Biogenic Synthesis of Gold Nanoparticles from Physalis peruviana and Application in Wound Healing

Wound management is key to healing. Poorly managed wounds lead to abnormal biological reactions and complications. Microorganisms, bacteria or fungi, infect such wounds leading to their chronic nature. Gold nanoparticles (Au NPs) show wound healing properties. In addition, ethnobotanical information from Siaya County in Kenya shows the leaves of Physalis peruviana L. to be eective in wound management. A combination of Au NPs and leave extracts of Physalis peruviana L. through a one pot biogenic synthesis leads to a new eective wound management substance. e synthesis was done at room temperature 25°C and at 85°C.e UV-visible spectroscopy results show ecient sharper plasmon bands with a blue shift indicating a decrease in λmax compared to red shift which show an increase in λ max. e surface plasmon resonance is a sharper at wavelength of about 540 nm. Dynamic light scattering and zeta potential analysis show that the polydispersity index is high and this is attributed to heterogeneity of chemical components of the plants. Transmission electronmicroscopy results for Au NPs show similarity in their shapes and sizes with grain size boundaries of between 1 nm and 100 nm.e particles are spherically shaped and crystalline with small lattice due to the small grains. e gold nanoparticles synthesized from Physalis peruviana show antimicrobial activities against gram-positive bacteria and, gram-negative bacteria as well as gram-positive fungus. e inhibition zones for Au NPs of dierent concentrations vary signicantly between concentrations (one-way ANOVA at P< 0.05). e highest antibacterial activity is at 100mM of Au NPs against Escherichia coli, Bacillus subtilis, and Staphylococcus aureus. e inhibition zones for Au NPs at concentration of 100mMand Physalis peruviana extract vary signicantly in all themicrobial cells, except for Pseudomonas aeruginosa (one-way ANOVA, F(3,11) 2.67, P 0.1189). Application of the Au NPs in wound healing is faster than controls. e Au NPs also have good biocompatibility as signs of infection were not present.


Introduction
e human skin is considered key to our survival: sensing the environment; maintaining physicochemical and thermal homeostasis: being a reservoir of essential nutrients; providing passive and active defense; responding to trauma and injury, etc. [1]. When the skin is injured, it results into a wound. Management of wounds has been a challenge to mankind.
ere are two speci c types of wounds: chronic and acute wounds [2]. Chronic wounds are considered silently epidemic and possess serious threat towards public health and global economy [3]. ey do not heal within a predictable period of time, leading to further complications due to infections and di culty in healing [4]. Examples of such wounds include diabetic ulcers, vascular ulcers, and pressure ulcers. For the case of acute wounds, they are caused by incisions and are with patients who pass through surgical treatments, traumas, abrasions, or epithelial burns [5].
Wounds are susceptible to infection due to breakage of cutaneous barrier that protects the underlying tissue against microorganisms such as S. aureus, P. aeruginosa, E. coli, and Streptococci [6].
e extent of infection depends on the degree of pathogenicity of the invading organisms and the ability of the host to defend itself [4]. e healing process is divided into four important phases; coagulation (haemostasis), inflammation, proliferation (granulation), and remodelling (maturation) [7].
Wound dressings containing plant extract with antimicrobial compounds can be applied in order to control wound infections. Wound infections can be caused by planktonic bacteria, biofilms, and fungus. It is essential to determine whether the plant extract loaded wound dressing has an effect on these species or not [8]. Wound therapy has moved from drying out the wound bed to maintaining a balanced moist environment [9]. Traditional dressings involve absorbing wound exudate and this made the wound to develop a crust on its surface with remarkable scarring. is has since been replaced by modern dressings which aim at improving healing by handling wound fluid in a way that prevents accumulation of excess exudate while maintaining a certain degree of moisture, and thereby enhancing the chance of obtaining new skin tissue without scarring [10].
ere has been a constant search for methods and materials which can help in reducing the quantity of scar tissue and, ultimately, its remodelling and hence a great progress in the preparation of engineered nanoparticles for different biological applications [11]. is has made researchers to exploit biological synthesis of nanoparticles using plant extracts [12][13][14]. e importance of gold nanoparticles (Au NPs) ranges from chemical stability, capacity to absorb infrared light, ease of synthesis and applications in wound therapy [15]. Several polymeric, lipid-based, ceramic, inorganic, metal, and metal oxide nanomaterials have been widely investigated for cutaneous wound healing [16]. According to a research study by Arafa and El-Kased [17], the surface plasmon resonance is tuned to make the Au NP gels gain thermo responsiveness, and this improves the NP antibacterial and healing properties, both in-vitro and in-vivo, a fact backed by histopathologic examinations [17].
Gold NPs can either directly target the bacterial cell wall or can bind to bacterial DNA, blocking the double-helix from uncoiling during replication or transcription, thus exerting bactericidal and bacteriostatic properties. As a result, they can inhibit multidrug-resistant pathogens, such as S. aureus and P. aeruginosa. Moreover, Au NPs prevent the formation of reactive oxygen species, thus acting as antioxidants, aiding the healing process [18]. A study on ex vivo permeation showed that gold NPs can also be used in the therapy of burns, being able to promote healing and inhibit microbial colonization, while being transdermally active [17]. It has been reported that interaction of inorganic nanoparticles and gold nanoparticles for this matter with microorganisms may exhibit antibacterial and antifungal activity [19]. e gold nanoparticles exhibit strong cytotoxicity to varied microorganisms; the interaction with various surface-exposed functional groups present on the bacterial cell surface may lead to bacterium destruction and inactivation. is activity may either be as a result of coating on the Au NPs surface or to reaction contaminants left over from the manufacturing approach rather than the Au NPs cores [20].

