Inhibitory Effect of Cinnamaldehyde on Main Destructive Microorganisms of Nanhai No. 1 Shipwreck

: Nanhai No. 1, a shipwreck in the Southern Song Dynasty, China, has a history of more than 800 years. It was salvaged in 2007 and is now on display in the Guangdong Maritime Silk Road Museum. Due to the fact that the hull is a wooden cultural relic and exposed to the air, the biological corrosion and biodegradation caused by microorganisms are key problems of hull protection. At present, the antimicrobial agent Euxyl ® K100 (isothiazolinone) has a signiﬁcant antimicrobial effect in the ﬁeld, but it has a certain negative impact on the environment and archeologists. In order to reduce the use of chemical antimicrobial agents, we evaluated the inhibitory effects of cinnamaldehyde on the main destructive microorganisms of Nanhai No. 1. Cinnamaldehyde is the main active component of cinnamon, and has broad-spectrum antimicrobial properties. The paper diffusion method, gas diffusion method and minimum inhibitory concentration experiment were used to detect the inhibitory effects of cinnamaldehyde on the main microorganisms of Nanhai No. 1. We found that cinnamaldehyde had signiﬁcant inhibitory effects on Bacillus tequilensis NK-NH5, Bacillus megaterium NK-NH10, Bacillus velezensis NK-NH11, Bacillus sp. NK-NH15, Bacillus sp. NK-NH16, Bacillus sp. NK-NH17, Fusarium solani NK-NH1 and Scedosporium apiospermum NK.W1-3. At the same time, cinnamaldehyde had more inhibitory effects on fungi than bacteria. Finally, we veriﬁed that cinnamaldehyde can effectively inhibit the growth of microorganisms in water, for storing the scattered wood blocks of the Nanhai No. 1 hull through laboratory simulation experiments. Cinnamaldehyde, as an environment-friendly antimicrobial agent, is of great signiﬁcance to protecting water-saturated wooden relics from microbial corrosion and degradation in the future.


Introduction
Nanhai No. 1, a Chinese Song Dynasty shipwreck, was discovered in 1987 near the Chuanshan archipelago in the South China Sea, Guangdong Province. In 2007, Nanhai No. 1 was salvaged and displayed in "the Crystal Palace" of the Guangdong Maritime Silk Road Museum. In 2012, archaeological excavation was officially started [1], and a large number of precious cultural relics such as gold, silver, bronze, iron, lacquer and porcelain were found in the wreck. The discovery of Nanhai No. 1 wreck is of great significance to Chinese underwater archaeology, and also provides important clues for the study of Maritime Silk Road.
The hull and the cultural relics of Nanhai No.1 are the key protected objects. With the excavation of Nanhai No.1, the exposed area of the hull increases gradually. The cultural relics need to go through the process of desalination, desulfurization and iron removal, so they are soaked in a specific buffer for a long time [2]. Due to the high humidity and high temperature in the storage environment of Nanhai No. 1, and the fact that wooden cultural relics are natural organic matter, this provides suitable conditions for the growth and reproduction of microorganisms [3]. Microorganisms are very harmful to wooden relics. Some bacteria and fungi can destroy wood by degrading cellulose, hemicellulose and lignin. For example, the ability of microorganisms such as Trichoderma viride, Trichoderma reesei, Bacteroides cellulosolvens, Bacteroides succinogenes to degrade cellulose has been reported [4]. This will cause structural and mechanical changes of wooden cultural relics, and cause irreversible impact on precious cultural artifacts [5][6][7].
At present, Euxyl ® K100 is the main antimicrobial agent used in Nanhai No.1 microbial control. Although it can effectively inhibit the growth of microorganisms, it is a little harmful to the environment and human body. Methylchloroisothiazolinone (MCI) and methylisothiazolinone (MI), the main components of Euxyl ® K100, are widely used in cosmetic products [11]. MI and MCI can cause allergic contact dermatitis [12]. At the same time, MI has a certain volatility; it will slowly volatilize into the air, affecting the surrounding environment, and then cause harm to the contacts [13]. Therefore, it is an important task to find environment-friendly and health-friendly antimicrobial agents. Plant-derived antimicrobial agents are relatively safe and friendly to the human body and environment [14,15]. At present, there are many reports that plant-derived antimicrobial agents are used in the actual control of microbial diseases [16]. Our research goal is to apply plant-derived antimicrobial agents to the microbial control of the Nanhai No. 1 shipwreck.
Cinnamaldehyde is the main component of cinnamon essential oil, which is a yellow oily liquid [17]. The antiinflammatory, antioxidation, antiulcer, antibacterial, hypoglycemic and hypolipidemic properties of cinnamaldehyde have been reported [18]. Cinnamaldehyde has been widely used in food, medicine, cosmetics and other fields [19]. Previous studies have shown that cinnamaldehyde has good inhibitory effect on Aspergillus, Fusarium, Penicillium, Rhizopus and other fungi [20][21][22], Escherichia coli, Bacillus subtilis, Staphylococcus spp. and other bacteria [23,24]. In this study, we first tested the cellulose degradation ability of the main destructive microorganisms of Nanhai No. 1, then tested the inhibition effect of cinnamaldehyde on these main destructive microorganisms. In order to play a practical role in the microbial control of Nanhai No. 1, the simulated experiment was performed in the laboratory, and the inhibitory effect of cinnamaldehyde on microorganisms of the wood blocks of Naihai No.1 was evaluated.

