在小鼠心跳骤停期间应用中度低温对复苏后抗氧化物酶活性的影响

目的：低温在许多小鼠心跳骤停后复苏模型的研究中被证实是有效的。心跳骤停后释放的氧自由基是产生继发性损伤的一个重要机制。本研究旨在探索心跳骤停期间应用中度低温对复苏后抗氧化物酶活性的影响。方法：用氯化钾诱导8min心跳骤停。此实验分为常温心跳骤停组（NCA）、低温心跳骤停组（HCA）TL对照组。HCA组在心跳骤停5min后开始降温使核心温度维持在（30．0±1．0）℃。应用胸部按压和肾上腺素来复苏。在心跳骤停两组各选择三个时间点：复苏后1h、4h和24h。测量超氧化物歧化酶（SOD）和过氧化氢酶（CAT）在心脏和肝脏的活性。结果：实验动物在HCA组比常NCA组生存率高。HCA组比NCA组复苏时间明显延长。与NCA组相比,HCA组复苏后24h的SOD活性在肝脏表达明显降低。与NCA组相比,HCA组复苏后4h的CAT活性在肝脏表达显著增高。结论：在心跳骤停过程中,与正常体温相比,应用中度低温能够提高生存率。与正常体温相比较,在心跳骤停中期间应用中度低温不影响心脏的SOD与CAT活性,应用中度低温在肝脏可延迟性抑制SOD的活性并且短暂提高CAT活性。     

经支气管镜气管插管与常规气管插管救治呼吸衰竭对比分析

目的：回顾性分析呼吸机辅助呼吸救治危重呼吸衰竭患者气管插管方式对于救治成功率的影响。方法：我科收治的各种呼吸衰竭患者94例,回顾分析插管方式对于救治成功率、引发心跳骤停及其对心肺复苏效果的影响。结果：经纤维支气管镜经口气管插管（35例）与经直接喉镜经口（59例）引发心跳骤停有明显统计学差异（X^2=11．5,v=1,t〈0．001）。经直接喉镜经口气管插管在术前用药与否对引发心跳骤停并无统计学意义,但是对于引发心跳骤停后心肺复苏成功率确有明显统计学意义。结论：经纤维支气管镜气管插管具有较高的安全性,在经直接喉镜气管插管是选择镇静药或浅麻醉药物应慎重,尽力避免心跳骤停和心肺复苏失败。     

H2S对心跳骤停复苏大鼠脑血流动力学及神经功能的影响

目的:探讨吸入外源性H_2S对心跳骤停复苏大鼠脑血流动力学及神经功能的影响。方法:选择成年雄性SD大鼠18只,随机分为假手术组(sham,n=6)、窒息导致心跳骤停复苏组(CA,n=6)、心跳骤停复苏+H_2S组(H_2S,n=6),观察H_2S对心跳骤停复苏大鼠脑血流的影响。选择成年雄性SD大鼠45只,随机分为sham组(n=5)、CA(n=20)和H_2S组(n=20),观察H_2S对心跳骤停复苏大鼠神经功能和存活率的影响。结果:CA组与H_2S组在ROSC后MAP和CPP均快速上升,远高于基础值(P0.05);而后两组MAP和CPP均缓慢下降,实验结束时,明显低于基础值(P0.05)。两组间比较差异无统计学意义(P0.05)。CA组与H_2S组CBF曲线在ROSC后上升至峰值,随后逐渐下降,两组在峰值无明显差异,但H_2S组CBF减少量显著少于CA组(P0.05)。而在CVR曲线,在实验最后,CA组CVR值仍明显高于基础值(P0.05),而H_2S组基本降至基础值,明显低于CA组(P0.05)。H_2S组的14天存活率(80%)明显高于CA组(50%,P0.05)。在胶带移除实验(tape removal test,TRT)所需时间上,CA组与H_2S组在第1天、第3天及第14天都存在显著差异(P0.05)。H_2S组第14天海马CA1区神经元存活数(33±8)明显多于CA组(20±6,P0.05),但仍较假手术组少(53±10,P0.05)。结论:外源性H_2S吸入对大鼠心跳骤停复苏后MAP及CPP无明显影响。外源性H_2S通过降低CVR,改善CBF,从而改善大鼠心跳骤停复苏后的脑循环。外源性H_2S能明显提高心跳骤停复苏后大鼠的存活率,降低TRT所需时间,同时显著增加海马CA1区神经元的存活,改善大鼠心跳骤停复苏后神经功能转归。     

