Li Qinghua, Sun Rongqing, Lyu Hongdi, Shen Dexin, Hu Qing, Wang Haiwei, Wang Nannan, Yan Jin, Wang Jing
Department of Intensive Care Unit, the 159th Hospital of PLA, Zhumadian 463008, Henan, China (Li QH, Lyu HD, Hu Q, Wang HW, Wang NN, Yan J, Wang J); Department of Intensive Care Unit, the First Affiliated Hospital of Zhengzhou University, Zhengzhou 450052, Henan, China (Sun RQ); Department of Pediatrics, the 153rd Hospital of PLA, Zhengzhou 450042, Henan, China (Shen DX). Corresponding author: Sun Rongqing, Email:
Zhonghua Wei Zhong Bing Ji Jiu Yi Xue. 2018 May;30(5):439-443. doi: 10.3760/cma.j.issn.2095-4352.2018.05.009.
To observe the effect of different core temperatures (Tc) after heat strike on serum inflammatory cytokines and multiple organ dysfunction syndrome (MODS) in rat.
120 male Sprague-Dawley (SD) rats were randomly divided into normal control group (n = 30) and heat strike group (n = 90). The rats in heat strike group were put into simulated thermal climate animal module after adaptive training. The module temperature was raised to 39 centigrade in 30 minutes with 65% humidity. The rats ran simultaneously at 15 m/min, on the slope of 0 degree angle, 8 minutes each time, 2 minutes interval, and the heat strike time was 90 minutes. After the rats came out of the module, rectal temperature, which was Tc value, was recorded. The rats died or Tc < 41 centigrade during the experiment were excluded, the remaining 73 rats were divided into three subgroups: 41.0-41.9 centigrade (n = 38), 42.0-42.9 centigrade (n = 26), and ≥43.0 centigrade (n = 9). The rats in the normal control group were reared at temperature of (25±2) centigrade, and humidity of (55±5)%. At 0 hour and 24 hours after the rats came out of the module, femoral artery blood was collected to determine serum interleukins (IL-1α, IL-1β, IL-17), tumor necrosis factor-α(TNF-α) andγ-interferon (IFN-γ) by enzyme-linked immunosorbent assay (ELISA). The cardiac troponin I (cTnI), MB isoenzyme of creatine kinase (CK-MB), serum creatinine (SCr), blood urea nitrogen (BUN), alanine aminotransferase (ALT), and aspartate aminotransferase (AST) levels were determined by automatic biochemical analyzer. The incidence of MODS and the number of accumulative organs within 24 hours of the rats in different Tc of heat strike group were compared and analyzed.
The serum inflammatory cytokines and biochemical parameters at 0 hour after heat strike were significant higher than those of the normal control group, and showed a time dependence. Further analysis showed that the inflammatory response and organ dysfunction in rats were increased gradually with the increase in Tc of rats. Compared with the normal control group, at 24 hours after heat strike, inflammatory cytokines in Tc≥43.0 centigrade rats were increased obviously [IL-1α (ng/L): 13.56±2.07 vs. 2.24±0.62, IL-1β (ng/L): 17.11±1.90 vs. 7.40±1.52, IL-17 (ng/L): 17.00±1.41 vs. 6.00±1.78, TNF-α (ng/L): 16.78±1.79 vs. 7.27±1.74, IFN-γ (ng/L): 21.11±2.09 vs. 10.43±2.31], and the biochemical parameters were also increased obviously [cTnI (ng/L): 50.78±6.67 vs. 20.53±3.09, CK-MB (U/L): 62.89±3.82 vs. 22.00±3.01, SCr (μmol/L): 149.22±4.35 vs. 92.53±8.32, BUN (nmol/L): 55.22±1.99 vs. 19.10±2.02, ALT (U/L): 388.33±4.97 vs. 100.23±10.61, AST (U/L): 361.22±6.53 vs. 97.67±10.54, all P < 0.01]. The incidence of MODS within 24 hours in the heat strike group was 54.79% (40/73), and the higher the Tc, the higher the incidence of MODS, and the more insulted organs [the incidence of MODS in 41.0-41.9 centigrade, 42.0-42.9 centigrade, and ≥43.0 centigrade subgroups was 36.84% (14/38), 65.38% (17/26), 100.00% (9/9), and the organ involvement rate was 12.17% (37/304), 23.08% (48/208), and 48.61% (35/72), respectively, when 8 organs or systems were calculated for each rat, both P < 0.01].
