ABSTRACT
The rapid emergence of antibioticresistant bacteria is a threat to global health particularly in the area of healthcareassociate pneumonia (HCAP) where there is high rate of mortality. In general, guidelines should serve as a framework that needs to be complemented by local antibiogram data due to multiple factors influencing the development of multidrugresistant (MDR) HCAP. Failure to administer prompt and appropriate empirical therapy would often result in a high mortality rate. Based on these concerns, the aim of the study was to evaluate the appropriate empirical use of antibiotic and risk factors of MDR HCAP based on local pathogen resistant pattern. This was a retrospective analysis on HCAP in critical care of a tertiarycare hospital with data fromJanuary 2016 to December 2018. Patients diagnosed with HCAP: hospitalassociated pneumonia (HAP) and ventilatorassociated pneumonia (VAP), with positive bacterial cultures were included into the study. Of the 269 patients and isolates included, 160 (59.5%) had MDR strains. The top causative pathogens isolated were Acinetobacter baumannii(n=104, 38.7%), Pseudomonas aeruginosa(n=66, 24.5%), Klebsiella spp(n==55, 20.4%), and Staphylococcus aureus(n=16, 5.9%). The incidence of inappropriate empirical antibiotic was significantly higher in patients with MDR HCAP (n=135, 84.4%) compared to those with nonMDR HCAP (n=34, 31.2%) (p < 0.001). Mortality was significantly higher in patients receiving inappropriate empirical therapy (n = 118, 72.4%) compared to those receiving appropriate empirical antibiotic (n = 36, 54.5%) (P = 0.009). The independent risk factors for MDR HCAP identified in this study were hypoalbuminemia (odds ratio [OR] 3.43, 95% confidence interval [CI] 1.08 –10.87, p = 0.036) and indwelling central venous catheter (OR 5.65, 95% CI 1.13 –28.18, p = 0.035). This work serves as a basis for a centerspecific guideline to improve antibiotic use among HCAP patients in intensive care setting.
ABSTRACT
Objective: To investigate the hypoglycemic targets of Polygonum capitatum. Methods: Human liver cancer HepG2 cells were adopted to detect the supernatant culture medium glucose content, and the effect on PPAR-α and GLUT4 gene expression was investigated by qRT-PCR after treatment of P. capitatum extracts (PCB). INS-1 cells similar to islet β cells, divided into drug protection group and repair group, were adopted to determine the cell proliferation activity by MTT; The intracellular SOD and MDA levels were measured by biochemical method; The Cyt C and Caspase-3 protein expression levels were detected by Western blotting. Adopting maltose as substrate of α-glycosidase enzyme inhibition model, the inhibitory efficiency of PCB on glycosidic enzyme was determined. Results: PCB group significantly promoted the absorption of HepG2 cells to supernatant glucose and increased the expression of PPAR-α and GLUT4 genes significantly. Aim at protection and repair of INS-1 cells, PCB group significantly increased cell vitality and SOD level, reduced MDA level compared with model group, and at the same time significantly reduced Cyt C and Caspase-3 protein expression levels. PCB had inhibitory activity to α-glycosidase enzymes, with IC50 of 11.53 mg/mL. Conclusion: PCB could significantly increase the PPAR-α and GLUT4 genes expression to promote the absorption of HepG2 cells to supernatant glucose by blocking the Cyt C-Caspase-3 pathways to reduce apoptosis of islet cells which were damaged by STZ and by raising SOD and declining MDA to improve INS-1 cell oxidative stress; What’s more it has inhibitory activity to α-glycosidase enzymes.