心肺脑复苏(CPCR)成功11例体会

心跳呼吸骤停是临床急救医学最紧急而又困难并具有挑战意义的问题之一。如何提高心肺脑复苏（CPCR）的成功率,是临床急救医务人员所关注的问题。我院按照2005版国际心肺复苏指南的要求进行抢救的11例心跳呼吸骤停患者收到一定的效果,现报告如下。     

心肺脑复苏后如何进行早期氧疗

心肺脑复苏（Cardiopulmonary—cerebralResuscitation,CPCR）是抢救心跳骤停（CardiacArrest）患者的重要手段,而早期氧疗（AcuteOxygenTherapy）是提高心肺脑复苏成功率的重要辅助措施。以往人们一直认为CPCR后应尽早给予患者高浓度氧疗;然而,近年认为早期氧疗不当非但达不到挽救心跳骤停患者生命、降低致残率之目的,反而会降低复苏成功率。基础研究和临床研究提示,与暴露于正常空气或低浓度氧气组相比,大脑缺氧后早期暴露于高浓度氧气中的动物或患者,脑组织损伤更加严重。其可能机制主要有高浓度氧含量引起的氧化应激和乳酸堆积造成的脑组织损伤。此外,复苏后高浓度氧疗还可造成心肌损伤,其主要机制有大量活性氧簇（ReactiveOxygenSpecies,ROS）造成心脏的继发性损伤、Ca2＋通道激活,引起血管收缩加重心肌缺血、K＋ATP通道关闭,造成心肌受损、血管紧张素Ⅱ释放增多和缩血管物质20-HETE生成增多,加重心肌缺血等。因此,在对复苏后病人进行氧疗过程中,目前主张限制复苏后早期氧疗。     

毒蛇咬伤并发心跳骤停的抢救

心跳骤停是临床最严重、最紧急的情况。需立即进行准确、有效的抢救。毒蛇咬伤最危重的并发症是心跳骤停,作为一个蛇伤医生必须熟悉抢救心跳骤停的基本知识与基本技能。一、心跳骤停在心电图上的三种表现 1、心室颤动(或扑动)QRS-T不能分辨,呈现振幅,形态和时距均不同(或均相同)的一系列小(大)波动。     

心肺复苏后大鼠神经元氧自由基的变化及卡尼汀的干预作用

目的:研究心肺复苏后大鼠脑细胞氧自由基的改变及卡尼汀的干预作用。方法:本实验采用窒息合并冰氯化钾停跳液致大鼠心跳骤停5min后开始心肺复苏的动物模型,SD大鼠88只,随机分为11组:对照组(假手术组)、复苏后3、12、24、48、72h组(每组8只),复苏后卡尼汀干预3、12、24、48、72h组(每组8只)。各组抽静脉血测定血液中丙二醛(MDA)含量及超氧化物歧化酶(SOD)活力。结果:心跳骤停/心肺复苏后各组大鼠血清中MDA含量较对照组显著升高(p<0.05),SOD活力显著降低(P<0.05)。使用卡尼汀干预后,血清MDA含量显著降低(P<0.05),SOD活力基本正常(P<0.05)。结论:心肺复苏后大鼠氧自由基产生增多,清除减少;卡尼汀干预后,氧自由基产生减少。卡尼汀对心肺复苏后大鼠具有保护作用。     

规范化心肺复苏的急救护理体会

目的:为了探究不同的急救措施对心脏骤停者心肺复苏的影响,并对如何改善急救时护理的方法来提高急救的成功率。方法:对从2013年6月至2014年6月1年中在我市某医院急救的84例心跳骤停者分为死亡组、有效组合存活组3组,并回顾和分析了84例患者的CPR时间(TC)、患者心脏骤停发生的时间和除颤开始时间。结果分析:在急救的84例患者中,死亡的52例,复苏成功的有32例患者。结论分析:在对患者进行心肺复苏急救的过程中,早期的复苏及其熟练的配合抢救是心肺复苏的关键要素。     

1007型THUMPER心肺复苏机在急诊心肺复苏中的临床观察

目的观察1007型THUMPER心肺复苏机（萨勃机）在急诊心肺复苏中的临床效果。方法将114例心肺骤停患者分为萨勃机组59例和徒手心肺复苏组55例,两组患者均使用电除颤和药物治疗,比较两种方法在心肺复苏中的有效率。结果萨勃机组在心肺复苏中的有效率明显高于徒手心肺复苏组,差异有统计学意义（P〈0.05）,但对患者的存活率无明显优势（P〉0.05）。结论 1007型THUMPER心肺复苏机在心肺复苏抢救中有效率得到提高,值得临床推广。     