Material and Methods
Hydrochloric acid, sodium hydroxide, and hydrogen tetrachloroaurate (III) were purchased from Sigma-Aldrich, South Africa. Autoclaved distilled water was used throughout the experiments. Eppendorf tubes of 1.5 mL were used for optimization. e ethical review number at Jaramogi Oginga Odinga University of Science and Technology is ERC/29/4/22-25 with a subsequent research permit from the National Commission for Science, Technology and Innovation, Kenya identification license number: NACOSTI/P/22/18037 (see support information file). e recommended small animal handling certificate by the ethical review committee was done at the Jomo Kenyatta University of Agriculture and Technology (support information file).

Collection of Plant Materials.
Plant materials, Physalis peruviana L. (see Figure 1), used for the study were collected from Gem Subcounty which is located in Siaya County in Kenya. Siaya County lies between latitude 0°26′ and 0°18′ north and longitude 33°58′ east and 34°33′ east [21]. e climate of the study area is heavily influenced by its geographical location and altitude relative to the Lake Victoria.
e study area stands in the upper eastern flanks of Lake Victoria, therefore benefiting from the convergence of the easterlies and lake winds. e samples were taken from April to end of July at different places within a radius of 100 meters in 2019. Leaves from these plants were harvested and kept in brown paper envelopes for transportation to the laboratory.

Synthesis and Characterization of Au NPs.
Synthesis and characterization of gold nanoparticles were done according to Kumar et al. [22]. ey are described fully in the support information. Synthesis was done for 1 hour both at room temperature (25°C). Colour changes were observed whereby a ruby red or a red wine colour was desired. e 96-well plate was used to determine the absorbance for the reaction. An efficient surface plasma resonance (SPR) was studied based on the peaks obtained using ultraviolet-visible spectroscope (Polar Star Omega, BMG LABTECH GmbH, 77656, Ortenberg, Germany). is informed the choice of synthesis conditions for the gold nanoparticles.

Characterization Studies.
Ultraviolet-visible spectroscopy (UV-Vis) was performed using UV-visible spectrophotometer (Polar Star Omega, BMG LABTECH GmbH, 77656, Ortenberg/Germany) in a range of 400-700 nm. e studies of size and morphology of the nanoparticles were performed using transmission electron spectroscopy (TEM) in the Physics Department, University of Western Cape, and surface area electron dispersion (SAED) using FEI Tecnai G2 20 field-emission gun. Samples for TEM studies were prepared by placing drops of the Au NPs on carbon-coated TEM copper grids. Dynamic light scattering (DLS) was used to determine the zeta potential of the synthesized Au NPs. e hydrodynamic diameter of the Au NPs was calculated by the Stokes-Einstein equation in which water was used as a continuous phase. e polydispersity index (PDI) measured the molecular mass distribution of the synthesized nanoparticles.

