Isolation and purification of polysaccharide

The polysaccharide fraction was extracted from RG by water extraction and alcohol precipitation. Then the crude RGP was obtained after removal of proteins and small molecules with a yield of 18.46%. Afterwards, RGP-1 (water fractions) was isolated from RGP by DEAE-52 column (Fig. 1A). RGP-1 was further separated by Sephadex G-100 column (Fig. 1B) and a homogeneous polysaccharide (RGP1-1) was obtained. The carbohydrate content of RGP1-1 was 95.68% according to the determination by the phenol–sulfuric acid assay. The UV scanning spectrum at 200–400 nm showed that the polysaccharide had no absorption at 280 nm and 260 nm, indicating absence of protein.

Fig. 1

Separation and characterization of RGP1-1. A Chromatogram of the crude RGP on DEAE-52 cellulose column; B Gel filtration chromatograms of RGP1-1; C HPGPC chromatograms of RGP1-1; D Chromatograms of monosaccharide compositions (a PMP derivative of monosaccharide reference substances; b PMP derivated of RGP1-1 sample; 1-Man, 2-Rib, 3-Rha, 4-GlcA, 5-GalA, 6-NAG, 7-Glc, 8-NAGA, 9-Gal, 10-Xyl, 11-Ara, 12-Fuc); E Fourier transform infrared spectrum of RGP1-1

Structural characterization of polysaccharide fractionsMolecular weight and monosaccharide composition analysis

As shown in Fig. 1C, the chromatogram of RGP1-1 was a symmetrical signal peak which indicating the RGP1-1 was homogeneous, and the molecular weight was 5655 Da according to the calibration curve obtained from a series dextran. As shown in Fig. 1D, standard monosaccharides PMP derivatives was separated within 50 min by HPLC. The monosaccharide composition analysis indicated that RGP1-1 was composed of Glc and Gal in the ratio of 94.26:4.92. Sun et al. reported a red ginseng polysaccharide was composed of Gal, Glc and Ara with the molar ratio of 3:95.3:1.3 [31]. And it indicated the Glc was dominant sectors in RG purified polysaccharides. In addition, the different in composition may be caused by raw materials and purified methods.

FT-IR analysis

As shown in Fig. 1E, the infrared spectra obtained a typical and strong wide stretching peak at 3389.43 cm−1 for O–H stretching vibration, an absorption peak at 2945.45 cm−1 was caused by the telescopic vibration of the C–H stretching vibration of –CH2– [32]. The absorption peak at 1417.85 cm−1 was caused by the variable-angle vibration peak of C-H [33]. The characteristic absorption band in the 1000–1200 cm−1 region might be caused by the stretching vibration of C–O–C of glycosidic structures [34]. The absorption peaks a 1078.36 cm−1 indicated a pyranose form of sugar [35]. Furthermore, the peak at 891.74 cm−1 was caused by α-d-glycosidic bonds. These results indicated that RGP1-1 was possessed typical absorption peaks of polysaccharides.

Glycosidic linkages analysis

The fully methylation product of RGP1-1 was hydrolyzed and acetylated for GC–MS analysis. The peaks of total ions chromatography (TIC) were identified by compared with standard PMAA spectra patterns and other literatures (Additional file 1: Fig. S1). The methylation analysis of each linkage patterns and the molar ratio of sugar residues were shown in Table 1. The methylation results shown that RGP1-1 contained four different glycosidic linkages T-Linked-Glcp, 1,4-Linked-Glcp, 1,4,6-Linked-Glcp and 1,4-Linked-Galp in the approximate ratio of 31.7:31.6:30.5:4.9. The ratio of these residues was accord with monosaccharide composition of RGP1-1. Furthermore, the molar ratio of branching point and terminal units was 1.03. And it was consistent with the fact that the number of terminal units is roughly equal to the number of branching points. Based on above results, the structure of RGP1-1 may be recognized as a branched polysaccharide, and the backbone was mostly composed of → 1)-Glcp-(4 → and → 1)-Galp-(4 → repeating units and amounts of → 1)-α-D-Glcp-(4 →, T-linked-D-Glcp branches.

