Synthesis of Carboxymethyl Chitosan-Capped Gold Nanoparticles by Gamma Irradiation with Novel Potential Applications as Antioxidant, Hepatoprotective, and Anticancer Substance

Gold nanoparticles capped by carboxymethyl chitosan (AuNPs/CM-chitosan) with particle sizes of 5.2 – 7.3nm were successfully synthesized by the γ -irradiation of Au 3+ solutions. Their characteristics were analysed by transmission electron microscope images, powder X-ray di ﬀ raction patterns, UV-visible spectroscopy, and Fourier transform infrared spectra. The antioxidant activity of AuNP/CM-chitosan was time dependent and much higher than that of ascorbic acid at the same concentration. On the other hand, the results of tail vein injection of AuNP/CM-chitosan in mice indicated that this product was not toxic to mice and that AuNPs were mainly distributed in liver tissue, at approximately 77.5%, 6 h after injection. The hepatoprotective activity of AuNP/CM-chitosan was also tested in acetaminophen-induced hepatotoxic mice by oral administration at daily doses of 0.5 – 2mg/head. The results indicated that compared to the control, supplementation with 2 mg of AuNPs/head strongly reduced the aspartate aminotransferase and alanine aminotransferase indexes in the blood of the tested mice by approximately 66.5 and 69.3%, respectively. Furthermore, the MTT (3[4,5 dimetylthiazol-2-yl]-2,5-diphenyltetrazol bromide) assay on a liver cancer cell line (HepG2) clearly con ﬁ rmed strong anticancer activity on HepG2 cells treated with 0.05 – 0.5 mM AuNPs and the tested cells did not survive after treatment with 0.5mM AuNPs, while the growth of the normal cell line (L929) has no signi ﬁ cant e ﬀ ect at the same treated concentration of AuNPs. The AuNP/CM-chitosan in the present study was synthesized by the γ -irradiation method without using any toxic-reducing chemical and stabilized in a natural biocompatible polymer. The strong antioxidant, hepatoprotective, and anticancer e ﬀ ects of this product may be supported to be used in the biomedical ﬁ eld.


Introduction
Recently, AuNPs have attracted increased attention and demonstrated promising effects and benefits in biosensor, bioimaging, and biomedical applications such as disease therapeutics, diagnostics, photothermal therapy, targeted delivery, and cancer treatment [1].It has been shown that AuNPs can absorb light and transfer the absorbed light into thermal energy; therefore, AuNPs conjugated to cancer cells are heated by laser pulses, which can be used as a new and efficient method for the treatment of tumours [2].AuNPs have been attached to epidermal growth factor receptor antibodies to help them adhere strongly to cancer cells and then kill them without affecting normal cells [3].In addition, AuNPs can be used in some methods to eliminate tumours in a short time [4].Moreover, AuNPs were proven to possess the ability to increase the production of hepatocytes when they were denatured in association with cysteamine and added to the culture medium of liver cells [5].
There are several methods for the fabrication of AuNPs, such as radiolytic, chemical [6,7], physical [8], and biological methods [9][10][11].Among these methods, gamma ray irradiation was reported to be effective with several advantages.First, the reactions are carried out under normal conditions with high efficiency and synthesized AuNPs are highly pure and lack contamination by excessive chemical reductants and Au 3+ ion residue.The size of AuNPs is easily controlled by varying the Au 3+ ion or stabilizer concentration.Furthermore, the gamma ray irradiation method can be favourably applied on a large scale and the production process meets the requirements for clean production [12][13][14].
To date, AuNPs have been synthesized by radiation techniques using various polysaccharides for stabilization, such as dextran [15], hyaluronate [16], chitosan [13,17], and alginate [12,18].Carboxymethyl chitosan (CM-chitosan), a derivative of chitosan, is a water-soluble and biocompatible polymer.This polymer possesses modulated physical and biological properties, such as sorption, moisture retention, cell function, antioxidant, antibacterial, and antiapoptotic activities.This polymer has also been used for controlled release drug delivery, pH-responsive drug delivery, and DNA delivery as a permeation enhancer [19].Therefore, CM-chitosan is attracting increasing interest for use in applications in the biomedical and pharmaceutical fields [20].Although CM-chitosan was reported to have several unique biological properties and has been used for stabilizing AuNPs synthesized by chemical reduction, heating, or UV-light irradiation methods [21][22][23][24], research on the synthesis of AuNPs by gamma irradiation using CM-chitosan as a stabilizer has not been carried out thus far.
The aim of the present study was at applying γ-ray (Co-60) irradiation techniques to synthesize AuNPs stabilized in CM-chitosan and to investigate their antioxidant, hepatoprotective, and anticancer activities for application as a special hepatoprotective and anticancer material.

