要想睡得好 可以这样吃

葱炒猪心功能补心安神。原料猪心150克,葱50克,姜3克,味精适量,料酒、酱油各10克,水淀粉8克,植物油50克。做法(1)猪心劈4瓣,洗净切片;葱洗净,切段。(2)锅加油烧至七成熟时,下猪心,迅速炒熟,捞出。锅上火,加少许油,姜葱煸香,下猪心,调料,勾芡出锅。适用人群神经衰弱而见惊悸失眠者可作为佐餐小菜,经常食用。小贴士猪心具有补心、定惊、安神的作用。小贴士莴笋中钾离子的含量丰富,是钠盐含量的27倍,有利于维持神经的正常功能。功能养心安神,益气助眠。原料熟腊肉250克,莴笋150克,调料适量。做法(1)将腊肉去皮,切薄片;莴笋去皮洗净,切成片。(2)…     

心脑血管术后药膳调理

双参炖猪心 原料：党参、丹参各30g,猪心1只,葱、姜、食盐、料酒各少许。 制作：先将党参、丹参分别洗净备用;把猪心剖开,去筋膜,洗净血水,放人沸水锅中炖煮3～5分钟后,捞出晾凉。     

猪心枣仁汤

每年3月6日左右是24节气的第3个节气——惊蛰。此时天气渐渐回暖，春雷开始震响，蛰伏在泥土里的冬眠动物和多种昆虫感于春季温暖，震惊而出。惊蛰处于冬春季节交替时期，气温变化幅度较大，并会出现雷雨或连续阴雨。     

猪心塑化标本的制作

目的：利用塑化标本制作技术,制作满足解剖学教学的心标本。方法：用经福尔马林固定的猪心,经常规解剖显示其大体结构,利用一系列塑化处理技术处理标本。结果：该标本无明显异味,显示直观,经久耐用,保存和携带方便,便于教学。结论：该方法制作的心标本能够满足教学及科研使用。     

艾司洛尔作为停搏液对离体猪心保护作用的实验研究

目的探讨艾司洛尔作为停搏液对离体猪心的保护作用及可能的机制。方法建立Langendorff猪离体心脏灌注模型。健康家养猪18头,雌雄不拘。随机分为KHB组（KHB液组）、ST组（St．ThomasⅡ停搏液）、ES组（艾司洛尔组）,每组6只。开胸立即取出心脏,置于Langendorff灌注装置上,用充氧的KHB液平衡灌注20min后,分别用两种不同的停搏液[艾司洛尔1mmol／L＋（95％O2＋5％CO2）和St．ThomasⅡ]液灌注,每隔10min灌注一次,灌注压为75mmHg（1mmHg=0．133Kpa）,温度37℃,时间为60min。停止停搏液灌注后,即恢复KHB再灌注60min。连续监测血流动力学的变化。在KHB灌注20min和KHB再灌注30min后记录心率（HR）。在KHB灌注20min、停搏液灌注30min、60min和KHB再灌注30min后留取5ml的灌注液检测心肌肌酸激酶同功酶（CK—MB）、肌钙蛋白I（cTnI）。KHB液再灌注60min后切取两小块心肌组织分别用于测湿干重比和测定ATP含量。结果KHB灌注20min时各组之间比较,心率无统计学意义（P〉0．05）;再灌注30min后,KHB组的心率明显低于ST组和ES组（P〈0．05）。ES组心肌含水量、CK—MB、cTnI和左心室舒张末压（LVEDP）均明显低于KHB组（P〈0．05）;而冠状动脉流量（CF）、心肌组织中ATP含量均显著高于KHB组（P〈0．05）。ES组与St．ThomasⅡ组相比,上述指标的变化差异无统计学意义（P〉0．05）。结论艾司洛尔可作为停搏液对离体猪心有良好的保护。     