Table 1 The methylation results of RGP1-1NMR analysis

NMR was applied to characterize the precise structure of RGP1-1 (Fig. 2 and Table 2) according to the NMR spectra and data of previous study [36].

Fig. 2

NMR spectra of RGP1-1. A 1H spectrum; B 13C spectrum; C 1H-1H COSY spectrum; D HSQC spectrum; E HMBC spectrum

Table 2 1H and 13C NMR chemical shifts of RGP1-1

In the 1H NMR spectrum (Fig. 2A), four anomeric protons were distinguished at 5.31, 4.87, 5.13 and 4.55 ppm which were corresponded to H-1of A, B, C and D respectively. The chemical shifts of anomeric protons were attributed to α-pyranose forms. In the 13C NMR spectrum (Fig. 2B), the main anomeric carbon signals were at 99.76, 98.70, 91.88 and 95.88 ppm corresponding to C-1 of residue A, B, C and D, which were within the range of 93–105 ppm [37]. It also indicated that four sugar residues were contained in RGP1-1. In the heteronuclear singular quantum correlation (HSQC) spectrum (Fig. 2D), the cross-peaks of 5.31/99.76, 4.87/98.70, 5.13/91.88 and 4.55/95.88 ppm appeared in the anomeric region which were assigned to A-1, B-1, C-1 and D-1 respectively, and the data were also consistent with 1H and 13C NMR spectra. The other C/H chemical shifts of all monosaccharide residues in RGP1-1were assigned (Table 2) according to the above results, 2D NMR spectra and data of previous study [38,39,40].

Residue A, B and C was attributed as α-1,4-Glcp, β-T-Glcp and α-1,4,6-Glcp on account of the anomeric shifts. The scales of anomeric C and H combined with the literatures indicated the 5.31/99.76 ppm chemical shift belongs to β-T-Glcp residue, the 4.87/98.70 ppm chemical shift belongs to α-1,4-Glcp residue and the 5.13/91.88 ppm chemical shift belongs to α-1,4,6-Glcp residue, and this assignment was also consistent with monosaccharide composition. Compared with previous studies, the other chemical shift signals were obtained from 1H-1H Cosy, HSQC and heteronuclear multiple bond correlation (HMBC) [41, 42]. The cross peaks of 5.31/3.51(H-1/H-2), 3.51/3.75(H-2/H-3), 3.75/3.60(H-3/H-4), 3.60/3.79(H-4/H-5), 3.79/3.85(H-5/H-6) in β-T-Glcp residue, the cross peaks of 4.87/3.55(H-1/H-2), 3.55/3.74(H-2/H-3), 3.74/3.57(H-3/H-4), 3.57/3.78(H-4/H-5), 3.78/3.76(H-5/H-6) in α-1,4-Glcp residue, 5.13/3.59(H-1/H-2), 3.59/3.62(H-2/H-3), 3.62/3.87(H-3/H-4), 3.87/3.57(H-4/H-5), 3.57/3.75(H-5/H-6) in α-1,4,6-Glcp residue were detected in 1H-1H homonuclear chemical shift correlation spectroscopy (COSY) spectrum (Fig. 2C). According to the chemical shift of residue H-1 and the HSQC spectrum (Fig. 2D), the chemical shifts of C-2 to C-6 of residue can be obtained, and they were also identified in 13C spectrum. The C-1 and C-4 chemical shift of α-1,4-Glcp residue were 99.76 ppm and 72.86 ppm respectively, the signals migrated to low-field which proved the possible link sites. The signal shifts of C-4 (δ 76.69 ppm) and C-6 (δ 71.16 ppm) of α-1,4,6-Glcp residue migrated to low-field which demonstrated C-4 and C-6 may be the substitute site, and it was consistent with the results of methylation analysis.