Synthesis of Gold Nanoparticles by γ-Ray Irradiation.
Colloidal AuNPs with different concentrations of 0.5, 1.0, and 1.5 mM stabilized in 0.5% CM-chitosan were prepared as follows: a stock solution of 10 mM [Au 3+ ] was added to a 2% CM-chitosan solution at an appropriate ratio with deionized water and then stirred for 10 min before adjusting the pH to 7 by 1 M NaOH.Subsequently, 200 ml of prepared [Au 3+ ]/CM-chitosan solution was placed into a glass bottle with a plastic cap and irradiated at 2-10 kGy by a gamma Co-60 source (model gamma cell GC-5000, Brit, India) at the Biotechnology Center of Ho Chi Minh City with a dose rate of 10 kGy/h.

Transmission Electron Microscope
Images.The transmission electron microscope (TEM) images of AuNP samples were characterized by a JEM 1400 transmission electron microscope (TEM) (JEOL, Japan).The particle sizes and size distribution of AuNP images were determined by statistical calculation from approximately 300 particles following methods described elsewhere [25][26][27].
2.5.FTIR Measurement.Fourier transform infrared (FTIR) spectra of CM-chitosan and AuNP/CM-chitosan samples were obtained at ambient temperature using a Shimadzu FTIR-8100A spectrophotometer linked with a Shimadzu DR-8030 computer system.Samples were prepared in a KBr tablet formed by well-dried mixtures containing samples and KBr.All obtained spectra were the result of 128 scans at a resolution of 4 cm −1 in a wavelength range between 4000 and 400 cm −1 [21].
2.6.X-Ray Diffraction.Powder X-ray diffraction (XRD) patterns were collected at room temperature on an X'Pert PRO powder diffractometer (model XRD D8 Advance ECO, Bruker, Germany) with parafocusing Bragg-Brentano geometry using CuKα radiation (λθ = 1:5418 Å, U = 40 kV, and I = 30 mA).Data were scanned with the ultrafast detector X'Celerator or with a scintillator detector equipped with a secondary curved monochromator over the angular range of 5-60 °(2θ) with a step size of 0.02 °(2θ) and a counting time of 0.3 s step −1 .Data were evaluated by the software package HighScore Plus [16,21].
2.7.Antioxidant Activity Test.The antioxidant activity of AuNP/CM-chitosan was investigated by using the free radical ABTS.ABTS •+ solution was prepared by mixing an equal volume of 7 mM K 2 S 2 O 8 solution with 2.45 mM ABTS solution.The solution was kept in the dark for 16 hours at room temperature.Then, the ABTS •+ solution was diluted with distilled water to obtain an optical density (OD) value of approximately 0.7 at 734 nm.To determine the antioxidant 2 Journal of Nanomaterials activity of AuNPs, 2.7 ml of ABTS Au 3+ 0,25 mM CMC 0,5% Au 3+ 0,5 mM CMC 0,5% Au 3+ 1 mM CMC 0,5%  administered acetaminophen at a dose of 2000 mg/kg body weight following the method described by Das et al. [32].After 24 h of APAP administration, 0.5 ml of blood from the myocardium of the tested mice was collected and placed into tubes containing heparin for analysis.The collected blood was then centrifuged at 4500 × g for 10 min to separate the serum [33].The obtained serum was used to analyse aspartate aminotransferase (AST) and alanine aminotransferase (ALT) indexes on a Beckman Coulter Au480 analyser (USA).The net changes in these indexes were the average mean difference in the blood of mice before and after administration of deionized water or AuNPs.