心肺复苏后脑复苏的研究进展

在过去的10年里,美国心脏学会进行了大量的基础和临床研究,于2010年10月颁布了《2010美国心脏协会心肺复苏及心血管急救指南》［1］。新指南强调了早期心脏按压的重要性,简化了心肺复苏的流程,对心脏按压的质量提出了新的要求。随着医疗技术的发展,近年来心脏骤停后自主循环恢复的成功率虽然已经有了一定的提高,但是患者长时间存活率并未提高,仍有25％~50％的心跳骤停患者虽然恢复了自主循环,但仅有2％～10％的患者不出现神经功能缺陷［2］。临床上心肺复苏后脑功能完全恢复非常少见。     

心肺复苏后脑缺血再灌注损伤治疗理念及相关动物模型研究进展

心肺复苏后脑缺血再灌注损伤是一个复杂的病理生理变化过程,由多种损伤机制共同参与。自心肺复苏后系统性综合治疗和亚低温治疗在临床上广泛应用后,目前已有多种治疗理念在不同的动物实验和动物模型基础上被提出,包括缺血预处理、药物预处理、缺血后处理、和药物后处理,而后吸入麻醉药对心肺复苏后脑缺血再灌注损伤的保护作用受到了人们的重视,而七氟烷后处理已经成为目前研究的热点之一。为了指导临床上的心肺复苏,人们一直在利用不同动物模型,探究不同保护方法,寻找有效的脑保护药物。而各种治疗理念的提出均是建立在动物实验和动物模型的基础上,窒息性心肺复苏模型模拟围术期气道梗阻,能较贴切的复制临床上由窒息引起的心肺复苏后脑损伤,对将来指导临床复苏具有重大意义。     

Cardiopulmonary arrest and resuscitation in Landrace/Large White swine: a research model

Sudden cardiac death (SCD) is a field of continuous research. In order to answer various questions regarding SCD, several animal models have been developed. The aim of the present study is to describe our experimental model of inducing cardiac arrest in Landrace/Large White pigs, and then resuscitated according to the International Guidelines on resuscitation. Fifteen Landrace/Large White pigs were anaesthetized and intubated while spontaneously breathing. The left and right jugular veins, as well as the femoral and the carotid arteries, were surgically prepared. Induction of cardiac arrest was achieved by using an ordinary rechargeable lithium battery, through a pacemaker wire inserted into the right ventricle. The typical Advanced Life Support (ALS) protocol was followed, and in case of restoration of spontaneous circulation, the animals were further evaluated for 30 min. Seven animals were successfully resuscitated using this protocol, whereas eight failed resuscitation efforts. Successful resuscitation was contingent on the restoration of the levels of coronary perfusion pressure and PETCO(2) during chest compressions. Among the different ways of inducing cardiac arrest, the ordinary lithium battery is a simple, safe and valuable technique. Landrace/Large White pigs' baseline haemodynamics closely resemble human haemodynamics, making the breed a favourable model for resuscitation.     

Nitrite therapy is neuroprotective and safe in cardiac arrest survivors

Cardiac arrest results in significant mortality after initial resuscitation due in most cases to ischemia-reperfusion induced brain injury and to a lesser degree myocardial dysfunction. Nitrite has previously been shown to protect against reperfusion injury in animal models of focal cerebral and heart ischemia. Nitrite therapy after murine cardiac arrest improved 22 h survival through improvements in myocardial contractility. These improvements accompanied transient mitochondrial inhibition which reduced oxidative injury to the heart. Based on preliminary evidence that nitrite may also protect against ischemic brain injury, we sought to test this hypothesis in a rat model of asphyxia cardiac arrest with prolonged survival (7d). Cardiac arrest resulted in hippocampal CA1 delayed neuronal death well characterized in this and other cardiac arrest models. Nitrite therapy did not alter post-arrest hemodynamics but did result in significant (75%) increases in CA1 neuron survival. This was associated with increases in hippocampal nitrite and S-nitrosothiol levels but not cGMP shortly after therapy. Mitochondrial function 1h after resuscitation trended towards improvement with nitrite therapy. Based on promising preclinical data, the first ever phase I trial of nitrite infusions in human cardiac arrest survivors has been undertaken. We present preliminary data showing low dose nitrite infusion did not result in hypotension or cause methemoglobinemia. Nitrite thus appears safe and effective for clinical translation as a promising therapy against cardiac arrest mediated heart and brain injury.     