Main Destructive Microorganisms of Nanhai No. 1 Shipwreck
In the previous work, we isolated and purified a variety of main destructive microorganisms from the samples of the Nanhai No.1 shipwreck. The details are as follows: Bacillus tequilensis NK-NH5, Bacillus megaterium NK-NH10, Bacillus velezensis NK-NH11 were isolated from the water samples of lacquerware plates [9]. Bacillus sp. NK-NH15, Bacillus sp. NK-NH16, and Bacillus sp. NK-NH17 were isolated from the hull wood and sea mud. Fusarium solani NK-NH1 is a fungus isolated from the wood of the shipwreck. Scedosporium apiospermum NK.W1-3 is a fungus isolated from water samples of wood storage [8,10]. All microorganisms were frozen at −80 • C.

Revitalizing the Microorganisms
The strain was taken out from the refrigerator (−80 • C) and inoculated in Luria Broth (LB) agar medium. After one day's culture at 37 • C, a single colony was selected and inoculated in the new LB agar medium again. The strain was cultured at 37 • C for one day for subsequent experiments; the fungi were inoculated in potato dextrose agar (PDA) medium and cultured at 28 • C for 3 days, then a single colony was selected and inoculated in the new PDA medium again and cultured at 28 • C for 3 days for subsequent experiments.

Determination of Cellulase Activity in Destructive Microorganisms
Two types of carboxylmethylcellulose (CMC) agar media were prepared to evaluate the ability of the microorganisms to degrade cellulose: (1) CMC agar media for bacteria: CMC Na 15.0 g, NaCl 5.0 g, KH 2 PO 4 1.0 g, MgSO 4 0.2 g, peptone 10.0 g, yeast extract 5.0 g, agar 18.0 g, and distilled water 1 L; (2) CMC agar media for fungi: NaNO 3 2 g, K 2 HPO 4 1 g, MgSO 4 0.5 g, KCl 0.5 g, CMC Na 2 g, peptone 2 g, agar 17 g and 1 L distilled water. The bacteria were put into the center of the plate, cultured at 28 • C for 4 days, and then the plate was dyed with 1 g/L Congo red solution. After 15 min, the dye was discarded, then 1 mol/L NaCl solution was added for washing, and 15 min later, the sodium chloride solution was discarded and the colony diameter and transparent circle diameter were determined [25]; a fungal disk with a diameter of 7.5 mm was cut from the edge of the active colony. Then, the disk was transferred to a CMC agar plate, cultured at 28 • C for 4 days, then 5 mL iodine-potassium iodide solution (2.0 g potassium iodide, 1.0 g iodine, 300 mL double distilled water) was added, and incubated in the dark at room temperature for 5 min to determine the colony diameter and transparent circle diameter [26]. According to the ratio of Hyaline circles (H) to colony diameter (D), the cellulase activity of the tested bacteria can be determined preliminarily. The higher the H/D value, the stronger the ability of cellulose degradation. All media were autoclaved at 121 • C for 20 min.

Preparation of Bacterial Culture Suspension and Spore Suspension of Fungi
The bacteria in LB agar medium were inoculated into LB liquid medium and cultured overnight at 180 rpm/min and then the bacterial standard curve was prepared. The final concentration of the bacterial solution was diluted to 10 6 CFU/mL. Then, 5 mL 1/1000 Tween-80 solution was added into the purified single colony plate (fungi), the fungal spores were scraped with a glass rod, the spore solution was filtered out through sterile gauze, the number of spores was detected with a blood cell counting plate, and the final concentration of spore suspension was diluted to 1 × 10 4 CFU/mL. This suspension was used in the subsequent antimicrobial experiment.