利用动物器官补充人体解剖教学的研究

人体标本来源的缺乏限制了其在人体解剖实验教学中的应用,利用新鲜动物器官接近人体结构、能真实展示活体形态的特．董,将其作为解剖学人体标本的补充,不仅弥补学生观察实物标本的不足,而且更能激发学生的学习兴趣,进一步提高解剖教学质量。     

科学吃才能安全补

我看过这样一个笑话．一对夫妻一起吃饭时，丈夫说起吃经来，说：“吃猪脑是补脑的，吃猪蹄是长筋骨的，总之吃什么补什么。”第二天妻子买来猪心、猪肝给丈夫吃．丈夫问妻子今天为什么买这些给他吃．妻子说：“平时你对我没心没肝的，今天我买猪心猪肝给你这个没心没肝的人补补呀!”     

药食同源话当归

祖国医学认为：当归味甘辛、性温,作用趋向能上能下,可攻可补,具有补血活血、凋经止痛、祛淤生新、润肠通便之功能。现代医学研究证明,当归富含挥发油、棕榈酸、β-谷甾醇、蔗糖、烟酸、叶酸、亚叶酸、氨基酸、生物碱、维生素B12维生素E,以及钾、钙、镁、锌、硒等矿物质。其临床主要用途有：(1)补血养肝,治疗肝血虚所致的头晕目花、四肢乏力、月经后延或量少色淡等症;     

健脑益智药膳方解

芝麻猪心煲 原料：黑芝麻60g,百合30g,红枣15枚,猪心1个,生姜2片,食盐少许。 制法：先将百合、红枣、生姜分别用清水洗净,红枣去核,生姜去皮切片;将猪心剖开,用清水洗净,切成片状,待用;将黑芝麻放锅内炒香,备用。用净瓦煲1个,加入适量清水,待水烧沸后投入原料,煲1小时后再加盐调味即可食用。功用：补血养滋,健脑强身。     

保留冠状动脉的猪心螺旋形心室肌带的解剖

Objective Based on the Helical Ventricular Myocardial Band (HVMB) theory proposed by Torrent-Guasp,the ventricular myocardial hand extends from the root of the pulmonary artery to the root of the aorta with two helical coils.This new theory is considered as a revolutionary concept for further understanding the global, three-dimensional and functional architecture of the ven- tricular myocardium. No repot had described techniques for disecting HVMB while keepin～ the integrity of the coronmy artery sys- tern. We explored techniques for dissecting HVMB in swine.Methads 33 fresh swine hearts were randomly divided intoll groups, 3 bearts in each. 160% barium sulfate (type I)suspmmion was injected into the coronary artery system. The coronary arteries were li- gated. The strial tissue was removed following puuing the hearts in boiling water then cooling for several hours. The superficial coro- nary vessels and fat tissue around the atrio-ventricular taxi inter-ventricular sulcus we～'e preserved. Some branches of the left anterior descending artery, distal segment, of posterior descending branch, and middle and distal segment of obtuse marginal branches were mu- tilated appropriately. HVMB dissection was completed with fingers in accordnce with Torrent Guasp' s technique. Results A contin- ued bundle of muscle, originated at the root of pulmonary artery and ended at the root of aorta, was unwrapped along the major dire- tion of the cardiac muscle fiber in all of the 33 hearts with spating of the coronary artery. The swine hearts' ventricular myocandium was cumosed of two loops, with basal loop firm the root of the pulmonart artery to the anterior papillary muscle and apical from the beginning of the anterior papillary muscle to the root tithe aorta. Each loop consisted of two segments: the right segment-coincid- ing with the right ventricular free wall and the left segment-coinciding with the basal d the left ventricular free wall. Posterior papillary muscle, which belongs to the descendant segment, denmrcated the border between the descendent and the ascendant of the HVMB's apical loop. Conclusion Although controversies about the theory of the HVMB remain, we have dissected the HVMB in the swine hearts' ventricular myocardium successfully with sparing of the coronary artery systems. This dissection procedure provides technical information for the studies of associated diseases based on the theory of HVMB.