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[绵羊吸入等量淡水和海水致溺后肺循环血流动力学及呼吸力学比较:一项随机对照研究]

[Comparison of pulmonary circulation hemodynamics and respiratory mechanics induced by drowning with equal volume of freshwater and seawater in sheep: a randomized controlled study].

作者信息

Feng Qingguo, An Youzhong, Wei Kai, Zhao Xuefeng, Wang Wei, Teng Hongyun, Yang Wanjie

机构信息

Department of Critical Care Medicine, the Fifth Center Hospital in Tianjin, Tianjin 300450, China.

Department of Critical Care Medicine, Peking University People's Hospital, Beijing 100044, China. Corresponding author: Yang Wanjie, Email:

出版信息

Zhonghua Wei Zhong Bing Ji Jiu Yi Xue. 2020 Feb;32(2):177-182. doi: 10.3760/cma.j.cn121430-20191103-00033.

DOI:10.3760/cma.j.cn121430-20191103-00033
PMID:32275002
Abstract

OBJECTIVE

To compare the effects of freshwater and seawater drowning on sheep's pulmonary circulation hemodynamics and respiratory mechanics.

METHODS

According to the random number table method, healthy crossbred sheep were divided into freshwater drowning group (n = 12) and seawater drowning group (n = 12). 30 mL/kg of freshwater or seawater was infused respectively through trachea for approximately 5 minutes. Before the drowning, immediately after drowning, and 30, 60, 120 minutes after drowning, the systemic circulation hemodynamic parameters [heart rate (HR), mean arterial pressure (MAP), cardiac output (CO)] were monitored by pulse indicator continuous cardiac output (PiCCO); the respiratory parameters were obtained through the ventilator, including tidal volume (VT), lung compliance (Cdyn), oxygenation index (PaO/FiO), peak airway pressure (Ppeak)]; PiCCO and the right heart floating catheter (Swan-Ganz catheter) was used to measure pulmonary hemodynamic parameters [pulmonary systolic pressure (PAS), pulmonary diastolic pressure (PAD), pulmonary artery wedge pressure (PAWP), and extravascular lung water (EVLW)]. The animals were sacrificed at the end of the experiment, and the amount of residual water in the respiratory tract was measured; the pathological changes in the lung tissue were observed by hematoxylin-eosin (HE) staining.

RESULTS

(1) Systemic circulation hemodynamics: compared with the values before drowning, HR, MAP, and CO at the time of immediately after drowning in both freshwater and seawater were significantly increased and peaked. In addition, all indicators in the freshwater drowning group were significantly higher than those in the seawater drowning group [HR (bpm): 170.75±1.87 vs. 168.67±2.27, MAP (mmHg, 1 mmHg = 0.133 kPa): 172.92±1.62 vs. 159.42±3.18, CO (L/min): 13.27±0.71 vs. 10.33±0.73, all P < 0.05]. (2) Respiratory parameters: compared with values before drowning, PaO/FiO, VT, and Cdyn decreased immediately in both freshwater and seawater drowning groups, Ppeak was significantly increased; in addition, the values in the seawater drowning group were decreased or increased more significantly than freshwater drowning group [PaO/FiO (mmHg): 37.83±1.99 vs. 60.42±5.23, VT (mL): 86.25±7.66 vs. 278.75±9.67, Cdyn (mL/cmHO): 8.86±0.33 vs. 23.02±0.69, Ppeak (cmHO, 1 cmHO = 0.098 kPa): 42.17±2.69 vs. 17.67±1.15, all P < 0.01]. In addition, PaO/FiO in the freshwater drowning group was gradually increased over time, while the seawater group continued to decline. (3) Pulmonary circulation hemodynamic parameters: PAS, PAD, PAWP at the time of immediately after drowning in both freshwater and seawater groups were significantly higher than before drowning; in addition, the freshwater drowning group was significantly higher than the seawater drowning group [PAS (mmHg): 34.58±2.87 vs. 26.75±1.66, PAD (mmHg): 27.25±1.22 vs. 16.75±0.87, PAWP (mmHg): 27.83±1.85 vs. 11.75±1.82, all P < 0.01]. Thereafter, PAS and PAD in the freshwater drowning group gradually decreased, while the parameters in the seawater drown group continued to increase. PAWP gradually decreased after freshwater or seawater drowning, and recovered to pre-drowning levels 120 minutes after drowning and 30 minutes after drowning, respectively. EVLW continued to increase after freshwater drowning, reaching a peak at 30 minutes, and then decreased, until 120 minutes after drowning was still significantly higher than that before drowning (mL/kg: 10.73±1.27 vs. 7.67±0.69, P < 0.01); EVLW could not be measured. (4) Residual water in the respiratory tract: residual water in the freshwater drowning group was significantly less than that in the seawater drowning group (mL: 164.33±25.21 vs. 557.33±45.23, P < 0.01). (5) HE staining: partial alveolar atrophied in the freshwater drowning group, some alveolar spaces were broken, alveolar spaces and alveolar cavity showed a little powdery substance deposition; it was noted that alveolar expanded in the seawater drowning group, alveolar spaces were broken and bleeding and edema were obvious in the interstitial space.