The higher the Tc of heat strike rats, the stronger the inflammatory reaction and the more serious the damage of tissue, and the more extensive damage of the organs.
观察热打击后不同核心温度(Tc)对大鼠血清炎症细胞因子及多器官功能障碍综合征(MODS)的影响。
将120只雄性Sprague-Dawley(SD)大鼠随机分为正常对照组(n = 30)和热打击组(n = 90)。热打击组大鼠经适应性训练后放入模拟热气候动物舱。舱内温度在30分钟内升至39℃,湿度为65%。大鼠同时以15米/分钟的速度奔跑,坡度为0度角,每次8分钟,间隔2分钟,热打击时间为90分钟。大鼠出舱后记录直肠温度,即Tc值。实验过程中死亡或Tc < 41℃的大鼠排除,其余73只大鼠分为三个亚组:41.0 - 41.9℃(n = 38)、42.0 - 42.9℃(n = 26)和≥43.0℃(n = 9)。正常对照组大鼠在温度为(25±2)℃、湿度为(55±5)%的环境中饲养。大鼠出舱后0小时和24小时,采集股动脉血,采用酶联免疫吸附测定(ELISA)法测定血清白细胞介素(IL-1α、IL-1β、IL-17)、肿瘤坏死因子-α(TNF-α)和γ-干扰素(IFN-γ)。采用自动生化分析仪测定心肌肌钙蛋白I(cTnI)、肌酸激酶MB同工酶(CK-MB)、血清肌酐(SCr)、血尿素氮(BUN)、丙氨酸氨基转移酶(ALT)和天冬氨酸氨基转移酶(AST)水平。比较并分析热打击组不同Tc大鼠24小时内MODS的发生率及累积器官数。
热打击后0小时血清炎症细胞因子和生化参数显著高于正常对照组,并呈时间依赖性。进一步分析表明,大鼠的炎症反应和器官功能障碍随大鼠Tc升高而逐渐增加。与正常对照组相比,热打击后24小时,Tc≥43.0℃大鼠的炎症细胞因子明显升高[IL-1α(ng/L):13.56±2.07 vs. 2.24±0.62,IL-1β(ng/L):17.11±1.90 vs. 7.40±1.52,IL-17(ng/L):17.00±1.41 vs. ;6.00±1.78,TNF-α(ng/L):16.78±1.79 vs.. 7.27±1.74,IFN-γ(ng/L):21.11±2.09 vs. 10.43±2.31],生化参数也明显升高[cTnI(ng/L):50.78±6.67 vs. 20.53±3.09,CK-MB(U/L):62.89±3.82 vs. 22.00±3.01,SCr(μmol/L):149.22±4.35 vs. 92.53±8.32,BUN(nmol/L):55.22±1.99 vs. 19.10±2.;02,ALT(U/L):388.33±4.97 vs. 100.23±10.61,AST(U/L):361.22±6.53 vs. 97.67±10.54,均P < 0.01]。热打击组24小时内MODS发生率为[54.79%(40/73),Tc越高,MODS发生率越高,受累器官越多[41.0 - 41.9℃、42.0 -;42.9℃和≥43.0℃亚组的MODS发生率分别为;36.84%(14/38)、65.38%(17/26)、100.00%(9/9),以每只大鼠计算8个器官或系统时,器官受累率分别为12.17%(37/304)、23.08%(48/208)和48.61%(35/72),均P < 0.01]。
热打击大鼠的Tc越高,炎症反应越强,组织损伤越严重,器官损伤越广泛。