Residue D was assigned to be β-1,4-Galp according to the literature [43] and the chemical shifts of anomeric region signal appeared at 4.55/95.88 ppm (H1/C1) (Fig. 2). And it indicated that residue D was in β configuration. The rest carbon and proton signals were distributed as 3.58/71.66, 3.66/72.68, 4.03/77.59, 3.96/71.75 and 3.71/60.91 corresponded to H2/C2, H3/C3, H4/C4, H5/C5 and H6/C6d from HSQC spectra. In addition, down-field signal at C-4 (77.59 ppm) indicated that there was a group attached to the C-4 position of residue D, which was consistent with the methylation results.

The connection sequence between residues can be judged from the HMBC spectrum (Fig. 2F), owing to there are cross peaks between residues and within residues. The anomeric carbon signal at 5.31 ppm of residue A has a correlation peak with its C-4 (72.86 ppm) indicated that the linkage type was presented as → 4)-α-D-Glcp-(1 → 4)-α-D-Glcp-(1 →. The anomeric hydrogen signal at 5.31 ppm of residue A has a correlation peak with C-6 (71.16 ppm) of residue C, suggesting the presence of → 4)-α-D-Glcp-(1 → 6)-α-D-Glcp-(1 →. The H-1 (δ 5.31 ppm) of residue A has a correlation peak with C-4 (76.69 ppm) of residue C, suggesting the presence of → 4)-α-D-Glcp-(1 → 4)-α-D-Glcp-(1 →. The H-1 (5.13 ppm) of residue C also correlates with its own C-6 (71.16 ppm), suggested that they were linked with each other in the form of → 4)-α-D-Glcp-(1 → 6)-α-D-Glcp-(1 →.

Combination of monosaccharide, methylation and NMR analysis in consideration, the possible repeating structure of RGP1-1 was predicted and drawn in Fig. 3. Zhang et al. [44] reported a new homogenous starch-like glucans named WGPN-N 1 which extracted from RG, it was elucidated with a molecular weight of 18 kDa. Moreover, these polysaccharides including RG1-1 were elucidated as starch-like polysaccharide owing to their backbone. The different molecular weight and branches in these polysaccharides lead to different biological activities and properties.

Fig. 3

Proposed structure of RGP1-1

SEM and TEM analysis

Compared with nucleotides and proteins, polysaccharide had a more complex three-dimensional morphology. Morphology was studied by TEM and SEM.

As shown in Fig. 4A, the surface of RGP1-1 has an amorphous morphological and irregular sheet structure under the 500× lens, and relatively smooth and flat under the 2500× lens in SEM. Moreover, the surface of RGP1-1 was smooth and tight along with little holes, and it may reveal powerful intermolecular forces in RGP1-1. In addition, the larger space in the flake layer may provide cohesive space for water molecules which bring on a better solubility, contributing to an increase of its activity [45]. TEM (Fig. 4B) showed that RGP1-1 was spherical structure with a particles size of are 100–200 nm. Drugs of this size may be easily to absorb [46].

Fig. 4

Stereo-shapes and physiochemical properties of RGP1-1. A Transmission electron micrographs of RGP1-1; B Scanning electron micrographs of RGP1-1; C Atomic force micrographs of RGP1-1; D Congo red analysis of RGP1-1; E The curves of DSC of RGP1-1; F Particle size distribution and zeta potential of the RGP1-1 aggregates in water at 1.0 mg/mL

AFM analysis

AFM was widely used to study the properties and spatial conformation of polysaccharide. In this experiment, AFM was used to examine the morphology of RGP1-1. As shown in Fig. 4C, the 2D and 3D image of RGP1-1 performed an irregular entanglement structure with a height ranged from 0.5–2 nm. In addition, the average height of chains of RGP1-1 were large than 1.0 nm, which was consistent with the Congo red analysis and the triple helix reported previously [47]. Li et al. conducted AFM analysis on the obtained polysaccharides and found that the polysaccharide chains were entangled with each other to form aggregates of various sizes [48]. These entangled appearances in polymers may be caused by van der Waals forces, intramolecular and intermolecular hydrogen bonds.