ABSTRACT
<p><b>OBJECTIVE</b>To evaluate the therapeutic effects of VSD combined with irrigation of oxygen loaded fluid on the growth of granulation tissue and macrophage polarization in chronic venous leg ulcers.</p><p><b>METHODS</b>Thiry-four patients with chronic venous leg ulcers hospitalized in our department from December 2010 to July 2014 were divided into VSD group ( A, n = 11) , VSD + irrigation group ( B, n = 11) , and VSD + oxygen loaded fluid irrigation group ( C, n = 12) according to the random number table. After admissian, debridement was performed, and granulation tissue in the center of the wound was harvested during the operation. After dehridement, the patients in group A were treated with VSD only (negative pressure from -30 to -25 kPa, the same below) ; the patients in group B were treated with VSD combining irrigation of normal saline; the patients in group C were treated with VSD combining normal saline loaded with oxygen irrigation (flow of 1 L/min) . On post treatment day (PTD) 7, the VSD devices were removed. Cross observation was conducted before debridement and on PTD 7. On PTD 7, the granulation tissue in the center of the wound was harvested for histopathological observation with HE staining and Masson staining, following calculation of granulation tissue coverage rate. After debridement but before the negative pressure therapy (hereinafter referred to as before treatment) and on PTD 7, partial pressure of oxygen of the skin around the wound was measured by transcutaneous tissue oxygen tension survey meter. On PTD 7, expression of vascular endothelial growth factor (VECF) was determined with immunohistochemistry. Before treatment and on PTD 7, cells with double positive expressions of induced nitric oxide synthase plus CD68 ( type I macro- phage) and arginase 1 plus CD68 ( type II macrophage) were observed with immunofluorescence staining and quantified. Data were processed with Fisher's exact test, one-way analysis of variance, covariance analysis, paired test, and LSD test.</p><p><b>RESULTS</b>(1) The gross observation showed that before debridement there was a certain amount of necrotic tissue and little granulation tissue in the wounds of patients in all the 3 groups. On PTD 7, new granulation tissue was found in the wounds of patients in all the 3 groups, and in group C its amount was the largest. (2) On PTD 7, the granulation tissue coverage rate of wounds in pa- tients of group C was higher than that of group A or B ( P <0.05 or P <0.01). (3) On PTD 7, HE staining showed that there appeared more abundant new born microvessels and fibroblasts in the wounds of patients in group C than those in groups A and B; Masson staining showed that there was more abundant fresh collagen distributed orderly in the wounds of patients in group C compared with group A or B. (4) On PTD 7, it was found that partial pressure of oxygen of the skin around the wounds in patients of group C [(40.7 +/- 4.1) mmHg, 1 mmHg = 0.133 kPa] was higher than that of group A [ (35.0 +/- 3.1) mmHg] or B [(35.4 +/- 2.7) mmHg, with P values below 0.01]; the partial pressure of oxygen of the skin around the wounds of patients in all the 3 groups was increased significantly compared with that before treatment (with values from 10.38 to 22.52, P values below 0.01). (5) On PTD 7, the expression of VECF in the wounds of patients in group C was higher than that in group A or B ( P <0.05 or P < 0.01). (6) On PTD 7, the number of type I macrophages in granulation tissue of patients was respectively 14.3 +/- 2.3, 11.5 +/- 3.0, and 10.7 +/- 2.3 per 400 times vision field in groups A , B, and C ( F = 25.14, P < 0.01), while the number in group C was less than that in group A or B ( P < 0.05 or P < 0.01). Compared with that before treatment, the number of type I macrophages was significantly decreased on PTD 7 in all the 3 groups (with values from 14.76 to 23. 73, P values below 0. 01). On PTD 7, the number of type II macrophages in granulation tissue of patients was respectively 32.7 +/- 3.2, 35.1 +/- 3.3 , and 41.3 +/- 3.2 per 400 times vision field in groups A, B, and C ( F = 81.10, P < 0.01), and the number in group C was lager than that in group A or B ( with P values below 0. 01). Compared with that before treatment, the number of type II macrophages in all the 3 groups was significantly increased (with t values from -69.34 to -47.95, P values below 0.01).</p><p><b>CONCLUSIONS</b>VSD combined with irrigation of oxygen loaded fluid can raise the partial pressure of oxygen of the skin around the wounds effectively, promoting the transition of macrophages from type I to type II, thus it may promote the growth of granulation tissue, resulting in a better recipient for skin grafting or epithelization.</p>