The effect of high-flux hemodialysis on the inflammatory factors and serum brain natriuretic in hemodialysis patients with uremia / 中国医师杂志

Objective To investigate the influence of the high-flux hemodialysis (HFD) on inflammatory factors [C-reactive protein (CRP),interleukin-6 (IL-6),tumor necrosis factor-α (TNF-α)] and serum brain natriuretic (BNP) in patients before and after hemodialysis.Methods Fifty patients with MHD were enrolled in our hospital in 2013 and divided randomly into HD group (n =25),and HFD group (n =25).Serum CRP,IL-6,TNF-α,and BNP were measured in patients before and after the first hemodialysis session and after the treatment for 6 months later.Results Serum CRP,IL-6,and TNF-α in HD group after the first dialysis session and after the treatment for 6 months were statistically insignificant (P ＞0.05).In HD group,serum BNP was decreased after the first hemodialysis session and the treatment for 6 months later,the decreases was statistically significant (P ＜0.01 or P ＜0.05).In HFD group,serum CRP,IL-6,and TNF-α were decreased after the first treatment,the decreases were statistically insignificant (P ＞ 0.05).However,after the 6 mouths,the decreases were statistically significant (P ＜ 0.05).Serum BNP was decreased after the first hemodialysis session and the treatment for 6 months later,the decrease was statistically significant(P ＜ 0.01).Between two groups,the different time-point and the interaction of two groups and the different time-point,the discrepancy above them were statistically significant (P ＜0.01).Conclusions The high-flux hemodialysis can eliminate more inflammatory factors such as CRP,IL-6,TNF-α,and serum BNP in patients with uremia.Serum BNP Helps to adjust the dry weight in time,relieve cardiac load and reduce the incidence of heart failure.High-flux hemodialysis is one of the ways of treatment that reduce the morbidity of the heart failure.It can improve prognosis of the patients with MHD.

The Protective Effects of IGF-1 on Different Subpopulations of DRG Neurons with Neurotoxicity Induced by gp120 and Dideoxycytidine In Vitro

Peripheral neuropathy induced by human immunodeficiency virus (HIV) infection and antiretroviral therapy is not only difficult to distinguish in clinical practice, but also difficult to relieve the pain symptoms by analgesics because of the severity of the disease at the later stage. Hence, to explore the mechanisms of HIV-related neuropathy and find new therapeutic options are particularly important for relieving neuropathic pain symptoms of the patients. In the present study, primary cultured embryonic rat dorsal root ganglion (DRG) neurons were used to determine the neurotoxic effects of HIV-gp120 protein and/or antiretroviral drug dideoxycytidine (ddC) and the therapeutic actions of insulin-like growth factor-1 (IGF-1) on gp120- or ddC-induced neurotoxicity. DRG neurons were exposed to gp120 (500 pmol/L), ddC (50 micromol/L), gp120 (500 pmol/L) plus ddC (50 micromol/L), gp120 (500 pmol/L) plus IGF-1 (20 nmol/L), ddC (50 micromol/L) plus IGF-1 (20 nmol/L), gp120 (500 pmol/L) plus ddC (50 micromol/L) plus IGF-1 (20 nmol/L), respectively, for 72 hours. The results showed that gp120 and/or ddC caused neurotoxicity of primary cultured DRG neurons. Interestingly, the severity of neurotoxicity induced by gp120 and ddC was different in different subpopulation of DRG neurons. gp120 mainly affected large diameter DRG neurons (>25 microm), whereas ddC mainly affected small diameter DRG neurons (< or =25 microm). IGF-1 could reverse the neurotoxicity induced by gp120 and/or ddC on small, but not large, DRG neurons. These data provide new insights in elucidating the pathogenesis of HIV infection- or antiretroviral therapy-related peripheral neuropathy and facilitating the development of novel treatment strategies.

The study on dual-energy lung perfusion imaging in the diagnosis of pulmonary embolism using dualsource CT / 中华放射学杂志

Objective To explore the diagnostic values of dual energy lung perfusion in the diagnosis of pulmonary embolism by using dual-source CT (DSCT). Methods Thirty patients with clinically suspected pulmonary embolism underwent dual-energy scanning with dual-source CT. The scanned data were integrated into three groups including 140, 80 kV and coefficient of 0.3. According to the CT pulmonary angiography (CTPA) of the fusion data, the patients were divided into pulmonary embolism group and normal group. The thin-slice reconstruction of data was analyzed using dual-energy perfusion imaging analysis software. The lung field was divided into upper, middle and lower part to make quantitative analysis of lung tissue perfusion. Paired t-tests were used in the normal patients to compare bilateral lungs, and independent samples t-tests were applied to compare the embolism group and normal group, while minimum intensity projection images (MinIP) were utilized in the assessment of lung ventilation. Results Dual energy CT showed symmetrical homogeneous perfusion in 16 normal cases, without significant perfusion defects. Quantitative analysis showed that left and right lung perfusion were (27 ± 7) and (28 ± 8 ) HU respectively, and no significant difference was found between the two sides ( t=-1.73, P ＞0.05 ).Perfusion of the left upper, middle and lower lung was ( 23 ± 6), (24 ± 6), and (28 ± 8) HU respectively, while the perfusion of right upper, middle and lower lung was (26 ±8), (27 ±8), and (28 ±9) HU respectively, showing no statistical significant difference between the two sides (t=-1.91, -1.96,-1.73 ,P＞0.05 ). Angiography of pulmonary embolism group(14 cases)showed filling defects in the pulmonary trunk, segments and sub-segments. Pulmonary perfusion imaging showed low perfusion or defectsin lung field that dominated by embolic vessels. Quantitative analysis showed that the perfusion of the whole lung and the middle and lower lung were (22 ±5), (22 ±8), and (21 ±8) HU in the embolism group,which were significantly different from the normal group (t=-2. 10, -2.32, -2.63, P＜0.05).Minimum intensity projection images showed a good consistency of abnormal ventilation zone area and perfusion abnormalities. Conclusions Pulmonary perfusion status, especially pulmonary embolism, can be analyzed by dual energy CT scanning. It helps to early discover and precisely locate the embolism.