Congo red analysis

Polysaccharides with helical conformation can form complexes with Congo red, and the maximum absorption performed red shift. As shown in Fig. 4D, compared with control group, the maximum absorption of RGP1-1-Congo red complex was increased observably. Interestingly, at the NaOH concentration of 0.35 M, the maximum absorption was decreased which declared the despiralization of RGP1-1 in strong basicity condition. These results suggested that RGP1-1 had triple-helical structure. Moreover, these findings were constituted with other polysaccharide which extracted from Inonotus obliquus with triple-helical conformations [49].

Physicochemical property analysisThermal properties analysis

Thermostability is an important factor for bioactive molecules and analyzed by thermogravimetric analyzer. As shown in Fig. 4E, the first stage was mainly related to the loss of combined water, which covered from 25 to 200 °C, the mass was reduced by nearly 15.45%. The second stage were chemical reactions and atomic recombination which was performed from 320 to 500 °C. The mass reduced approximatively 75.2%. The DSC was used to detect the thermal changes with the increased temperature. As showed in Fig. 4E, three endothermal peaks were 92.0 °C, 215.6 °C and 336.6 °C, respectively. And the enthalpy changes of system were 12.66 J/g, 4.12 J/g and 9.69 J/g correspondingly. It revealed that RGP1-1 may be structurally stable and had good thermal stability.

Particle size and zeta potential analysis

The zeta potential is the direction of surface charge and the performance of stability of system. The larger absolute value of zeta potential perform that the mixed system is more stable. As shown in Fig. 4F, the zeta potential of RGP1-1 solution was 6.82 mV and the average particle distribution of RGP1-1 was 117.4 nm. It revealed the aggregation of polysaccharide molecules and confirmed the AFM analysis. The anionic charge character in polysaccharides may be the cause of this polymerization phenomenon [49].

Antioxidant activities of polysaccharide fractions in vitro

DPPH, hydroxyl radical and superoxide anion assay were stable and widely used methods to estimate the free radical scavenging ability of polysaccharide. RGP was proved to have good antioxidant activity [8]. In order to estimate the antioxidant activities of RGP1-1, DPPH, hydroxyl radical and superoxide anion free radical scavenging experiments were applied for study. As shown in Fig. 5A, with the increase of RGP1-1 concentration, the scavenging free radical rate also increases gradually. It indicated the antioxidant activity of RGP1-1 was in dose-dependent manner within the range of 0.125–10 mg/mL. The highest scavenging rate of DPPH, hydroxyl radical and superoxide anion were at the concentration of 10 mg/mL, and it was 75.33%, 69.33% and 65.36%, respectively. In brief, RGP1-1 has a strong ability to scavenge free radicals. In addition, it can provide bonding electrons, and resulting in radical scavenging activity [50]. Besides, the mechanism of hydroxyl radical scavenging of polysaccharide was responsible for the interaction of hydrogen with radicals, and followed by a termination of the radical chain reaction. Unfortunately, the details of this mechanism have not yet been elucidated [51].

Fig. 5

Effect of RGP1-1 on antioxidant activity in vitro, and the area of myocardial infarction in mice. A In vitro antioxidant activity assay of RGP1-1 (a-DPPH radical scavenging assay, b-Hydroxyl radical scavenging ability assay, c-Superoxide anion-scavenging activity assay, Values are means ± SD, n = 3); B Effect of RGP1-1 on cardiac index of mice; C, D Effect of RGP1-1 on area of myocardial infarction in mice. (a control blank; b model group (ISO); c inderal group; d low-dose RGP1-1; e medium-dose RGP1-1; f high-dose RGP1-1). The data are presented as means ± SD (n = 10 mice per group). vs. blank control, ##P < 0.01, ##P < 0.05, vs. model control, **P < 0.01, *P < 0.05