In-Vitro Studies of Gold Nanoparticles.
e interaction between gold nanoparticles against various kinds of pathogenic microorganisms was studied. e experimental studies involved the measurements of the mortality constant rate for various gram-negative and gram-positive bacterial strains from the American Type Culture Collection (ATCC) as well as fungal strains; E. coli (ATCC, 10536), P. aeruginosa, C. albicans, and B. subtilis (ATCC, 6538). e agar solution was incubated for 24 hours at 37°C after sterilization. e inhibition zone was measured after 24 hours of incubation by the disc diffusion method that was performed on Mueller-Hinton agar. To ensure reproducibility, the experiment was repeated three times. e minimum inhibitory concentration (MIC) and the minimum bactericidal concentration (MBC) were also obtained using E. coli (ATCC, 8739), E. faecalis, S. aureus (ATCC, 6538), and S. saprophyticus in nutrient agar medium after 24 hours of incubation [23].

Inoculation of Microorganism.
e nutrient agar medium was prepared by dissolving 28 g of nutrient agar in 1000 mL of hot distilled water and allowed to cool. e mixture was then sterilized by autoclaving at 120°C for about 15 min at 15 psi pressure and cooled to 50°C [23]. e medium was dispensed into Petri-dishes to yield a depth of 4 mm and isolated colonies were aseptically transferred to nutrient broth in the Petri-dishes and incubated at 37°C for 24 hours so as to mimic human body temperature since the bacteria that were used are human pathogens.

Sample Preparation.
Minimum inhibitory concentration (MIC) of Au NPs for various concentrations (range: 100-0.01 mM) was tested [23]. Disks of 6 mm were placed in solutions of gold nanoparticles prepared from different concentrations of gold salt. e disks were screened for anti-E. coli, anti-S. aureus, anti-P. aeruginosa, anti-C. albicans, and anti-B. subtilis activities by using disc diffusion method in Botany Department, J.K.U.A.T [23]. Inoculum suspension (108 CFU/Ml) was spread over the nutrient agar surface by sterile collection swab and 6 mm disc was sterilized at 120°C for about 15 min and then loaded with gentamycin (10 mg/mL) each as positive controls. e films were placed onto the surface of inoculated plates with flamed forceps. e plates were labeled and incubated at 37°C for 24 hours for 2-3 days. e zone of inhibition (ZOI) was measured using a ruler in millimeters around the disc as low activity (1-6 mm), moderate activity (7-10 mm), high activity (11-15 mm), very high activity (16 and above), and no activity (0) [24].

In-Vitro Disc Diffusion Antimicrobial Assays.
e interaction between gold nanoparticles against various kinds of microorganisms was studied using disc diffusion assays.
e experimental studies were focused on the measurements of the mortality constant rate for E. coli (ATCC, 10536), S. aureus (ATCC, 6538), P. aeruginosa, C. albicans, and B. subtilis. e agar solution was incubated for 24 h at 37°C after sterilization [25]. e zones of inhibition were measured after incubation of 6 mm disk impregnated with Au NPs for 24 h on Mueller-Hinton agar. To ensure reproducibility, the experiments were carried out three times and the zones of inhibition reported as the mean ± standard deviation. e minimum inhibitory concentrations (MIC) were obtained using Au NPs prepared using different concentrations [25].

In-Vivo Wound Healing Studies.
To evaluate the wound healing properties of Au NPs, a nude rabbit with no hair on the skin was used [7]. (Training in small animal handling was done at JKUAT in collaboration with JICA). Using a cotton swab, part of the back was scrubbed off by rubbing a depilatory on the epidermis of the skin and incising a wound 2 cm in length using a scalpel blade.
is procedure was carefully carried out to avoid damaging the subcutaneous tissue under the dermis. Before placing the bandage on the prepared wound, the Au NPs were applied on the sterile cotton swabs by deep coating the gauze in the nanoparticle's solution for 1 hr followed by drying in an oven set at 50°C to constant weight. e Au NP coated gauze was then stuck on the wounded part and the healing condition was observed for 14 days [26].