Analysis of the Cytotoxicity of AuNP/CM-Chitosan on
HepG2 and L929 Cells.MTT assays were performed with concentrations of AuNPs up to 0.5 mM to evaluate the in vitro cytotoxicity of liver cancer (HepG2) and mouse fibroblast (L929) cell lines.HepG2 and L929 cells were cultured in DMEM (Dulbecco's modified Eagle medium) containing 10% foetal bovine serum (FBS), 1% penicillin, and streptomycin at 37 °C and 5% CO 2 [34].Tested cells were plated in 96-well plates at a concentration of approximately 2 × 10 4 cells/well and incubated for 24 h.Consequently, cells were treated with 0.05-0.5 mM AuNPs at 37 °C for 48 h in a 5% CO 2 incubator.After removal of the treated medium, the cells in each well were carefully washed with PBS (pH 7.4)  and incubated with 50 μl of MTT (0.4 mg/ml in PBS) for 4 h at 37 °C and 5% CO 2 .Finally, the medium was discarded before adding 100 μl of DMSO to each well to dissolve crystals.Spectrophotometrical absorbance of the purple blue formazan dye was measured by an ELISA (enzyme-linked immunosorbent assay) microplate reader at a wavelength of 570 nm (model VERSAMAX, Molecular Devices, USA).The sample without any cells served as a blank, and the toxic effect of samples on the proliferation of treated cells was determined and compared with the blank.The percentage survival of cells was determined by equation ( 1) as follows: where ODs and ODblank are the absorbance of the test sample and blank sample, respectively [34,35].
All tests in mice were conducted according to the ethical guidelines for animal research of the Institute of Malariology Parasitology and Entomology in Ho Chi Minh City, Ministry of Health of Vietnam, and followed the rules of the Declaration of Helsinki.All experiments were carried out in triplicate, and data were statistically analysed using the analysis of variance (ANOVA) test.The mean values were compared using Duncan's multiple range test with the least significant difference (LSD) at a probability level of 5%.

Radiation Synthesis and Characterization of AuNPs
Capped by CM-Chitosan.The dose for radiation synthesis of AuNPs has been reported by Diem et al. [15].These authors indicated that the required dose for completely reducing 1 mM [Au 3+ ] in Au 3+ /dextran solution by gamma-ray irradiation was 6 kGy.Sun et al. [23] also informed that CM-chitosan at a concentration of 0.3-0.45%could be used as dual roles of the reducing agent and stabilizer for synthesizing AuNPs, while Ibrahim et al. [24] successfully prepared electrospun nanofibers containing AuNPs using 2% CM-chitosan.In this study, solutions with different concentrations of 0.5, 1.0, and 1.5 mM [Au 3+ ] stabilized in 0.5% CM-chitosan were irradiated by gamma-rays at doses in the range of 2-10 kGy for the synthesis of AuNPs.The results in Figure 1 show that after irradiation, the solutions containing 0.5, 1.0, and 1.5 mM [Au 3+ ] changed to a purple-red colour with optical extinction peaks (λ max ) at 507-526 nm (Figure 2 and Table 1).The visually changing colour is due to the characteristic surface plasmon resonance band of AuNPs after synthesis from Au 3+ ions by irradiation [23,24,36,37].The results in Figure 2 and Table 1 also indicate that the optical extinction band intensities (OD values) of solutions containing 0.5, 1.0, and 1.5 mM [Au 3+ ] reached maximal values at irradiation doses of 4, 6, and 8 kGy, respectively.These results are in good agreement with those reported by Diem et al. [15] on the dose for completely reducing [Au 3+ ] into AuNPs by gamma-ray irradiation.
Using other natural polymer such as dextran and hyaluronate, Hien et al. [16] and Diem et al. [15] successfully prepared AuNPs with particles below 10 nm.In the present study, TEM images and corresponding histograms of parti-cle size distributions of AuNPs in Figure 3 also showed that the AuNPs synthesized by irradiation were almost spherical.The average particle sizes of the AuNP products were found to slightly increase from 5.2 to 7.3 nm with an increasing [Au 3+ ] concentration from 0.5 to 1.5 mM.
FTIR analysis was also carried out to investigate the role of CM-chitosan in the stabilization of AuNPs.It can be seen clearly in Figure 5 that in the spectra of CM-chitosan, peaks appeared at 3371, 1599, 1414, 1324, and 1064 cm −1 assigned to O-H, C=O, N-H, N-H 2 , and C-O-C linkages, respectively [21,24].In the spectra of AuNPs stabilized in CM-chitosan, the peaks at 3370, 1601, and 1416 cm −1 were shifted to longer wavelengths of 3367, 1600, and 1415 cm −1 , respectively.According to Huang et al. [21], these results may indicate the formation of a coordination bond between AuNPs and nitrogen/oxygen atoms in the CM-chitosan molecule.

