Scholar
Dwivedi, D., Dwivedi, M., Malviya, S. & Singh, V. Evaluation of wound healing, anti-microbial and antioxidant potential of Pongamia pinnata in wistar rats. J. Tradit. Complement. Med. https://doi.org/10.1016/j.jtcme.2015.12.002 (2017).
Article PubMed Google Scholar
Carvalho, L., Jacinto, A. & Matova, N. The Toll/NF-κB signaling pathway is required for epidermal wound repair in Drosophila. Proc. Natl. Acad. Sci. U. S. A. https://doi.org/10.1073/pnas.1408224111 (2014).
Article PubMed PubMed Central Google Scholar
George, B., Suchithra, T. V. & Bhatia, N. Burn injury induces elevated inflammatory traffic: the role of NF-κB. Inflamm. Res. https://doi.org/10.1007/s00011-020-01426-x (2021).
Article PubMed Google Scholar
Van Ostade, X., Tavernier, J., Prange, T. & Fiers, W. Localization of the active site of human tumour necrosis factor (hTNF) by mutational analysis. EMBO J. https://doi.org/10.1002/j.1460-2075.1991.tb08015.x (1991).
Article PubMed PubMed Central Google Scholar
Abazari, M., Ghaffari, A., Rashidzadeh, H., Badeleh, S. M. & Maleki, Y. A systematic review on classification, identification, and healing process of burn wound healing. Int. J. Low. Extrem. Wounds https://doi.org/10.1177/1534734620924857 (2022).
Article PubMed Google Scholar
Jeschke, M. G. et al. Burn injury. Nat. Rev. Dis. Prim. https://doi.org/10.1038/s41572-020-0145-5 (2020).
Article PubMed Google Scholar
Ju, K. Y., Lee, Y., Lee, S., Park, S. B. & Lee, J. K. Bioinspired polymerization of dopamine to generate melanin-like nanoparticles having an excellent free-radical-scavenging property. Biomacromol https://doi.org/10.1021/bm101281b (2011).
Article Google Scholar
Kumar, J., Das, S. & Teoh, S. L. Dietary acrylamide and the risks of developing cancer: facts to ponder. Front. Nutr. https://doi.org/10.3389/fnut.2018.00014 (2018).
Article PubMed PubMed Central Google Scholar
du Sert, N. P. et al. The arrive guidelines 2.0: updated guidelines for reporting animal research. PLoS Biol. 18, (2020).
Nasiri, E. et al. The healing effect of arnebia euchroma ointment versus silver sulfadiazine on burn wounds in rat. World J. Plast. Surg. 4, 134 (2015).
PubMed PubMed Central Google Scholar
Buege, J. A. & Aust, S. D. Microsomal lipid peroxidation. Methods Enzymol. https://doi.org/10.1016/S0076-6879(78)52032-6 (1978).
Article PubMed Google Scholar
Beutler, E. Glutathione in red cell metabolism : A manual of biochemical methods. J. Lab. Clin. Med. (1975).
Aebi, H. E. Catalase in methods of enzymatic analyses. Methods Enzym. Anal. (1983).
Murthy, S. et al. Evaluation of in vivo wound healing activity of Bacopa monniera on different wound model in rats. Biomed. Res. Int. https://doi.org/10.1155/2013/972028 (2013).
Article PubMed PubMed Central Google Scholar
Li, X. Q. et al. Wound-healing activity of Zanthoxylum bungeanum maxim seed oil on experimentally burned rats. Pharmacogn. Mag. https://doi.org/10.4103/pm.pm_211_16 (2017).
Article PubMed PubMed Central Google Scholar
Download references
We would like to acknowledge Animal House Facility, Khalsa College of Pharmacy, Amritsar, India, who opened their doors to us for a collaborative study with School of Biotechnology, National Institute of Technology Calicut, Kozhikode, India. Special thanks to Dr. Madhukar Saxena, Babasaheb Bhimrao Ambedkar University Lucknow, for all the support during the final stage. We would also like to thank Dr. Anugya Bhatt and her team for allowing us to perform toxicity optimization of the hydrogel.
School of Biotechnology, National Institute of Technology Calicut, Kozhikode, India
Benu George & Suchithra T. V.
Department of Pharmacology, Khalsa College of Pharmacy, Amritsar, Punjab, India
Nitish Bhatia & Abhitinder Kumar
School of Medical and Allied Sciences, G. D. Goenka University, Haryana, India
Nitish Bhatia
CSIR-Central Leather Research Institute, Adyar, Chennai, India
Gnanamani A., Thilagam R. & Shanuja S. K.
Division of Biochemistry and Molecular Biology, Department of Zoology, University of Calicut, Kozhikode, India
Kannan Vadakkadath Meethal & Shiji T. M.
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
B.G.: Conceptualization, Validation, Methodology, Investigation, Formal analysis, Writing—original draft; S.T.V.: Methodology, Validation, Supervision, Writing—review and editing; N.B. and A.K.: Methodology, Resources, Formal analysis, Editing; G.R.T. and S.K.S.: Resources, Editing; K.V.M. and S.T.M.: Methodology, Resources, Editing.
Correspondence to Suchithra T. V..
The authors declare no competing interests.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
Reprints and Permissions
George, B., Bhatia, N., Kumar, A. et al. Bioinspired gelatin based sticky hydrogel for diverse surfaces in burn wound care. Sci Rep 12, 13735 (2022). https://doi.org/10.1038/s41598-022-17054-w
Download citation
Received: 12 April 2022
Accepted: 20 July 2022
Published: 12 August 2022
DOI: https://doi.org/10.1038/s41598-022-17054-w
Anyone you share the following link with will be able to read this content:
Sorry, a shareable link is not currently available for this article.
Provided by the Springer Nature SharedIt content-sharing initiative
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.