Polysaccharide fractions protect against ISO-induced MI injury in miceEffects of polysaccharide fractions on heart index

Isoproterenol was a β-adrenergic agonist which can induce myocardial ischemia through increasing the force and frequency of myocardial contractions [52]. In this study, an animal model induced by ISO to estimate the protective effect of RGP1-1 on MI. As shown in Fig. 5B, the heart index of model group was higher than the blank group, indicating increase in size and generate oedema of heart. Compared with model group, the heart index of mice pre-treated with RGP1-1(100, 200 or 400 mg/kg), showing a significant reduction (P < 0.01). In the Inderal pre-treated group (positive group), the heart index had significantly decreased, when compared with model group (P < 0.01). It was stated that the heart weight increment of mice induced by ISO may according to the increased water content, edema intermuscular space and connected with onset of myocardial necrosis [53]. The pretreatment of RGP1-1 obviously decreased the heart weight in ISO-induced mice, and it revealed RGP1-1 had protective effect on ISO-induced MI in mice.

Effects of polysaccharide fractions on area of myocardial infarction

The myocardial TCC results of the mice were shown in Fig. 5C, D. The myocardial tissue of the blank group was ruddy, and there was no obvious area of white infarction. Compared with blank group, the myocardial tissue in the model group had large area of myocardial infarction which the was 51.02 ± 5.15% (P < 0.01). After the pre-treated with Inderal (positive group), the infarct area was reduced to 16.41 ± 1.37% (P < 0.01). In addition, the myocardial infarction area of RGP1-1 groups (100 mg/kg, 200 mg/kg, 400 mg/kg) were significantly reduced to 23.54 ± 1.78%, 31.54 ± 3.03%, 40.09 ± 2.91%, respectively. These results indicated that polysaccharide fraction can significantly improve the blood condition during the course of onset of myocardial ischemia, reduce myocardial tissue infarction, and exert its protective effect on myocardial ischemia injury.

Effects of polysaccharide fractions on serum marker enzymes

Heart is one of the most active organs which contains a mass of cardiac troponin and enzymes. cTnT and cTnI were regulatory protein of myocardial muscle tissue contraction and a marker of myocardial injury and necrosis. Its elevated level indicates that myocardial tissue and function were damaged. It can be used for the diagnosis and evaluation of myocardial ischemia. Moreover, cytosolic enzymes such as AST, LDH, CK, and CK-MB were usually use as diagnostic markers of myocardial tissue injury. These cellular enzymes in serum during the occurrence of myocardial ischemic reperfusion can reflect severity of cardiomyopathy and loss of functional integrity and permeability of cell membrane [54, 55]. The activities of serum biomarkers were characterized to evaluate the cardioprotective effect of RGP1-1 in ISO-induced mice.

As shown in Fig. 6, compared with blank group, the cardiac troponin (cTnT, cTnI) in model group were significantly increased (P < 0.01), it indicated myocardial tissue were damaged. Interestingly, while pre-treated with Inderal or polysaccharide fraction, these cardiac troponins showed an obvious reduction in activities compared with model group. Besides, As shown in Fig. 6, the marker enzymes (AST, LDH, CK and CK-MB) in the serum of mice in model group were significantly increased (P < 0.01). And the increased activities of these enzymes in serum owing to their leaked from the heart as a result of myocardial necrosis induced by ISO. When pre-treated with Inderal or RGP1-1(100, 200 and 400 mg/kg, respectively), these enzymes in serum showed an obvious reduction in activities when compared with model group. These results indicated that RGP1-1 could maintain cellular membrane integrity and permeability. Consequently, it could reduce the leakage of these enzyme and attenuate ISO-induced tissue injury.