Disk Diffusion Experiment
The inhibition of cinnamaldehyde (Rhawn, Shanghai, China) was determined by disk diffusion method. Cinnamaldehyde was dissolved in the mixture of 10/1000 dimethyl sulfoxide (DMSO) and 1/1000 Tween-80 and mixed evenly to make the final concentration of cinnamaldehyde 100 mg/mL and 50 mg/mL respectively. 0.5% Euxyl ® K100 (Schülke, Norderstedt, Germany) was used as the positive control group, and the mixed solution of 10/1000 DMSO and 1/1000 Tween-80 was used as the negative control group. For bacteria, 100 µL bacterial culture solution was added to the LB agar plate and then spread evenly with a glass spreading rod. Four pieces of sterile filter paper with diameters of 7 mm were placed on each plate, then 15 µL of 50 mg/mL cinnamaldehyde, 100 mg/mL cinnamaldehyde, 0.5% Euxyl ® K100, mixed solution of 10/1000 DMSO and 1/1000 Tween-80 were added on the corresponding filter paper sheets. After incubation at 37 • C for 24 h, the size of inhibition zone was observed. The larger the diameter of the inhibition zone was, the stronger the inhibitory effect of the drug on bacteria was. For fungi, 100 µL spore suspension was added to a PDA plate and evenly coated with a sterile cotton swab. A piece of filter paper was placed on each plate and 15 µL drug or mixed solution was dropped.
After being cultured at 28 • C for 3 days, the size of the inhibition zone was observed. All materials (media, cotton swabs, etc.) were autoclaved at 121 • C for 20 min.

Antimicrobial Experiment of Cinnamaldehyde Volatile Gas
The antimicrobial effect of cinnamaldehyde volatile gas was determined by dichotomy plate. LB agar medium (bacteria) or PDA medium (fungi) was poured into one side of a split plate. After the medium solidified, 100 µL bacterial culture suspension or spore suspension of fungi were taken and coated evenly with a sterile cotton swab on one side of the plate. The air concentration of cinnamaldehyde was 250 µL/L when 20 µL cinnamaldehyde was added to the other side and the volume of the 90 mm culture dish was about 80 mL. After 24 h at 37 • C, the inhibition area was observed and the inhibition rate was calculated. Mixed solvents were used as negative control, and Euxyl ® K100 as positive control.

Determination of Minimum Inhibitory Concentration of Cinnamaldehyde
Minimum inhibitory concentration assays were performed in 96 well plates. Cinnamaldehyde and Euxyl ® K100 were diluted by the double dilution method using a mixed solution of 10/1000 (DMSO) and 1/1000 Tween 80. The concentrations of cinnamaldehyde ranged from 0.003125 mg/mL to 2 mg/mL and the concentrations of Euxyl ® K100 ranged from 0.003906 mg/mL to 5 mg/mL. Different concentrations of drugs (50 µL) and bacterial culture suspension or spore suspension of fungi (150 µL) were added to each well. Then, 150 µL bacterial culture suspension/spore suspension and 50 µL mixed with solution of 20/1000 DMSO and 1/1000 Tween-80 were added to the wells as negative control, Euxyl ® K100 as positive control, 150 µL medium and 50 µL mixed solution of 10/1000 DMSO and 1/1000 Tween-80 were added to the wells as blank control. The 96 well plates with fungi were kept at a constant temperature of 28 • C for 36 h, and the 96 well plates with bacteria were kept at a constant temperature of 37 • C for 24 h. At the end of incubation, the growth of microorganisms was determined by measuring the absorbance of each well at 595 nm (fungi)/600 nm (bacteria) with a multifunctional microplate reader, calculating the minimum inhibitory concentration, and each test was done in three replicates.

Laboratory Simulation Experiments
Five pieces of Nanhai No. 1 hull wood samples (length: 3 cm; width: 2 cm; height: 1 cm) were taken and placed in five boxes with volumes of 5 L. Two liters of distilled water was added into each box, and 500 µL of each bacterial culture suspension (Bacillus sp.