CONCLUSIONS

The effect of seawater drowning on the respiratory mechanics and pulmonary circulation of animals is more obvious than that of freshwater drowned animals, and the amount of residual water in the respiratory tract is also significantly more than that of freshwater drowned animals.

摘要

目的

比较淡水溺水和海水溺水对绵羊肺循环血流动力学及呼吸力学的影响。

方法

采用随机数字表法,将健康杂交绵羊分为淡水溺水组(n = 12)和海水溺水组(n = 12)。分别经气管注入30 mL/kg淡水或海水,持续约5分钟。在溺水前、溺水即刻、溺水后30、60、120分钟,采用脉搏指示连续心输出量监测仪(PiCCO)监测体循环血流动力学参数[心率(HR)、平均动脉压(MAP)、心输出量(CO)];通过呼吸机获取呼吸参数,包括潮气量(VT)、肺顺应性(Cdyn)、氧合指数(PaO/FiO)、气道峰压(Ppeak)];使用PiCCO和右心漂浮导管(Swan - Ganz导管)测量肺血流动力学参数[肺动脉收缩压(PAS)、肺动脉舒张压(PAD)、肺动脉楔压(PAWP)和血管外肺水(EVLW)]。实验结束时处死动物,测量呼吸道内残留水量;采用苏木精 - 伊红(HE)染色观察肺组织病理变化。

结果

(1)体循环血流动力学:与溺水前相比,淡水和海水溺水即刻的HR、MAP和CO均显著升高并达到峰值。此外,淡水溺水组所有指标均显著高于海水溺水组[HR(次/分钟):170.75±1.87 vs. 168.67±2.27,MAP(mmHg,1 mmHg = 0.133 kPa):172.92±1.62 vs. 159.42±3.18,CO(L/分钟):13.27±0.71 vs. 10.33±0.73,均P < 0.05]。(2)呼吸参数:与溺水前相比,淡水和海水溺水组的PaO/FiO、VT和Cdyn即刻下降,Ppeak显著升高;此外,海水溺水组各项指标下降或升高幅度均比淡水溺水组更显著[PaO/FiO(mmHg):37.83±1.99 vs. 60.42±5.23,VT(mL):86.25±7.66 vs. 278.75±9.67,Cdyn(mL/cmH₂O):8.86±0.33 vs. 23.02±0.69,Ppeak(cmH₂O,1 cmH₂O = 0.098 kPa):42.17±2.69 vs. 17.67±1.15,均P < 0.01]。此外,淡水溺水组PaO/FiO随时间逐渐升高,而海水组持续下降。(3)肺循环血流动力学参数:淡水和海水组溺水即刻的PAS、PAD、PAWP均显著高于溺水前;此外,淡水溺水组显著高于海水溺水组[PAS(mmHg):34.58±2.87 vs. 26.75±1.66,PAD(mmHg):27.25±1.22 vs. 16.75±0.87,PAWP(mmHg):27.83±1.85 vs. 11.75±1.82,均P < 0.01]。此后,淡水溺水组的PAS和PAD逐渐下降,而海水溺水组参数持续升高。淡水或海水溺水后PAWP逐渐下降,分别在溺水后120分钟和30分钟恢复至溺水前水平。淡水溺水后EVLW持续升高,30分钟时达到峰值,随后下降,至溺水后120分钟仍显著高于溺水前(mL/kg:10.73±1.27 vs. 7.67±0.69,P < 0.01);海水溺水后无法测量EVLW。(4)呼吸道内残留水量:淡水溺水组呼吸道内残留水量显著少于海水溺水组(mL:164.33±25.21 vs. 557.33±45.23,P < 0.01)。(5)HE染色:淡水溺水组部分肺泡萎缩,部分肺泡间隔破坏,肺泡腔和肺泡间隙可见少量粉末状物质沉积;海水溺水组肺泡扩张,肺泡间隔破坏,间质内出血、水肿明显。

结论

海水溺水对动物呼吸力学和肺循环的影响比淡水溺水更为明显,呼吸道内残留水量也显著多于淡水溺水动物。

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