Fig. 6

Effect of RGP1-1 on the cardiac enzyme activity. The data are presented as means ± SD (n = 10 mice per group). vs. blank control, ##P < 0.01, ##P < 0.05, vs. model control, **P < 0.01, *P < 0.05

Effects of polysaccharide fractions on serum antioxidant activity

Heart damage was related to the oxygen free radicals which could damage various biological targets [56]. In order to illuminate the protective effect of RGP1-1 on MI injury, antioxidant activity of RGP1-1 was evaluated. As shown in Fig. 7, compared with blank group, the activities of SOD, CAT and GPx in serum of mice in model group were observably decreased, along with an increase of MDA (P < 0.01). On the contrary, compared with model group, the activities of SOD, CAT and GPx in serum of mice in RGP1-1 administration group showed a significant increase (P < 0.05 or P < 0.01), while a significant decrease in MDA (P < 0.05 or P < 0.01). These results proved for the first time that administration of RGP1-1 could effectively attenuate anti-oxidant stress damage in ISO-induced mice.

Fig. 7

Effect of RGP1-1 on oxidative stress biochemical markers and inflammatory factors. The data are presented as means ± SD (n = 10 mice per group). vs. blank control, ##P < 0.01, ##P < 0.05, vs. model control, **P < 0.01, *P < 0.05

The role of oxidative stress in the pathophysiological mechanism of ischemic heart disease and ISO-induced MI injury has been fully demonstrated [57]. In the antioxidant defense system, free radical scavenging enzymes such as SOD, GPx and CAT are the first line of defense. Some eliminating reactive oxygen radicals such as superoxide anion, hydrogen peroxide, and hydroxyl radical can protect the tissue from oxidative damage [58]. A significant marker of oxidative stress is reduction in the SOD level, and SOD was usually existed in the plasma membrane. CAT was used as a catalyst for the removal of hydrogen peroxide [59]. And GPx protects the cellular membranes from the peroxidative damage by reducing hydrogen peroxide and lipid peroxides [60]. Inhibiting these enzymes leads to the accumulation of these oxidants, making the myocardial cell membrane more susceptible to oxidative damage. Pretreatment with RGP1-1 obviously increase the activities of these enzymes in serum, which suggest the antioxidant activity of RGP1-1 in ISO-induced mice.

MDA was regarded as an index of cellular damage and cytotoxicity [55]. The levels of MDA in serum of mice in model group was significantly increased when compared to blank group. While pretreatment with RGP1-1, the MDA content was decreased in serum when compared to model group. These results might be owing to the enhanced activities in antioxidant enzymes (SOD, GPx and CAT), and the free radicals were effectively scavenged.

The above findings indicated that RGP1-1 could greatly improve cellular anti-oxidative stress effect. And this result due to the therapeutic action of RGP1-1 in against peroxidative injury. These results suggested that RGP1-1 provided important protection against ISO-induced MI in mice by enhancing endogenous antioxidant activity.

Effect of polysaccharide fractions on ROS level

In the process of MI, the mitochondrial electron transport chain was destructed and led to generation of a large amount of reactive oxygen species (ROS). And the antioxidant enzymes such as SOD and CAT that use ROS as substrates were over-consumed. As a result, ROS cannot be reduced and metabolized which produced accumulation. ROS could attack nucleic acids, proteins and other macromolecules, destroy biofilm unsaturated fatty acids, and generate biotoxic MDA [61]. Inhibition of ROS production which is an effective mean to improve oxidative stress damage in MI.

In this study, the anti-oxidative stress activity of RGP1-1 polysaccharide was evaluated by estimated the inhibitory effect of ROS. As shown in the Fig. 7, ROS level in model group was significantly enhanced. After giving RGP1-1, the level of ROS was significantly down-regulated which indicated the production of ROS was inhibited, it suggested that RGP1-1 had the effect of protecting oxidative damage.