Examination of Physiological Function and Biochemical Disorders in a Rat Model of Prolonged Asphyxia-Induced Cardiac Arrest followed by Cardio Pulmonary Bypass Resuscitation

Background

Cardiac arrest induces whole body ischemia, which causes damage to multiple organs particularly the heart and the brain. There is clinical and preclinical evidence that neurological injury is responsible for high mortality and morbidity of patients even after successful cardiopulmonary resuscitation. A better understanding of the metabolic alterations in the brain during ischemia will enable the development of better targeted resuscitation protocols that repair the ischemic damage and minimize the additional damage caused by reperfusion.

Method

A validated whole body model of rodent arrest followed by resuscitation was utilized; animals were randomized into three groups: control, 30 minute asphyxial arrest, or 30 minutes asphyxial arrest followed by 60 min cardiopulmonary bypass (CPB) resuscitation. Blood gases and hemodynamics were monitored during the procedures. An untargeted metabolic survey of heart and brain tissues following cardiac arrest and after CPB resuscitation was conducted to better define the alterations associated with each condition.

Results

After 30 min cardiac arrest and 60 min CPB, the rats exhibited no observable brain function and weakened heart function in a physiological assessment. Heart and brain tissues harvested following 30 min ischemia had significant changes in the concentration of metabolites in lipid and carbohydrate metabolism. In addition, the brain had increased lysophospholipid content. CPB resuscitation significantly normalized metabolite concentrations in the heart tissue, but not in the brain tissue.

Conclusion

The observation that metabolic alterations are seen primarily during cardiac arrest suggests that the events of ischemia are the major cause of neurological damage in our rat model of asphyxia-CPB resuscitation. Impaired glycolysis and increased lysophospholipids observed only in the brain suggest that altered energy metabolism and phospholipid degradation may be a central mechanism in unresuscitatable brain damage.     

A Rat Model of Ventricular Fibrillation and Resuscitation by Conventional Closed-chest Technique

A rat model of electrically-induced ventricular fibrillation followed by cardiac resuscitation using a closed chest technique that incorporates the basic components of cardiopulmonary resuscitation in humans is herein described. The model was developed in 1988 and has been used in approximately 70 peer-reviewed publications examining a myriad of resuscitation aspects including its physiology and pathophysiology, determinants of resuscitability, pharmacologic interventions, and even the effects of cell therapies. The model featured in this presentation includes: (1) vascular catheterization to measure aortic and right atrial pressures, to measure cardiac output by thermodilution, and to electrically induce ventricular fibrillation; and (2) tracheal intubation for positive pressure ventilation with oxygen enriched gas and assessment of the end-tidal CO₂. A typical sequence of intervention entails: (1) electrical induction of ventricular fibrillation, (2) chest compression using a mechanical piston device concomitantly with positive pressure ventilation delivering oxygen-enriched gas, (3) electrical shocks to terminate ventricular fibrillation and reestablish cardiac activity, (4) assessment of post-resuscitation hemodynamic and metabolic function, and (5) assessment of survival and recovery of organ function. A robust inventory of measurements is available that includes – but is not limited to – hemodynamic, metabolic, and tissue measurements. The model has been highly effective in developing new resuscitation concepts and examining novel therapeutic interventions before their testing in larger and translationally more relevant animal models of cardiac arrest and resuscitation.     

Brain nuclear DNA survives cardiac arrest and reperfusion.

Iron-mediated peroxidation of brain lipids is known to occur during reperfusion following cardiac arrest. Since in vitro damage to DNA is caused by similar iron-dependent peroxidation, we tested whether free radical damage to genomic DNA also develops during reperfusion following cardiac arrest and resuscitation. Genomic DNA was isolated from the cerebral cortex in (i) normal dogs, (ii) dogs subjected to a 20-min cardiac arrest, and (iii) dogs resuscitated from a 20-min cardiac arrest and then allowed to reperfuse for 2 or 8 h. DNA strand nicks were evaluated by in vitro labeling of newly created 3' and 5' termini. DNA base damage was evaluated utilizing reaction with piperidine prior to labeling of 5' termini. The 3' DNA termini were labeled before and after digestion with exonuclease III, and the 5' DNA termini were labeled before and after treatment with piperidine. In vitro experiments with genomic DNA damaged by oxygen radicals verified that these labeling methods identified radical damage. In the experimental animal groups, terminal incorporation and electrophoretic mobility of brain nuclear DNA are not significantly changed either by 20 min of complete brain ischemia or during the first 8 h of reperfusion. We conclude that genomic DNA is not extensively damaged during cardiac arrest and early reperfusion, and therefore such DNA damage does not appear to be an important early aspect of the neurologic injury that accompanies cardiac arrest and resuscitation.     