Determination of Colony Forming Units(CFU)
At the end of the laboratory simulation experiment, the water samples were stirred well with a glass rod, and 1 mL of water sample was taken out of each box for the determination of the total amount of bacteria. Water samples from each group were subjected to ten-fold gradient dilution to give a final concentration of 10 0 -10 −3 . 100 µL of water samples at each concentration were taken and dropped onto LB agar plates, respectively, and spread well with a sterile coating rod before being incubated for 24 h. Colony forming units were counted. Each concentration was repeated three times.

Quantitative Real-Time PCR
After the laboratory simulation experiment, the water samples in each box were passed through a suction filter device for bacteria collection, the microorganisms were cut off on a 0.22 µM filter membrane, and then DNeasy powersoil Kit (Qiagen, Germany) was employed to extract the total DNA in the water samples. The total biomass of bacteria was determined by qPCR using primers Eub338(5 -ACTCCTACGGGAGGCAGCAG-3 )/Eub518(5 -ATTACCGCGGCTGCTGG-3 ) targeted on the 16S rRNA gene [27]. The standard curve was constructed by drawing the logarithm of the concentration of seven gradient dilutions of genomic DNA and the threshold period (Ct value) produced by qPCR analysis. E. coli genomic DNA was used as the standard template for quantitative detection of bacteria. QPCR was performed in a Step One Plus ™ real-time PCR system using faststart universal SYBR Green master (Rox) (Roche, Switzerland). Each PCR reaction included 1 µL DNA template, 2 µL 10 mM bacterial primers Eub338 / Eub518, 10 µL SYBR green mix, and 7 µL H 2 O for a total of 20 µL. The cycling program consisted of denaturation at 95 • C for 10 min, followed by 40 cycles of 95 • C for 15 s, 54 • C for 30 s, 72 • C for 20 s. Melting curve analysis was established by increasing the temperature from 60 to 95 • C.

Cellulolytic Enzyme Activities of Hull Main Microorganisms
To examine the extent of microbial influence on the hull, we determined the cellulose degrading capacity of these destructive microbes. As shown in Figure 1, all of these strains were able to degrade cellulose to generate degradation circles (H/D: 1.

Determination of Antimicrobial Activity of Cinnamaldehyde by Disc Diffusion Method
To determine the inhibitory activity of cinnamaldehyde against the tested microorganisms, we first employed the disk diffusion method. As shown in Figure 2, different

Determination of Antimicrobial Activity of Cinnamaldehyde by Disc Diffusion Method
To determine the inhibitory activity of cinnamaldehyde against the tested microorganisms, we first employed the disk diffusion method. As shown in Figure 2, different sizes of inhibition zones were all produced around the filter paper sheets containing cinnamaldehyde, which illustrated that, at a certain concentration, cinnamaldehyde had inhibitory activities on the strains to be tested. As the concentration of cinnamaldehyde increased, the more obvious of an inhibitory effect was observed. Cinnamaldehyde at the concentration of 100 mg/mL showed strong inhibitory ability against Bacillus sp. The antimicrobial effect of 100 mg/mL cinnamaldehyde was similar to that of 0.5% Euxyl ® K100. The inhibitory ability of cinnamaldehyde on fungi was stronger than that of bacteria. We found that S. apiospermum (NK.W1-3) was very sensitive to cinnamaldehyde. Cinnamaldehyde of 50 mg/mL could completely inhibit the growth of S. apiospermum (NK.W1-3), but 0.5% Euxyl ® K100 could not.  (50), cinnamaldehyde at concentration of 50 mg/mL; cinnamaldehyde (100), cinnamaldehyde at concentration of 100 mg/mL; Euxyl ® K100, the concentration of Euxyl ® K100 was 0.5%.

Determination of Antimicrobial Activity of Cinnamaldehyde Volatile Gas in Air
To determine the inhibitory activity of cinnamaldehyde volatile gas in air against destructive microorganisms, we completed the experiment using dichotomy plates. As shown in Figure 3, when the volatile gas concentration of cinnamaldehyde is 250 μL/L, cinnamaldehyde exerted antimicrobial activity on all the tested strains, while Euxyl ® K100 did not ( Figure S1). Specifically, cinnamaldehyde exhibited the strongest inhibitory effect against S. apiospermum (NK.W1-3) with an inhibition rate of 100%, and against F. solani (NK-NH1) with an inhibition rate of 45%.

