ABSTRACT
Objective To investigate the difference of the disease progression in patients with chronic obstructive pulmonary disease (COPD) with different muscle mass levels and the influence of related factors on the disease progression. Methods A total of 308 newly diagnosed patients with COPD from February 2021 to February 2022 were selected for this study. All patients were below moderate COPD. The patients were divided into two groups according to their muscle mass levels: sarcopenia group (98 cases) and control group (210 cases). The diagnostic criteria for sarcopenia were based on sarcopenia diagnostic thresholds: RSMI 2 in men and 2 for women. All subjects were followed up for 4 months to observe the progress of the patient's condition. The correlation between the muscle mass level and pulmonary function level, as well as the results of 6-minute walking test and CAT score was evaluated, and the influence of muscle mass level on the patient's disease progress was analyzed. At the same time, the potential influence of related factors (body fat rate, vitamin D level, etc.) on the condition of patients with different muscle mass levels was discussed. SPSS 19.0 software was used to perform statistical analysis. Results Under the same treatment intervention, the baseline and follow-up lung function improvement levels of patients in the sarcopenia group were lower than those in the control group, and the difference was statistically significant (P<0.05). At the same time, the baseline and follow-up 6-minute walk test results of the patients in the sarcopenia group were also worse than those of the control group, and the difference was statistically significant (P<0.05). Further correlation analysis was carried out between the patient's muscle mass level and the post-treatment pulmonary function indicators and 6MWD test level. The results showed that the muscle mass level was positively correlated with several pulmonary function indicators (FEV1, FEV1% predict) and 6MWD (both P<0.05). Considering the possible influence of other factors on the control and progress of the patient's condition, the present study used follow-up CAT score results to distinguish the prognosis of the patient's condition improvement, and used improvement and non-improvement as dependent variables to analyze the influence of various potential influencing factors. The results of regression model analysis showed that lower baseline muscle mass, women, lower body fat percentage, and lower vitamin D level were the main risk factors. Conclusion Under the same treatment condition, COPD patients with different muscle mass levels improve more slowly when complicated with sarcopenia and have poor prognosis. Women, lower body fat percentage and lower vitamin D level are potential risk factors for poor prognosis.
ABSTRACT
Objective:To investigate the medicinal retention of different concentrations of melatonin in the bone tissue of type 2 diabetic osteoporosis (T2DOP) rats and explore to efficacy of improvement of the bone microstructure of T2DOP rats.Methods:A total of 95 SD rats were selected, 60 of which had intraperitoneal in jection of high-fat diet combined with low-dose streptozotocin establishing a T2DOP rat model. Two months later, 45 rats' model was determined to be successful by detecting blood glucose and insulin sensitivity index. 30 successful modelling and 30 normal SD rats were randomly selected for melatonin distribution experiment, and were divided into four groups according to the injected melatonin concentration, including modeling rat high concentration group (50 mg/kg), modeling rat low concentration group (10 mg/kg), normal rat high concentration group (50 mg/kg) and normal rat low concentration (10 mg/kg), and there were15 rats in each group. Each group was divided into 5 sub-groups according to the time point of sampling (5, 15, 30, 60, 120 min), 3 animals per group. The bone tissue of each group was pretreated, and then the melatonin drug distribution in the bone tissue was detected by high performance liquid chromatography (HPLC). Another 15 rats were successfully modeled, and were divided into T2DOP group, high melatonin group (50 mg/kg) and low melatonin group (10 mg/kg), 5 rats in each group. 5 normal SD rats were taken as controls (control group), and Micro-CT was used to detect changes in bone microstructure after 8 weeks of treatment with melatonin.Results:The results of the drug distribution experiment showed that after melatonin was injected intraperitoneally, there were drugs remaining in the bone tissues of the rats in each group. The drug concentration reached the highest after 30 min of administration, and significantly decreased after 120 min. Compared with the normal rat low concentration group, there was no significant difference in the drug concentration between the two groups at 5 time points. However, the drug concentration at the four time points of 5, 15, 30, and 60 min in the modeling rat high concentration group were 7.613±2.568 ng/ml, 13.983±2.262 ng/ml, 18.816±1.291 ng/ml, 6.172±1.962 ng/ml, 1.112±0.566 ng/ml, which were significantly different compared with normal rat high group. Micro-CT results showed that after 8 weeks of melatonin treatment, the bone density of the high concentration group was (205.72±28.41 g/cm 3) significantly lower than that in the low concentration group (223.63±35.41 g/cm 3), but both groups were significantly higher than the normal rat group (158.31±31.86 g/cm 3). Conclusion:Exogenous melatonin is distributed in bone tissue, and the drug absorption rate of T2DOP rats is higher. Meanwhile, there is no difference in the distribution of melatonin in bone tissue with different concentrations, and these two concentrations of melatonincan canimprove the bone microstructure of T2DOP rats.