Possibility of brain recovery after electrically induced cardiac arrest and reanimation in dogs

The changes of aortic blood pressure (BP), carotid artery flow (CAF), power spectrum of analysed EEG, neurologic deficit and survival rate were determinated in dogs after experimental cardiac arrest of different duration. Following artificially induced ventricular fibrillation of 1, 4, 10, 12 and 15 min duration successful cardiopulmonary resuscitation was performed in 30 experimental animals. Alterations of power spectrum during and after reanimation procedures, severity of the neurologic state and the survival rate deteriorated in parallel with the increasing duration of circulatory stop. Advantageous effect of direct heart massage could be demonstrated by the measuring circulatory parameters. Following a 15 min fibrillation, all animals were lost in a few hours despite the successful restoration of circulation and ventilation. Considering the various experimental and clinical conditions experimental cardiac arrest lasting for 12 min seems to be useful in extrapolating the results to human cases. The suggested model allows to study the brain function recovery after circulatory stop and resuscitation.     

CARDIAC ARREST DURING ANESTHESIA

In cases of acute cardiac arrest from transient or reversible causes resuscitation is a distinct possibility. Prompt action is of the utmost importance.The sequelae of cardiac arrest will depend on the degree of anoxia that has developed and the amount of irreversible damage to brain tissue. Efficient manual artificial circulation, begun immediately, can prevent such damage.Four cases of cardiac arrest are described. Sudden circulatory collapse, which may or may not imply cardiac arrest, is not uncommon during surgical procedures. Usually the patient recovers quickly when treatment is prompt.     

The use of mice and rats as animal models for cardiopulmonary resuscitation research

Cardiopulmonary resuscitation (CPR) after the induction of cardiac arrest (CA) has been studied in mice and rats. The anatomical and physiological parameters of the cardiopulmonary system of these two species have been defined during experimental studies and are comparable with those of humans. Moreover, these animal models are more ethical to establish and are easier to manipulate, when compared with larger experimental animals. Accordingly, the effects of successful CPR on the function of vital organs, such as the brain, have been investigated because damage to these vital organs is of concern in CA survivors. Furthermore, the efficacy of several drugs, such as adrenaline (epinephrine), vasopressin and nitroglycerin, has been evaluated for use in CA in these small animal models. The purpose of these studies is not only to increase the rate of survival of CA victims, but also to improve their quality of life by reducing damage to their vital organs after CA and during CPR.     

2月龄和4月龄大鼠制备心肺复苏模型后神经功能评价及亚组评分的比较

目的：本研究旨在选择适合的大鼠,对比2月龄大鼠与4月龄大鼠CPR后神经功能评分及亚组评分,摸索利用不同月龄的大鼠CPR的可行性。方法通过严格监测SD大鼠制备模型过程中的心电、血压生理指标、测定各组大鼠不同时间点的神经功能缺失评分以及神经功能亚组评分、对比制备4月龄和2月龄大鼠心肺复苏模型的稳定性。结果电刺激致室颤,4月龄组大鼠的成模率为87.5％,远高于2月龄组大鼠,而死亡率无差异;在电刺激诱发CA过程中造成的血压变化,4月龄组大鼠明显低于2月龄组大鼠,存在极显著性差异（ P ＜0.01）;4月龄组大鼠与2月龄组大鼠CPR后各时间点的神经功能评分无统计学差异,而4月龄组大鼠与2月龄组大鼠的神经功能亚组评分在不同时间点,存在显著差异（P ＜0.05）,4月龄大鼠与2月龄大鼠对比,心肺复苏后脑损伤的程度加重。结论4月龄大鼠更适合制备心肺复苏模型,该月龄组的大鼠制备模型成模率高,脑损伤程度重,更适合于用于心肺复苏的基础研究及治疗评价。