Antioxidant Activity of AuNPs/CM-Chitosan. Duy et al.
[13] evaluated antioxidant activity of AuNPs stabilized in water-soluble chitosan with different particle sizes by free radical cation ABTS •+ scavenging method.The authors claimed that the antioxidant activity increased with the The antioxidant activity of AuNP/CM-chitosan with a particle size of approximately 7.3 nm was also investigated by using the free radical ABTS method, and the obtained results in Figure 6 show that the antioxidant activity of AuNPs increased with increasing AuNP concentration.Figure 6 clearly shows that the antioxidant activities of AuNPs also increased with increasing reaction time.The reason may be due to the crystalline face-centered cubic structure of AuNPs consisting of several gold molecules, and the reaction only occurred on the surface of the particle; therefore, it may take time for all gold molecules in the nanoparticles to completely interact with free radicals [43].This result suggests a good option for the in vivo application of AuNPs as antioxidant agents, especially by oral supplementation, because it will take time for AuNPs to be taken up into the blood and liver.Esumi et al. [44] reported that the antioxidant activity of AuNPs was approximately 80-fold higher than that of ascorbic acid.In this study, Figure 7 shows that the antioxidant activities after reaction of AuNPs for 72 h at concentrations ranging from 0.00625 to 0.05 mM were much higher than those of ascorbic acid at the same concentration.Since the capped chitosan derivative also contributed to the antioxidant activity, its activity was rather low compared to that of AuNP itself [13].Therefore, the high-antioxidant activity of the AuNP/CM-chitosan may due to the small size (about 7.3 nm) of product particles.These results are in good agreement with those reported by Duy et al. [13].

In Vivo Distribution of AuNPs/CM-Chitosan in Mice.
Luan et al. [12] reported that AuNPs stabilized in alginate with an average particle size of about 20 nm synthesized by gamma Co-60 irradiation were not toxic to mice at an injected dose of approximately 33.3 mg/kg body weight and the AuNP/alginate product could potentially be applied as an X-ray contrast agent, especially for the blood and liver.In this study, AuNP/CM-chitosan prepared by irradiation was injected into mice via the tail vein and the distribution in various organs was investigated to understand the in vivo distribution of this AuNP product.After injection, the content of AuNPs in the blood, liver, kidney, and lung tissues of mice was analysed at 1, 3, 6, 9, and 12 h postinjection.The results in Figure 8 indicated that in blood tissue, the AuNP content decreased with postinjection time and almost disappeared at 6 h postinjection (0.004 mg/g tissue).Figure 8 also shows that 1 h after injection, AuNPs started penetrating into the liver, kidney, and lung tissues and were mainly concentrated in the liver and lung tissue 6 h after injection.In particular, the gold content in liver tissue was approximately 0.775 mg/g tissue (comprising approximately 77.5% of the injected dose), while the content in lung tissue was approximately 0.075 mg/g tissue (approximately 7.5% of the injected dose).The gold content in kidney tissue was quite low (0.018 mg mg/g tissue, comprising only approximately 1.8% of the injected dose) compared to those in liver and lung tissues.Twelve hours after injection, the gold content in liver tissue was reduced to 0.467 mg/g tissue (comprising approximately 46.7% of the injected dose), while this content was almost unchanged in lung (0.076 mg/g  Journal of Nanomaterials tissue) and kidney tissues (0.012 mg/g tissue).It can also be seen in Figure 8 that after injection, AuNPs were transferred from blood tissue into other organs and mostly accumulated in the liver and lung, with maximal accumulation found at 6 h post injection.A kinetic study was performed by Jong et al. [45] to determine the influence of the particle size on the in vivo tissue distribution of spherical-shaped AuNPs in the rat.They concluded that AuNPs with a size about 10 nm in aqueous solution concentrated mainly in the liver at 24 h after intravenous injection.In addition, Luan et al. [12] also reported that AuNPs/alginate with a particle size about 20 nm penetrated with 76.33% in the liver of mice at 6 h post injection.It seems that the in vivo distribution of AuNPs was affected by its particle size.In the present study, AuNPs with a size about 7.3 nm were used and the obtained results are in good agreement with those of previous reports [12,45].These results also suggest the appropriate application of AuNPs as hepatoprotective and liver anticancer agents.
3.4.The In Vivo Hepatoprotective Activity of AuNP/CM-Chitosan in Mice.Wang et al. [46] reported that AuNPs with particle sizes in the range of 5-70 nm were not toxic to human skin cells.In addition, the results from Pokharkar et al. [47] indicated that the LD 50 value for oral administration of AuNPs stabilized in chitosan in rats was more than 2000 mg/kg.These authors concluded that AuNPs/chitosan produced no toxicity in rats and could be exploited for potential therapeutic applications.Furthermore, a study on the in vivo toxicity of 15 nm AuNPs capped by bovine serum albumin (BSA) via tail vein injection by Nghiem et al. [48] also proved that the tail vein injection of AuNPs at a dose up to 5.84 mg/kg did not cause any mortality or gross behavioural changes in tested mice.On the other hand, Negahdary et al. [49] demonstrated that AuNPs with a particle size of approximately 10 nm reduced the CAT and GPX indexes in Wistar mice.The hepatoprotective activity of AuNP/CM-chitosan was also tested in Swiss mice by oral supplementation with a daily dose from 0.5 to 2.0 mg of AuNPs/head.The AST and ALT indexes in the blood of the tested mice were analysed after 7 days of daily supplementation.The effect of AuNPs on the AST index in the blood of mice is shown in Figure 9.After 7 days of supplementation with AuNPs at concentrations of 0.5-2.0mg/head, the AST index in the blood of both normal mice and APAP-induced hepatotoxic mice was decreased.7