Determination of Antimicrobial Activity of Cinnamaldehyde Volatile Gas in Air
To determine the inhibitory activity of cinnamaldehyde volatile gas in air against destructive microorganisms, we completed the experiment using dichotomy plates. As shown in Figure 3, when the volatile gas concentration of cinnamaldehyde is 250 µL/L, cinnamaldehyde exerted antimicrobial activity on all the tested strains, while Euxyl ® K100 did not ( Figure S1). Specifically, cinnamaldehyde exhibited the strongest inhibitory effect against S. apiospermum (NK.W1-3) with an inhibition rate of 100%, and against F. solani (NK-NH1) with an inhibition rate of 45%.

MIC Determination of Cinnamaldehyde
To compare the inhibitory ability of cinnamaldehyde, the minimum inhibitory co centration of eight destructive microorganisms was measured. As shown in Table  cinnamaldehyde
MIC values of cinnamaldehyde against destructive microorganisms of Nanhai No.1 (mg/mL).  NH11) and B. tequilensis (NK-NH5) was added in the water, then covered and the contact of wood with air was reduced ( Figure S2). After standing for 14 days, the total number of bacteria in the water samples was determined. As shown in Table 2, the total number of bacteria in water samples without cinnamaldehyde was 4.27 × 10 5 ± 2.04 × 10 4 CFU/mL. Cinnamaldehyde could inhibit microbial growth in water, and as the concentration of cinnamaldehyde rose, the number of microorganisms in the water continuously decreased. When the cinnamaldehyde concentration reached the highest value of 1.25 mg/mL, the total number of colonies in the water was 1.2 × 10 1 ± 5.10 CFU/mL. At the same time, the method of qPCR was applied to determine the biomass of bacteria in water samples. The correlation coefficient of the standard curve for E. coli was >0.99. ( Figure 4A). As shown in Figure 4B, the biomass of bacteria showed a decreasing trend with increasing concentrations of cinnamaldehyde. When the concentration of cinnamaldehyde was 1.25 mg/mL, the concentration of bacterial DNA was 1.34 ± 0.09 ng/µL, which was significantly lower than that of the negative control (584.65 ± 52.26 ng/µL). 1.67 × 10 5 ± 9.02 × 10 3 1.2 × 10 4 ± 5.89 × 10 2 5.07 × 10 2 ± 3.86 1.2 × 10 1 ± 5.10

Discussion
The present archaeological digging work of Nanhai No. 1 is close to its end, with the hull chronically exposed to air and with high hull humidity (74.3%), which provides a suitable growth environment for microbial growth. Microorganisms, on the one hand, can affect the aesthetics of cultural relics, and on the other hand can cause harm to the cultural relics themselves. So, in the process of cultural relic protection, the prevention and control of microorganisms is of great significance. Previous studies have found that Nanhai No. 1 is affected by multiple microorganisms. F. solani (NK-NH1) is the major destructive fungus on ship wood, accounting for 90% of the total fungal load on the hull, which presents white plaques [8]. S. apiospermum (NK. W1-3) is a major destructive fun-

