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Study on the correlation between the reduction of islet β-cell function and the ratio of GLP-1/GLU in severely scalded MODS mice |
LUO Yanji1, HUANG Zhihong2, XIAO Chuangqing2, YE Chunmei1, ZHONG Jie2, CAO Wenjing2 |
1. Department of Clinical Laboratory, Changsha Hospital of Traditional Chinese Medicine/ Changsha Eighth Hospital, Changsha 410100, China; 2. Department of Clinical Laboratory, the PLA 921 Hospital, Changsha 410003, China |
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Abstract Objective To study the correlation between the reduction of islet β-cell function and the ratio of glucagon-like peptide 1/glucose (GLP-1/GLU) and explore its mechanism in severely scalded MODS mice so as to provide experimental basis for the prevention and treatment of the reduction of islet β-cell function in severely scalded MODS from a new perspective of improving the function of GLP-1 secretion in intestine. Methods 90 Kunming mice of Specific Pathogen Free (SPF) grade were randomly divided into three groups: 10 mice as the control group, 30 mice as simple scald group and 50 mice as MODS group. The mice in MODS group were made into MODS mice with 30% total body surface area Ⅲ degree scald and intraperitoneal injection of LPS. The mice in simple scald group were only inflicted with 30% total body surface area Ⅲ degree scald, and mice in the control group were sham scalded. Blood samples of mice in the control group were collected. At 1 day and 3 days after injury, 10 mice were randomly captured respectively from simple scald group and MODS group, and blood samples were collected. At 5 days after injury, blood samples of all surviving mice in scald group and MODS group were collected. The levels of GLU, plasma insulin, GLP-1 and diamine oxidase (DAO) of mice were determined. Homeostasis model assessment of β-cell function (HOMA-β) was applied, and then the index of islet β-cell function (HOMA-β) and the ratio of plasma GLP-1/GLU were calculated and observed. The correlation coefficient between HOMA-β and plasma GLP-1/GLU was calculated. The ileum tissues of mice were collected to observe the expression of GLP-1 by immunohistochemistry, and then the levels of intestinal GLP-1 secretion relative to blood glucose (intestinal GLP-1/GLU) were calculated and observed. The correlation coefficient between plasma GLP-1/GLU and intestinal GLP-1/GLU, and the correlation coefficient between intestinal GLP-1/GLU and plasma DAO were calculated. Data were statistically analyzed with one-way analysis of variance and Bonferroni test, Kruskal-Wallis and Bonferroni test, and Spearman rank correlation analysis. Results HOMA-β, plasma GLP-1/GLU and intestinal GLP-1/GLU of severely scalded MODS mice at 1, 3 and 5 days after injury were significantly lower than those of mice in the control group and simple scald group at the same time point (P<0.05). HOMA-β was positively correlated with plasma GLP-1/GLU of mice (r=0.685, P<0.001). Plasma GLP-1/GLU was positively correlated with intestinal GLP-1/GLU (r=0.851, P<0.001). Intestinal GLP-1/GLU was negatively correlated with DAO (r=-0.732, P<0.001). Conclusion The islet β-cell function and the ratio of GLP-1/GLU were decreased in severely scalded MODS mice. Insufficiency of plasma GLP-1 relative to blood glucose was correlated with the reduction of islet β-cell function. Intestinal damage led to relatively insufficient GLP-1 secretion. Protecting intestinal cells to increase the ratio of plasma GLP-1/GLU in severely scalded MODS mice can be used as an important measure to improve the reduction of islet β-cell function.
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Received: 05 July 2022
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