Results and Discussion
Temperature, time, pH, and concentration of the plant extracts as well as concentration ratio of the gold salt to the plant extracts were optimized. e concentration of hydrogen tetrachloroaurate (III) was 1 mM. Aqueous leaf extract of Physalis peruviana was used for optimization and synthesis.
e formation of the ruby red colour was an indication that synthesis had taken place. 3.1. Au Nanoparticle Synthesis. Synthesis of Au NPs to determine the optimum ratio of the gold salt to the plant extract was done with 1 mM HAuCl 4 , for the duration of 60 minutes at varied ratio of hydrogen tetrachloroaurate (III) and the aqueous leaf extract of the plant. Choice of 1 mM was from a similar study that optimized synthesis parameters and found that 1 mM concentration of HAuCl 4 was suitable for biogenic synthesis [27]. e formation of the ruby red colour was attributed to successful synthesis of Au NPs because of the presence of polyphenolic content and radical scavenging ability of the plant extract [28]. e phenolic compounds present in polyphenols serve as both reducing and capping agents by forming complexes with the metal ions, reducing them to nanoparticles of diverse sizes and morphologies [29][30][31].
e change in colour of the solution was observed within 20-30 min and the reaction was allowed to proceed for 60 minutes. e UV-Vis spectroscope was further used to characterise the synthesized gold nanoparticles. e UV-Vis spectra revealed the presence of the SPR band of the Au NPs at a wavelength of approximately 540 nm. Transmission electron spectroscopy (TEM) was further used to confirm the analysis by UV-Vis spectroscopy which suggested that the biogenically synthesized Au NPs were likely to be anisotropic in shape as well as size.