Effect of polysaccharide fractions on inflammatory factor content

After MI, a large number of pathologically stimulated inflammatory factors are released. Among them, TNF-α and IL-6 are used as inflammatory chemokines, which can stimulate inflammation and damage myocardial tissue. IL-6 could activate inflammatory cells, aggravate the inflammatory response, and stimulate vascular endothelial cells to release ROS [62]. TNF-α is a pro-inflammatory cytokine, which can induce the release of other inflammatory mediators, and can significantly promote apoptosis [63]. In this study, the anti-inflammatory effect of RGP1-1 polysaccharide was evaluated by estimated the content of TNF-α and IL-6 in serum. As shown in Fig. 7, compared with blank group, the content of TNF-α and IL-6 in serum of mice in model group were observably increased (P < 0.01). On the contrary, compared with model group, the content of TNF-α and IL-6 in serum of mice in RGP1-1 administration group showed a significant decrease (P < 0.05 or P < 0.01). These results proved that administration of RGP1-1 has an antagonistic effect on inflammation, and may indirectly inhibit oxidative damage and resist apoptosis.

Effects of polysaccharide fractions on cardiomyocyte apoptosis

The TUNEL assay was applied to evaluate the effect of RGP1-1 on cardiomyocyte apoptosis. ISO caused DNA fragmentation in nucleosomes. As shown in Fig. 8, compared with blank group, a number of TUNEL-positive cells increased obviously in model group. And it indicated many cardiomyocytes produced apoptosis in the model group. The results of RGP1-1 pretreatment group (100, 200 and 400 mg/kg, respectively) showed that the number of TUNEL-positive cells significantly reduced when compared with model group. Positive group (Inderal) pre-treated also showed the similar results with RGP1-1. These results suggested that RGP1-1 could inhibit ISO-induced apoptosis by the mitochondria-dependent apoptotic pathway.

Fig. 8

Effect of RGP1-1 on apoptosis of cardiomyocytes. The data are presented as means ± SD (n = 10 mice per group). vs. blank control, ##P < 0.01, ##P < 0.05, vs. model control, **P < 0.01, *P < 0.05

Effects of polysaccharide fractions on myocardial histopathology

Histopathology of heart was examined to evaluated the protective effect of RGP1-1 on the myocardial tissues. As shown in Fig. 9A, compared with blank group, the model group showed histopathological changes in myocardial tissue in HE stained. Specifically, obvious myocardial cell degeneration and necrosis leading to impairment of membrane structural and functional integrity, more inflammatory cell infiltrated. Pretreatment with RGP1-1 (100, 200 and 400 mg/kg, respectively), heart histopathological changes were partially repaired, which indicated that RGP1-1 has significant cardioprotective effects. Photomicrograph of positive group (Inderal) pre-treated also showed the similar results of myocardial tissue with less cellular infiltration and necrosis. Compared with the blank group, model group showed histopathological changes in myocardial tissue with Masson stained. The cells were moderate fibrous tissue hyperplasia and moderate fibrosis, and a large number of inflammatory cells and moderate degeneration and necrosis. The positive group (Inderal) showed a small amount of blue reaction in cardiomyocytes and myocardial interstitial blood vessels, indicating no obvious fibrosis, proliferation, inflammation and degeneration. Cardiac histopathological changes were repaired by RGP1-1 pretreatment (100, 200 and 400 mg/kg, respectively). In addition, there was only a small amount of blue reaction at high doses. It suggested that high dose of RGP1-1 can significantly protect myocardial tissue.

Fig. 9

Effect of RGP1-1 on morphological changes and western blot analysis for examining the expressions of Nrf2, HO-1, NOQ-1, Keap-1 in cardiac tissues. A Representative images of pathological structure of heart in mice (a control blank; b model group (ISO); c inderal group; d low-dose RGP1-1; e medium-dose RGP1-1; f high-dose RGP1-1;HE staining ×400, Masson staining ×400); B, C Western blot assessments of Nrf2, HO-1, NOQ-1, Keap-1 expression in cardiac tissues. The data are presented as means ± SD (n = 10 mice per group). vs. blank control, ##P < 0.01, ##P < 0.05, vs. model control, **P < 0.01, *P < 0.05

Polysaccharide fractions regulated Nrf2/HO-1 expression to prevent myocardial membrane injury in mice

The Nrf2 pathway is the mos