Discussion
The present archaeological digging work of Nanhai No. 1 is close to its end, with the hull chronically exposed to air and with high hull humidity (74.3%), which provides a suitable growth environment for microbial growth. Microorganisms, on the one hand, can affect the aesthetics of cultural relics, and on the other hand can cause harm to the cultural relics themselves. So, in the process of cultural relic protection, the prevention and control of microorganisms is of great significance. Previous studies have found that Nanhai No. 1 is affected by multiple microorganisms. F. solani (NK-NH1) is the major destructive fungus on ship wood, accounting for 90% of the total fungal load on the hull, which presents white plaques [8]. S. apiospermum (NK. W1-3) is a major destructive fungus in water samples stored in shipwreck wood. The genus Scedosporium accounted for 72.28% of the total fungi in water samples. B. tequilensis (NK-NH5), B. velezensis (NK-NH11), B. megaterium (NK-NH10) were the main bacteria in water samples storing wooden lacquer plates, Bacillus sp. (NK-NH15), Bacillus sp. (NK-NH16), Bacillus sp. (NK-NH17) were the main harmful bacteria isolated on ship wood. These destructive microorganisms can degrade cellulose and lignin, causing irreversible effects on hulls. Currently, the main measures for controlling microbial degradation of Nanhai No. 1 are to moisturize and inhibit the hulls by spraying them with distilled water containing 0.5% Euxyl ® K100. Although the process can be effective in controlling microbial degradation of the hull, once the use of bacteriostatic agents is discontinued, the microorganism undergoes substantial reproductive growth. At the same time, Euxyl ® K100 was found to cause some negative effects on the archaeological and relic protection workers' bodies. As such, finding safer and more environmentally friendly ways to inhibit these destructive microorganisms is very important. The aim of this study was to investigate the inhibitory activity of cinnamaldehyde against the destructive microorganisms of Nanhai No. 1. We first show that these destructive microorganisms are potentially harmful to hulls. Cellulose degradation experiments found that except for B. velezensis (NK-NH11), other microorganisms to be tested had the ability to degrade cellulose. The prevention and treatment of destructive microorganisms of Nanhai No. 1 should take both fungi and bacteria into account. Meanwhile we determined the antimicrobial activity of cinnamaldehyde. Previous studies have reported that cinnamaldehyde has a broad spectrum of antimicrobial activity [17,19,28,29]. We first preliminarily measured the inhibition of destructive microorganisms of Nanhai No. 1 by the disk diffusion method and found that cinnamaldehyde, at a certain concentration, could effectively inhibit microbial growth, which was comparable to the effects of Euxyl ® K100 at 0.5%. At the same time, we found that fungi were more sensitive to cinnamaldehyde. Taking into account the volatile properties of cinnamaldehyde, we measured the inhibition effect of cinnamaldehyde volatile gas in air. Similarly to the paper disk diffusion method results, airborne cinnamaldehyde can effectively inhibit microbial growth, although the inhibition effect is more obvious on fungi. Cinnamaldehyde, through its volatile properties, exerts antimicrobial ability, which can be used on the inhibition of destructive microorganisms of cultural relics in practical work. This provided us with ideas for the future practical application of cinnamaldehyde in the protection of cultural relics, and cinnamaldehyde can be slowly released in a closed vessel to achieve the effect of sustained antimicrobial activity. Edible films containing cinnamaldehyde have been reported to be effective in inhibiting Salmonella on vegetables sealed plastic bags [30]. In the results of MIC, cinnamaldehyde showed obvious antimicrobial activity, but lower than Euxyl ® K100. For the antimicrobial mechanism of cinnamaldehyde has been intensively studied, and it has been reported that cinnamaldehyde can cause changes in the fatty acids of cell membranes and alter its structure, thus prompting the binding of cinnamaldehyde or other compounds to cells [31]. It also provides ideas for our later experiments: through the combined use of multiple antimicrobial agents, so as to achieve the effect of reducing the hazard and improving the drug efficacy.
The antimicrobial activity of cinnamaldehyde has been largely evaluated in laboratory experiments, while it is also widely used in the food industry [32]. The ability of antimicrobial agents against microorganisms is closely related to the host, the environment, and so on. To evaluate the feasibility of cinnamaldehyde application for microbial degradation control in Nanhai No. 1, we simulated the protection status of the scattered wood of Nanhai No. 1 and added Cinnamaldehyde to observe its bacteriostatic effect. The results showed that cinnamaldehyde could inhibit the growth of bacteria in water, and the concentration of bacteria in water decreased as the concentration of cinnamaldehyde increased. When the concentration of cinnamaldehyde is 0.5 mg/mL, it can inhibit the reproduction of most bacteria. The application of cinnamaldehyde to the protection of wooden cultural relics in water will provide a new way to develop environmentally friendly, safe and inexpensive bacteriostatic agents of plant origin in the future. In the following work, we will pay more attention to the practical use and effect of cinnamaldehyde in field protection, and the combined use of cinnamaldehyde with other antimicrobial agents is also of interest. In this study, cinnamaldehyde was found to inhibit the main destructive fungi of Nanhai No. 1, which is comparable to the Euxyl ® K100 effect used for conservation on-site and also has some inhibitory activity against bacteria. Cinnamaldehyde not only showed antimicrobial ability in laboratory experiments, but also effectively inhibited the reproductive growth of bacteria in simulated experiments, indicating that cinnamaldehyde has a promising application in the prevention and control of cultural relic biodegradation.
Supplementary Materials: The following are available online at https://www.mdpi.com/article/10 .3390/app11115262/s1, Figure S1: Microbial growth on the dichotomy plate, Figure S2: The state of shipwreck hull scattered wood in water tank. Table S1: Molecular identification of strains isolated from the hull, sea mud.