Au Nanoparticle Characterization.
Characterization was done on the synthesized Au NPs using UV-Vis spectroscopy at room temperature ( Figure 1). It was also used to estimate the size, shape, and concentration of the Au NPs by observing their optical intensity through the surface plasmon resonance (SPR) effect which gives rise to an absorption band at a wavelength ranging from 400 to 700 nm [32]. e surface plasmon resonance wavelength of Au NPs is mainly dependent on the size of individual Au NPs and the aggregation state of the Au NPs [33]. e UV-Vis spectra of the Au NPs are affected by various factors including the size, shape, and concentration of the nanoparticle [34]. e standard SPR of gold is between wavelengths 500-550 nm [35]. e UV-Vis spectra revealed the presence of the SPR band of the Au NPs at approximately 540 nm. is is in agreement with previous research [36,37]. e presence of the SPR band was as a result of collective oscillations of the free electrons caused by an interacting electromagnetic field in metallic NPs [38]. e synthesis of Au NPs at room temperature (25°C) with a 2 : 1 ratio of hydrochloroauric acid trihydrate to the plant extract was observed to provide efficient sharper plasmon bands with a blue shift (indicated by decrease in λ max) compared to the synthesis at higher concentration ratio showing values as well as higher concentration of plant extract compared to the gold salt, leading to a red shift (indicated by increase in λ max). Higher concentrations show concentration values leading to instability of the Au NPs and this may have affected capping agents and hence formation of less anisotropic Au NPs.
is temperature dependent correlation was also reported in various other studies [39,40] while the effect of concentration on size of particles was also reported in other studies [41]. Further optimization showed that plant concentration of 17.5 mg/ml and pH of 9 were more viable for synthesis. However, in another study, pH 7, 8, and 12 showed characteristic absorption during biogenic synthesis of gold nanoparticles [42]. is reaction was timed for 1 hr and synthesis took 50 minutes to reach a completion. Similar synthesis reactions took 120 to 150 mins though some syntheses would take as low as 10 minutes [42]. Other than room temperature synthesis, another synthesis was also carried out with temperature ranging between 25°C and 85°C.
Temperature of 85°C was found to be the most viable for the synthesis within the selected temperature range (Figure 2(b)). UV-visible spectroscopy is used to estimate the size, shape. And concentration of the Au NPs by observing their optical intensity through the SPR effect which gives rise to an absorption band at a wavelength ranging from 400 to 700 nm [32]. e Beer-Lambert law is applied where a beam of monochromatic light is passed through a solution of an absorbing substance and the intensity of radiation monitored. e rate of decrease of intensity of radiation with thickness of the absorbing solution is proportional to the incident radiation and the concentration of the solution.
e resultant Au NPs from the optimum concentrations of Physalis peruviana L. plant extracts were chosen for further study and their UV-Vis spectra results provided. e UV-Vis spectra of the Au NPs are affected by various factors including the size, shape, and concentration of the nanoparticle [34].
Synthesis at low temperatures may favour synthesis unlike in high temperatures.
is could be due to the unique properties of the phytochemicals present in the plant, which react differently with the gold salt under the specific conditions. Moreover, it could also be postulated that the sensitive phytochemicals could be destructed by some heat which affects the synthesis of Au NPs. Higher temperature is believed to alter the interaction of phytochemicals with the nanoparticle surface, thereby inhibiting incorporation of adjacent nanoparticles into the structure of nanoribbons. Furthermore, in some situations, higher temperatures may facilitate the nucleation process to the detriment of the secondary reduction process and further condensation of a metal on the surface of nascent nanoparticles [43].
Dynamic light scattering (DLS) and zeta potential showed that the PDI was high and this may be attributed to the heterogeneity of the chemical components of the plants. Figure 3 shows the size distribution histogram by intensity from zeta potential for synthesized Au NPs using Physalis peruviana plant extract at room temperature.
It is observed from the histogram that the highest single peak is between 10 nm and 100 nm. is shows that after reaching a peak point, the scattering light intensity actually decreases. Some of the laser light is absorbed or scattered by the sample before the beam reaches the scattering volume, thereby decreasing the laser intensity at the scattering volume and reducing the amount of light available for scattering in the scattering volume. Likewise, light scattered from the scattering volume is absorbed or rescattered by the medium on the way to the detector, thereby also decreasing the amount of scattered light reaching the detector [44].
Transmission electron microscopy as technique is used to show the morphology and the shape of the synthesized nanoparticles. In this research study, spherical shapes are more dominant with room temperature synthesis. ere is a diversity in the geometrical shapes of green synthesized Au NPs [40,45]. e anisotropic nature of the synthesized Au NPs as shown by TEM confirms the analysis done by UV-Vis which suggested that the Au NPs synthesized from Physalis peruviana plant extract are likely to be anisotropic in shape and size. Figure 4 shows the TEM images and the SAED for room temperature synthesis, i.e., Figures 4(a) and 4(b), as well as synthesis at 85°C, i.e., Figures 4(c) and 4(d), respectively.
e Au NPs are porous and have a hollow structure. e grain boundaries are of size 10 nm. e smaller the grains, many pores could lead to large surface area. e particles are also crystalline and the small lattice is due to the small grains. Room temperature synthesis resulted in spherical-shaped Transmission electron microscopy image for synthesis at temperature of 85°C showed that the particles synthesized are generally spherical-shaped, porous, and polycrystalline materials. e particle size was generally 5 nm in size. e SAED showed that the particles are polycrystalline considering that the diffraction is given in concentric circles.

Antimicrobial Activity of the Biogenic Au Nanoparticles.
Antimicrobial activities of Au NPs from Physalis peruviana were studied for their antimicrobial activities as well as wound management. is was done to determine inhibition zones for gram-positive bacteria (S. aureus and B. subtilis) and gram-negative bacteria (E. coli and P. aeruginosa) as well as gram-positive fungus (C. albicans).