Journal of Nanomaterials
The results in Figure 9 show that AST indexes in the blood of normal mice and the APAP-induced hepatotoxic group were in the ranges of 107.5-157.6U/L and 115.3-344.4U/L (Figure 9(a)), respectively.The reduction in this index was found to be directly proportional to the supplemented concentration of AuNPs.In the normal group, the maximum reduction in AST was found in the blood of only approximately 31.7% of mice supplemented with a daily dose of 2 mg of AuNPs/head.The maximum reduction in this index in the blood of APAP-induced hepatotoxic mice supple-mented with 2 mg of AuNPs/head was approximately 66.5% (compared to the APAP-induced hepatotoxic mice supplemented with only distilled water).In the blood of mice supplemented with silymarin (positive control mice), the net change in the AST index was found to be similar to that of mice supplemented with 0.5-1 mg of AuNPs/head (Figure 9(b)).
On the other hand, the oral administration of AuNP products lowered the AST index in the blood of both the normal and APAP-induced hepatotoxic groups  (Figure 10(a)).For the normal group, AuNP supplementation with daily doses of 0.5-2 mg per mouse reduced the AST index by approximately 29.1-51.6%(compared to that in the blood of control mice) (Figure 10(b)).The net change in this index in the blood of mice supplemented with silymarin (the positive control) was only 15%.In the case of APAP-induced hepatotoxic groups, the results from Figure 10(b) also showed that oral supplementation with AuNPs at daily doses of 0.5-2 mg/head reduced the ALT index to 57.7-69.3%.The net change in ALT in the blood of positive control mice supplemented with silymarin was similar to that in the blood of mice supplemented with 0.5-1.0mg/head but far lower than that in the blood of mice orally administered a daily dose of 2 mg/head.It can be seen clearly in Figures 6-8 that the AuNPs stabilized in CMchitosan and synthesized by gamma Co-60 irradiation displayed strong antioxidant activity and the in vivo distribution of this product was mainly in liver tissue.These results may be the main reason for the reduction in the AST and ALT indexes in the blood of the tested mice.

