ABSTRACT
Objective To investigate protective effects of the hydrogen saturated saline on acute lung injury and pulmonary fibrosis in rats with paraquat (PQ) poisoning. Method Forty-eight Sprague-Dawley rats were randomly divided into 3 groups, namely control group, PQ poisoning group and intervention group (n = 16 rats in each group) . Animals in PQ poisoning group and intervention group were fed with PQ in dosage of 50 mg / kg. Rats of control group were fed equivalent amount of distilled water instead. One hour after administration of PQ, rats of intervention group were treated with 5 ml / kg hydrogen saturated saline injected intra-peritoneally twice a day until the rats were sacrificed. The rats of poisoning group and control group were treated with intra-peritoneal injection of equivalent amount of normal saline. Arterial partial pressure of oxygen ( PaO2 ), 8-hydroxy-2' -desoxyguanosine (8-OHDG) and transforming growth factor β1 (TGF-β1) of lung tissue were measured on the 3rd and 21st day after PQ administration. Quantitative data was expressed as mean ±standard deviation (x-±s) . SPSS version 12. 0 package was applied for variance analysis and SNK-q test, and statistical differences were considered significant when P < 0. 05. Results ① PaO2 decreased significantly in poisoning group (9. 34 ± 0. 47 kPa) and intervention group (10. 30±0.62 kPa) compared with control group (11.87 +/- 0.42 kPa) on the 3d (P <0.01), and as intervention group was compared with poisoning group, there was a significant difference ( P < 0. 05 ) . On the 21st day, PaO2 was still lower in poisoning group (8. 36 ±0. 51 kPa) and intervention group ( 10. 14 ±0. 27 kPa) than that in control group ( 11.87 +0. 24 kPa) (P <0. 01 and P <0. 05, respectively), and as intervention group was compared with poisoning group, there was a significant difference ( P < 0. 01 ) . ②The levels of 8-OHDG in lung tissue increased significantly in poisoning group (23.58±7. 18 ng/ml ) and intervention group (9. 49± 2. 45 ng/ml) on the 3rd day after PQ administration compared with control group (7.71 + 1.96 ng/ml) (P<0. 01 and P<0. 05, respectively), and as intervention group was compared with poisoning group there was a significant difference ( p <0. 01 ) . There were no significant differences in 8-OHDG level found among the groups on the 21st day after PQ administration (P > 0. 05 ) . ③ The level of TGF-β1 (measured by mean optic density, MOD) in lung tissue of rats in poisoning group ( 10. 11±2.49 MOD) and intervention group (8. 14 + 1.58 MOD) exhibited in higher levels than control group (5.93 + 1. 98 MOD) on the 3rd and (5.97 + 2. 35 MOD) on the 21st day after PQ administration (P <0. 01 and P <0. 05, respectively), and however, a lower level of TGF-β1 was observed in intervention group on 3d and 21d compared with poisoning group (P <0. 05 and P <0. 01, respectively) . Conclusions Hydrogen saturated saline can alleviate oxidative stress, mitigate oxidative damage and inhibit pulmonary fibrosis of lung induced by PQ intoxication.
ABSTRACT
@#BACKGROUND: Paraquat (PQ) intoxication causes lung oxidative stress damage. Saturated hydrogen saline, a newly explored antioxidant, has been documented to play a powerful antioxidant role in preventing oxidative stress damage. This study aimed to investigate the protective effects and the possible mechanisms of intoxication on rats with acute lung injury (ALI) caused by paraquat poisoning. METHODS: Thirty PQ poisoned rats were randomly divided into a PQ intoxication group (intoxication group), a saturated hydrogen saline intervention group (intervention group), and a control group, with 10 rats in each group. The first two groups accepted an intragastric administration of PQ at a dose of 50 mg/kg for every single rat, and the control group was fed with a same volume of normal saline. Five mL/kg of saturated hydrogen saline was given to the intervention group three times a day by peritoneal injection for three days after intoxication. Arterial blood gas was detected on the third day. The rats were executed and their lungs were taken for measurement of wet dry weight ratio, homogenate malondialdehyde (MDA), and 8-hydroxy-2'-deoxyguanosine (8-OhdG). Histological changes of the lungs were also observed. RESULTS: Compared with the control group, the intoxication group had more serious hypoxemia, greater wet/dry weight ratio, higher MDA level, higher expression of 8-OhdG and more severe lung damage (P<0.01 or P<0.05). However, after intervention with saturated hydrogen saline, poisoned animals turned to have lighter hypoxemia, smaller wet/dry weight ratio, lower MDA level, lower expression of 8-OhdG, and milder lung damage (P<0.01 or P<0.05). CONCLUSIONS: Saturated hydrogen saline is effective in preventing acute lung injury caused by PQ. Possibly, it can neutralize toxic oxygen radicals selectively and alleviate the oxidative stress injury induced by PQ.