Analysis of the Microbial Activities.
e analysis of the microbial activities was studied by determining the inhibition zones for the aqueous green gold nanoparticles. is was compared to those of the selected standard antibiotics. Table 1 shows minimum inhibition zones for aqueous green gold nanoparticles at different concentrations.
As the concentration of Au NPs increased, antimicrobial activity also increased due to a subsequent increase in interaction between Au NPs and the microbial cell wall. is may be attributed to generation of reactive oxygen species (ROS) [18]. Gold nanoparticles are usually not bactericidal at low concentrations but show higher bactericidal properties at relatively high concentrations [46,47]. is may be attributed to the effect of coexisting chemicals, such as gold ions, surface coating agents, and chemicals involved in the synthesis that were not completely removed [46,47]. In a study, higher concentration of CuO nanoparticles was required for a bactericidal effect to be achieved [48]. e antibacterial mechanism of Au NPs was associated to (i) the collapse in the membrane potential, hindering ATPase activity causing a deterioration of the cell metabolism and (ii) hindering the binding subunit of the ribosome to tRNA [49], and (iii) Shamaila et al. showed that Au NPs may affect the bacterial respiratory chain by attacking nicotinamide [50].
Comparison was also made between minimum inhibition zones using Au NPs at the concentration of 100 mM and that of aqueous Physalis peruviana extract. Table 2 shows the comparison of minimum inhibition zones of aqueous Au NPs at 100 mM with the aqueous Physalis peruviana extract. From Table 2, it is evident that the minimum inhibition zones varied significantly.
Gold nanoparticles can exert antibacterial activity through a multitude of mechanisms.
is includes direct interaction of the Au NPs with the bacterial cell wall. e Au NPs inhibit respiratory enzymes such as cytochrome oxidases, malate, and succinate dehydrogenases. It has been reported that nanoparticles are capable of holding fast onto the bacterial cell membrane followed by penetration into the cytoplasm. Once in the cytoplasm, the Au + transverses via the ion channels leading to the ribosomes, in effect it leads to the death of cells as a result of denaturing and suppression of enzymes/proteins needed to produce energy.
e Au + present in the nanoparticles are also capable of interacting with phosphorus and sulphur present in both DNA and RNA leading to the disruption of DNA and RNA functions as reported [51]. e Au NPs may also inhibit the formation of biofilm, triggers innate as well as adaptive host immune responses, generates reactive oxygen species, and induces interactions of the Au NPs with DNA and/or proteins. e fact that the mechanism of action of Au NPs against bacteria is different from known standards, they can be of great usefulness against multidrug-resistant (MDR) bacteria [35,52]. Table 3 shows inhibition zones for standard antibiotics compared to Au NPs. e antimicrobial activity of Au NPs against E. coli was comparable to those of amoxyclav, nitrofurantoin, nalidixic acid, gentamicin, sulphamethoxazole and ceftriaxone. However, when compared to norfloxacin and ofloxacin, its antimicrobial activity was lower but its antifungal activity was significantly higher or comparable to sulphamethoxazole and ofloxacin. As observed in Table 3, the microorganism under study demonstrated a significant level of resistance to the standards used in this study at the tested concentration. is activity was concentration dependent as when the nanoparticles were prepared using hydrochloroauric acid trihydrate of 100 mM, the activity was higher as more Au NPs were generated. As the concentration of Au NPs increased, antimicrobial activity increased due to a subsequent increase in interaction between Au NPs and the microbial cell wall due to generation of reactive oxygen species [18,53]. Figure 5(a) shows the zones of inhibition of Au NP solution; Figure 5(b) shows the zones of inhibition for antibiotic standards, respectively.