In Vitro Cytotoxicity of AuNP/CM-Chitosan on Liver
Cancer (HepG2) and Mouse Fibroblast (L929) Cell Lines.Biosynthesized AuNPs have been reported to have cytotoxic effects on various cancer cell lines, such as PA1 (human ovarian cancer cell line), MCF7 (breast cancer cell line), A549 (lung cancer cell line), and HepG2 [50][51][52].Even so, the cytotoxicity of AuNPs synthesized by gamma irradiation on cancer cell lines is still limited.In the present study, the anticancer activity of AuNPs was tested in vitro using the HepG2 cell line.The anticancer activity of AuNP/CM-chitosan against the HepG2 cell line was carried out at concentrations in the range of 0.05-0.5 mM.In the MTT assay, the anticancer effect of AuNP concentration on HepG2 cell lines was evaluated via the cell viability percentage.Figure 11 shows that the viability of HepG2 cells was decreased by increasing the AuNP concentration.This means that the anticancer activity of AuNPs against HepG2 cells was directly proportional to the concentration of the AuNP product.Compared to the control (without AuNP treatment), the survival rates of HepG2 cells were decreased from 57.9 to 12.2% by treatment with AuNPs at concentrations ranging from 0.05 to 0.2 mM.The viability of this cell line was only approximately 5.9% after the addition of 0.25 mM AuNPs.After treatment with 0.5 mM AuNPs, HepG2 cells did not survive.AuNPs have reported to show a significant inhibition on the growth of HepG2 cells at the concentration of 50-250 mg/l [50,51].Li et al. [34] demonstrated that AuNPs stabilized in plant-based extract strongly inhibited the viability of HepG2 liver carcinoma cells at the concentration of 50-100 mg/l.The treatment of this AuNP product to HepG2 cells reduced the expressions of antiapoptotic proteins (Bcl-XL and Bcl-2) and improved the expressions of proapoptotic protein (Bax, caspase-3, and caspase-9).While 9 Journal of Nanomaterials Lopez-Chaves et al. [53] reported that the deleterious effect of AuNPs on HepG2 cells was due to reactive oxygen species (ROS) production and DNA damage.The authors also mentioned that the smaller size of AuNPs could induce a stronger cytotoxicity effect on the HepG2 cell line.Our results are in good agreement with those reported in previous papers [34,50,51,53].
On the other hand, the cytotoxicity of AuNPs were also evaluated on normal cells including L929 cell line mouse fibroblast [54,55].Pattanayak et al. [54] informed that AuNPs capped with β-D glucan did not exhibit any cytotoxicity on normal cell (mouse fibroblast L929 cell line) at the treated concentration unto 1000 mg/l.Raju et al. [55] also reported that the treatment of the L929 cell line with 1.1-1% AuNPs capped with citrate had no effect on the growth and viability of treated cells.In this study, the cytotoxicity of AuNP/CN-chitosan was also tested on the L929 cell line.The results in Figure 12 indicate that the cell viability of the normal cell line was significantly decreased by the treated AuNP concentration from 0.01 to 0.25 mM.However, the L929 cell viability decreased to 54.5% at the treated AuNP concentration of 0.5 mM.These results clearly revealed that AuNP/CN-chitosan synthesized by the γ-irradiation method had a low cytotoxicity effect in normal cell.

Conclusions
AuNPs with particle sizes of 5.3 -7.2 nm capped in CMchitosan were successfully synthesized by the γ-irradiation method.The antioxidant activity of AuNP/CM-chitosan prepared by radiation was much stronger than that of ascorbic acid at the same concentration.The intravenous administration test indicated that the AuNP/CM-chitosan product was not toxic to mice and AuNPs were mainly distributed in liver tissue (approximately 77.5%) after injection.The oral administration trial with a daily dose of 2 mg/head for mice also confirmed a strong reduction effect of AuNP/CM-chitosan on the AST (66.5%) and ALT (69.3%) indexes in APAPinduced hepatotoxicity.Additionally, the present study clearly showed strong anticancer activity of AuNPs on the HepG2 cell line and the tested liver cancer cells could not survive treatment with 0.5 mM AuNPs.While the treatment of this product at concentrations up to 0.5 mM did not show any significant inhibition on the growth of normal cell line (mouse fibroblast L929 cell).The radiationsynthesized AuNP/CM-chitosan product may potentially be used as an antioxidant, hepatoprotective, and liver anticancer agent in nutraceutical food production, cosmetics, and/or biomedicine.

Figure 8 :Figure 9 :
Figure 8: The in vivo accumulation content (a) and distribution ratio (b) of AuNPs (d~7.3 nm) in different tissues of mice after intravenous injection with a dose of 1 mg of AuNPs per mouse.

Figure 10 :Figure 11 :
Figure 10: ALT index (a) and the net change in this index (b) in the blood of tested mice after 7 days of oral administration of AuNPs at various daily doses.

was recorded at 734 nm after 1 to 72 h. The efficiency of free radical capture was calculated based on the research of Huang et al. [28], and ascorbic acid was used as the ref- erence [29, 30].
•+ solution was added to 0.3 ml of AuNP colloidal solution.The OD of the samples 2 ml of AuNP/CM-chitosan solution containing 0.5-2.0mg of AuNPs/head once daily for 7 days.The control mice received only distilled water, while the positive control mice were supplied with silymarin at a daily dose of 2 mg/head.On day 8, all mice in the APAPinduced hepatotoxic group were orally intravenously