Pedoto A, Tassiopoulos A K, Oler A, McGraw D J, Hoffmann S P, Camporesi E M, Hakim T S
Department of Anesthesiology, SUNY Health Science Center, Syracuse, NY 13210, USA.
Crit Care Med. 1998 Dec;26(12):2021-8. doi: 10.1097/00003246-199812000-00034.
To evaluate the effect of treatment with a combination of nitric oxide synthase inhibitors and inhaled nitric oxide on systemic hypotension during sepsis.
Prospective, randomized, controlled study on anesthetized animals.
A cardiopulmonary research laboratory.
Forty-seven male adult Sprague-Dawley rats.
Animals were anesthetized, mechanically ventilated with room air, and randomized into six groups: a) the control group (C, n=6) received normal saline infusion; b) the endotoxin-treated group received 100 mg/kg i.v. of Escherichia coli lipopolysaccharide (LPS, n=9); c) the third group received LPS, and 1 hr later the animals were treated with 100 mg/kg i.v. Nw-nitro-L-arginine (LNA, n=9); d) the fourth group received LPS, and after 1 hr, the animals were treated with 100 mg/kg i.v. aminoguanidine (AG, n=9); e) the fifth group received LPS and 1 hr later was treated with LNA plus 1 ppm inhaled nitric oxide (LNA+NO, n=7); f) the sixth group received LPS and 1 hr later was treated with aminoguanidine plus inhaled NO (AG+NO, n=7). Inhaled NO was administered continuously until the end of the experiment.
Systemic mean blood pressure (MAP) was monitored through a catheter in the carotid artery. Mean exhaled NO (ENO) was measured before LPS (T0) and every 30 mins thereafter for 5 hrs. Arterial blood gases and pH were measured every 30 mins for the first 2 hrs and then every hour. No attempt was made to regulate the animal body temperature. All the rats became equally hypothermic (28.9+/-1.2 degrees C [SEM]) at the end of the experiment. In the control group, blood pressure and pH remained stable for the duration of the experiment, however, ENO increased gradually from 1.3+/-0.7 to 17.6+/-3.1 ppb after 5 hrs (p< .05). In the LPS treated rats, MAP decreased in the first 30 mins and then remained stable for 5 hrs. The decrease in MAP was associated with a gradual increase in ENO, which was significant after 180 mins (58.9+/-16.6 ppb) and reached 95.3+/-27.5 ppb after 5 hrs (p< .05). LNA and AG prevented the increase in ENO after LPS to the level in the control group. AG caused a partial reversal of systemic hypotension, which lasted for the duration of the experiment. LNA reversed systemic hypotension almost completely but only transiently for 1 hr, and caused severe metabolic acidosis in all animals. The co-administration of NO with AG had no added benefits on MAP and pH. In contrast, NO inhalation increased the duration of the reversal in MAP after LNA, alleviated the degree of acidosis, and decreased the mortality rate (from 55% to 29%).
In this animal model, LPS-induced hypotension was alleviated slightly and durably after AG, but only transiently after LNA. Furthermore, co-administration of NO with AG had no added benefits but alleviated the severity of metabolic acidosis and mortality after LNA. We conclude that nitric oxide synthase (NOS) inhibitors, given as a single large bolus in the early phase of sepsis, can exhibit some beneficial effects. Administration of inhaled NO with NOS inhibitors provided more benefits in some conditions and therefore may be a useful therapeutic combination in sepsis. NO production in sepsis does not seem to be a primary cause of systemic hypotension. Other factors are likely to have a major role.
评估一氧化氮合酶抑制剂与吸入一氧化氮联合治疗对脓毒症期间系统性低血压的影响。
对麻醉动物进行的前瞻性、随机、对照研究。
心肺研究实验室。
47只成年雄性Sprague-Dawley大鼠。
动物麻醉后,用室内空气进行机械通气,并随机分为六组:a)对照组(C,n = 6)输注生理盐水;b)内毒素治疗组静脉注射100 mg/kg大肠杆菌脂多糖(LPS,n = 9);c)第三组接受LPS,1小时后动物静脉注射100 mg/kg Nω-硝基-L-精氨酸(LNA,n = 9);d)第四组接受LPS,1小时后动物静脉注射100 mg/kg氨基胍(AG,n = 9);e)第五组接受LPS,1小时后用LNA加1 ppm吸入一氧化氮治疗(LNA+NO,n = 7);f)第六组接受LPS,1小时后用氨基胍加吸入一氧化氮治疗(AG+NO,n = 7)。持续吸入一氧化氮直至实验结束。
通过颈动脉导管监测系统性平均血压(MAP)。在注射LPS前(T0)及之后每30分钟测量一次平均呼出一氧化氮(ENO),持续5小时。在最初2小时内每30分钟测量一次动脉血气和pH值,之后每小时测量一次。未尝试调节动物体温。实验结束时,所有大鼠体温均同等程度降低(28.9±1.2℃[标准误])。对照组中,血压和pH值在实验期间保持稳定,然而,5小时后ENO从1.3±0.7逐渐升至17.6±3.1 ppb(p<0.05)。在接受LPS治疗的大鼠中,MAP在最初30分钟内下降,然后在5小时内保持稳定。MAP的下降与ENO的逐渐升高相关,180分钟后显著升高(58.9±16.6 ppb),5小时后达到95.3±27.5 ppb(p<0.05)。LNA和AG可防止LPS后ENO升高至对照组水平。AG使系统性低血压部分逆转,且在实验期间持续存在。LNA几乎完全逆转系统性低血压,但仅持续1小时,并导致所有动物出现严重代谢性酸中毒。AG与NO联合使用对MAP和pH值无额外益处。相比之下,吸入NO可增加LNA后MAP逆转的持续时间,减轻酸中毒程度,并降低死亡率(从55%降至29%)。
在该动物模型中,AG治疗后LPS诱导的低血压略有且持久缓解,而LNA治疗后仅短暂缓解。此外,AG与NO联合使用无额外益处,但可减轻LNA后的代谢性酸中毒严重程度和死亡率。我们得出结论,在脓毒症早期单次大剂量给予一氧化氮合酶(NOS)抑制剂可显示出一些有益效果。在某些情况下,吸入NO与NOS抑制剂联合使用可带来更多益处,因此可能是脓毒症中一种有用的治疗组合。脓毒症中一氧化氮的产生似乎不是系统性低血压的主要原因。其他因素可能起主要作用。
