Objective:To investigate the risk factors for refeeding syndrome (RFS) in patients with severe stroke.Methods:Patients with stroke admitted to the Neuro Intensive Care Unit, Nanfang Hospital, Southern Medical University and received enteral nutrition support >72 h from January 2013 to July 2019 were enrolled retrospectively. RFS was defined as a new onset of hypophosphatemia within 72 h after the start of nutritional support, that is, blood phosphorus <0.65 mmol/L and a decrease of >0.16 mmol/L from the baseline value. The independent risk factors for RFS were identified by multivariate logistic regression model. Results:A total of 209 patients with severe stroke were included, with a median age of 65 years (interquartile range [ IQR] 53 to 72 years), and 154 were males (73.7%); 136 patients had cerebral infarction (65.1%), 73 had intracerebral hemorrhage (34.9%). The baseline median National Institutes of Health Stroke Scale (NIHSS) score was 15 ( IQR, 11-20), the median Glasgow Coma Scale score was 9 ( IQR, 6-12), the median Acute Physiology and Chronic Health Score was 16 ( IQR, 11-20), the median Nutrition Risk in Critically Ill (NUTRIC) score was 3 ( IQR 2-5), and the median Sequential Organ Failure Assessment (SOFA) score was 4 ( IQR, 3-6); the baseline median serum phosphorus was 1.05 mmol/L ( IQR, 0.90-1.19 mmol/L). A total of 34 patients (16.3%) developed RFS. Multivariate logistic regression analysis showed that male (odds ratio 3.565, 95% confidence interval 1.150-11.053; P=0.028) and patients with higher SOFA score (odds ratio 1.246, 95% confidence interval 1.077-1.442; P=0.032) were more likely to develop RFS. Conclusions:RFS is not rare in patients with severe stroke. Males and patients with severe disease are more likely to develop RFS.

Global warming caused by the increasing CO2 concentration in atmosphere is a serious problem in the international political, economic, scientific and environmental fields in recent years. Intensive carbon dioxide capture and storage (CCS) technologies have been developed for a feasible system to remove CO2 from industrial exhaust gases especially for combustion flue gas. In these technologies, the biofixation of CO2 by microalgae has the potential to diminish CO2 and produce the biomass. In this review, the current status focusing on biofixation of CO2 from combustion flue gases by microalgae including the selection of microalgal species and effect of flue gas conditions, the development of high efficient photobioreactor and the application of microalgae and its biomass product were reviewed and summarized. Finally, the perspectives of the technology were also discussed.
Air Pollutants ; isolation & purification ; metabolism ; Air Pollution ; prevention & control ; Biodegradation, Environmental ; Carbon Dioxide ; isolation & purification ; metabolism ; Microalgae ; metabolism ; Photochemistry