In-Vivo Wound Healing Studies.
e ability of Au NP coated sterile wound gauze to promote wound healing was evaluated using nude rabbits. Figure 6 shows macroscopic appearance of experimental wounds at various time intervals after surgery. e rate of wound healing using Au NP coated sterile cotton gauze was faster as compared to the control cotton gauze and this trend was observed from the third day after application of the dressings on the wound area. On the 6 th day, re-epithelization in animals dressed with Au NP coated cotton gauze had already begun, while in the control group, hematoceles could still be observed. On the 14 th day, both the control group and the animals coated with Au NPs were observed to be completely healed which implies that Au NPs had good biocompatibility as signs of infection were not present. In addition, we had hypothesized that the antimicrobial activity of Au NPs effectively prevented the proliferation of microorganisms which accelerated tissue regeneration and healing.
Wound treated with the cotton gauze with Au NPs did not show the evidence of pus accumulation, fibrin deposition, polymorphonuclear cells infiltration, or edema in the lesions of the animal, but were seen in control and basal ointment groups as was observed in another study [54]. Accumulation and overactivation of lymphocytes, macrophages, and neutrophils in the wound site and their extreme secretion produced pus in the wound which reduced the healing process. Further, as reported elsewhere, the presence of free radicals may increase the amount of pus [54,55]. e wound healed within the first 15 days and that is similar to the results in another study on wound healing using metal nanoparticles [56]. Endogenous collagen matrix may have supported tissue regeneration [57].
Mechanistically, in wound healing, Au NPs may adhere to the surface of bacterial cells by electrostatic interaction in the form of metallic gold which causes impairment of cell membrane, leakage of cell contents, and production of reactive oxygen species (ROS) [58]. Moreover, gold ions released may also tend to bind to thiol (sulfhydryl) groups of cellular lipoproteins to interfere with the respiratory chain and generate ROS [59]. In aerobic life of an organism, reactive oxygen species (ROS) are never welcome. ese partial or activated derivatives of oxygen (singlet oxygen ( 1 O 2 ), superoxide anion (O 2 -), hydrogen peroxide (H 2 O 2 ) and hydroxyl radical (HO)) are highly reactive and toxic, possible of causing oxidative destruction of cell components [60]. e effectiveness of ROS in damaging, as a protective or signaling factor, depends on the delicate equilibrium between ROS production and scavenging at the proper site of the cell and time [61]. When the rate of generation of ROS overweighs the rate at which ROS is scavenging, it leads to a harmful imbalance in the antioxidative system of the cell.
is imbalance (often called as oxidative burst) results in widespread damage in cells including peroxidation of membrane lipids, oxidative damage to vital biomolecules such as nucleic acids and proteins, and also the activation of   aureus. e inhibition zones for Au NPs of different concentrations varied significantly between concentrations (one-way ANOVA at P < 0.05). e Au NPs showed antimicrobial activities at different concentrations with the mean inhibitory zone diameter of 16-19 mm in E. coli, 9-11 mm against P. aeruginosa, 12-17 mm against C. albicans, 14-17 mm against B. subtilis, and 12-17 mm against S. aureus. is activity was concentration-dependent and the inhibition zones against the microbes increased significantly with concentration, except for P. aeruginosa with minimum inhibition zone of 9 mm. e highest antibacterial activity was at 100 mM of Au NPs against EC, BS, and SA. e Au NPs were also effective against fungal infection based on the inhibition zone of C. albicans (17 mm).   (3,11) � 2.67, P � 0.0306), and S. aureus (F (3,11) � 2.67, P � 0001) which was highly significant. Antimicrobial activity exhibited by the Au NPs was significantly higher than that of the aqueous extract, implying that there was enhanced activity, as a result of incorporation of the gold ions. 8 Journal of Chemistry programmed cell death (PCD) pathway probably making it possible for the NPs to initiate membrane lipid peroxidation. Consequently, the disintegration of membranes then facilitates the entrance of metals and NPs. However, as reported by [59], changes, including collagen content, epithelial thickness, and related growth factors, cannot be determined by the external phase.

Conclusion
In this study, aqueous leaf extract of Physalis peruviana was found to successfully synthesize gold nanoparticles at room temperature as well as at varied temperatures (25°C to 85°C). e synthesized Au NPs, DLS, and zeta potential analysis showed that the polydispersity index was high and this was attributed to the heterogeneity of the chemical components of the plants.
e Au NPs synthesized from Physalis peruviana plant extract were likely to be anisotropic in shape and size.
is was shown from the UV-Vis spectra and confirmed by the TEM images obtained. e Au NPs are porous and have a hollow structure. e grain boundaries are of size 10 nm. e particles are also crystalline and the small lattice is due to the small grains. e gold nanoparticles have been found to have a higher antibacterial and antifungal activity compared to plant extract. Study on the wound healing efficacy of the plant was also positive with the incision healing within 14 days showing positivity towards wound management by the biogenically synthesized gold nanoparticles.
Data Availability e authors confirm that the data supporting the findings of the study are available within the article. Raw data that support the findings of the study are available from corresponding author upon request.  Figure 6: Macroscopic appearance of wounds at various time intervals. CD1, CD3, CD6, and CD9 show experimental wound appearances for control, on day one, three, six, and nine, respectively. AuNPD1, AuNPD3, AuNPD6, and AuNPD9 show wound appearance when treated with Au NPs on day one, three, six, and nine, respectively.

Conflicts of Interest
e authors declare no conflicts of interest.